Biofilms appear to be getting
better understood. We learn the cells
take advantage of osmosis to do the job of colonizing a surface. One develops respect for this process which
also is fundamental to a lot of damaging processes including tooth decay.
All good stuff
These could well be precursors in evolution to the development of slime moulds.
The Mighty Mesh Of Biofilms
by Staff Writers
Top view of a Bacillus subtilis colony in conditions where
extracellular matrix is produced, leading to biofilm formation.
New research at Harvard explains how bacterial biofilms expand to form
slimy mats on teeth, pipes, surgical instruments, and crops. Through experiment
and mathematical analysis, researchers have shown that the extracellular matrix
(ECM), a mesh of proteins and sugars that can form outside bacterial cells,
creates osmotic pressure that forces biofilms to swell and spread.
The ECM mechanism is so powerful that it can increase the radius of
some biofilms five-fold within 24 hours.
The results have been published in the Proceedings of the National Academy
Biofilms, large colonies of bacteria that adhere to surfaces,
can be harmful in a wide range of settings, resulting in tooth decay,
hospital infections, agricultural damage, and corrosion. Finding ways to
control or eliminate biofilms is a priority for many industries.
In order for a biofilm to grow, a group of bacterial cells must first
adhere to a surface and then proliferate and spread. When a vast number of
cells are present, this can translate into the creation of a filmy surface
spanning several meters.
"Our work challenges
the common picture of biofilms as sedentary communities by showing how cells
in a biofilm cooperate to colonize surfaces," says lead author Agnese
Seminara, a research associate at the Harvard School of Engineering and Applied
Sciences (SEAS).
Several types of biofilms have been characterized based on composition
and antibiotic resistance, but until now it has not been clear what roles the
whip-like flagella and the ECM play in the outward movement of cells.
While the presence of a flagellum has traditionally been associated
with greater movement capability, the new research has found that a flagellum
actually confers little advantage in the formation of biofilms. In the Harvard study,
mutant bacteria lacking flagella were able to spread at almost the same rate as
the wild-type (natural) ones. Mutants that could not secrete the ECM, however,
showed stunted growth.
The team of physicists, mathematicians, chemists, and biologists
examined the formation of biofilms in Bacillus subtilis, a type of rod-shaped
bacteria often found in soil. Their focus on this particular species was led by
Roberto Kolter, Professor of Microbiology and Immunobiology at Harvard Medical School,
an expert on biofilms and the genomics of B. subtilis.
"This project establishes a link between the phenotype, the
physically observable traits of biofilm growth, and the genetic underpinning
that allows spreading to happen in B. subtilis," notes co-principal
investigator Michael Brenner, the Glover Professor of Applied Mathematics and
Applied Physics at SEAS.
The researchers had speculated about a possible connection between the
biofilm's quest for nutrition and the process of spreading. Because biofilms
absorb nutrients through their exposed surface area, they can only swell
vertically to a certain point before the surface-area-to-volume ratio makes it
impossible to adequately nourish every cell.
At this point, the biofilm must begin to spread outward so that the
surface area increases along with the number of cells.
The ECM, a complex mesh of proteins, sugars, and other components
outside of the individual cells, holds the key to one aspect of this movement:
it apparently increases osmotic pressure within the biofilm.
In response to the increased pressure, the biofilm immediately
absorbs water from its surroundings, causing the entire mass to swell upward.
The final change in the shape of the biofilm is due to a combination of this
swelling and the horizontal spreading that follows.
Seminara and Brenner created a mathematical model that mirrored many of
the team's physical observations. The model supported the experimental
observations; by considering the relationship between swelling and spreading,
they were able to find the "critical" time at which horizontal
outward motion begins.
"This work is led by theoretical predictions which were tested by
experiment and proved to be correct," reflects co-principal investigator
David Weitz, Mallinckrodt Professor of Physics and Applied Physics at SEAS and
Co-Director of the BASF Advanced Research Initiative at Harvard. "
The results also demonstrate how simple physical principles can provide
considerable insight into the behavior of biofilms."
The motion of biofilms represents only a small part of a complex
subject. Further research will investigate how biofilms adapt and possibly
manipulate their environment. The ultimate goal is to alter biofilms' behavior
to minimize their harmful effects.
"The natural question at this point is: do cells actively
control biofilm expansion and can they direct it toward desired targets?"
says Seminara. "This is a first step toward understanding the striking
evolutionary success of these ubiquitous organisms, and it may open the way to
unconventional methods of biofilm control."
Seminara, Brenner, and Weitz worked with Thomas Angelini, an Assistant
Professor at the University of Florida and a former member of the Weitz lab;
James Wilking, a SEAS research associate in applied chemistry; Senan Ebrahim
'12, an undergraduate at Harvard; and Hera Vlamakis and Roberto Kolter of
Harvard Medical School.
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