Intracellular and extracellular components as bacterial thermometers, and early warning against thermal stress

Bacterial metabolites from intra- and inter-species influencing thermotolerance: the case of Bacillus cereus and Geobacillus stearothermophilus

Bacterial metabolites with communicative functions could provide protection against stress conditions to members of the same species. Yet, information remains limited about protection provided by metabolites in Bacillus cereus and inter-species. This study investigated the effect of extracellular compounds derived from heat shocked (HS) and non-HS cultures of B. cereus and Geobacillus stearothermophilus on the thermotolerance of non-HS vegetative and sporulating B. cereus. Cultures of B. cereus and G. stearothermophilus were subjected to HS (42 or 65 °C respectively for 30 min) or non-HS treatments. Cells and supernatants were separated, mixed in a combined array, and then exposed to 50 °C for 60 min and viable cells determined. For spores, D values (85 and 95 °C) were evaluated after 120 h. In most cases, supernatants from HS B. cereus cultures added to non-HS B. cereus cells caused their thermotolerance to increase (D ₅₀ 12.2-51.9) when compared to supernatants from non-HS cultures (D ₅₀ 7.4-21.7). While the addition of supernatants from HS and non-HS G. stearothermophilus cultures caused the thermotolerance of non-HS cells from B. cereus to decrease initially (D ₅₀ 3.7-7.1), a subsequent increase was detected in most cases (D ₅₀ 18-97.7). In most cases, supernatants from sporulating G. stearothermophilus added to sporulating cells of B. cereus caused the thermotolerance of B. cereus 4810 spores to decline, whereas that of B. cereus 14579 increased. This study clearly shows that metabolites in supernatants from either the same or different species (such as G. stearothermophilus) influence the thermotolerance of B. cereus.

Proteome analysis at the subcellular level of the cyanobacterium Spirulina platensis in response to low-temperature stress conditions

The present study addresses the differential expression of Spirulina platensis proteins detected during cold-induced stress, analyzed at the subcellular level. In performing differential expression analysis, the results revealed upregulated proteins in every subcellular fraction, including two-component response systems, DNA repair, molecular chaperones, stress-induced proteins and proteins involved in other biological processes such as secretion systems and nitrogen assimilation. The chlorophyll biosynthetic proteins, protochlorophyllide oxidoreductase and ChlI, had unique expression patterns as detected in the thylakoid membrane; the levels of these proteins immediately decreased during the first 45 min of low-temperature exposure. In contrast, their expression levels significantly increased after low-temperature exposure, indicating the relevance of the chlorophyll biosynthesis in Spirulina in response to low-temperature stress in the light condition. In addition, this is the first report in which genome-based protein identification in S. platensis by peptide mass fingerprinting was performed using the database derived from the unpublished Spirulina genome sequence.