The Division of Materials Research and the Division of Molecular and Cellular Biosciences contribute funds to this award. This award supports theoretical and computational research and education to understand the physical mechanism by which living organisms propel themselves.

Certain motile biological objects, such as the bacterium Listeria monocytogenes and replicating chromosomes in asymmetric bacteria like Caulobacter crescentus and Vibrio cholerae, generate their propulsion by polymerizing or depolymerizing protein filaments. This establishes a concentration gradient in the protein so that there are more filaments on one side of the object than the other.

A colloid that maintains an asymmetric concentration of a small solute around it will propel itself through a fluid with a well-defined velocity. This phenomenon, known as self-diffusiophoresis, has been exploited as a means of propulsion of micro- or nano-swimmers. In a typical example, the concentration gradient is controlled by an active region on the colloid that catalyzes a chemical reaction, leading to more product and less reactant near the active region than on the far side of the colloid. The distribution of solute around the colloid is determined by a combination of diffusion and advection. An interaction between the colloid and solute sets up fluid flow that ultimately propels the particle. If the solute is small, so that its diffusion is rapid compared to advection, it is known that only two conditions are needed to achieve motility: the motile object must be able to maintain an asymmetric solute distribution in steady state, and there must be a net interaction between the solute and the object.

This award supports theoretical and computational research aimed at understanding a new regime relevant to Listeria, Caulobacter and Vibrio, in which the particle surface catalyzes self-assembly or disassembly rather than a chemical reaction involving simple ions or molecules. Questions to be addressed include: Can the mechanism of self-diffusiophoresis explain effects of biological perturbations that have been studied experimentally? Does it suffice to produce an asymmetric concentration profile of a solute when the solute is large and has an effectively vanishing diffusion constant, as in the biological examples? How does self-diffusiophoresis differ in the advection and diffusion-dominated regimes? Might motility driven by self-assembly and disassembly of filaments be more robust to opposing forces than motility driven by chemical reactions involving simple solutes?

The project will train students at the interface of physics and biology to combine biophysics and far-from-equilibrium physics, two areas that have been identified as grand challenges for condensed matter and materials physics in the NRC CMMP-2010 study. Students will be trained both in interdisciplinary model-building and in computational methods, providing versatility for their entry into the workforce.

Nontechnical Summary

The Division of Materials Research and the Division of Molecular and Cellular Biosciences contribute funds to this award. This award supports theoretical and computational research designed to understand how certain living organisms - particularly bacteria or components within bacteria such as chromosomes - propel themselves. Such organisms live in a fluid environment so they must swim. Bacteria such as Listeria monocytogenes, responsible for listeriosis, generate branched filaments at their rear that propel them forward so that they can infect other cells, while chromosomes in Vibrio cholera, responsible for cholera, disassemble protein filaments in front of them in order to move across the cell before the cell divides. It is known that micron-sized particles that are coated on one side with a chemical reaction enabling material such as platinum can propel themselves through a fluid by enabling a chemical reaction at the surface. In that case, an interaction between the product or reactant and the particle surface drives fluid flow that ultimately propels the particles forward. But the interplay of filament assembly and disassembly on fluid flow is very different from that of simple chemical reactions with fluid flow. The aim of this research is to understand the physical mechanism by which the assembly or disassembly of filaments can drive motion, and to explore whether such locomotion might be more robust to physical and biochemical perturbations than the simple reaction-driven locomotion that has been studied in the materials community.

Filament-assembly-driven propulsion is key to many immune processes in living organisms, including how immune cells move, how cancer cells spread and how cells migrate during wound healing. A better understanding of the physical mechanism underlying how these cells move may be important to developing ways of helping or hindering them. These biological realizations, which have evolved to be remarkably robust, may also inspire better motile materials such as micro- or nano-swimmers that can move forwards against large opposing forces and may be useful for applications including drug delivery.

This award will prepare graduate students for rapidly evolving challenges in the workforce by training them in model-building and computational methods at the intersection of the physical and life sciences. The exposure to different fields and opportunity to work directly with biologists as well as theoretical, computational and experimental physicists will prepare them to collaborate and communicate effectively with colleagues with very different areas of expertise.

Agency
National Science Foundation (NSF)
Institute
Division of Materials Research (DMR)
Type
Standard Grant (Standard)
Application #
1104637
Program Officer
Daryl Hess
Project Start
Project End
Budget Start
2011-09-15
Budget End
2016-08-31
Support Year
Fiscal Year
2011
Total Cost
$545,000
Indirect Cost
Name
University of Pennsylvania
Department
Type
DUNS #
City
Philadelphia
State
PA
Country
United States
Zip Code
19104