7 research outputs found
Bacteria colonies modify their shear and compressive mechanical properties in response to different growth substrates
Bacteria build multicellular communities termed biofilms, which are often
encased in a self-secreted extracellular matrix that gives the community
mechanical strength and protection against harsh chemicals. How bacteria
assemble distinct multicellular structures in response to different
environmental conditions remains incompletely understood. Here, we investigated
the connection between bacteria colony mechanics and the colony growth
substrate by measuring the oscillatory shear and compressive rheology of
bacteria colonies grown on agar substrates. We found that bacteria colonies
modify their own mechanical properties in response to shear and uniaxial
compression with the increasing agar concentration of their growth substrate.
These findings highlight that mechanical interactions between bacteria and
their microenvironment are an important element in bacteria colony development,
which can aid in developing strategies to disrupt or reduce biofilm growth.Comment: biophysics, soft matter, biofilm rheology, biofilm mechanic
Materials science and mechanosensitivity of living matter
Living systems are composed of molecules that are synthesized by cells that use energy sources within their surroundings to create fascinating materials that have mechanical properties optimized for their biological function. Their functionality is a ubiquitous aspect of our lives. We use wood to construct furniture, bacterial colonies to modify the texture of dairy products and other foods, intestines as violin strings, bladders in bagpipes, and so on. The mechanical properties of these biological materials differ from those of other simpler synthetic elastomers, glasses, and crystals. Reproducing their mechanical properties synthetically or from first principles is still often unattainable. The challenge is that biomaterials often exist far from equilibrium, either in a kinetically arrested state or in an energy consuming active state that is not yet possible to reproduce de novo. Also, the design principles that form biological materials often result in nonlinear responses of stress to strain, or force to displacement, and theoretical models to explain these nonlinear effects are in relatively early stages of development compared to the predictive models for rubberlike elastomers or metals. In this Review, we summarize some of the most common and striking mechanical features of biological materials and make comparisons among animal, plant, fungal, and bacterial systems. We also summarize some of the mechanisms by which living systems develop forces that shape biological matter and examine newly discovered mechanisms by which cells sense and respond to the forces they generate themselves, which are resisted by their environment, or that are exerted upon them by their environment. Within this framework, we discuss examples of how physical methods are being applied to cell biology and bioengineering
Mechanobiology as a tool for addressing the genotype-to- phenotype problem in microbiology
The central hypothesis of the genotype–phenotype relationship is that the phenotype of a developing organism (i.e., its set of observable attributes) depends on its genome and the environment. However, as we learn more about the genetics and biochemistry of living systems, our understanding does not fully extend to the complex multiscale nature of how cells move, interact, and organize; this gap in understanding is referred to as the genotype-to-phenotype problem. The physics of soft matter sets the background on which living organisms evolved, and the cell environment is a strong determinant of cell phenotype. This inevitably leads to challenges as the full function of many genes, and the diversity of cellular behaviors cannot be assessed without wide screens of environmental conditions. Cellular mechanobiology is an emerging field that provides methodologies to understand how cells integrate chemical and physical environmental stress and signals, and how they are transduced to control cell function. Biofilm forming bacteria represent an attractive model because they are fast growing, genetically malleable and can display sophisticated self-organizing developmental behaviors similar to those found in higher organisms. Here, we propose mechanobiology as a new area of study in prokaryotic systems and describe its potential for unveiling new links between an organism\u27s genome and phenome
A Torsion-Based Rheometer for Measuring Viscoelastic Material Properties
Rheology and the study of viscoelastic materials are an integral
part of engineering and the study of biophysical systems. Tissue rheology is even
used in the study of cancer and other diseases. However, the cost of a rheometer is
feasible only for colleges, universities, and research laboratories. Even if a rheometer
can be purchased, it is bulky and delicately calibrated, limiting its usefulness to the
laboratory itself. The design presented here is less than a tenth of the cost of a
professional rheometer. The design is also portable, making it the ideal solution to
introduce viscoelasticity to high school students as well as for use in the field for
obtaining rheological data
Bacteria Colonies Modify Their Shear and Compressive Mechanical Properties in Response to Different Growth Substrates
Bacteria build multicellular communities termed biofilms,
which
are often encased in a self-secreted extracellular matrix that gives
the community mechanical strength and protection against harsh chemicals.
How bacteria assemble distinct multicellular structures in response
to different environmental conditions remains incompletely understood.
Here, we investigated the connection between bacteria colony mechanics
and the colony growth substrate by measuring the oscillatory shear
and compressive rheology of bacteria colonies grown on agar substrates.
We found that bacteria colonies modify their own mechanical properties
in response to shear and uniaxial compression in a manner that depends
on the concentration of agar in their growth substrate. These findings
highlight that mechanical interactions between bacteria and their
microenvironments are an important element in bacteria colony development,
which can aid in developing strategies to disrupt or reduce biofilm
growth