Apresentação
"Biology is wet and dynamic" (Howard Berg )
"Navegar é preciso" (Fernando Pessoa)
Este minicurso tem dois objetivos. O primeiro é
apresentar um rápido (portanto extremamente incompleto…) panorama
de temas em movimento biológico que tiveram um extraordinário
desenvolvimento nos últimos dez anos, em particular os "motores
moleculares". Assim, nossa meta será cumprida se for possivel motivar,
complementarmente, o minicurso do Prof. Marcelo Magnasco "Problemas matematicos
em Bioinformática". Recomendamos neste sentido ver antecipadamente
seu web site
www.asterion.rockefeller.edu/marcelo/marcelo.html,
www.rockefeller.edu/labheads/magnasco/magnasco.htm
Outras informações sobre bioinformática
podem ser vistas no site de Laura Landweber
http://www.molbio.princeton.edu/faculty/landweber.html:
Hoje em dia os mecanismos moleculares do movimento
biológico começam a ser entendidos. Como um matemático
poderia iniciar-se nestes temas? O Prof. Berg nos recomendou: Molecular
Cell Biology by Darnell, Lodish e Baltimore (Alberts et al., Essential
Cell Biology, Garland 1998 é um pouco menos enciclopédico.
Stryer's Biochemistry, 4th Ed., Freeman, 1995 também é excelente).
O segundo objetivo do minicurso é divulgar alguns
resutados sobre o movimento de microorganismos (limite Stokesiano) e da
zoo-biofluidinâmica (limite Euleriano).
historia: reynolds
navier
stokes
A biofluidinâmica (cujo maior expoentes foram G.I.
Taylor e James Lighthill)) também rege o movimento dos fluidos internos
(sangue, secreções) nos animais. Diremos algo sobre o impacto
da biologia na robótica ("zoobótica"). E’ extraordinário
que, do ponto de vista matemático, a modelagem da natação
e do vôo utiliza uma mesma equação diferencial parcial,
a "equação de Navier-Stokes". Um parâmetro importante
nesta equação é o número de Reynolds
( Re ), que mede a razão entre as forças inerciais e as forças
viscosas. Para os microorganismos, Re é tão pequeno que pode
ser tomado = 0 e obtemos a "equação de Stokes", uma equação
linear bem mais simples. Poderosos métodos matemáticos permitem
explicar os movimentos de ciliados e flagelados de vários formatos.
No movimento de pássaros e peixes, que já fascinava Leonardo
da Vinci, Re é muito alto. Mas não podemos tomar diretamente
a viscosidade nula, Re = infinito, o que forneceria a "equação
de Euler". Isto porque na vizinhança do corpo, devido a seus movimentos,
aparecem efeitos de "camada limite" (boundary layer), criando vórtices
e provocando turbulência, fenômenos de enorme complexidade.
Eis uma bibliografia básica:
historia: taylor
lighthill starkisland
David B. Dusenbery, Life at small scale – the behavior
of microbes, Scientific American Library, 1996.
Hans J. Lugt, Vortex flow in nature and technology, J.
Wiley, 1983.
Stephen Childress, Mechanics of swimming and flying, Cambr.
University Press, 1981.
James Lighthill, Mathematical Biofluiddynamics, Siam,
1975.
Howard Berg, Random walks in Biology, Princeton Univ.
Press, 1993.
Muitas outras fontes você encontrará em minhas
notas:
Microbiofluidinamica parcial.ps
e em versão completa: completo.ps
(5000 Kb)
Problems and progress in Microswimming, com Richard Montgomery
e
Kurt Ehlers, J.Nonlinear Science 6, 507-541,
1996. probprog.ps
Spectral methods for Stokes flows, com M.A.Raupp, J.D.Fernandez,
K. Ehlers e R. Montgomery, Computational and Applied Mathematics,
17 :3, 343-371, 1998. spectral.ps
On efficiency calculations for nonholonomic locomotion
problems, com J.D.Fernandez,
Reports on Mathematical Physics, 42: 1/2, 165-183,
1998. eficiencia.ps
Movimiento de microorganismos, La Gaceta de la Real Sociedad
Matematica Espanola, 2:3 1999, 423-445, 1999. gaceta.ps
(artigo divulgatorio)
Movimiento Biologico, minicurso en Univ. Intl. Menendez
Pelayo, 2000 movbiosan.ps
Low Reynolds number Swimming in two dimensions,
com Kurt Ehlers, Alexandre Cherman, Joaquin Delgado, Richard Montgomery
e Fernando Duda, Proc. HAMSYS98, World Scientific, editado
por Ernesto Lacomba, 2000. mexico.ps
K.Ehlers, J. Koiller, Optimal gaits and efficiencies in
microswimming, Proceedings METMBS2000, Las Vegas lasvegas.ps
K. Ehlers et al., Do cyanobacteria swim using traveling
surface waves? Proc. Nat. Acad. USA 93, 8340-8343,
1996 ehlers.pdf
(see brahamsha.pdf
hansel.pdf )
A quantidade de temas biológicos que permitirão
novos aportes matemáticos é enorme. Um tema não tratado
aqui é a morfogênese, que permite abordagens clássicas
tão diferentes quanto as de Turing, D'Arcy Thompson, e Thom.
Se for preciso mencionar apenas um site com os principais
temas da Biologia Matemática na atualidade, recomendo o do ano especial
na Universidade de Minnesota (www.ima.umn.edu;
olhar workshops 98-99) Para se procurar bibliografia em biociencias, o
site mais detalhado é o Medline, em www.cos.com
(Community of Science). Como fonte geral, o site da Enciclopédia
Britanica, www.britannica.com
.
É possivel encontrar informações
maravilhosas na internet, ainda que não possamos escapar da
sensação de nos perdermos num dos labirintos de Jorge Luis
Borges… Os sites mencionados abaixo formam obviamente uma lista muito incompleta,
e com certeza deixamos de fora muitos sites importantes. Não há
tãopouco uma organização muito coerente, devido a
premência do tempo que tivemos para a preparação do
texto. Alguns trechos em inglês foram simplesmente copiados
dos sites para dar uma idéia prévia dos assuntos.
Para dar uma idéia do número de publicações,
basta ver que usando fazendo uma busca em Science, obtivemos há
algum tempo, para “anywhere in article: molecular motors”: 3810 !
"Isto tinha de ser por concurso?"
Fig.3 (Mysterious swimmer)
The cyanobacteria Synecococcus is 2 microns long and 1 micron
wide, swims fast at 25 microns/sec. Kurt Ehlers’ model is deceivingly simple.
Waves
propagate tangentially along the membrane. The resulting motion of the
organism is (counterintuitively) in the same direction. This hypothesis
is presently being under investigation.
Cyanobacteria are important in photosynthesis. Some can produce toxic
substances in drinking water supplies (See http://bilbo.bio.purdue.edu/www-cyanosite.)
O que é a biomatemática
Para termos uma idéia das muitas areas de atuação
da Matemática na Biologia, podemos examinar o programa de alguns
workshops no ano espacial realizado entre 1998 e 1999 no Institute for
Mathematics and its Applications, University of Minnesota ( www.ima.umn.edu
; ver em "Program for 1998-99")
Os worshops 5,6,12 são de especial interesse para
nosso curso.
Os organizadores foram: Lisa Fauci , Tulane University;
Simon A. Levin, Princeton University; James D. Murray, University of Washington;
Alan Perelson (Chair), Los Alamos Natl. Lab.; Michael Reed, Duke University.
"Significant applications of mathematics to biology have
occurred for nearly a century, starting from the early work of Vito Volterra
and Alfred Lotka oninteracting populations, and maturing through fundamental
work in population genetics (Haldane, Fisher, and Wright), epidemiology
(Ross, Kermach and MacKendrick), development (Turing) and neurobiology
(Hodgkin and Huxley, Fitzhugh and Nagumo, McCulloch and Pitts). Much of
this research stimulated important contributions by other mathematicians
(Kolmogorov, Petrovsky, Piscunox, Karlin, etc.); in general, however, until
the past 10--20 years, communication between mathematicians and biologists
remained problematical; much work in mathematical biology was relatively
sterile, unsullied by contact with data, while experimental work suffered
from a lack of theoretical generality.
The situation has changed dramatically in the past decade
or so. Today's biologists are, in many areas, very sophisticated mathematically;
mathematicians have learned the importance of becoming immersed in data;
and the spectrum of practitioners has filled in, providing a continuum
of highly mathematical work to collaborations. New and exciting areas (e.g.
molecular biology, epidemiology and immunology) have opened up to mathematical
investigations. A century of research has elucidated fundamental mechanisms
in evolution, collective phenomena and pattern formation, and laid the
foundations for more specialized modeling; and the development of new computational
tools has greatly expanded the potential both for fundamental studies and
for communications.
Thus the time is right for this special year at the IMA,
built upon a selected series of workshops highlighting some of the mathematical
challenges emerging from the consideration of biological issues, and endeavoring
to show how the mathematics can be applied to the resolution of those issues.
This program focuses on some particularly rich areas of investigation,
complementing activities which have been carried out at the IMA in MRI,
molecular biology and neurobiology in earlier years."
September - December, 1998: Theoretical Problems In Developmental
Biology and Immunology
Tutorial: Mathematical and Computational Issues in Pattern
Formation, September 3-4, 1998
Workshop 1: Pattern Formation and Morphogenesis: The Basic
Process, September 8-12, 1998
Workshop 2: Pattern Formation and Morphogenesis: Model
Systems, September 14-18, 1998
Tutorial: Immunology, Cell Signaling, the Physiology of
the Immune System and the Dynamics of the Immune Response, October 8-9,
1998
Workshop 3: Immune System Modeling & Cell Signaling,
October 12-16, 1998
Period of Concentration: Forging an Appropriate Immune
Response as a Problem in Distributed Artificial Intelligence, October 19-23,
1998
Tutorial: Mathematical Models of AIDS, November 6, 1998
Workshop 4: Dynamics and Control of AIDS, November 9-13,
1998
Minisymposium: Cancer, November 15-19, 1998
January - March, 1999 Mathematical Problems in Physiology
***** Workshop 5: Cell Adhesion and Motility, January
4-8, 1999
***** Workshop 6: Computational Modeling in Biological
Fluid Dynamics, January 25-29, 1999
Workshop 7: Membrane Transport and Renal Physiology, February
8-12, 1999
Tutorial: Endocrinology: Mechanism of Hormone Secretion
and Control, February 14, 1999
Workshop 8: Endocrinology: Mechanism of Hormone Secretion
and Control, February 15-19, 1999
Tutorial: Audition, March 5, 1999
Workshop 9: Audition, March 8-12, 1999
April - June, 1999 Dynamic Models of Ecosystems and Epidemics
Workshop 10: Local Interaction and Global Phenomena in
Vegetation and Other Systems, April 19-23, 1999
"HOT TOPICS" Workshop: Challenges and Opportunities in
Genomics: Production, Storage, Mining and Use April 24-27, 1999
Tutorial: Introduction to Epidemiology and Immunology,
May 13-14, 1999
Workshop 11: Mathematical Approaches for Emerging and
Reemerging Infectious Diseases, May 17-21, 1999
***** Workshop 12: From Individual to Aggregation: Modeling
Animal Grouping, June 7-11, 1999
"HOT TOPICS" Workshop: Decision Making Under Uncertainty:
Energy and Environmental Models, July 20-24, 1999.
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Links para Biologia Matemática
Sociedades Científicas
Sugiro uma visita inicialmente ao site da Society for Mathematical
Biology
( http://www.smb.org).
Em http://www.smb.org/sites.shtml
você encontrará uma grande quantidade de links!
"Our society is committed to attracting members from all
countries, and from a wide spectrum of interests. We hope to be able to
provide a forum for discussion of research in biology, mathematical biology,
and mathematics applied to or motivated by biology. Interdisciplinary research
such as biophysics, computational biology, and many other similar realms
are a growing part of our mandate. We hope that you will help broaden our
horizons with your particular approach or research interests by joining
thesociety and participating in our meetings."
No site da Biophysics Society, você encontrará
todas as informações biológicas de interesse.
http://www.biophysics.org/biophys/society/biohome.htm
Em particular recomendamos a coleção de
monografias "on line"
http://biosci.umn.edu/biophys/OLTB/Textbook.html
Eis alguns dos temas que se pode encontrar: Bioenergetics
and Photosynthesis , Cell Biophysics , Channels, Receptors and Transporters,
Computational Biology, Electrophysiology, Intermolecular Forces, Kinetics
of Biological Systems , Membranes, Muscle and Cell, Contractility, Nucleic
Acids, Photobiophysics, Proteins, Supramolecular Assemblies, Diffraction
and Scattering, EPR, NMR , Separations and Hydrodynamics, Sequence Analysis,
Single Molecule Techniques, Spectroscopy, Thermodynamics, Becoming a Biophysicist,
Teaching Biophysics - published in Biophysical Journal , BJ Supplements
and Computer Programs
Outras sociedades científicas das mais importantes
são: American Physics Society www.aps.org,
o American Institute of Physics, www.aip.org,
American Mathematical Society, www.ams.org
e a Society for Industrial and Applied Mathematics www.siam.org.
Visitando estes sites, ficará claro o enorme interesse que a biologia
tem despertado.
A http://www.biolinks.com/
uma organização que se define como uma "Internet Search Engine
Designed by Scientists, for Scientists".
Sites em Universidades podem ser vistos diretamente. Para
mencionar apenas um, sugerimos http://www.mcb.harvard.edu/BioLinks.html,
em Harvard.
