Effects of inactivation or overexpression of the sspF gene on properties of Bacillus subtilis spores

Amino acid substitutions in transmembrane domains 9 and 10 of GerVB that affect the germination properties of Bacillus megaterium spores

The molecular basis for differences in germinant recognition of Bacillus megaterium QM B1551 spores containing the GerVB and/or GerUB receptor proteins has been examined by site-directed mutagenesis and the construction of cross-homologue chimeras. Focusing on nonconserved residues predicted to reside in transmembrane domains 9 and 10, we demonstrate that GerVB residues Ser319 and Leu345 are of particular importance in defining the specificity and apparent affinity of the receptor for germinants. Kinetic analyses of mutants with different amino acid substitutions at these positions indicate that Ser319 and Leu345 are not involved directly in the binding of germinants, but probably reside in regions of the receptor where structural perturbations can affect the conformation of, or access to, germinant binding sites. Position 345 is also shown to be of importance in GerUB, where the F345A mutation severely impairs receptor function. Functionality is restored in the GerUB Ala345 background by substituting putative outer-loop residues adjacent to TM10 for the corresponding residues in GerVB, indicating that a degree of structural coordination between these regions is important to receptor function.

Identification of a new gene essential for germination of Bacillus subtilis spores with Ca2+-dipicolinate

Bacillus subtilis spores can germinate with a 1:1 chelate of Ca(2+) and dipicolinic acid (DPA), a compound present at high levels in the spore core. Using a genetic screen to identify genes encoding proteins that are specifically involved in spore germination by Ca(2+)-DPA, three mutations were identified. One was in the gene encoding the cortex lytic enzyme, CwlJ, that was previously shown to be essential for spore germination by Ca(2+)-DPA. The other two were mapped to an open reading frame, ywdL, encoding a protein of unknown function. Analysis of ywdL expression showed that the gene is expressed during sporulation in the mother cell compartment of the sporulating cell and that its transcription is sigma(E) dependent. Functional characterization of YwdL demonstrated that it is a new spore coat protein that is essential for the presence of CwlJ in the spore coat. Assembly of YwdL itself into the spore coat is dependent on the coat morphogenetic proteins CotE and SpoIVA. However, other than lacking CwlJ, ywdL spores have no obvious defect in their spore coat. Because of the role for YwdL in a part of the spore germination process, we propose renaming ywdL as a spore germination gene, gerQ.

Bacterial cold shock responses

As a measure for molecular motion, temperature is one of the most important environmental factors for life as it directly influences structural and hence functional properties of cellular components. After a sudden increase in ambient temperature, which is termed heat shock, bacteria respond by expressing a specific set of genes whose protein products are designed to mainly cope with heat-induced alterations of protein conformation. This heat shock response comprises the expression of protein chaperones and proteases, and is under central control of an alternative sigma factor (sigma 32) which acts as a master regulator that specifically directs RNA polymerase to transcribe from the heat shock promotors. In a similar manner, bacteria express a well-defined set of proteins after a rapid decrease in temperature, which is termed cold shock. This protein set, however, is different from that expressed under heat shock conditions and predominantly comprises proteins such as helicases, nucleases, and ribosome-associated components that directly or indirectly interact with the biological information molecules DNA and RNA. Interestingly, in contrast to the heat shock response, to date no cold-specific sigma factor has been identified. Rather, it appears that the cold shock response is organized as a complex stimulon in which post-transcriptional events play an important role. In this review, we present a summary of research results that have been acquired in recent years by examinations of bacterial cold shock responses. Important processes such as cold signal perception, membrane adaptation, and the modification of the translation apparatus are discussed together with many other cold-relevant aspects of bacterial physiology and first attempts are made to dissect the cold shock stimulon into less complex regulatory subunits. Special emphasis is placed on findings concerning the nucleic acid-binding cold shock proteins which play a fundamental role not only during cold shock adaptation but also under optimal growth conditions.

Coping with the cold: the cold shock response in the Gram-positive soil bacterium Bacillus subtilis

All organisms examined to date, respond to a sudden change in environmental temperature with a specific cascade of adaptation reactions that, in some cases, have been identified and monitored at the molecular level. According to the type of temperature change, this response has been termed heat shock response (HSR) or cold shock response (CSR). During the HSR, a specialized sigma factor has been shown to play a central regulatory role in controlling expression of genes predominantly required to cope with heat-induced alteration of protein conformation. In contrast, after cold shock, nucleic acid structure and proteins interacting with the biological information molecules DNA and RNA appear to play a major cellular role. Currently, no cold-specific sigma factor has been identified. Therefore, unlike the HSR, the CSR appears to be organized as a complex stimulon rather than resembling a regulon. This review has been designed to draw a refined picture of our current understanding of the CSR in Bacillus subtilis. Important processes such as temperature sensing, membrane adaptation, modification of the translation apparatus, as well as nucleoid reorganization and some metabolic aspects, are discussed in brief. Special emphasis is placed on recent findings concerning the nucleic acid binding cold shock proteins, which play a fundamental role, not only during cold shock adaptation but also under optimal growth conditions.

