Sunday, 9 October 2022

The thinking undead: How dormant bacteria calculate their return to life

OCTOBER 6, 2022, by U. of California - San Diego

Custom artwork illustrates an abacus made from bacterial cells known as spores used to count stimuli.
 Credit: Anne Hashimoto

Facing starvation and stress conditions, some bacteria enter a dormant state in which life processes stop. Shutting down into a deep dormancy allows these cells, called spores, to withstand punishing extremes of heat, pressure and even the harsh conditions of outer space.

Eventually, when conditions become favorable, spores that may have been dormant for years can wake up in minutes and spring back to life.

Spores wake up by re-hydrating and restarting their metabolism and physiology. But until now scientists did not know whether spores can monitor their environment "in their sleep" without waking up. In particular it was not known how spores deal with vague environmental signals that do not indicate clearly favorable conditions. Would spores just ignore such mixed conditions or take note?

University of California San Diego biologists have solved this mystery in a new study published in the journal Science. Researchers in the School of Biological Sciences discovered that spores have an extraordinary ability to evaluate their surrounding environment while remaining in a physiologically dead state. They found that spores use stored electrochemical energy, acting like a capacitor, to determine whether conditions are suitable for a return to normal functioning life.

https://youtu.be/p-oOhtKbhTs
A microscopy time-lapse movie depicts the color-coded electrochemical potential value overlaid on top of the phase image of a single spore. As revealed by the phase image, the spore remains dormant while exhibiting the ability to count stimuli, as indicated by the multicolor-coded flashes of electrochemical potential changes. 
Credit: Süel Lab—Kaito Kikuchi

"This work changes the way we think about spores, which were considered to be inert objects," said Gürol Süel, a professor in the Department of Molecular Biology. "We show that cells in a deeply dormant state have the ability to process information. We discovered that spores can release their stored electrochemical potential energy to perform a computation about their environment without the need for metabolic activity."

Many bacterial species form spores—partially dehydrated cells surrounded by a resilient protective coat—as a survival strategy that allows them to remain dormant for thousands of years. Such a remarkable capability makes them a threat in the form of bacterial anthrax as well as a contamination hazard in medicine and the food industry.

https://youtu.be/qPhZRQRUibQ
This microscopy time-lapse movie shows the color-coded jumps in electrochemical potential value of a single spore in response to short stimuli. With each stimulus, the spore gets closer and closer to exiting dormancy, as visualized by the color transitioning from deep purple to yellow. 
Credit: Süel Lab—Kaito Kikuchi

Süel and his colleagues tested whether dormant Bacillus subtilis spores could sense short-lived environmental signals that were not strong enough to trigger a return to life. They found that spores were able to count such small inputs and if the sum reached a certain threshold, they would decide to exit the dormant state and resume biological activity.

Developing a mathematical model to help explain the process, the researchers discovered that spores use a mechanism known as integrate-and-fire, based on fluxes of potassium ions for appraising the surrounding environment. They found that spores responded to even short-lived favorable signals that were not enough to trigger an exit from dormancy. Instead of waking up, spores released some of their stored potassium in response to each small input and then summed consecutive favorable signals to determine if conditions were suitable for exiting. Such a cumulative signal processing strategy can reveal whether external conditions are indeed favorable, and prevents spores from "jumping the gun" into a world of unfavorable conditions.

https://youtu.be/-gO4kAaBOn0
A composite movie showing the phase contrast of a single spore (top left) to visualize the dormant state. A movie (top right) shows the color-coded electrochemical potential of the same spore. The plot (bottom left) shows the corresponding time trace of the electrochemical potential values changing over time. Finally, a corresponding bar plot (bottom right) visualizes the jumps toward the threshold for returning to life. 
Credit: Süel Lab

"The way spores process information is similar to how neurons operate in our brain," said Süel. "In both bacteria and neurons, small and short inputs are added up over time to determine if a threshold is reached. Upon reaching the threshold spores initiate their return to life, while neurons fire an action potential to communicate with other neurons." Interestingly, spores can perform this signal integration without requiring any metabolic energy, while neurons are among the most energy-dependent cells in our bodies.

A microscopy image reveals several spores with their electrochemical potential color-coded according to the strength of the signal. Credit: Süel Lab—Kaito Kikuchi and Leticia Galera

The researchers believe the new information about spores reframes popular ideas about cells in extremely dormant states that seem dead. Such findings hold implications for evaluating life on objects such as meteors as well as space missions seeking evidence of life.

"This work suggests alternate ways to cope with the potential threat posed by pathogenic spores and has implications for what to expect from extraterrestrial life," said Süel, who holds affiliations with the San Diego Center for Systems Biology, BioCircuits Institute and Center for Microbiome Innovation. "If scientists find life on Mars or Venus, it is likely to be in a dormant state and we now know that a life form that appears to be completely inert may still be capable of thinking about its next steps."

Authors of the Science paper include: Kaito Kikuchi, Leticia Galera-Laporta, Colleen Weatherwax, Jamie Lam, Eun Chae Moon, Emmanuel Theodorakis, Jordi Garcia-Ojalvo and Gürol M Süel.


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