Links educacionais
Um site diretamente accessivel a alunos e professores de secundário,
é "Mathematical Biology pages de Brandeis University" (evolução,
resposta de sinapse, predador-presa, e muito mais!)
www.bio.brandeis.edu/biomath/top/html
http://www.bio.brandeis.edu/biomath/menu.html
No UTK Mathematical Life Sciences Archives home page:
http://archives.math.utk.edu/mathbio/
você encontrará vários cursos preparados.
E’ uma coleção de "Life Science Pages" organizada
por E. Dobos, L. Gross and C. Zimmermann na University of Tennessee, com
o apoio da National Science Foundation Undergraduate Course and Curriculum
Program.
Tutoriais em Biologia estrutural, produzidos pelo National
Institute of Health, USA: http://cmm.info.nih.gov/modeling/tutorials.html
Para história da Física, recomendamos: http://www.aip.org/history/
Em http://www.aip.org/history/web-link.htm
há links para história de outras ciências.
Em http://www.nobelprizes.com/
e em www.nobel.se você encontrará
biografias dos detendores de premios Nobel.
Para história da Matemática: http://www-history.mcs.st-andrews.ac.uk/history/Mathematicians
http://www.petersons.com/
(site geral em assuntos educacionais)
Sites sobre a vida marinha e terrestre
Site do Marine Biological Laboratory: catálogo
da zoologia marinha.
http://www.mbl.edu/MRC/CATALOG/
Para quem está interessado em fazer um insetos
e animais polizadores, veja o site do Smithsonian Institute, com lindas
fotos de insetos e aves participantes deste importante aspecto da ecologia.
web2.si.edu/pollinators
www.si.edu/whatsnew/body_whatsnew.htm
www.smithsonianmag.si.edu/smithsonian/issues00/apr00/pollen.html
www.pollinators.com/
http://www.geocities.com/~pollinators/
"The coevolution of flowering plants and their pollinators
has filled the earth with a diversity of life-forms: a quarter-million
species of plants, and almost as many animal pollinators, including at
least 1,200 vertebrates. The range of pollinators is staggering — in addition
to birds, bees and bats, plants rely on such creatures as beetles, butterflies,
ants, spiders, earthworms, parrots, even a New Zealand gecko and the pygmy
gliding possum of Australia."
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Um exemplo de trabalho em biomatemática: hemodinâmica
Um tema tradicional da biomatemática é o
estudo do fluxo sanguíneo (hemodinâmica). Não trataremos
deste tema nestas notas, mas apenas mencionamos o o trabalho do grupo do
Prof. Charles S. Peskin, do and Courant Institute of Mathematical Sciences,
com quem colabora meu colega Alexandre Roma, da Universidade de São
Paulo. Sites relevantes são (incluindo outras áreas de trabalho):
http://www.cns.nyu.edu/associates/Peskin.html
http://www.psc.edu/science/Peskin/CWSA.html
http://www.psc.edu/science/Peskin/Boundary.html
" Charles Peskin, David McQueen, and their group at the
Courant Institute of Mathematical Sciences of New York University are well
known for their heart modeling. Their model, originally in 2D but now 3D,
combines tissue and fluid mechanics and permits the examination of the
performance of modeled artificial heart valves for any of the four valves
of the human heart. The two-dimensional model, in fact, led to a patent
on such a valve.
It was the advent of the NSF supercomputer centers, Peskin
says, that permitted his group to extend their computations from two to
three dimensions. The calculation and examination of a single heartbeat
in the present 3D model has taken approximately one week of CPU time on
a single PSC C90 processor. When the code was parallelized recently to
use all 16 processors, Peskin and McQueen obtained a speedup of a factor
of 10. The group is currently reorganizing the code to take advantage of
domain decomposition methods and to make use of the powerful IBM SP-2,
Cray T3D, and similar machines.
Interestingly, Peskin notes, both the original 2D model
and the first 3D model had defects corresponding to human mitral valve
prolapse, a common but non-life-threatening heart murmur, and the models
had to be corrected to simulate a nondefective heart. "That the models
got 'sick' the way humans do is a kind of validation of the approach,"
Peskin says.
An important application of the model will be to simulate
valve action, and a complete run of several heartbeats will be used to
determine whether a given valve design creates any regions of stagnation
(low-velocity flow) in the circulating blood. Such regions can nucleate
the formation of clots, and clot formation can threaten both the valve
action and (if the clot breaks free) other regions of the circulation.
Clot formation is, in fact, the chief risk associated with artificial heart
valves.
High resolution is also needed to make the Reynolds number
(Re) realistic. To use a realistic Re for blood flow in the heart direction.
Fortunately, the flow pattern of blood in the heart is not very sensitive
to the Reynolds number, and improvements in numerical methodology, such
as local mesh refinement near boundaries or the use of entirely grid-free
methods, may make it possible to avoid the extreme computational requirements
implied by such a refinement of a uniform grid. Nevertheless, a fully satisfactory
computation of blood flow in the heart will require a substantial increase
in computer power, Peskin says--possibly as great or greater than the increase
that was needed to move from two to three dimensions.
Increased computer power is needed not only to do the
current computation more correctly, but also to bring in additional phenomena
that are highly relevant to blood flow in the heart. Two examples of such
phenomena are the electrical activity that coordinates and controls the
heartbeat and the dynamics of the blood clotting process, which is important
in evaluating the function of prosthetic cardiac valves. Models of these
phenomena are being developed separately from the model of cardiac mechanics
described here. Microscopic and macroscopic models of the clotting process
are being developed by Aaron Fogelson, a former student of Peskin's who's
now at the University of Utah. Ultimately, Peskin and McQueen hope to combine
such models with their mechanical model to increase its realism and predictive
power. Again, a dramatic increase in computer power would be required.
"My situation is absolutely typical," Peskin insists.
"Almost any time-dependent problem in three space dimensions pushescurrent
computational capabilities to their limits. Inadequate resolution can lead
to incorrect conclusions and to inappropriate attempts to 'fix' a model
that isn't really broken."
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Movimento de Microorganismos
nossos
trabalhos
Para dar uma pequena idéia desta área, começamos
um um artigo que nós escrevemos para o livro
"Fotografiando las Matematicas, World Mathematical
Year, editorial Carrogio, Barcelona, 2000.
Four decades ago, Richard Feynman anticipated research
on Micro-robots in an amusing talk called
"There’s plenty of room in the bottom". He was not joking
that time. Engineers, Mathematicians and Biologists are teaming together
to make them (see Science, April 7 2000).
Industrial Robots or Automatons are machines controlled
by primitive brains, whose software uses the theory of Cellular Automata.
There are many lessons to be learned from microscopic living beings, which
we can call "cellular robots".
We chose a confusing title on purpose because "celulas
automatas" are also "automatas celulares".
How does one describe the motile behavior of microorganisms?
How much do they move on average? Professor Howard Berg, from Harvard,
is one of the leaders in this field of study. For him and many others these
questions are as fascinating today as they where to Anton van Leeuwenhoek
in 1676. A bacterium’s cycle lasts about 20min. As in a James Bond movie,
it’s an adventurous life: they are subject to strong Brownian forces in
the aqueous environment and enemies are everywhere. But there are compensations:
their sexual life is active and interesting. As Stephen J. Gould says,
for bacteria, we humans are just some big mountains full of goodies. They
have been around for almost 4 billion years. Humans appeared about 1 million
years ago (civilization exists for 10 thousand years only).
My coworkers (Kurt Ehlers and Richard Montgomery) and
I have some mathematical models for microorganism locomotion (see our article
Movimiento de microorganismos, Gaceta Matematica, Noviembre 1999). Viscosity
dominates over inertia ("zero Reynolds number"): only geometry matters.
Motion of the body in the fluid is an indirect result of shape changes.
It is a "gauge theory" – like the theory a cat needs to know to fall upright
(see Richard Montgomery’s chapter). Fix a particular configuration of an
isolated organism, and first consider a trial " boundary condition" V
along
the located boundary of the body, corresponding to a given shape deformation.
There is an unavoidable ambiguity: V plus an infinitesimal rigid
motion X (consisting of infinitesimal translation and rotation)
is as good as V because the intrinsic shape deformation is the same.
In self-propulsion, the correct V is picked out of the collection
of V(trial) + X by imposing the constraint that it induces
no net force or torque on the fluid. The "scallop paradox" states that
a one degree of freedom organism or robot swimming at zero Reynolds
number goes nowhere. We extended the theory to "social life" at low Reynolds
number. Then two can swim fine by cooperating.
Says Berg: "biology is wet and dynamic". Subcellular organelles
of eukaryotes, just as the whole cell, are immersed in an aqueous environment.
Everything is subject to very strong thermal fluctuations. Inside the cell
there is a "railroad system" formed by microtubules runnig in all directions.
Proteins are transported along by specialized molecules, kinesins, acting
as "cargo vans". Kinesin uses the ATP (adenosine tri-phosfate, the biological
fuel) hydrolysis to drive powerstrokes. Such "molecular motors" are being
intensively studied. Other motions, like protein translocation across membranes
may be driven by a "ratchet" mechanism (Feynman would like this idea).
Here Brownian energy is "tamed" (rectified) with the help of chemical reactions
at favorite places.
A seguir, descrevemos o trabalho de três grupos
de pesquisa nesta área.
Grupo do Prof. Howard C. Berg (Professor, Molecular
and Cellular Biology, Harvard University, e pesquisador do Rowland
Intitute of Science).
http://www.mcb.harvard.edu/Faculty/Berg.html
O Prof. Berg é o nosso "guru". No site www.rowland.org,
você encontrará informações sobre o trabalho
do grupo do Prof. Berg em comportamento e motilidade das bactérias
e belissimos filmes de seu movimento.
" We study bacteria, the simplest free-living single-celled
organisms. We are interested in how they sense changes in their environment,
analyze sensory data, and respond in a purposeful manner. Our quest is
an understanding of behavior at the molecular level. Our primary subject
is the peritrichously-flagellated organism Escherichia coli. We are trying
to learn how its flagellar motors work, how their directions of rotation
are controlled during responses to chemical stimuli (chemotaxis), and what
effect that rotation has on modes of flagellar propulsion. We have worked
on other bacteria that swim without flagella (a cyanobacterium, Synechococcus)
and are beginning work on bacteria that glide across surfaces (Mycoplasma,
which moves by an unknown mechanism, and Pseudomonas aeruginosa, which
uses thinfibers called type IV pili)."
Estas são portanto as áreas de trabalho:
"Bacterial Motility and Behavior: Motion of fluorescent flagellar filaments,
Bleaching of components of fluorescent flagellar motors, Directions of
rotation of the flagellar rotary motor at high speed, Gliding motility
in Mycoplasma, Gliding motility generated by type IV pili".
Para uma revisão recente, ver
Berg, H.C. "Motile behavior of bacteria". Physics Today,
53(1), 24-29 (2000).
" Flagellated bacteria possess a remarkable motility system
based on a reversible rotary motor linked by a flexible coupling (the proximal
hook) to a thin helical propeller (the flagellar filament). The motor derives
its energy from protons driven into the cell by chemical gradients or electrical
fields. The direction of the motor rotation depends in part on signals
generated by sensory systems, of which the best studied analyzes chemical
stimuli. This system allows cells to move up spatial gradients of chemical
attractants and down spatial gradients of chemical repellents. Under certain
conditions, cells excrete chemical attractants on their own and respond
to one another, forming aggregates with remarkable geometric order. We
are trying to learn how the motor works, the nature of the signal that
controls the motor's direction of rotation, how this signal is processed
by the chemical sensory system, and mechanisms for pattern formation. We
are also studying a nonflagellated bacterium that swims by an as yet unknown
mechanism. We are trying to learn what this mechanism might be. Finally,
we are beginning to think about enzymes that move along DNA. These problems
are being approached by a variety of molecular-genetic and physical techniques.
The goal is an understanding of motility and sensory transduction at the
molecular level."
Recomendamos fortemente seu livro:
Berg, H.C. Random Walks in Biology. Princeton: Princeton
University Press. Revised 1993.
Eis uma pequena bibliografia:
K.M. Ehlers, A.D.T. Samuel, H.C. Berg, and R. Montgomery,
"Do cyanobacteria swim using traveling surface waves?" Proc. Natl. Acad.
Sci. USA 93, 8340 (1996).
H.C. Berg, "Symmetries in bacterial motility," Proc. Natl.
Acad.Sci. USA 93, 14225 (1996).
A.D.T. Samuel and H.C. Berg, "Statistical kinetics of
the bacterial flagellar motor," Phys. Rev. E 55, 7801 (1997).
Grupo do Prof. Charles J. Brokaw, Professor of Biology, Caltech:
Computer simulation of biological movement
http://broccoli.caltech.edu/~biology/brochure/faculty/brokaw.html
Recomendo o filme que se encontra em
http://www.cco.caltech.edu/~brokawc/Demo1/BeadExpt.html
VER O FILME DO FLAGELO EM MOVIMENTO!!
brokaw
"Demonstration of microtubule sliding in a beating flagellum.
This sea urchin spermatozoon was treated with detergent, Triton X-100,
to remove the cell membrane, and then transferred to a solution containing
a relatively low concentration of MgATP, to reactivate the bending of its
flagellum at a frequency of about 1.5 cycles per second. This spermatozoon
was swimming freely, but the photographs have been repositioned to eliminate
movement and rotation of the sperm head."
"My work seeks to understand the mechanisms of motility
of eukaryotic flagella and cilia. Specifically, I want to understand how
the activity of the motor enzymes (dyneins) that cause sliding between
the flagellar microtubules is regulated in order to produce particular
patterns of bending.
