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April 16, 2024 feature

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Spiraling insights: Scientists observe mechanical waves in bacterial
communities

by Tejasri Gururaj , Phys.org

Spiraling insights: Scientists observe mechanical waves in bacterial
communities Propagating spiral waves in a bacterial film ~2 mm in
diameter. The color map represents the phase angle distribution of
the wave pattern. Credit: Dr. Shiqi Liu

A new study by researchers from The Chinese University of Hong Kong
has reported the emergence of mechanical spiral waves in bacterial
matter.

Spiral waves are commonly seen in artificial and natural systems
(such as the heart). These emerge from interactions of neighboring
elements, such as cardiac cells in the case of the heart. These
spiral waves can have varying effects, sometimes leading to
life-threatening conditions like fibrillation in the heart.

The new study, published in Nature Physics, explores spiral waves in
bacteria--something that has not been observed before. In particular,
the researchers' focus was on the species Pseudomonas aeruginosa.
These are commonly found in soil and water and are also known to
colonize hospitals.

The research is a continuation of their previous work where the
authors studied long-range material transport in bacterial
communities via open fluid channels.

Co-author of the study, Dr. Shiqi Liu, told Phys.org, "While we
studied the development of bacterial canals, we discovered signatures
of density waves and were intrigued by this beautiful wave pattern."

Spiral waves mapped in live human hearts.

Pilus motors

These spiral waves as observed by the researchers in bacteria are an
emergent phenomenon. Emergent phenomena are a crucial aspect of
complex systems, which are systems where the interaction of
individual entities leads to phenomena that otherwise can't be
observed.

This means we need to understand what is happening at the level of
each entity, which in this case is a Pseudomonas aeruginosa
bacterium. These bacteria have pilus motors, which are the key to the
spiral waves.

Pilus motors are molecular motors, which are attached to pili--thin,
hair-like appendages present on the bacterial cell surface. These
motors play an important role in various processes for the bacterium,
such as movement and surface attachment.

"The propagating spiral waves resulted from the coordinated activity
of the pilus motor, a grappling-hook-like motile organelle found in
many bacterial species," explained a co-author of the study, Dr.
Yilin Wu.

The mechanical movements of the pilus motors in many bacteria result
in these spiral waves, which are like ripples on the bacterial
surface.

[INS::INS]

Protein markers and coupled oscillators

To study the spiral waves, the researchers employed both experimental
techniques and mathematical modeling.

The researchers relied on using fluorescent protein as markers. They
tracked the movement of individual cells by labeling a small fraction
of the population with these fluorescent proteins.

Then, they used a microscope to observe the behavior of individual
bacteria and bacterial populations. Researchers also used the markers
to track cell densities to visualize the spatial distribution of
cells within the bacterial populations.

To further understand the role of pilus motor activity in spiral wave
generation, the researchers treated bacterial populations with drugs
known to affect pilus motor activity. By observing the effects of
these treatments on wave dynamics, they could infer the importance of
pilus motors in wave formation.

Finally, the researchers developed a mathematical model based on
coupled oscillators, where the movement of one oscillator affects the
others and vice versa. The mathematical model was built to simulate
the behavior of bacterial populations and to validate their
experimental work.

Non-reciprocating interactions and large-scale coordination

The researchers found that the spiral waves resulted from the
coordinated activity of pilus motors. They also observed that the
waves were self-sustaining and stable, with nearly stationary spiral
cores.

This stability is a characteristic shared by certain types of
electrical and chemical spiral waves found in other living systems.
However, the spiral waves observed in the bacteria are distinct from
the other spiral waves.

Dr. Liu explained, "The spiral tension waves we discovered in
bacterial populations are due to cyclic mechanical processes at the
single-cell level, distinct from the spiral waves in most chemical/
biological processes, where the spiral waves are in the form of
oscillating chemical concentration."

"Moreover, the spiral tension waves in bacterial populations
spontaneously emerge without external stimulation or inhomogeneity,
while the spiral waves in many other systems require stimulation or
spatial inhomogeneity."

Further, the researchers demonstrated the role of non-reciprocal
interactions between bacterial cells on the spiral waves. They found
that these interactions (which are asymmetric, meaning that the
impact of one cell on another is not mirrored) are essential for the
stable formation of spiral waves.

Essentially, this means that these interactions can lead to a form of
self-organization (or sustenance) that gives rise to collective
behaviors at a large scale or emergent phenomenon, such as the
propagation of spiral waves.

Biofilms and dispersal

The findings shed light on bacterial populations and behavior, such
as the formation of biofilms.

When bacteria adhere to a surface, it does so by producing
extracellular polymeric substances (EPS). This substance forms a
structured community known as biofilm, such that the bacteria is
embedded in a matrix of EPS, protecting the bacteria from
environmental stresses like antibiotics and host immune responses.

This entire process, known as the formation of biofilms, is essential
for the survival of bacterial colonies. The opposite of this
phenomenon--dispersal--is equally important.

When bacteria within a biofilm detach and spread to new locations, it
is known as dispersal. Dispersal can occur in response to
environmental cues, nutrient availability, or as part of the life
cycle of the bacteria.

This mechanism can help bacteria colonize new surfaces or host
environments and can influence the spread of infectious diseases or
the formation of microbial communities in various ecosystems.

The researchers believe that the pilus motors not only serve as
mechanical actuators but also as sensors. This means that they can
detect mechanical stimuli in the environment in the environment,
which allows for synchronized movements within bacterial populations.

"We believe that the coordination or coupling of pilus activities
allows bacterial populations to control large-scale tension forces
and may influence their dispersal," explained Dr. Wu.

Therefore, understanding spiral waves can help to understand the
behavior of bacterial species.

Additionally, stationary spiral waves are found in many diverse
systems. "The wave pattern in the pilus-powered bacterial matter may,
therefore, provide a tractable mechanical analog for investigating
the origin and control of stable spiral waves in diverse living
systems, such as cardiac tissues," explained Dr. Liu.

For future work, the researchers want to study how spiral waves can
be controlled.

"The information may guide the control of stable spiral waves in
other living systems. For instance, controlling spiral waves in heart
tissues associated with life-threatening cardiac arrhythmia," said
Dr. Wu.

More information: Shiqi Liu et al, Emergence of large-scale
mechanical spiral waves in bacterial living matter, Nature Physics
(2024). DOI: 10.1038/s41567-024-02457-5

Journal information: Nature Physics  

(c) 2024 Science X Network

Citation: Spiraling insights: Scientists observe mechanical waves in
bacterial communities (2024, April 16) retrieved 17 April 2024 from
https://phys.org/news/
2024-04-spiraling-insights-scientists-mechanical-bacterial.html
This document is subject to copyright. Apart from any fair dealing
for the purpose of private study or research, no part may be
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