[Activation of protein biosynthesis in outgrowing spores of Bacillus subtilis]

Physiological proteomics and stress/starvation responses in Bacillus subtilis and Staphylococcus aureus

Gel-based proteomics is a useful approach for visualizing the responses of bacteria to stress and starvation stimuli. In order to face stress/starvation, bacteria have developed very complicated gene expression networks. A proteomic view of stress/starvation responses, however, is only a starting point which should promote follow-up studies aimed at the comprehensive description of single regulons, their signal transduction pathways on the one hand, and their adaptive functions on the other, and finally their integration into complex gene expression networks. This "road map of physiological proteomics" will be demonstrated for the general stress regulon controlled by sigma(B) in Bacillus subtilis and the oxygen starvation response with Rex as a master regulator in Staphylococcus aureus.

Analysis of temporal gene expression during Bacillus subtilis spore germination and outgrowth

Bacillus subtilis forms dormant spores upon nutrient depletion. Under favorable environmental conditions, the spore breaks its dormancy and resumes growth in a process called spore germination and outgrowth. To elucidate the physiological processes that occur during the transition of the dormant spore to an actively growing vegetative cell, we studied this process in a time-dependent manner by a combination of microscopy, analysis of extracellular metabolites, and a genome-wide analysis of transcription. The results indicate the presence of abundant levels of late sporulation transcripts in dormant spores. In addition, the results suggest the existence of a complex and well-regulated spore outgrowth program, involving the temporal expression of at least 30% of the B. subtilis genome.

Transcriptional responses during outgrowth of Bacillus subtilis endospores

The Bacillus subtilis 168 genome contains an array of alternative sigma factors, many of which play important roles in reprogramming expression during stress and sporulation. The role of the different sigma factors during outgrowth, when the germinated endospore is converted back to a vegetative cell, is less well characterized. The activity of the alternative sigma factors sigmaB, sigmaD and sigmaH during endospore outgrowth was analysed by Northern blotting and lacZ reporter assays. While sigmaD and sigmaH were transcriptionally active during outgrowth, sigmaB-dependent transcription was not observed until after the first cell division, when growth slowed. Using an IPTG-controllable copy of sigA, an optimal level of expression was required to maintain growth rate at the end of outgrowth. The genes encoding the putative extracytoplasmic function (ECF) sigma factors sigmaI, sigmaV, sigmaW, sigmaZ and YlaC were insertionally inactivated using pMUTIN4. These strains, together with sigM and sigX mutants, were tested to determine their role and measure their expression during endospore outgrowth. Transcripts or beta-galactosidase activity were observed for each of the ECF sigma factors early after germination. With the exception of MJH003 (sigM), which showed an exacerbated salt stress defect, inactivation of the ECF sigma factor genes did not affect outgrowth in the conditions tested.

Escherichia coli proteins synthesized during recovery from starvation

Proteins synthesized in Escherichia coli during recovery from starvation were resolved by two-dimensional polyacrylamide gel electrophoresis. Nine outgrowth-specific proteins, which appeared in two kinetic groups, that were not detected in either starved or exponential-phase cells were synthesized. Five other proteins whose rate of synthesis during outgrowth was > or = 5-fold higher than during exponential growth were observed.

[Protein biosynthesis following heat shock in Bacillus subtilis]

Heat-activated spores of Bacillus subtilis synthesize during the early outgrowth special proteins which are absent from vegetative cells (Hecker 1983). Some of these outgrowth-specific proteins may be synthesized in response to heat activation of spores. In vegetative cells of B. subtilis synthesis of several proteins is markedly induced when temperature is shifted up from 30 to 44 degrees C. None of these putative heat shock proteins is synthesized during early outgrowth of heat-activated spores at 30 degrees C.

[Molecular biology of the germination of Bacillus spores]

The review deals with recent results and problems of gene expression during germination of Bacillus spores. Three problems were selected: 1. The activation of metabolism as a prerequisite for the synthesis of nucleic acids and proteins. 2. The activation of nucleic acid and protein synthesis during germination. 3. The gene expression programme of germinating spores. Using the highly sensitive two-dimensional polyacrylamide gel analysis three major classes of proteins were distinguished, depending on the time of onset and duration of their syntheses: a) proteins made throughout germination (main class), b) proteins whose synthesis started only after a lag phase and then continued throughout germination, and c) proteins which are synthesized only during the early phases of germination. The programme of protein synthesis is an indicator for the control of gene expression during germination. The regulation of expression of these major gene groups during spore outgrowth is discussed.

[Effect of nalidixic acid on the activation of RNA synthesis in outgrowing spores of Bacillus subtilis]

Outgrowth of B. subtilis spores depends on the action of DNA gyrase (comp. Matsuda and Kameyama 1980). Application of nalidixic acid (100 micrograms/ml) to dormant spores of Bacillus subtilis prevents the outgrowth. Application of nalidixic acid (100 micrograms/ml) during the early outgrowth phase (after a 20 min germination period) does not prevent, but only delay spore outgrowth. Germination of spores is not influenced. Nalidixic acid is an effective inhibitor of RNA synthesis in outgrowing spores, whereas vegetative cells are more resistant. Spores can grow out inspite of a remarkably reduced intensity of RNA synthesis. Nalidixic acid particularly inhibits the synthesis of stable RNA, probably that of ribosomal RNA. We suggest that DNA gyrase-catalyzed alterations in DNA structure are involved in the regulation of the gene expressional program of outgrowing B. subtilis spores.