Experimental work is carried out at the Kerckhoff Marine
Laboratory, operated by the Division of Biology in Corona del Mar, about
60 miles from the Pasadena campus. This laboratory has facilities for maintaining
sea urchins as sources of spermatozoa on a year-round basis, as well as
access to spermatozoa from other marine invertebrates such as the tunicate,
Ciona. We mostly use spermatozoa that have been demembranated with detergent
and then reactivated with MgATP. This in vitro system provides an excellent
system for precise measurements of the parameters of flagellar movement
in response to various experimental manipulations. The measurements are
made using high-speed photographic recording and computerized image analysis."
Entre os links recomendados por Brokaw ,http://numbat.murdoch.edu.au/spermatology/spermhp.html,
a "Spermatology home page", onde se encontra alguma informação
histórica sobre a percepção de Leeuwenhoek: http://zygote.swarthmore.edu/fert1.html
Entre os principais grupos desta comunidade, mencionamos
http://www.bio.ph.kcl.ac.uk/
artigo de revisão: holwill
"The Biophysics Group is part of the Department of Physics
at King's College London. It aims to establish the molecular mechanisms
involved in sperm motility using an original approach based on computer
modelling techniques with corresponding experimental studies. The flagellum
used to propel the sperm is a long slender organelle. The forces required
to bend it are generated by molecular motors called dynein. Cilia, like
flagella, are microscopic motile organelles which propel individual cells,
and are also present in large numbers in the human lung to remove particulate
matter. Malfunction of cilia and flagella can lead to respiratory and reproductive
disorders, e.g. cystic fibrosis, primary ciliary dyskinesis and Kartagener's
syndrome. Some diseases of commercially important crops, such as cocoa
and potatoes are spread by flagellated cells. An understanding of the motor
mechanisms of these organelles is therefore of medical and biological significance,
as well as having commercial implications. The successful use of computer
modelling in the study of dynein will also lead to its application in the
investigation of the other families of biological molecular motors, myosin
(involved in muscle contraction) and kinesin (used to transport cargo from
one part of a cell to another), and to the study of molecular structure
and function in a range of medical and biological systems".
Grupo do Prof. Raymond Goldstein (Arizona State University,
Biophysics)
http://biophys.physics.arizona.edu/~gold
Reprints: 1
2 3 4 567
89 10
Este grupo trabalha na elastohidrodinamica de filamentos
e membranas biológicas. Trabalham também em efeitos coletivos
na chemotaxia. Sobre esta última área:
"We want to understand various macroscopic phenomena associated
with morphogenesis in cellular populations. Using the prototype system
{\it Dictyostelium discoideum}, our goal is to develop quantitative and
controlled experiments on the interplay between chemical signaling and
collective behavior such as organized chemotaxis. It is known from a large
amount of earlier experimental work on this system that collective chemotaxis
occurs in response to coherent chemical waves either in the form of target
patterns driven by autonomous pacemakers or as rotating spiral waves. Little
quantitative information exists on the origin of the transition from signaling
to collective chemotaxis, the symmetry-breaking which produces the pacemakers,
or the factors that influence the selection of one of these patterns over
another. Our initial experiments have shown that by varying the overall
cell population density there is a transition from target-dominated to
spiral-dominated behavior, suggesting a crucial role for the diffusive
coupling of cells in the selection process. These studies also reveal an
interesting entrainment dynamics of spirals and pacemakers. Experiments
underway seek to understand more clearly the biochemical basis for the
selection of wave patterns, and to probe the instabilities associated with
chemotaxis in the presence of periodic waves.
Na página http://www.physics.arizona.edu/physics/newsletter/fall97/biophys.html
Encontramos um depoimento do Prof. Goldstein:
"A Perspective on Biological Physics":
"In his classic work On Growth and Form, the great natural
scientist D'Arcy Wentworth Thompson said, "Cell and tissue, shell and bone,
leaf and flower, are so many portions of matter, and it is in obedience
to the laws of physics that their particles have been moved, moulded and
conformed... Their problems of form are in the first instance mathematical
problems, their problems of growth are essentially physical problems, and
the morphologist is, ipso fact, a student of physical science."
D'Arcy Thompson's attempts to understand the world of
living things through physical reasoning anticipated by decades the current
explosion of interest in the physics community of things biological. As
we in the department begin our own search this year for a new faculty member
in experimental biological physics, I thought it would be useful to give
an overview of the whole field and to describe some newly initiated projects
in my group. The intellectual threads that are important in biological
physics include statistical mechanics, kinetic theory, hydrodynamics, continuum
mechanics, nonlinear dynamics and colloidal physics. As such, the field
is not unlike astrophysics, where many different disciplines meet. Emerging
techniques involving micromanipulation (e.g. optical traps), microlithography
(to create structured environments), fluorescence methods (for direct visualization
of living processes), and the like will all play an important role. An
important question is: What can the discipline of physics bring to this
area? Clearly, it is not productive for physicists to move into biology
simply to copy the methods and adopt the paradigms of the biologists already
there. To a much greater extent than is found in the biology or chemistry
communities, physics is deeply connected with "model building" and testing,
in which one makes contact with reality through a series of progressively
more detailed physical and mathematical descriptions. At each stage, there
is emphasis on consistency with established laws, introduction of dimensionless
control parameters (related to time, length, energy, and force) to delineate
the space of possible behaviors, establishment of scaling laws (expressing
commonality or even universality of behavior), and some degree of logical
and mathematical rigor regarding the results of those models.
On the experimental side, lessons from the study of phase
transitions and critical phenomena as well as nonlinear dynamics are important:
the identification of fundamental control parameters(even if this entails
bringing the experimental system far from physiological conditions), development
of in vitro model systems for living processes (e.g. the study of artificial
lipid vesicle shapes and dynamics in order to understand cell membranes),
and of course the development of new methods and technologies for these
experiments. Finally, let me outline briefly some of the experimental research
I have begun here on form and motion in biological systems. The first project
is aimed at understanding the elastic and dynamic properties of bacterial
filaments that undergo iterated supercoiling instabilities. These filaments
are formed by mutants that exhibit failure of the separation of daughter
cells, and supercoil as a consequence of twisting stresses built up in
the cell walls through this process of growth. Many years of experimentation
by Mendelson and collaborators established remarkableproperties of these
filaments, whose handedness and dynamics can be tuned through external
solution conditions. Yet, no fundamental understanding of the origins of
this phenomenon exists, and there is little quantification of the forces
involved in the conformational evolution. Besides the biological relevance
of this work, this system serves as a "laboratory" for the study of very
general problems in nonlinear dynamics and differential geometry.
To begin an investigation of these issues, we have built
laser tweezers to manipulate the filaments in order to measure basic elastic
properties and have a preliminary measurement of the elasticity of a bacterial
wall that we hope will help us understand this phenomenon in detail.
The second effort, in collaboration with Prof. John Kessler
(Physics) involves the study of the biofluiddynamics of individual and
collective bacterial motion. We seek to understand fundamental features
of low Reynolds number hydrodynamics relevant to organismal motion. One
phenomenon of interest is the bundling of
bacterial flagella in cells with multiple flagellae. In
E. coli, coherent rotation of the helical flagella in one of the two possible
directions results in the formation of a tight bundle; rotation in the
opposite sense makes them fly apart. These two modes of operation produce
the so-called "run-and-tumble" dynamics of bacterial chemotaxis. Yet there
is very little understanding of this bundling process and the hydrodynamic
forces involved. There is also scant attention paid to the possible relevance
of long-range fluid stirring from flagellar motion on nutrient uptake.
We propose experiments using high-speed video microscopy and particle tracking
methods to address these issues as well as long-range hydrodynamic interactions
that may produce collective swimming behavior.
A third project will explore the physics of actin-based
motility. In many cells motility is achieved through motion of the cytoskeleton,
a cross-linked network of actin filaments. The extension of pseudopods
and lamellipods proceed apparently through inhomogeneous polymerization
and depolymerization of the actin network, but there is little quantification
of the resultant forces; I propose to develop an in-vitro model system
involving actin encapsulated in synthetic lipid vesicles to attempt to
understand the essential aspects of this process. By controlling the polymerization
and depolymerization of the actin network with fine spatial resolution,
it may be possible to probe the motive forces generated by inhomogeneous
polymerization coupled to an elastic membrane.
Fig.4 (Patterns obtained by Elena Budrene in H. Berg’s
laboratory.) Under certain conditions, bacteria excrete chemical attractants
on their own and respond to one another, forming aggregates with remarkable
geometric order. What are the mechanisms of pattern formation?
.voltar ao indice
Movimento: de molecular `a robótica
Número especial de Science, vol 288, Number 5463,
7 Apr 2000 , "Movement: molecular to robotic"
leituras recomendadas: dickinsonmatsudaira
On the Move, Lisa Chong, Elizabeth Culotta, and Andrew
Sugden
" From the trafficking of intracellular cargoes to the
flight of the wandering albatross, movement is one of life's central attributes.
All organisms have a three-dimensional spatial context that is both internal
and external; directed, organized motion, which creates as well as operates
within this context, has been a prime target of natural selection from
the dawn of evolutionary time. This special issue examines the principles
of movement as expressed at scales ranging from the subcellular to that
of individual organisms, and in robots as well as in living creatures.
At the root of all existence lies movement at the subcellular
and molecular levels. Recent studies of molecular motors such as the proteins
myosin and kinesin, which are not only responsible for muscle movement
but are also involved in processes such as cell division and membrane transport,
have revealed how underlying similarities at the molecular structural level
can generate a diversity of functional properties and mechanisms of converting
chemical to mechanical energy. These findings are reviewed on page 88 by
Vale and Milligan. These molecular analogs to motors are not the only way
of controlling and organizing the movement of material within cells. As
reviewed by Mahadevan and Matsudaira (p. 95), much has been learned about
the polymeric analogs to other mechanical systems, especially springs and
ratchets. Such systems mediate another sizable cross section of cellular
activities, including fertilization, which can be governed by the dynamics
of actin filaments in some instances.
Of course, whole cells move too, with profound consequences
for a host of physiologic processes, including development, when cells
traverse the embryo to find their correct places. In a News story (p. 86),
Gretchen Vogel reports that developmental biologists, long focused on genetic
signals rather than cell movements, are at last catching glimpses of the
molecules that promptcells to move or stay still at crucial moments in
development.
At the level of the individual animal, the wealth of solutions
to the problem of getting from point A to point B--swimming, running, jumping,
flying, diving--has been keenly explored by natural historians and biomechanicists
for centuries. Yet the past decade has been a particularly vigorous period
for biomechanics, propelled not only by an unprecedented harnessing of
computing power and the runaway development of robotics, but also by a
growing appreciation of the feedbacks between animal sensory and locomotory
systems and of the parallels between different types of locomotion (see
the Review by Dickinson et al., p. 100). Studies at the interfaces between
behavior, physiology, and motion, employing ever more ingenious methods,
are also yielding remarkable new insights. For example, the Report by Williams
et al. (p. 133) reveals the stop-and-start behavior of dolphins and other
marine mammals, including the world's largest animal, the enigmatic blue
whale. A related News story (p. 83) by Elizabeth Pennisi discusses these
findings, which are among the most dramatic of a series of recent discoveries
concerning the diverse advantages gained by moving intermittently.
Mechanical creatures may also help illuminate the principles
of motion, as reported in the News story by Gary Taubes (p. 80). As biologists
learn from a new generation of robotic lobsters, moths, flies, and fish,
roboticists are deliberately modeling their creations on natural principles.
Not since the bird's wing gave us the airfoil has the application of natural
knowledge in this area looked so promising.
The study of motion is one of those rare and challenging
disciplines that draws together the biological, the chemical, and the physical,
and it holds endless fascination for the pure and applied scientist alike.
We can predict many fruitful collaborations in the future and expect many
surprises."
Este artigo, que abre a seção especial sobre
Movimento Biológico, despertou vários comentários
posteriores. Eis alguns:
" The interesting array of articles for the special issue
"Movement: Molecular to Robotic" (7 Apr., pp. 79 106) examines the biology
of movement for animals with endoskeletons, animals with exoskeletons,
robots, and molecules, but movement in an entire kingdom--the plant kingdom—is
overlooked. Movement in plants is based on physical mechanisms that are
very different from most animal movements, and movements have been a central
factor in the evolution of many plant adaptations. Mechanisms include hydraulic
shifts operating by means of osmotic engines (1), differential growth,
fracturing of structures due
to localized desiccation, and cell separations or dissolution
leading to projectile actions.
Examples of movements based on hydraulic shifts include
the cyclic flapping of leaves and the opening and closing of some petals
and flowers. Cells on one side of a petiole, pulvinus, stem, or pedicel
will lose water, whereas cells on the opposite side will maintain or even
increase turgidity, and movement of leaf, stem, or flower will occur. These
osmotic engines are driven principally by ionic pumps across the cell membrane
that usually transport K+ or Ca2+ (or both), and in some cases, such as
the leaf folding in the sensitive mimosa plant, an action potential is
involved.
Examples of movement by differential growth on opposite
sides of a plant organ include phototropism, gravitropism, the opening
and closing of some flowers, and the coiling of stems and tendrils. In
the case of the stilt palm (Iriartea gigantea) (2), the trunk is held aloft
on supporting brace roots, and movement of the tree toward a light-gap
can occur by differential growth of the brace roots on the lighted side
and abandonment of such roots on the shaded side.
Another group of movements involves localized cell degradation
to produce a throwing action. Such movements include the explosive projection
of pollen, spores, or seeds, which occur when tension is released in a
cluster of cell walls that have degraded, resulting in a catapult-like
action.
Movement can also occur by negative growth. Below-ground
bulbs or stems can move down to a desirable depth by means of contractile
roots. These roots have been found in more than 90% of the plants studied
(3). They become thickened and develop extensive wrinkles as the root contracts.
