Regulation of gene expression under high hydrostatic pressure: the versatile role of the master regulator SurR in energy metabolism
Abstract
InThermococcus barophilus, a piezophilic hyperthermophilic archaeon, the expression of several gene clusters, including those of energy metabolism, is modulated by hydrostatic pressure. InThermococcales, SurR, a redox-sensitive transcriptional regulator that responds to sulfur availability, regulates genes involved in energy metabolism. To better understand how high hydrostatic pressure (HHP) influences the expression of energy metabolism genes, several gene deletion mutants includingsurRpartial knockout, were constructed and analyzed under various culture conditions, including different hydrostatic pressures and the presence or absence of sulfur.
Phenotypic analysis of thesurRmutant revealed that SurR affects both growth and gene expression, independently of sulfur availability. This regulatory behavior differs from that observed in non-piezophilic Thermococcales species such asPyrococcus furiosusandThermococcus kodakarensis. These findings suggest that hydrostatic pressure influences the physiological role or functional state of SurR inT. barophilus, highlighting its adaptive versatility in extreme environments.
IMPORTANCE
This study provides new insights into the adaptive mechanisms of hyperthermophilic archaea to high hydrostatic pressure, a key factor in deep-sea environments. By demonstrating that SurR regulation differs inT. barophiluscompared to non-piezophilic species, it suggests that pressure can modify transcriptional control mechanisms, potentially reshaping energy metabolism strategies in deep-sea archaea. Understanding these regulatory adaptations contributes to our broader knowledge of microbial life under extreme conditions and may have implications for biotechnology, particularly in designing pressure-resistant enzymes or metabolic pathways.
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