Analysis of the regulation and function of five genes encoding small, acid-soluble spore proteins of Bacillus subtilis

Four genes [sspI, sspK, sspM, and sspO (originally called cotK)] encoding minor small, acid-soluble proteins (SASP) unique to spores of Bacillus subtilis are expressed only in the forespore compartment of sporulating cells of this organism. The sspI, sspK and sspM genes are monocistronic, while sspO is the first gene in a likely operon with sspP (originally called cotL), which also encodes a putative very small protein. Transcription of these genes is primarily, if not exclusively, by RNA polymerase with the forespore-specific sigma factor, sigma(G). Sequences centered 10 and 35nt upstream of the 5'-ends of sspI, sspK, sspM and sspO also show homology to the -10 and -35 sequences recognized by sigma(G). Mutations deleting these genes cause the loss of the appropriate SASP from spores, and the sspK, sspM and sspO (and likely sspP) mutations had no discernable effect on sporulation, spore properties or spore germination. Loss of sspI also had no effect on sporulation, spore properties or spore germination, but DeltasspI spores had a significant defect in spore outgrowth.

Regulation of four genes encoding small, acid-soluble spore proteins in Bacillus subtilis

Three genes (sspH, sspL, and tlp) encoding new, minor small, acid-soluble proteins (SASP) unique to spores of Bacillus subtilis are expressed only in the forespore compartment during sporulation of this organism. The sspH and sspL genes are monocistronic, whereas tlp is the second gene in an operon with a second small orf, which we have termed sspN. The sspH and sspL genes are recognized primarily by the forespore-specific sigma factor for RNA polymerase, sigmaG; the sspN-tlp operon is recognized equally well by sigmaG and the other forespore-specific sigma factor, sigmaF. Sequences centered 10 and 35nt upstream of the 5'-ends of sspH, sspL, and sspN mRNAs all show homology to -10 and -35 sequences recognized by sigmaF and sigmaG, which are generally quite similar. Mutations disrupting the sspH, sspL, sspN-tlp, or tlp loci cause a loss of the appropriate SASP from spores, but have no discernible effect on sporulation, spore properties, or spore germination.

New small, acid-soluble proteins unique to spores of Bacillus subtilis: identification of the coding genes and regulation and function of two of these genes

Eleven small, acid-soluble proteins (SASP) which are present in spores but not in growing cells of Bacillus subtilis were identified by sequence analysis of proteins separated by acrylamide gel electrophoresis of acid extracts from spores which lack the three major SASP (alpha, beta, and gamma). Six of these proteins are encoded by open reading frames identified previously or by analysis of the complete sequence of the B. subtilis genome, including two minor alpha/beta-type SASP (SspC and SspD) and a putative spore coat protein (CotK). Five proteins are encoded by short open reading frames that were not identified as coding regions in the analysis of the complete B. subtilis genomic sequence. Studies of the regulation of two of the latter genes, termed sspG and sspJ, showed that both are expressed only in sporulation. The sspG gene is transcribed in the mother cell compartment by RNA polymerase with the mother cell-specific sigma factor for RNA polymerase, sigmaK, and is cotranscribed with a downstream gene, yurS; sspG transcription also requires the DNA binding protein GerE. In contrast, sspJ is transcribed in the forespore compartment by RNA polymerase with the forespore-specific sigmaG and appears to give a monocistronic transcript. A mutation eliminating SspG had no effect on sporulation or spore properties, while loss of SspJ caused a slight decrease in the rate of spore outgrowth in an otherwise wild-type background.

Characterization of yhcN, a new forespore-specific gene of Bacillus subtilis

A new Bacillus subtilis sporulation-specific gene, yhcN, has been identified, the expression of which is dependent on the forespore-specific sigma factor sigmaG and to a much lesser extent on sigmaF. A translational yhcN-lacZ fusion is expressed at a very high level in the forespore, and the protein encoded by yhcN was detected in the inner spore membrane. A yhcN mutant sporulates normally and yhcN spores have identical resistance properties to wild-type spores. However, the outgrowth of yhcN spores is slower than that of wild-type spores.