The irreversible contraction effect is achieved by a combination of thickening
and shortening of individual cells along the root axis, combined with programmed
cell death of layers of cells in the root cortex.
And finally, there is a large array of thigmo movements,
movements stimulated by touch (mechanical perturbation) (4). The coiling
of tendrils around an object involves two component movements (5): an initial
movement (involving a contractile adenosine triphosphatase) resulting in
hydraulic changes that lead to rapid coiling, followed by differential
growth on opposing sides of the tendril, which allows the tendril to continue
coiling around the support. There is evidence that such thigmo coiling
movements involve the classic stimulus-response syndrome, including the
opening of calcium channels and a probable sequence of phosphorylations.
Another example of thigmo movement is the motor pulvinus
of the sensitive mimosa plant (Mimosa pudica) (6). When a leaf is touched,
the signal is transmitted to the base of the leaf by a lever action. An
action potential is generated. Special structures called tannin vacuoles
in the motor cells at the base of the leaf, analogous to the sarcoplasmic
reticulum in muscle sarcomeres, release Ca2+ into the cytoplasm. This causes
actomyosin microfilaments to contract, opening putative potassium channels
in the plasma membrane. The K+ effluxes, drawing water after it by the
osmotic engine mechanism. The turgor of these cells thus decreases, causing
the leaf to bend downward as a result of the turgor differential between
the upper and lower sides. Action potentials then travel up and down the
stem, activating motor cells at the bases of other leaves.
In conclusion, the various movements performed by plants
are special in that they are primarily based not on contractile proteins,
but on physical and cellular alterations. The wide array of repositioning
movements and adaptations for reproductive effectiveness has evolved principally
as components of photosynthetic and reproductive strategies
A. Carl Leopold, Mordecai J. Jaffe, Boyce Thompson Institute
of Plant Research,
Ithaca, NY 14853, USA
1. S. Vogel, Life's Devices: The Physical World of Animals
and Plants (Princeton Univ.
Press, Princeton, NJ, 1988), pp. 255-263.
2. P. H. Allen, The Rain Forests of Golfo Dulce (Stanford
Univ. Press, Stanford, CA, 1977).
3. H. De Vries, Land. Jahrbuch. (Ver. Wiegandt, Hempel
& Pasrey, 1880); A. Rimbach, Beit. Wissenschasft. Botanik 2, 1 (1898);
Ber. Deuts. Bot. Ges. 44, 328 (1926).
4. M. J. Jaffe, Encycl. Plant Physiol. 11, 444 (1985).
5.------ and A. W. Galston, Plant Physiol. 41, 1014 (1966);
Plant Physiol. 42, 845 (1967); Plant Physiol. 43, 537 (1968).
6. H. Toriyama, Cytologia 20, 367 (1955); ------ and M.
J. Jaffe, Plant Physiol. 49, 72
(1972); H. M. Turnquist et al., Protoplasma 176, 91 (1993);
T. Sibaoka, Symp. Soc. Exp. Biol. 20, 49 (1966).
In the "Movement" special issue, the News article "In
nature, animals that stop and start with the race" by Elizabeth Pennisi
(7 Apr., p. 83) misses one of the neatest examples. Once fish discovered
the energetic advantages of "burst-and-coast" swimming (D. Weihs, J. Theor.
Biol. 48, 215,1974), they also discovered the advantage of coasting above
the surface of the water, to minimize drag and increase the distance covered
by the coasting phase--hence, "flying fish." This was also discovered (independently)
by flying squids, which inherently have a burst-and-coast mode of locomotion.
Charles J. Brokaw, Division of Biology, California Institute
of Technology.
I was writing up notes from Gary Taubes' News article,
"Biologists and engineers create a new generation of robots that imitate
life" (Science, 7 Apr., p. 80). Taking the notes was a bit troublesome
because of the lack of a convenient term to categorize robots based on
cockroaches, spiders, snakes, fish, and so on. The descriptive phrase "zoologically
inspired robots" worked, but was a bit clumsy. The answer was then obvious--"zoobots"
(Greg Goebel) .
Fig. 5. Muybridge, Eadweard (1830-1904) http://www.kingston.ac.uk/muytext0.htm
Muybridge was a young man when he left Kingston for America. The exact
year of his departure is uncertain, but by 1856 he was established as a
bookseller and a publisher's agent in San Francisco, trading under the
name EJ Muygridge. In 1860 he was injured in a stage coach crash whilst
travelling overland from San Francisco to New York for a visit to Europe.
Muybridge returned to America in about 1866 to become a professional photographer.
voltar ao indice
Complexidade
textos extra capa cardume
Science, vol. 284, 2 de abril de 1999, "Complex systems" , p. 79-109.
p.80:Células virtuais (artificial life) : www.e-cell.org,
Masanu Tomita e seu grupo de bioinformática da Keio University,
Leslie Loew U.Connecticut, Farmington; www.nrcam.uchc.edu
.
p.82. "Unraveling Bacteria's dependable homing system":
o sistema contem diversas sub-unidades: i) para "cheirar" a fonte dos nutrientes;
ii) para mover os flagelos; iii) para transmitir os sinais. Como este sistema
é integrado? Como garantir sua robustez num meio variável?
Há um padrão independente das características dos
diferentes organismos? Stanislas Leibler (Dept Biol. Molecular) e Naama
Barkai, (Princeton) : equações diferenciais para a taxia
randomica da E.coli.
p. 99-101 J.K. Parrish (Zoologia, U. Washington Seattle)
e L.Edelstein-Keshet (Math, U. British Columbia, Canada), "Complexity,
pattern, and evolutionary trade- offs in animal agregation": modelos matemáticos
de agregação, estratégias para a proteção
do coletivo contra predadores.
"Sinfonia das bacterias", pg. 1302, por E.Strauss. As
bactérias podem comunicar-se com membros de sua e de outros espécies,
permitindo-lhes coordenarem suas atividades. Algumas requerem um grupo
para que possam ter impacto: se voce está sozinho num grande auditório,
não é escutado; mas se está num coro, as vozes se
juntam. Os micróbios sabem que há poder na união.
Algumas vezes os microbios se tornam virulentos. Outras vezes, estas atividades
são benéficas. Segundo Bonnie Bassler (http://www.molbio.princeton.edu/faculty/bassler.html),
" as bactérias querem fazer algumas coisas quando estão sozinhas
e outras quando estão numa comunidade … Respondendo a uma maior
densidade populacional lhes permite mudar para um novo conjunto de tarefas
micróbios quanto para as criaturas que eles habitam. A bactéria
luminescente Vibrio Fischeri vive num órgão especializado
em animais como o Hawaian bobtail squid. Quando há um número
suficiente de bactérias, a luz é "ligada", eliminando a sombra
e a lula nada a luz da lua.
Movimento e Cérebro
Nestas notas, evidentemente não poderemos abordar
(principalmente por sermos meros curiosos ) a parte mais fascinante (a
nosso ver) da biologia atual, os processos de enorme complexidade no sistema
nervoso central. Em particular, as atividades do cérebro ligadas
ao movimento. Neste tema, apenas mencionamos dois exemplos.
De Susan A. Greenfield, The Human Brain, Basic Books,
1997. "Charles Sherrington, um dos grandes pioneiros da fisiologia durante
a primeira metade do século 20, resumiu a contribuição
pervasiva do movimento em nossas vidas: ‘desde um sopro na floresta
até a queda de uma árvore, tudo é movimento’. Das
sutilezas da linguagem corporal, à precisão da palavra, e
à total desambiguidade de um abraço, virtualmente toda comunicação
depende do movimento.
Embora as plantas podem se mover pois voltam-se para a
luz, elas não podem gerar movimento como nós. Fora da ficção
cientifica, nenhuma planta se locomove de um lugar para outro. Em contraste
clarissimo, todos os animais estão em movimento – ou seja, eles
são animados. Interessantemente a palavra Latina animus
significa
`consciencia’.
Se voce é um organismo multicelular e está
em movimento, então você tem, pelo menos um tipo primitivo
de cérebro. A importância para as criaturas que se movem terem
um cérebro é muito bem ilustrada por uma observação
feita inicialmente pelo falecido Imperador Hirohito do Japão, para
quem a vida marinha era um hobby apaixonante. O unicado em questão
se chama sea squirt.
Quando ainda é uma larva imatura, o sea squirt
passa o tempo nadando por aí: não apenas é capaz de
fazer movimentos coordenados, como também possui um sensor primitivo
de vibrações, grosseiramente comparável com um ouvido,
e um sensor primitivo de luz, grosseiramente comparável com um olho.
De fato, o pode se dizer que o sea squirt possui um cérebro modesto.
Porém, quando se torna maduro, o sea squirt muda de estilo de vida
e se prende a uma pedra. Ele não precisa mais de nadar por aí,
porque ele agora vive filtrando a água do mar.
(
Webster: sea squirt
any tunicate, esp. a sessile ascidian, so called from its
habit of contracting its body and ejecting streams of water when disturbed.
1. tunicate Zool. any sessile marine chordate of
the subphylum Tunicata (Urochordata), having a saclike body enclosed in
a thick membrane or tunic and two openings or siphons for the ingress and
egress of wa 2. sessile: l. permanently attached; not freely
moving.
[1715–25; < L sessilis fit for sitting on,
low enough to sit on, dwarfish (said of plants), equiv. to sess(us)
(ptp. of sedre to SIT1) + -ilis -ILE]
)
Nesta etapa, o sea squirt na verdade realiza um ato
notável:
consome seu próprio cérebro!
A pista para a finalidade do cérebro dada por esta
estória é que você só precisa de um cérebro
se voce está se movendo. Para formas de vida estacionárias,
um cérebro não é mais necessário. O ponto todo
é que para um animal se movendo, existe uma interação
com o meio que está mudando incessantemente. Voce precisa de um
equipamento para lhe dizer muito ràpidamente o que está acontecendo
e, o que é mais importante, que lhe permita responder ao que está
acontecendo, para escapar dos predadores ou para caçar as suas presas.
Portanto o cérebro, de qualquer forma, tamanho e grau de sofisticação
que seja, é ligado de forma fundamental para garantir a sobrevivência,
tanto como consequencia tal como causa do movimento."
Cérebro e sexo (ver Scientific American, vol.
283 nb 2, August 2000, : Pg. 56-61 Male Sexual Circuitry, Irwin Goldstein,
Boston University)
"Quinhentos anos atrás, Leonardo da Vinci fez uma
observação sobre o pênis que parece correta ainda hoje
para muitos homens e suas companheiras. O scientista da Renascença
– inventor e artista – um numa longa linha de investigadores que tentaram
resolver a charada da rigidez peniana – observou que este orgão
por vezes traiçoeiro parece ter vontade própria. "O pênis
não obedece as ordens do seu mestre, que tenta enrigecê-lo
ou encolhe-lo, ao contrário, o pênis se enrigece livremente
enquanto seu dono dorme. Pode-se dizer que o pênis tem sua própria
mente", escreveu ele.
Da Vinci, que dissecou inúmeros penis de cadáveres
de homens executados por enforcamento, foi o primeiro cientista a reconhecer
que durante a erecção, o pênis enche-se de sangue.
Porém, na sua percepção de que o pênis possui
vontde própria, este estudioso de muitos talentos estava equivocado.
Muito ao contrário de ter sua própria mente,
como pensava da Vinci, sabe-se hoje que o pênis está sob completo
controle do sistema nervoso central – o cérebro e a espinha dorsal….
As pesquisas tem demonstrado muitas semelhanças entre os sexos no
papel do sistema nervoso central no controle da excitação,
orgasmo e várias outras funções" .
Em resumo, o orgão sexual mais importante é
… o cérebro.
Fig 6. No brain, no sex.
voltar ao indice
Biomecânica e Robótica
Aristoteles
Ao que se sabe, os primeiros estudos de biomecânica
foram escritos cerca de 350 A.C por Aristoteles ( "On the Gait of Animals",
"The History of Animals" e "On the Motion of Animals" ; traduções
para inglês podem ser encontradas em http://classics.mit.edu
). Do primeiros deles, extraimos o trecho inicial:
motion
gait
"We have now to consider the parts which are useful to
animals for movement in place (locomotion); first, why each part is such
as it is and to what end they possess them; and second, the differences
between these parts both in one and the same creature, and again by comparison
of the parts of creatures of different species with one another. First
then let us lay down how many questions we have to consider. The first
is what are the fewest points of motion necessary to animal progression,
the second why sanguineous animals have four points and not more, but bloodless
animals more than four, and generally why some animals are footless, others
bipeds, others quadrupeds, others polypods, and why all have an even number
of feet, if they have feet at all; why in fine the points on which progression
depends are even in number.
Next, why are man and bird bipeds, but fish footless;
and why do man and bird, though both bipeds, have an opposite curvature
of the legs. For man bends his legs convexly, a bird has his bent concavely;
again, man bends his arms and legs in opposite directions, for he has his
arms bent convexly, but his legs concavely. And a viviparous quadruped
bends his limbs in opposite directions to a man's, and in opposite directions
to one another; for he has his forelegs bent convexly, his hind legs concavely.
Again, quadrupeds which are not viviparous but oviparous have a peculiar
curvature of the limbs laterally away from the body. Again, why do quadrupeds
move their legs criss-cross?
We have to examine the reasons for all these facts, and
others cognate to them; that the facts are such is clear from our Natural
History, we have now to ask reasons for the facts."
