Mechanisms of bacterial persistence during stress and antibiotic exposure

Mechanisms of bacterial persistence during stress and antibiotic exposure

Bacterial persister cells avoid antibiotic-induced death by entering a physiologically dormant state and are considered a major cause of antibiotic treatment failure and relapsing infections. Such dormant cells form stochastically, but also in response to environmental cues, by various pathways that...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2016-12, Vol.354 (6318), p.1390-1390
Hauptverfasser: Harms, Alexander, Maisonneuve, Etienne, Gerdes, Kenn
Format: Artikel
Sprache:eng
Schlagworte:
Adaptation, Physiological - genetics
Adaptation, Physiological - physiology
Anti-Bacterial Agents - pharmacology
Anti-Bacterial Agents - therapeutic use
Antibiotics
Bacteria
Bacteria - drug effects
Bacteria - metabolism
Bacterial Infections - drug therapy
Bacterial Infections - microbiology
Bacterial Proteins - metabolism
Bacterial Toxins - antagonists & inhibitors
Bacterial Toxins - metabolism
Biofilms
Cellular biology
Cues
DNA Damage
Drug resistance
Drug Resistance, Multiple, Bacterial
Elementary Secondary Education
Formations
Guanosine Pentaphosphate - metabolism
Heterogeneity
Pathways
Persistence
Probability theory
Proton-Motive Force
Research Methodology
REVIEW SUMMARY
Sigma Factor - metabolism
Signal Transduction
SOS Response (Genetics)
Stochastic Processes
Stress response
Stress, Physiological - genetics
Stress, Physiological - physiology
Tolerances
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Zusammenfassung:Bacterial persister cells avoid antibiotic-induced death by entering a physiologically dormant state and are considered a major cause of antibiotic treatment failure and relapsing infections. Such dormant cells form stochastically, but also in response to environmental cues, by various pathways that are usually controlled by the second messenger (p)ppGpp. For example, toxin-antitoxin modules have been shown to play a major role in persister formation in many model systems. More generally, the diversity of molecular mechanisms driving persister formation is increasingly recognized as the cause of physiological heterogeneity that underlies collective multistress and multidrug tolerance of persister subpopulations. In this Review, we summarize the current state of the field and highlight recent findings, with a focus on the molecular basis of persister formation and heterogeneity.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.aaf4268