Publications by authors named "Thomas Nipper"
Starvation triggers bacterial spore formation, a committed differentiation program that transforms a vegetative cell into a dormant spore. Cells in a population enter sporulation nonuniformly to secure against the possibility that favorable growth conditions, which put sporulation-committed cells at a disadvantage, may resume. This heterogeneous behavior is initiated by a passive mechanism: stochastic activation of a master transcriptional regulator.
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- Starvation prompts bacterial cells to form spores as a survival strategy, with not all cells responding uniformly to ensure some can thrive if conditions improve.
- A newly discovered communication pathway allows early sporulating cells to export glycerol, which both signals non-sporulating cells to delay their sporulation and serves as a nutrient.
- This cooperation among cells enhances population diversity, making it more adaptable to sudden nutrient availability compared to random genetic variation alone.
Chromosomally encoded toxin-antitoxin systems have been increasingly identified and characterized across bacterial species over the past two decades. Overproduction of the toxin gene results in cell growth stasis or death for the producing cell, but co-expression of its antitoxin can repress the toxic effects. For the subcategory of type I toxin-antitoxin systems, many of the described toxin genes encode a small, hydrophobic protein with several charged residues distributed across the sequence of the toxic protein.
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