Leonardo
Esposição no ScienceMuseum, Londres: robot
filme modelos
curator new
1 2 345678910111213141516171819202122232425
262728293031323334
35 36 37 38 39 40
voo1 voo2
Com certeza aborreceremos os que conhecem melhor que nós
a história da ciência, ao passarmos direto a Leonardo da Vinci
(estaremos esquecendo as contribuições importantes das civilizações
do oriente e do oriente médio). Informações na web,
podem ser encontradas em muitos sites (a máquina de busca www.google.com
deu 205,000 em 0.05 segundos). Recomendamos os seguintes, para as contribuições
cientificas de Leonardo:
Museo Nazionale della Scienza e della Tecnica - Milano
– Italia : http://www.museoscienza.org/.
Ali se pode encontrar muitos links para Leonardo na web
:
http://www.museoscienza.org/english/leonardo/Default.htm.
O Instituto e Museo di Storia della Scienza, Florence,
Italy e o Science Museum, Londres acabam (10/99-08/2000) de fazer uma exibição
importante sobre Leonardo e os engenheiros da Renascença:
http://galileo.imss.firenze.it/news/mostra/index.html
http://www.sciencemuseum.org.uk/on-line/leonardo
http://galileo.imss.firenze.it/news/mostra/6/index.html
Em http://www.imss.fi.it/~tsettle/index.html
você encontrará muitos links para a história da ciencia,
medicina e tecnologia.
Voce deverá olhar nesta linda exposição
virtual as idéias de Leonardo sobre biomecânica, robótica,
e propulsão na água e no ar.
IMPERDIVEL
Curiosamente, há ainda o interesse de curiosos
em imitar o voo das aves, ver
http://www.catskill.net/evolution/flight/home.html
(flapping flight website)
Eis algumas informações sobre os manuscritos
científicos de Leonardo:
"After Leonardo's death in 1519 Francesco Melzi, his favourite
pupil, brought many of his manuscripts and drawings back to Italy. This
is confirmed by a note written by an agent of the Duke of Ferrara, dated
1523, referring to: "those little books by Leonardo about the anatomy,
and many other interesting things. But this huge mass of writings, undoubtedly
the largest collection of the entire Renaissance, has endured many vicissitudes
following Leonardo's death. It was Melzi's heirs who, after his death in
1579, began to scatter the material. Having no idea of their importance,
they initially stored Leonardo's drawings and manuscripts in a loft, later
giving parts of it away or selling sheets cheaply to friends and collectors.
Already in 1630, the Barnabite Antonio Mazenta speaks of the dispersal
of the Leonardo manuscripts, and singles out Pompeo Leoni, a sculptor at
the court of the King of Spain, as one of those chiefly responsible not
only for losing part of the collection, but even worse, for rearranging
the order of its contents. Indeed, in an effort to sort the artistic drawings
from the technical ones, and to put together the scientific notes, he split
up the original manuscripts, cut and pasted pages and created two separate
collections. One is now called the "Codex Atlanticus", the other the Windsor
collection, which contains some six hundred drawings. Using the same method,
Leone went on to create at lest four more volumes. Upon Leoni's death,
his heirs brought part of the manuscripts
back to Italy, where they were purchased by Count Galeazzo
Arconati who, in 1637, donated them to the Biblioteca Ambrosiana where
they remained until 1796, the year of Napoleon Bonaparte's arrival in Milan.
Napoleon ordered the manuscripts to betransferred to Paris, but in 1851
the Austrian government requested their return. Only the Codex Atlanticus
was actually returned, while the other twelve manuscripts, marked with
the letters A to M, remained in Paris, and were regarded as lost. Other
manuscripts stayed in Spain and then went their different ways. Others
remained undiscovered until 1966, when they were found quite by chance
in the archives of the National Library of Madrid".
Dos dez diferentes manuscritos que existem, os que nos
interessam aqui são:
Codex Atlanticus
"This Codex, kept in the Biblioteca Ambrosiana in Milan,
contains a number of drawings, most of which can be dated in the period
1480 to 1518. Various themes are touched on, from mathematics to geometry,
astronomy, botany, zoology and the military arts. Today it consists of
twelve leather-bound volumes, comprising 1,119 supports which gather together
pages of different sizes. The name "Codex Atlanticus" derives from the
fact that originally all the sheets were contained in a single large-sized
volume, rather like an atlas in fact. The Codex Atlanticus was created
around the end of the sixteenth century by the sculptor Pompeo Leoni who
- in a disastrous operation - dismembered the original Leonardo manuscripts
which had came into his possession. Leoni separated all the scientific
and technical drawings, today contained in the Codex, from the naturalistic
and anatomical ones, many of which are today part of the Royal Windsor
collection."
Codex 'On the Flight of Birds'
Held in the Biblioteca Reale of Turin, this collection
includes 17 pages (measuring 21 x 15 cm) out of the original 18. It deals
primarily with the flight of birds, which Leonardo analysed with a very
rigorous approach, paying particular attention to the mechanics of flight,
as well as to air resistance, winds and currents. The pages can be dated
to approximately 1505.
Codices of the Institut de France
These documents are to be found at the Institut de France
in Paris, and comprise twelve paper manuscripts, some bound in parchment,
others in leather, and others still in cardboard. They are in a variety
of sizes, the smallest being Codex M (10 x 7 cm) and the largest Codex
C (31 x 22 cm). They are conventionally identified by a letter of the alphabet,
from A to M. Various subjects are covered: military art, optics, geometry,
the flight of birds, hydraulics. The majority of the pages can be dated,
presumably, to the period between 1492 and 1516.
Codex Forster
These manuscripts are in London, at the Victoria and Albert
Museum. The paper manuscripts are parchment-bound and are known as: "Forster
I" (14 x 10 cm), "Forster II" (10 x 7 cm) and "Forster III" (9 x 7 cm).
They include studies on geometry, weights and hydraulic machine which Leonardo
carried out in different periods, between 1490 and 1496 for "Forster III",
between 1495 and 1497 for "Forster II" and between 1487 and 1490-1505 for
"Forster I".
Codex Leicester
This Codex was purchased by Bill Gates in 1995. It is
a paper manuscript, bound in leather and comprising 64 sheets measuring
30 x 22 cm, dedicated for the most part to studies in hydraulics and the
movement of water; the manuscripts can be dated to the period between 1504
and 1506. Several studies in geology and astronomy are also included.
The Madrid Codices
These manuscripts are in the National Library of Madrid,
where they were rediscovered only in 1966. The two paper manuscripts are
bound in red morocco leather. For fast identification purposes, they were
named "Madrid I" and "Madrid II". Most of the pages contained in "Madrid
I" - 192 sheets (21 x 15 cms. in size) - prevalently concern studies in
mechanics and can be dated to between 1490 and 1496, whilst those in "Madrid
II" are dedicated to studies in geometry, and date to between 1503 and
1505.
Robótica e Biomecânica na atualidade.
Para uma (longa) viagem ao mundo atual da Biomecânica,
ver http://www.per.ualberta.ca/biomechanics/
Existe um grande aporte da biomecânica na medicina
de reabilitação. Entre os muitos sites, ver por exemplo,
http://www.gait.com
(The Derby Gait Analysis Laboratory, Bioengineering Research Centre, England)
"We offer the very latest diagnostic information for informed
treatment planning and care management. Objective, quantitative data on
limb movement and rotation, joint moments and energy expenditure, and muscle
activity involved in movement". Na Johns Hopkins University, http://www.biomech.jhu.edu/
. Ver os projetos ali desenvolvidos e os muitos links.
Entre os grupos de pesquisas na biomatemática do
movimento, com os quais tivemos contato, apontamos os seguintes:
Grupo de Andy Ruina, em Cornell (http://www.tam.cornell.edu/~ruina/)
IMPERDIVEL!!!
Vale a pena olhar com detalhe o seu maravilhoso site.
Apartir dos links ali encontrados você poderá ter uma idéia
do estado da arte. Uma apreciação do seu trabalho, para o
leitor geral, foi feita na revista the Economist (20/12/1997).
" Except perhaps after parties, most grown-up humans take
the ability to walk on two legs forgranted. Yet with bipedal walking, evolution
has pulled off an impressive feat of engineering,one that human engineers
have not been able to reproduce in a robot. This may be because engineers
have been looking in the wrong place.
How humans walk has been pondered in great detail. A better
understanding of the process could lead not just to more nimble robots
but also to better prosthetic limbs and new treatments of muscular diseases
that impair walking. But most research in the field has focused on the
complicated interactions between the nervous system and the muscles. However,
this may only be part of the story.
In the late 1980s, Tad McGeer, a mechanical engineer,
built a pair of leg-like objects with no control mechanism, and showed
that they were capable of marching down shallow slopes all by themselves,
powered only by gravity. This suggested that the design of the body might
matter as much as the signals the legs receive from the brain.
Since then, more people have become interested in the
mechanics of walking. With his colleagues, Andy Ruina, an engineer at Cornell
University in Ithaca, New York, has been building a range of legs that
can walk by themselves. The simplest model has two straight rods, joined
at a ``hip'', with two semi-circular ``feet'' attached to the ends of the
rods. These can walk down slopes without signals from any brain and without
falling over. But making toys that can walk is only part of what the group
does to understand walking. A lot of the walking is ``virtual''. Mariano
Garcia and Michael Coleman, graduate students in the group, have written
a number of computer simulations to see if a model of walking fits what
legs do in practice. The equations that describe the motion of the walker
take into account the mass of the feet and hips, the angle of the slope
and the force of gravity. Cranking through the calculations, the computer
looks for motions that will be stable.
The results show that even a simple pair of legs is capable
of a diverse array of gaits. There is the standard one leg in front of
the other motion, called ``period one'' motion because it repeats itself
after each step. Change the angle of the incline, and you get ``period
two'' motion, which looks like limping: the same motion is repeated only
after two steps. Make the slope even steeper, and the period of the motion
keeps doubling-after limping comes staggering, and finally chaotic walking,
where the legs take short and long steps at random never settling down
into a pattern but not falling down either. On the steepest slopes the
legs finally succumb, and simply fall over.
The latest toy from Dr Ruina's laboratory, however, is
a walker with more complex behaviour. Named Mr FancyPants (owing to the
pair of trousers it sports), it has no knees, but is stabilised with weights
around its ankles. Mr FancyPants has the distinction of being the first
walker that can walk, but cannot stand still.
This is important, because Mr FancyPants does not have
a big, wide base, which is what makes most things stable. Rather, some
aspect of the motion keeps it from falling over. In many ways, Mr FancyPants
moves like a person who has stumbled, but instinctively knows where to
put his leg to avoid taking a spill. Remarkably, Mr FancyPants seems to
put its legs in exactly the right place to stop falling, just because of
the way it is constructed, not because of any complicated signals from
a control mechanism like a brain.
The computer model that attempts to describe Mr FancyPants's
motion shows that it walks in an unstable way. Unstable walking is only
possible under the most ideal conditions-even the slightest change will
cause the walker to topple over. But Mr FancyPants walks in the real world,
where conditions are never ideal. How it does so while remaining stable
is something of a mystery.
For a system to be stable, small disturbances must not
affect it. For instance, friction acts to stabilise the motion of a pendulum
through the air. But stability can also arise from what are known as ``non-holonomic
constraints''. An ice-skater is nonholonomically constrained, for example,
because he can move back and forth, but not from side to side. So the skater
is constrained in a way that a person on ice without skates, who can slip
and slide where he pleases, is not. What Dr Ruina and Mr Coleman are proposing
in a forthcoming paper in Physical Review Letters is that Mr FancyPants
may be constrained in a similarly non-holonomic way: Mr FancyPants cannot
move by slipping and sliding, only by lifting its leg and making contact
with the ground as it steps.
A complete model of how two-legged creatures walk will
eventually have to include the muscular system, nerves, brain and skeleton.
But Dr Ruina and his colleagues have shown that two legs can walk a long
way alone, without the guidance of an active brain. Be glad of that after
the party."
Os aspectos de simetria são destacados no estudos
de Martin Golubitsky, Ian Stewart, Luciano Buono and James J. Collins.
Ver o site de Martin Golubitsky, University of Houston
(http://www.math.uh.edu/~mg):
Animal
Gaits
"Joint research with Ian Stewart, Luciano Buono and James
J. Collins: Collins and Stewart noted that many quadruped gaits can be
described by spatio-temporal symmetries. For example, when a horse paces
it moves both left legs in unison and then both right legs and so on. The
motion is described by two symmetries: Interchange front and back legs,
and swap left and right legs with a half-period phase shift. Biologists
postulate the existence of a central pattern generator (CPG) in the neural
system that sends periodic signals to the legs. CPGs can be thought of
as electrical circuits that produce periodic signals and can be modeled
by coupled systems of differential equations with symmetries based on leg
permuation. In this lecture we discuss animal gaits; describe how periodic
solutions with prescribed spatio-temporal symmetry can be formed in symmetric
systems; construct a CPG architecture that naturally produces quadrupedal
gait rhythms; and make several testable predictions about gaits".
voltar ao indice
Roteiro de estudos em Biologia Molecular
textos extra cilia microtubulosmicrotestrutura
mitocondria membrana
Eis algumas palavras chaves importantes em Biologia Molecular:
DNA, Recombinant
Enzymes
Gene Expression Regulation
Genetic Screening
Genetic Techniques
Molecular Biology
Nucleic Acids
Oncogenes
Obtivemos um "dicionário" de Biologia Molecular
no site da American Society of Hematology (http://www.hematology.org/education/index.html),
elaborado pelo Dr.Kenneth Kaushansky (Professor of Medicine, Adjunct Professor
of Biochemistry, University of Washington School of Medicine). Está
em formato pdf. Este trabalho foi republicado, Kaushansky K, Glossary of
molecular biology terminology., Biologicals 24: 3, 157-75, Sep, 1996.
