Dmitry Malyshev scite author profile

Membrane-potential dynamics mediate bacterial electrical signaling at both intra- and intercellular levels. Membrane potential is also central to cellular proliferation. It is unclear whether the cellular response to external electrical stimuli is influenced by the cellular proliferative capacity. A new strategy enabling electrical stimulation of bacteria with simultaneous monitoring of single-cell membrane-potential dynamics would allow bridging this knowledge gap and further extend electrophysiological studies into the field of microbiology. Here we report that an identical electrical stimulus can cause opposite polarization dynamics depending on cellular proliferation capacity. This was demonstrated using two model organisms, namely Bacillus subtilis and Escherichia coli, and by developing an apparatus enabling exogenous electrical stimulation and single-cell time-lapse microscopy. Using this bespoke apparatus, we show that a 2.5-second electrical stimulation causes hyperpolarization in unperturbed cells. Measurements of intracellular K+ and the deletion of the K+ channel suggested that the hyperpolarization response is caused by the K+ efflux through the channel. When cells are preexposed to 400 ± 8 nm wavelength light, the same electrical stimulation depolarizes cells instead of causing hyperpolarization. A mathematical model extended from the FitzHugh–Nagumo neuron model suggested that the opposite response dynamics are due to the shift in resting membrane potential. As predicted by the model, electrical stimulation only induced depolarization when cells are treated with antibiotics, protonophore, or alcohol. Therefore, electrically induced membrane-potential dynamics offer a reliable approach for rapid detection of proliferative bacteria and determination of their sensitivity to antimicrobial agents at the single-cell level.

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Mode of Action of Disinfection Chemicals on the Bacterial Spore Structure and Their Raman Spectra

Malyshev

Dahlberg

Wiklund

et al. 2021

Anal. Chem.

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Contamination of toxic spore-forming bacteria is problematic since spores can survive a plethora of disinfection chemicals and it is hard to rapidly detect if the disinfection chemical has inactivated the spores. Thus, robust decontamination strategies and reliable detection methods to identify dead from viable spores are critical. In this work, we investigate the chemical changes of Bacillus thuringiensis spores treated with sporicidal agents such as chlorine dioxide, peracetic acid, and sodium hypochlorite using laser tweezers Raman spectroscopy. We also image treated spores using SEM and TEM to verify if we can correlate structural changes in the spores with changes to their Raman spectra. We found that over 30 min, chlorine dioxide did not change the Raman spectrum or the spore structure, peracetic acid showed a time-dependent decrease in the characteristic DNA/DPA peaks and ∼20% of the spores were degraded and collapsed, and spores treated with sodium hypochlorite showed an abrupt drop in DNA and DPA peaks within 20 min and some structural damage to the exosporium. Structural changes appeared in spores after 10 min, compared to the inactivation time of the spores, which is less than a minute. We conclude that vibrational spectroscopy provides powerful means to detect changes in spores but it might be problematic to identify if spores are live or dead after a decontamination procedure.

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Hypervirulent R20291 Clostridioides difficile spores show disinfection resilience to sodium hypochlorite despite structural changes

et al. 2023

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Background Clostridioides difficile is a spore forming bacterial species and the major causative agent of nosocomial gastrointestinal infections. C. difficile spores are highly resilient to disinfection methods and to prevent infection, common cleaning protocols use sodium hypochlorite solutions to decontaminate hospital surfaces and equipment. However, there is a balance between minimising the use of harmful chemicals to the environment and patients as well as the need to eliminate spores, which can have varying resistance properties between strains. In this work, we employ TEM imaging and Raman spectroscopy to analyse changes in spore physiology in response to sodium hypochlorite. We characterize different C. difficile clinical isolates and assess the chemical’s impact on spores’ biochemical composition. Changes in the biochemical composition can, in turn, change spores’ vibrational spectroscopic fingerprints, which can impact the possibility of detecting spores in a hospital using Raman based methods. Results We found that the isolates show significantly different susceptibility to hypochlorite, with the R20291 strain, in particular, showing less than 1 log reduction in viability for a 0.5% hypochlorite treatment, far below typically reported values for C. difficile. While TEM and Raman spectra analysis of hypochlorite-treated spores revealed that some hypochlorite-exposed spores remained intact and not distinguishable from controls, most spores showed structural changes. These changes were prominent in B. thuringiensis spores than C. difficile spores. Conclusion This study highlights the ability of certain C. difficile spores to survive practical disinfection exposure and the related changes in spore Raman spectra that can be seen after exposure. These findings are important to consider when designing practical disinfection protocols and vibrational-based detection methods to avoid a false-positive response when screening decontaminated areas. Graphical Abstract

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Laser induced degradation of bacterial spores during micro-Raman spectroscopy

Malyshev

Öberg

Dahlberg

et al. 2022

Spectrochimica Acta Part A: Molecular and Biomolecular Spectros

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Electrically induced bacterial membrane potential dynamics correspond to cellular proliferation capacity

Stratford

Edwards

Ghanshyam

et al. 2019

Preprint

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11Membrane-potential dynamics mediate bacterial electrical signaling at both intra-and inter-cellular 12 levels. Membrane potential is also central to cellular proliferation. It is unclear whether the cellular 13 response to external electrical stimuli is influenced by the cell's proliferative capacity. A new strategy 14 enabling electrical stimulation of bacteria with simultaneous monitoring of single-cell membrane 15 potential dynamics would allow bridging this knowledge gap and further extend electrophysiological 16 studies into the field of microbiology. Here we report that an identical electrical stimulus can cause 17 opposite polarization dynamics depending on cellular proliferation capacity. This was demonstrated 18using two model organisms, namely B. subtilis and E. coli, and by developing an apparatus enabling 19exogenous electrical stimulation and single-cell time-lapse microscopy. Using this bespoke apparatus, we 20show that a 2.5 sec electrical stimulation causes hyperpolarization in unperturbed cells. Measurements 21 of intracellular K + and the deletion of the K + channel suggested that the hyperpolarization response is 22caused by the K + efflux through the channel. When cells are pre-exposed to UV-violet light, the same 23 electrical stimulation depolarizes cells instead of causing hyperpolarization. A mathematical model 24 extended from the FitzHugh-Nagumo neuron model suggested that the opposite response dynamics are 25 due to the shift in resting membrane potential. As predicted by the model, electrical stimulation only 26induced depolarization when cells are treated with antibiotics, protonophore or alcohol. Therefore, 27electrically induced membrane potential dynamics offer a novel and reliable approach for rapid detection 28 of proliferative bacteria and determination of their sensitivity to antimicrobial agents at the single-cell 29 level. 30 31

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Dmitry Malyshev

Electrically induced bacterial membrane-potential dynamics correspond to cellular proliferation capacity

Mode of Action of Disinfection Chemicals on the Bacterial Spore Structure and Their Raman Spectra

Hypervirulent R20291 Clostridioides difficile spores show disinfection resilience to sodium hypochlorite despite structural changes

Laser induced degradation of bacterial spores during micro-Raman spectroscopy

Electrically induced bacterial membrane potential dynamics correspond to cellular proliferation capacity

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