Para um estudo mais detalhado, a nivel universitário,
o Prof. Howard Berg sugere as seguintes referências:
1. Molecular Cell Biology, Harvey Lodish, David Baltimore,
Arnold Berk, S. Lawrence Zipursky, Paul Matsudaira, 3rd edition (March
1995), W H Freeman & Co.; ISBN: 0716736861;Molecular Cell Biology Hardcover
Cd-Rom edition (February 1996) , W H Freeman & Co.; ISBN: 0716727110;A
Student's Companion in Molecular Cell Biology, H. Lodish, J. E. Darnell,
3rd edition (December 2000) W H Freeman & Co.; ISBN: 0716726726; Answer
Book: Molecular Cell Biology, David Scicchitano, H. Lodish, J. E. Darnell,
3rd edition (December 1998) , W H Freeman & Co.; ISBN: 071672703X
2. Molecular Biology of the Cell , Bruce Alberts (Editor),
Bray Alberts, 3rd Bk&cdr edition (June 1999) Garland Pub; ISBN: 0815336233;
Essential Cell Biology : An Introduction to the Molecular Biology of the
Cell, Bruce Alberts, Dennis Bray, Alexander Johnson, Julian Lewis, Peter
Walter, Keith Roberts, Martin Raff, Garland Pub; ISBN: 0815320450
3. Biochemistry (4E & CDR Media) , Lubert Stryer,
4th Bk&cdr edition (March 1995), W H Freeman and Co; ISBN: 071673687X
Student Companion for Stryer's Biochemistry , Lubert
Stryer, Richard I. Gumport
4th edition (February 1996), W H Freeman & Co.; ISBN:
0716725606
Mencionamos agora um número especial da revista
Science, sobre a biologia celular do citoesqueleto.
Cell Biology of the Cytoskeleton (Science, volume 279,
Number 5350 Issue of 23 Jan 1998, p 459.)
"Cells come in a huge variety of shapes and sizes, from
the almost spherical lymphocyte, to amoeboid cells such as macrophages,
to flattened spindle-shaped fibroblasts or polygonal epithelial cells,
to neuronal cells with the complex branching extensions the dendrites and
the very long extension the axon. Such cellular architecture is constructed
and maintained by the cytoskeleton, a dynamic network of intracellular
proteinaceousstructural elements. The cytoskeleton is responsible for cell
shape, motility, migration, and polarity, and for establishing intercellular
contacts to produce tissue architecture. In addition, the cytoskeleton
plays many roles inside the cell. For example, in cell division it forms
the scaffold on which chromosomes are segregated to daughter cells and
separates the daughter cells after mitosis. Like the vertebrate skeleton,
certain types of cytoskeletal elements are more or less permanent features
of cells, including the actin and myosin filament bundles in muscle cells
and the microtubule arrays in cilia and flagellae. Other cytoskeletal structures
are very dynamic, continuously assembling and disassembling like the tracks
of a child's train set as part of their functional cycle or for use in
various cellular processes. One particularly radical example of cytoskeletal
dynamics is the complete remodeling of the microtubule array of a cell
during mitosis--it changes from a network radiating throughout the cell
to the compact, bipolar, mitotic spindle.
In this special issue of Science, some of the emerging
areas of research on cytoskeletal dynamics are examined. The basic building
blocks of the cytoskeleton include actin microfilaments (about 7 nm in
diameter), tubulin microtubules (about 24 nm in diameter), and a variety
of intermediate filaments (about 10 nm in diameter). Each filament type
is composed of linear polymers of globular protein subunits, which are
assembled and disassembled by the cell in a carefully regulated fashion,
sometimes at astonishing rates. One of the classical images of the cytoskeleton
is the molecular machinery of muscle tissue, in which microfilament arrays
are linked by myosin motor filaments, forming sliding filaments that expand
and contract in generating force. Mermall and colleagues (p. 527) review
the current state of knowledge about the roles of nonmuscle myosins, which
do not form filamentous structures, in various cellular processes, including
membrane traffic, cell movement, and signal transduction. Microtubules
play fundamental roles in the formation of complex cellular geometries
such as axons, the extremely elongated processes of neurons. Microtubule-based
motors use microtubule tracks to move a variety of cargoes around cells--the
movement of chromosomes along the mitotic spindle during mitosis is an
example. Hirokawa (p. 519) describes the large number of microtubule-based
motors, encoded by the kinesin and dynein multigene families, and elaborates
on their roles in intracellular transport. A kinesin Web site has details
on many of the aspects of the cell biology and biophysics of this important
intracellular motor protein (www.blocks.fhcrc.org/~kinesin/). The actin
cytoskeleton also shapes cellular processes; for example, in the formation
of filopodia or cell contact sites. Hall (p. 509) looks at the interplay
between actin architecture and the signal transduction machinery of the
cell in promoting profound changes in cell shape and motility in response
to extracellular signals. Less is known about the role of intermediate
filaments in cells, mainly because of a lack of tools with which to study
their assembly and disassembly. Fuchs and Cleveland (p. 514) summarize
recent advances in our understanding of the roles of multiple types of
intermediate filaments, which have become clear through the discovery of
several diseases linked to intermediate filament pathology. A Research
News story by Elizabeth Pennisi (p. 477) focuses on the kinetochore, the
part of the chromosome that interacts with the microtubules of the mitotic
spindle. Finally, Echard and co-workers (p. 580) describe a putative new
motor that is likely to play a role in intracellular transport through
the secretory pathway.
Problems with the cytoskeleton can cause disorders of
the skin, the nervous system, and the muscles. Changes in the cytoskeleton
are key, and even diagnostic, in the pathology of some diseases, including
cancer. Understanding the basic cell biology of the cytoskeleton has contributed
to our understanding of the pathology of some of these disorders and will
continue to affect approaches to understanding, diagnosis, and therapy
for various conditions.
(Stella M. Hurtley)."
voltar ao indice
Motores Moleculares
textos extras: hirokawahirokawa1hirokawa2hirokawa3
block frey
Se você deseja imediatamente se informar sobre o
estado da arte, olhe a home page do congresso recentemente realizado na
Universidade de Alberta:
http://www.phys.ualberta.ca/~biophys/banff2000
Mas é melhor talvez começarmos bem devagar…
Um site educacional maravilhoso para biologia celular, accessivel para
crianças inclusive, é
http://www.cellsalive.net/ ou
http://www.cellsalive.com/
Em particular, veja como bactérias se movem: http://www.cellsalive.net/animabug.htm
Um lindo tutorial sobre biologia celular, onde apendemos
todas as informações básicas (você conhece os
nomes " microtubulos, cilia, flagella, etc, …"?) para alunos (e professores)
em final de ensino secundário se encontra em:
http://cellbio.utmb.edu/CELLBIO/(University
of Texas Medical Branch., Galveston, Texas)Veja por exemplo as páginas
http://cellbio.utmb.edu/CELLBIO/microtub.htm#Menu
http://cellbio.utmb.edu/CELLBIO/microtubule_structure.htm
Ali há links para outros tutoriais, históricos,
etc.: http://cellbio.utmb.edu/Links.htm
A "home page da Kinesin" - com filmes, material informativo
muito completo é
http://www.blocks.fhcrc.org/~kinesin/
Entre os links ali mencionados, veja
http://www.scripps.edu/milligan/research/movies/kinesin_text.html
animações do laboratório de
Ron Vale (vale@phy.ucsf.edu)
Ron Milligan (milligan@scripps.edu)
Graham Johnson (graham@fiVth.com)
Para outros links em motores moleculares, ver http://motility.york.ac.uk:85/
(dali em diante, a navegação prosseguirá
de vento em popa, incluindo a home page da miosina)
---
Comecemos com a descrição do trabalho do
grupo da Universidade de York (as pessoas estão listadas no site)
http://motility.york.ac.uk:85/
"The Problem. It is well known that the breakdown of ATP
powers the generation of force by myosin (and most other molecular motors).
The biochemistry and kinetics of this process have been extensively studied,
and the mechanics of muscle contraction are well documented. Recently,
mechanical data for single molecules has been obtained. However, we still
lack a full understanding of the way that the biochemical and mechanical
events are coupled.
Questions in Coupling We know that the energy released
by the breakdown of a single ATP molecule is ~10-19 J. Recent optical tweezer
measurements have shown that skeletal muscle myosin moves in steps of 4-5nm,
and can generate a force of approximately 2pN. This would be equivalent
to ~10-20J of mechanical work per step. However there remain many questions
about coupling:
How many ATP molecules are consumed for each mechanical
step?
Which steps of the biochemical cycle produce force?
Are all the bound states of myosin mechanically equivalent?
What are the properties of mutant myosins and non-muscle
myosins (e.g. myosin I)?
Our Approach We believe that the best way to resolve these
issues is to make direct observations of the ATP hydrolysis and mechanical
events on a single myosin head. This can be achieved by combining two techniques:
Optical Tweezers and Total Internal Reflection Fluorescence Microscopy
(TIRFM). We are currently building the apparatus to perform these experiments."
---
Site do Grupo da Universidade de Munique IMPERDIVEL
http://www.med.uni-muenchen.de/phychem/zellbio/
Schliwa Lab: centrosome structure and dynamics using Dictyostelium
amebae as a model system; molecular motors, in particular kinesins of fungi;
optical tweezers
Schleicher Lab: actin-binding proteins of Dictyostelium
O site do grupo do Prof. Manfred Schliwa é fantástico.
Eis algumas informações:
Cell Biology of intracellular motility - http://www.med.unimuenchen.de/phychem/zellbio/tI/resIK2.html
"Eukaryotic cells are highly compartmentalized. Localization
of, and communication between, these compartments is mediated by cytoskeletal
polymers such as microtubules and molecular motors such as kinesin or dynein.
We are interested in the molecular basis of organelle transport and have
chosen to study the motor kinesin using Neurospoa crassa as a model system."
(Ver uma grande quantidade de links em http://www.med.uni-muenchen.de/phychem/zellbio/tO/linO.html)
----
Site de Julie Therriot (Stanford) IMPERDIVEL
http://cmgm.stanford.edu/theriot/
http://cmgm.stanford.edu/theriot/movies.htm
Este é outro site fantástico, de uma excelente
pesquisadora, que também tem a preocupação de divulgar
sua área ao público geral. Há filmes maravilhosos!
"Actin-Based Motility for the Non-Biologist. Imagine that
you're mostly made up of water. Well, you are, so you don't have to try
very hard. But now imagine that, instead of keratin-rich skin, the only
thing that holds you together is a thin bilayer of lipids--molecules which
are most familiar to most people as components of fat. Finally, imagine
that you're only 10 microns (.000010 meters) wide. Now you have a problem.
You're much, much smaller than most water droplets. Water droplets form
because of surface tension, which you're familiar with if you've ever watched
rain on the window. The water molecules organize themselves in such a way
that they can rise above the glass. These forces are so strong that if
you fill a straw with water and put your finger over the top, the water
won't run out the bottom, even though the water column is exerting a lot
of pressure on the tiny hemisphere of surface-tension-secured water at
the bottom. The narrower the straw, the higher the water column it can
hold.
So if you're only 10 microns wide, mostly water, and
held together by a flexible lipid-lined bag, you have a serious problem
which cells have confronted since their appearance in the primordial soup.
Surface tensionwill easily force you to collapse into a sphere. But cells
are rarely spherical: they can be cylindrical (intestine lining), amoeboid
(immune cells), long and slender (muscle cells), covered with protrusions
(neurons) or more. Moreover, cells can crawl, drastically changing their
shape in order to pull themselves along. Our job is to ask them how they
do it.
The answer starts with the cell's skeleton, a fibrous
network made up of filaments of varying thickness. Motility is mostly the
jurisdiction of actin filaments, whose remarkable strength helps resist
the forces of surface tension. Actin filaments are made up of protein monomers--individual
building blocksthat can be linked together like Legos to form long or short
chains. Other proteins in the cell bind actin filaments to link them together,
stop their growth, accelerate their growth, or chop them up. Yet other
proteins bind to actin monomers to regulate the biochemical equilibrium
between monomers and filaments. In other words, a cell's skeleton is nothing
like our skeleton in that it changes structure very quickly.
Our two favorite pathogenic bacteria--Listeria monocytogenes
and Shigella flexneri are excellent cell biologists. They understand actin-based
motility so well that when they invade into the interior of cells, they
hijack the cell's actin-based motility system to facilitate their own spread
into adjacent cells. Since their motility is easier to measure than that
of a cell, we spy on them as they've spied on cells, trying to learn what
they know.
Here's what we and other labs have figured out. Each bacterium
produces a single protein (ActA for Listeria or IcsA for Shigella) which
encourages the growth of new actin filaments at the bacterial surface.
As these filaments grow (polymerize), they exert force on the bacterium,
pushing it forward from the outside, much as actin filaments push their
cells forward from the inside. The bacterium rockets forward, leaving behind
a comet tail of short, highly networked actin-filaments which shrink (depolymerize)
over time. You can see one of these tails in the movie at the top of the
page.
Think of it like a jet contrail (800k file). Addition
of new material only occurs at the back of the 'organism,' and the organism
causes that addition. The tail is stationary with respect to its environment
(the cytoplasm or the atmosphere). And finally, that environment governs
how fast the tail falls apart (host proteins or wind).
In an incredible example of pathogenic evolution, these
bacteria become the terrorists of the cell, hijacking it's transportation
mode to ram them into the cell's membrane. The bacterium then protrudes
into an adjacent cell, and, upon escaping into the cell's neighbor, continues
dividing and spreading to other cells. By never exiting cytoplasm, the
bacterium avoids the commandos of the immune system: large, crawling cells
called macrophages which are constantly policing the body for harmful intruders
to eat.
By studying how these pathogens move, we deepen our understanding
of many biological problems. It's a two-for-one deal. On the bacterial
side, we can learn about the relationship between host and pathogen, helping
modern medicine combat the diseases caused by these organisms. Effects
of listeriosis and shigellosis include diarrhea, meningitis, spontaneous
abortions, and even death for immunocompromised individuals (children,
the elderly, AIDS patients). On the host cellular side, we can learn how
cells use their skeletons to change shape in developing tissues, how they
move in the development of a new organism, how wounds are healed by migrating
cells, how metastatic tumor cells crawl into the blood, and many otherphysiological
processes.
How cells hold or change their shape may seem at first
like an esoteric question. Yet to the cell, it's anything but. And since
cells make up every living thing on this planet, we think listening to
them is worth the effort.
------
Grupo de George Oster, Professor of Cell & Developmental
Biology, Berkeley,
http://nature.berkeley.edu/~goster/home.htmlVer
a "gallery" com as animações da ATP Synthase e outros motores
moleculares.
"My research involves construction and testing of theoretical
models of molecular, cellular and developmental processes. Current projects
include investigations into the basic physics and chemistry of protein
motors, cell motility and membrane organization."
LINDOS MODELOS MATEMATICOS ! Fizemos o "download"
de alguns artigos e filmes, voce encontrará mais no site.
artigos: 12
3 45
6 789
10 11 12 13 14 15 16 17
18 19 20
---
Site dos Profs. S. G. Boxer e A. van Oudenaarden (Geometrical
Brownian ratchets). Contém informações básicas
sobre o mecanismo dos ratchets, além de explicações
qualitativas sobre os ratchets geométricos estudados por eles.
http://www.stanford.edu/group/boxer/
http://web.mit.edu/biophysics/research.html
"Recently interest in Brownian ratchets and fluctuation-driven
transport has increased enormously because of the relevance of these concepts
for biological systems such as molecular motors, ion pumps, and for the
design of biomolecular sieves. Brownian ratchets have
the unique ability to exploit thermal fluctuations to drive directional
transport. A 2 dimensional fluid phospholipid bilayer membrane on a patterned
surface is an experimental realization of a particular type of Brownian
ratchet called a geometrical Brownian ratchet. This system has many of
the properties of interest in the general area of Brownian ratchets, can
be described quantitatively, and has potential applications in the separation
of membrane-associated molecules and assemblies.
Actin Propulsion Engines. Actin filaments are biopolymers
that can both polymerize (grow) and depolymerize (shrink). These highly
dynamical molecules are capable of exerting significant mechanical forces.
A complex of many actin filaments that is randomly growing and shrinking
is used by living cells to change shape and to move. How this inherently
stochastic process self-organizes in a well-defined propulsion engine is
a challenging problem that involves knowledge from both physics and biology."
---
Site do grupo do Prof. Eberhard Unger em Jena:
http://www.imb-jena.de/www_elmi/molcyto_cyto.html
http://www.imb-jena.de/www_elmi/molcyto_members.html#unger
na página do Prof. K.Boehm, há muitos links
ótimos para outros grupos, um tutorial, e "applets" sobre a kinesina.
http://www.imb-jena.de/~kboehm/
http://www.imb-jena.de/~kboehm/Kinesin.html
http://www.imb-jena.de/~kboehm/Tubulin.html
otimo review didatico
---
Site de Lawrence S.B. Goldstein (University of California
San Diego)
http://medicine.ucsd.edu/pharmaco/lsgoldstein.html
(o site do Departamento de Famacologia é interessante
de ser ver,
http://medicine.ucsd.edu/pharmaco/
e o de biologia http://www-biology.ucsd.edu/
http://biosciences.sdsc.edu/http://www-biology.ucsd.edu/
"My laboratory is interested in understanding the molecular
mechanisms of intracellular movement in neurons and the role of transport
dysfunction in neurodegenerative diseases. Our focus is on the attachment,
function, and regulation of kinesin and dynein microtubule motor proteins.
The major questions we are addressing are: 1) What role(s) do these motors
play in axonal transport, transport of visual system components in photoreceptors,
and transport of informational signaling molecules? 2) Does motor-driven
transport dysfunction play a major role in neurodegenerative diseases such
as retinitis pigmentosum and Alzheimer's disease? 3) How are kinesins and
dyneins coupled to intracellular cargoes and regulated? 4) How are appropriate
destinations in the neuron found (e.g., axons versus dendrites)? 5) Do
intracellular transport processes play important roles in neuronal cell
polarization, signaling, growth, and pathfinding? Technologically, our
work utilizes molecular and classical genetics, cell biology, and biochemistry
in D.melanogaster and M. musculus. Thus, we are making mutants in defined
motor proteins and inferring function by phenotypic analysis. We are also
using genetic screens to identify novel proteins that couple motors to
cargo and regulate their function."
---
Site de E. Frey (Physics Department, Harvard) e colaboradores
; ver os Java applets de Motores Moleculares)
http://cmtw.harvard.edu/~frey/
ver também de seus colaboradores:
http://WWW.Physik.TU-Muenchen.DE:81/~avilfan/ecmm/
(elastically coupled molecular motors)
http://www.ph.tum.de/~avilfan/relax/
(1-dim dimer absorption)
---
Site de Joe Howard, U. Washington
http://depts.washington.edu/pbiopage/faculty/howard.html
Ali podemos ver "applets" da kinesina andando, e modelo
como um ‘motor de combustão".
"Our laboratory is interested in the mechanical properties
of cells and molecules. How do cells detect and effect changes in their
mechanical environment? How do they establish and change shape? How do
they move? To answer these questions, we havedeveloped highly sensitive
techniques that allow us to visualize and manipulate individualmolecules,
and to measure directly the influence of forces on their structural conformations.
Using these techniques, we have measured the force required to open asingle
ion channel, we have determined the elasticity of individual cytoskeletal
filaments, and we have characterized the mechanical output - the force,
displacement and work - of single motor proteins. Current projects in the
lab include the following: (i) The molecular mechanisms of force generation
by motor proteins. By combining single-molecule techniques with biochemical
and protein-engineering methods, we hope to identify, at the amino acid
level, the moving parts that make up motor proteins- the springs, shafts,
and axles - and to understand how the motion of these parts is coupled
to the hydrolysis of ATP. (ii) The structural basis for the regulation
of motor proteins. We are trying to understand how motor proteins recognize
and bind to their cellular cargoes, and how the binding to the cargo leads
to the switching on of the motor activity. (iii) Mechanoelectrical transduction
by cutaneous sensory receptors. We are studying the cellular and molecular
mechanisms underlyingthe sensation of touch to the skin: which cells are
mechanoreceptive, what molecules and structures are initially perturbed
by the mechanical stimuli, and which ion channels are ultimately gated
by these mechanical forces? (iv) Remodeling of the extracellular matrix.
How do cells such fibroblasts reorient in response to forces in tissues
and how, in turn, does this lead to a reorientation and polarization of
the extracellular matrix.
---
Site de Frank Julicher (Instituto Curie)
http://perso.curie.fr/Frank.Julicher/
"The main focus of our research is the physics of nonequilibrium
processes in biological systems on the scale of the cell. Important examples
are the force and motion generation in cells by motor enzymes or assemblies
of such motors as well as the mechanical and dynamical properties of membranes,
filaments and the cytoskeleton. Some examples are: Sound Detection and
Sensory Systems (Auditory Sensitivity by Critical Oscillations of Hair
Cells); Active Processes in Biological Systems (Beating and Swimming of
Flagella and Cilia; A Stochastic Model for RNA Polymerase Motion along
DNA); Molecular Motors (Modelling Molecular Motors; Molecular Motors: From
Individual to Collective Behavior ); Energy Transduction and Efficiency
of Molecular Motors (Elastic Properties and Dynamics of the Cytosceleton;
Pulling on a Filament )"
A modelagem matemática é muito interessante!
---
Grupo do Prof. Nobutaka Hirokawa (Department of Cell Biology
and Anatomy, Graduate School of Medicine, University of Tokyo).
cb.m.u-tokyo.ac.jp/profile-hirokawa.html,
cb.m.u-tokyo.ac.jp/
Ver a excelente revisão: "the neurnal cytosqueleton"
.
O Prof. Hirokawa e seus colaboradores estão classificando as
famílias de kinesianas e seus tipos de locomoção.
Ver http://cb.m.u-tokyo.ac.jp/KIF/index.html
(Kinesin Superfamily Protein (KIF) Home Page) .
Outros exemplos de processos celulares envolvendo movimento
R. Bruce Nicklas (Duke University; http://www.dcmb.duke.edu/faculty/nicklas.htm
How Cells Get the Right Chromosomes? When cells divide,
the chromosomes must be delivered flawlessly to the daughter cells. Missing
or extra chromosomes can result in birth defects and cancer. Chance events
are the starting point for chromosome delivery, which makes the process
prone to error. Errors are avoided by diverse uses of mechanical tension
from mitotic forces. Tension stabilizes the proper chromosome configuration,
controls a cell cycle checkpoint, and changes chromosome chemistry. Every
time a cell divides, the daughter cells must get the right chromosomes.
For example, in humans, Down syndrome occurs when an error in meiosis results
in a child with an extra copy of chromosome 21. Beyond the cost in human
terms, Down syndrome has an estimated annual economic cost of $3.6 billion.
Cells with missing or extra chromosomes can be equally ruinous inadults,
by fueling the development of malignant cancer cells (2). Given the cost
of errors, it is not surprising that cells take pains to avoid them.
Site do Prof. Andrew Maniotis, U. Iowa (Movimento envolvido
em tumores )
http://www.anatomy.uiowa.edu/pages/directory/research/maniotis.html
"Tumor cells are like other cells in that they reqire
food, and a route by which they can eliminate waste. Recent observations
have suggested that a critical regulatory step in the primary growth and
spread of melanoma involves solid state mechanical changes that determine
the vascular architecture within the tumor microenvironment. Therefore,
we are defining how these solid state signaling pathways within human tumor
biopsies, and within various three-dimensional reconstituted experimental
systems control the responses of both host and tumor cells when tumor cells
of differing invasive, metastatic, or dormant potential interact with host
cells. In addition, we have discovered both in vivo and in vitro that invasive
tumor cells themselves have vasoformative potential which is distinctly
different than what is typically observed in normal tissues or in wounded
tissues. In normal cells, we have previously defined how tensionally continuous
molecular networks spanning between the extracellular matrix, the cytoskeleton,
and the genome control cell growth, and have now turned our attention toward
how tumor cells might use these mechanisms to control tumor vessel or sinusoid
formation, and host cell apoptosis. In addition, we have discovered that
certain classes of intermediate filaments and endothelial-specific epitopes
are uniquely expressed in aggressive tumor cells specifically along vascular
structures. To study how cells might control non-linear genetic responses
to differences in the mechanical environment, we are now utilizing a method
we have developed in which we microsurgically remove nucleoplasm or chromosomes
from living cells under isotonic conditions, without the use of detergents
or fixatives. Using this approach, we have learned to induce spontaneous
decondensation and recondensation of chromosome form and position throughout
an entire genome, and by manipulating proteases and certain exogenously
added proteins, we can reconstitute the complete human genome in normal
host endothelium and are applying this approach to tumor cells to identify
unknown condensing or decondensing proteins (histone H1, topoisomerases)
or other highly charged molecules. It is hoped that these approaches will
provide an experimental basis to understand and perhaps one day control
oncodevelopment, and aneuploidy."
Site de Stanilas Leibler (Princeton) Mecanismos moleculares
regulando a quimiotaxia das bactérias.
http://www.molbio.princeton.edu/faculty/leibler.html
In recent years, it has become clear that molecular biology
is facing a new challenge: to move from the description of individual components
and their mutual interactions toward system analysis. Such an analysis
would describe the functioning of systems of interacting biomolecules on
a more global level, much closer to a phenotypic, rather than a genetic,
description. In physics and chemistry, one often studies systems in which
many components interact with one another, giving rise to new "collective
phenomena." We are interested in such collective phenomena taking place
in biological systems. In particular, it is attractive to think that a
detailed study of the best known prototype systems could uncover the underlying
general "design principles." Even the simplest unicellular organisms, such
as bacteria, perform a sophisticated kind of "information processing."
For instance, Escherichia coli can direct itself in space by measuring
the temporal gradients of chemicals. The enzymatic network responsible
for chemotaxis is relatively simple (with a small number of components)
and is extremely well characterized at the molecular level. Yet the "system
analysis" of this signal transduction network is far from complete. We
do not understand the source of the sensitivity to small signals in chemotaxis,
the response to different competing signals, or the structural stability
of the circuit. Nor do we understand the reasons why common building blocks
such as phosphorylation cascades appear in these and other signal transduction
systems, or the evolutionary significance of the observed network architectures.
We have been studying, both theoretically and experimentally, the chemotaxis
network. Through quantitative analysis of bacterial behavior and modifications
of the intracellular biochemistry, we have been able to demonstrate that
this network presents some properties (such as adaptation precision) that
are "robust" with respect to variations of its individual components. Such
robustness is the consequence of the network’s connectivity, and it may
become one of the "design principles" for a large class of biological networks.
In addition, we are applying fluorescence correlation spectroscopy to monitor
the concentrations of the network’s components, while simultaneously analyzing
the behavior of individual bacteria. This allows us to determine the source
of the observed "nongenetic individuality," namely the large variations
in the behavior of genetically identical bacteria. We plan further to pursue
our studies of simple, prototype systems in search of a quantitative, "systemic"
description of their functioning. We have started preliminary experiments
and theoretical work on the following genetic and biochemical phenomena:
(1) Circadian rhythms in microorganisms. We are particularly interested
in the phenomenon of temperature compensation (independence of the internal
clock of temperature) and its physical/biochemical basis. (2) Epigenetic
cellular phenomena. Even the simplest gene regulation networks present
multiple steady-states which can be transmitted for many generations. We
plan to extend classical observations in the series of quantitative experiments
inbacterial systems. (3) Evolvability of simple networks. We are now trying
to build simple artificial networks from natural components (e.g., from
the networks of bacteria and phages), which would perform a predefined
function in vivo (e.g., an oscillator). Such experiments could become a
starting point for a more general study of networks-their classification,
compatibility, and evolvability. These are just a few examples of phenomena
governed by networks with a small number of known components. Over the
past decades, researchers have been gathering an enormous volume of data
(such as genomic DNA sequence information, transcript levels, etc.) across
a wide spectrum of biological systems. We are now trying to develop mathematical
and physical tools to extract information about signal transduction networks
based on the analysis of transcription levels under different conditions.
voltar ao indice
Nanotecnologia e sua interface biológica
A nanotecnologia deixou de ser ``science fiction''. Em breve a
prática médica sofrerá uma revolução.
fantasticvoyage feynman
Uma organização inteiramente dedicada a divulgação
da nanotecnologia é o Foresight Institute.
Recomendamos uma visita a sua página: http://www.foresight.org
. Outros sites estão relacionados
abaixo.
Reproduzimos aqui o artigo de Robert F. Service, "Nanotechnology:
Borrowing From Biology to Power the Petite, Science, volume 283, Number
5398 Issue of 1 Jan 1999, pp. 27 – 28:
Nanotechnology researchers are harvesting molecular
motors from cells
in hopes of using them to drive nano-sized devices
"If you received a molecule-sized car, snowmobile, or
jet ski for Christmas, you've probably realized by now that the thing is
totally useless. It just sits there on your microscope slide like an inert
dust speck, incapable of going for a spin around the cover slip. Okay,
so molecular vehicles are pure fantasy. But their immobility is a problem
that's all too real for would-be builders of nano-sized devices. Such devices
are so small, there's no obvious way to power them. Now, researchers are
turning to biology for what may be a possible solution: molecular motors
from living things.
Cells are packed with protein-based motors powered by
the chemical fuel of life, adenosine triphosphate, or ATP. These motors
ferry cargo, flex muscles, and even copy DNA. And at a recent meeting,*
two groups, one led by Carlo Montemagno of Cornell University in Ithaca,
New York, and the other by Viola Vogel of the University of Washington
in Seattle, reported taking the first baby steps toward harnessing these
motors to power nanotechnology devices. Like molecular mechanics, the researchers
have unbolted the motors from their cellular moorings, remounted them on
engineered surfaces, and demonstrated that they can in fact perform work,
such as twirling microscopic plastic beads. "What we're really trying to
do is makeengineered systems that tap into the energy system of life,"
says Montemagno.
The effort still has a long way to go. But the early work
is already generating enthusiasm in the community. "I think it's a very
productive path to follow," says Al Globus, a nanotechnology expert at
the National Aeronautics and Space Administration's Ames Research Center,
Moffat Field, California. If the effort does pan out, it could help researchers
make everything from tiny pumps that release lifesaving drugs when needed
to futuristic materials that heal themselves when damaged.
For their molecular motor, Montemagno and his colleagues
turned to one of the cell's heavy lifters: ATPase, a complex of nine types
of proteins that work together to generate ATP. While tiny--it measures
just 12 nanometers across and 12 high—this cellular motor is remarkably
sophisticated, containing a cylinder of six proteins surrounding a central
shaft. ATPase converts the movement of protons within the cell's energy
powerhouse, the mitochondrion, into a mechanical rotation of the shaft,
a motion that helps catalyze the formation of ATP. But the motor can also
run in reverse, burning ATPs to rotate the shaft and move protons.
Last year, Hiroyuki Noji and his colleagues at the Tokyo
Institute of Technology and Keio University in Yokohama, Japan, captured
this rotational motion on camera for the first time (see Science, 4 December,
p. 1844). They dangled a fluorescent-tagged molecule off the end of the
shaft, fed the motor ATP, then put it through a microscope and took sequential
pictures of the shaft as it rotated in circles around the cylinder.
Based on the number of rotations produced by a given amount
of ATP, the researchers calculated that the motor operates at near 100%
efficiency-- "well above the efficiency of motors we're capable of building,"
says Montemagno. "If the motor was as big as a person, it would be able
to spin a telephone pole about 2 kilometers long about one revolution per
second."
That result inspired Montemagno and his Cornell colleagues--George
Bachand, Scott Stelick, and Marlene Bachand--to see if they could use the
ATPase rotary motor to move man-made objects. They started by genetically
engineering two changes into ATPase proteins, one to stick the motors to
metal surfaces and the other to provide an attachment site for the beads
that they wanted the motor to move.
To make the first change, the team added an amino acid
sequence loaded with histidine, which binds tightly to metals, to the base
of the proteins that form the motor's cylinder. Next they used electron
beam lithography to pattern an array of nickel islands--each roughly 40
nanometers across--atop a glass microscope cover slip. When they then spritzed
water on top to keep the proteins happy and added the motors, the base
of the cylinders bound to the nickel islands, causing the motors tostand
upright.
To attach the beads, which were made of plastic or a plastic/iron
composite and coated with a small organic molecule called biotin, Montemagno
and his colleagues added cystine, a sulfur-containing amino acid, to the
top of the central shaft. That allowed the shaft to grab a small sulfur-binding
protein called streptavidin, which could in turn bind the biotin-coated
beads. When the researchers then added ATP fuel to the solution atop the
slide and used a laser-based interferometer to track the beads' movement,
they could see their array of motors twirling in endless loops, like a
dance floor of nano-sized dervishes. "I had the thing running for well
over 2 hours at a time," says Montemagno. "It was seriously cool."
But whirling beads--impressive as they may be--are still
a long way from nanorobots rooting through the body. So Montemagno's team
is pressing ahead. They're currently working on replacing the beads with
tiny magnetic bars. If the motors spin the bars, the researchers will be
able to measure precisely how strong the motors are by applying an outside
magnetic field: By increasing the field until the motors can no longer
spin, they will be able to probe the limit of the motor's power.
What's more, the spinning bars should generate an electrical
current that might eventually be used to power devices, such as chip-based
drug delivery pumps or chemical weapons sensors implanted in the body.
But these uses, Montemagno says, are just the beginning. "There's 100,000
different things you could do with these motors," he says.
Washington's Vogel says much the same thing about her
team's contraption, a nanoscale monorail in which a collection of molecular
motors all lined up on a surface pass a tiny tube hand over hand down the
line. Vogel based her monorail on one of the cell's own transport systems,
which consists of tracks made of microtubules, tube-shaped assemblies of
a protein called tubulin, and small motors made of another protein, kinesin.
In cells, the kinesin motors latch onto the fixed microtubules and churn
like steam engines from one end of the line to the other, ferrying molecular
cargo such as proteins and lipids. But for their experiment, Vogel and
her colleagues John Dennis and Jonathan Howard reversed these roles, fastening
kinesin motors to a surface and having them shuttle microtubules down the
line from one motor to the next.
Biophysicists studying kinesin motors had done related
experiments in the past. But in those, Vogel says, the kinesins were in
random locations on surfaces. When microtubules and ATP were then added,
the kinesins shuttled microtubules in all directions. To control the transport,
the Washington team had to line up the kinesins. Here, the researchers
took a low-tech approach. They simply rubbed a block of polytetrafluoroethylene,
or PFTE, across a glass slide, causing molecules of the chainlike polymers
to rub off and coat it. The scraping acted something like a hair brush,
getting all the PFTE chains to line upon the surface, creating a series
of grooves running for micrometers along the slide.
After submerging the slides in water and coating them
with a small protein called casein, to protect overlying proteins, they
added the kinesin motors, which settled into the grooves. They then sprinkled
on a few microtubules, which were tagged with fluorescent compounds so
they could be seen, and dropped some ATP fuel into the solution.
By turning on a xenon lamp to set the microtubules aglow
and letting their cameras roll, Vogel and her colleagues could see the
kinesins push their tubular cargo in one direction, moving it hand over
hand down the parallel grooves. "Even though kinesins move on the nanoscale,
we could watch the microtubules move on the micron scale," says Vogel.
For now, the team is using the monorail to study the performance
of their motors. But down the road, Vogel says that the tinyrail lines
could be used to transport replacement components for self-healing biomaterials
for medical implants. If this and other efforts to motorize the nanoworld
are successful, those microscope slides may soon see their first traffic
jams.
Sites em nanotecnologia
Podemos começar com o home page da nanotecnologia.
http://www.zyvex.com/nano/
e
recomendamos a leitura do artigo de Feynman, "There’s plenty of room in
the bottom".
"Legos" em escala atomica. (Science vol. 284, 21/05/99
pg. 1231,Net Watch)
Máquinas em escala atômica estão se
tornando realidade. Ver as imagens e videos da NASA Ames em http://www.nas.nasa.gov/Groups/Nanotechnology/gallery
Por exemplo as, "Fullerene Gears" (14,0) tube based gear:
gear.jpg; largeSystem.jpg .
A idéia é usar padrões de fluor e
hidrogenio numa superficie de carbono para guardar bits de dados. Para
ler os dados, voce passa um buckytubo de carbono preso a um microscopio
de varredura (scanning probe). Este esquema permitiria ler 10.000.000 mais
dados por área do que os atuais discos óticos.
A Universidade de Cornell tem um grande centro em nanotecnologia.
Ver
http://www.nbtc.cornell.edu/
http://www.cnf.cornell.edu/
Sugerimos ver a página do Prof. Carlo Montemagno
(Agricultural and Biological Engineering)
Dr. Montemagno's research is focused on the application
of nanotechnology to biological systems. His current projects are directed
at the development of biomolecular motor powered nanoelectromechanical
devices and the engineering of on-chip detectors for pathogens. "My current
and near term investigations focus upon the development of numeric and
experimental techniques to explore: 1) methods of integrating single molecule
biological motors with nanoscale silicon devices; 2) the influence of interfaces
in multiphase fluid flow through and within biological materials; 3) the
role of fluid-fluid and biological interfaces in the transport of nutrients
and chemicals between the physical and biological domains; 4) fracture/pore
geometry and its contribution to the transport of fluids and microorganisms
in porous media; 5) the role of the cytoskeleton in processing intracellular
information; and 6) biological processing of organic wastes."
Para alguns recursos para professores, ver a página
educacional nestes sites e também
http://www.nanospace.systems.org/ns_2000/NS00_Sessions.htm
Outros reviews em nanotecnologia:
http://www.resonance-pub.com/nanotech.htm(este
é um portal em divulgação da ciencia)
Micro/Nanotechnology Conference -- http://www.aero.org/conferences/micro-nano/
No ETH Zurich, http://www.nanotechnology.ethz.ch/
A Duke University tem também um centro integrado
em Bioengenharia: ver
http://bme-www.mc.duke.edu/Research/Cellsurf/faculty.html
(Cellular and Biosurface Engineering):
Although centered in the school of engineering, the CBE
faculty members have primary and/or secondary appointments in one of seven
degree granting entities - the Departments of Biochemistry, Biomedical
Engineering, Cell Biology, Chemistry, Electrical Engineering, and Mechanical
Engineering and Materials Science - or in clinical departments training
program provide strong expertise in biomaterials, material property characterizations,
functional evaluation, surface modifications, cell culture, and tissue
and cell biomechanics. Chemistry faculty affiliated with the training program
provide expertise in patterned surface, protein immobilization, and separations.
Faculty from the biomedical sciences provide expertise in cellular physiology,
biophysics, protein engineering, protein structure and function, tumor
oncology, and cell culture. The research interests of the participating
departments cover a wide range of fundamental and applied topics, many
of which are important to biotechnology.
Ainda em Duke, http://www.zoology.duke.edu/crenshaw/,
Grupo do Prof. Crenshaw.
Distributed Robotics: The Micro-Hunter project is a collaborative
research effort between the Crenshaw Laboratory and Nekton Technology Incorporated,
sponsored by DARPA. The goal of the project is to construct small, cheap,
reliable aquatic robots, whose primary objective will be to gather underwater
data. The project is well underway, and is expected to deliver a maneuverable
robot within the next three years. Our contribution to this project is
twofold: (1) design of orientation algorithms, and (2) analysis of the
motion of robots.
Locomotion and Orientation of Micro-organisms: The locomotion
and orientation of micro-organisms has been studied since people first
observed them with microscopes. Nevertheless, these processes remain poorly
understood. The Crenshaw lab has examined the orientation of free-swimming
single cells (spermatozoa, flagellates, and ciliates) for 10 years. We
have developed new techniques for collecting and analyzing the 3D trajectories
of freely swimming cells to examine the responses of these cells to external
stimuli, such as beams of light and concentration gradients of chemicals.
Our primary objective has been to test the theory of helical klinotaxis
(references below) to determine if these cells use this mechanism of orientation.
Our research has in more recent years turned to different levels of biological
organization, studying both molecular mechanisms of signal transduction
in protists and the ramifications of orientation behaviors on the distributions
of protists in natural environments.
Fig. 7 (Celular Automata)Paramecia, protozoa
about 100 microns length, are very sophisticated ``Celulas Automatas’’.
Ray Fearing, from Berkeley Electrical Engineering, showed that they can
learn to perform tasks such us doing a baseball run If completely domesticated
they could to become micro-robotic workhorses. They do not need to be fueled
and their fabrication is ridiculously inexpensive.
voltar ao inicio
