The forespore line of gene expression in Bacillus subtilis

Endospore formation by Bacillus subtilis involves three differentiating cell types, the predivisional cell, the mother cell, and the forespore. Here we report the program of gene expression in the forespore, which is governed by the RNA polymerase sigma factors sigma(F) and sigma(G) and the DNA-binding proteins RsfA and SpoVT. The sigma(F) factor turns on about 48 genes, including the gene for RsfA, which represses a gene in the sigma(F) regulon, and the gene for sigma(G). The sigma(G) factor newly activates 81 genes, including the gene for SpoVT, which turns on (in nine cases) or stimulates (in 11 cases) the expression of 20 genes that had been turned on by sigma(G) and represses the expression of 27 others. The forespore line of gene expression consists of many genes that contribute to morphogenesis and to the resistance and germination properties of the spore but few that have metabolic functions. Comparative genomics reveals a core of genes in the sigma(F) and sigma(G) regulons that are widely conserved among endospore-forming species but are absent from closely related, but non-spore-forming Listeria spp. Two such partially conserved genes (ykoU and ykoV), which are members of the sigma(G) regulon, are shown to confer dry-heat resistance to dormant spores. The ykoV gene product, a homolog of the non-homologous end-joining protein Ku, is shown to associate with the nucleoid during germination. Extending earlier work on gene expression in the predivisional cell and the mother cell, we present an integrated overview of the entire program of sporulation gene expression.     

Dual localization pathways for the engulfment proteins during Bacillus subtilis sporulation

Engulfment in Bacillus subtilis is mediated by two complementary systems, SpoIID, SpoIIM and SpoIIP (DMP), which are essential for engulfment, and the SpoIIQ-SpoIIIAGH (Q-AH) zipper, which provides a secondary engulfment mechanism and recruits other proteins to the septum. We here identify two mechanisms by which DMP localizes to the septum. The first depends on SpoIIB, which is recruited to the septum during division and provides a septal landmark for efficient DMP localization. However, sporangia lacking SpoIIB ultimately localize DMP and complete engulfment, suggesting a second mechanism for DMP localization. This secondary targeting pathway depends on SpoIVFA and SpoIVFB, which are recruited to the septum by the Q-AH zipper. The absence of a detectable localization phenotype in mutants lacking only SpoIVFAB (or Q-AH) suggests that SpoIIB provides the primary DMP localization pathway while SpoIVFAB provides a secondary pathway. In keeping with this hypothesis, the spoIIB spoIVFAB mutant strain has a synergistic engulfment defect at septal thinning (which requires DMP) and is completely defective in DMP localization. Thus, the Q-AH zipper both provides a compensatory mechanism for engulfment when DMP activity is reduced, and indirectly provides a compensatory mechanism for septal localization of DMP when its primary targeting pathway is disrupted.     

Sporulation: an alternative way to recover recombinant proteins from Bacillus subtilis

A recombinant strain of Bacillus subtilis engineered for endocellular expression of human interleukin-1 receptor antagonist (IL-Ira) was subjected to sporulation. The recombinant protein was recovered from the sporulation supernatant in quantities, purity, and activity comparable with those obtained from a traditional cell lysate. Thus, exploitation of this natural mechanism of autolysis could overcome problems of intact protein recovery related to the cell disruption step. (c) 1995 John Wiley & Sons, Inc.     

Septal localization of penicillin-binding protein 1 in Bacillus subtilis.

Previous studies have shown that Bacillus subtilis cells lacking penicillin-binding protein 1 (PBP1), encoded by ponA, have a reduced growth rate in a variety of growth media and are longer, thinner, and more bent than wild-type cells. It was also recently shown that cells lacking PBP1 require increased levels of divalent cations for growth and are either unable to grow or grow as filaments in media low in Mg2+, suggesting a possible involvement of PBP1 in septum formation under these conditions. Using epitope-tagging and immunofluorescence microscopy, we have now shown that PBP1 is localized at division sites in vegetative cells of B. subtilis. In addition, we have used fluorescence and electron microscopy to show that growing ponA mutant cells display a significant septation defect, and finally by immunofluorescence microscopy we have found that while FtsZ localizes normally in most ponA mutant cells, a significant proportion of ponA mutant cells display FtsZ rings with aberrant structure or improper localization, suggesting that lack of PBP1 affects FtsZ ring stability or assembly. These results provide strong evidence that PBP1 is localized to and has an important function in the division septum in B. subtilis. This is the first example of a high-molecular-weight class A PBP that is localized to the bacterial division septum.     

Signal-anchor sequences are an essential factor for the Golgi-plasma membrane localization of type II membrane proteins

Despite studies of the mechanism underlying the intracellular localization of membrane proteins, the specific mechanisms by which each membrane protein localizes to the endoplasmic reticulum, Golgi apparatus, and plasma membrane in the secretory pathway are unclear. In this study, a discriminant analysis of endoplasmic reticulum, Golgi apparatus and plasma membrane-localized type II membrane proteins was performed using a position-specific scoring matrix derived from the amino acid propensity of the sequences around signal-anchors. The possibility that the sequence around the signal-anchor is a factor for identifying each localization group was evaluated. The discrimination accuracy between the Golgi apparatus and plasma membrane-localized type II membrane proteins was as high as 90%, indicating that, in addition to other factors, the sequence around signal-anchor is an essential component of the selection mechanism for the Golgi and plasma membrane localization. These results may improve the use of membrane proteins for drug delivery and therapeutic applications.     

Autolysins during sporulation of Bacillus subtilis 168

Conditions for zymographic detection of a 41-kDa spore cortex hydrolysis-specific autolysin, A6, from Bacillus subtilis 168 were optimised. A6 was present during sporulation from stages II–IV and remained active in the dormant spore. Its expression was controlled by the mother cell-specific early-sporulation sigma factor σ^E. The characteristic muramic acid δ-lactam of spore cortical peptidoglycan was not necessary for cortex hydrolysis by A6, but it may be important in the inability of the major vegetative autolysin LytC to digest wild-type cortex. Two other minor autolysins were also observed during sporulation. The possible physiological significance of these observations is discussed.     

Peptide anchoring spore coat assembly to the outer forespore membrane in Bacillus subtilis

Spore formation in Bacillus subtilis involves the formation of a thick, proteinaceous shell or coat that is assembled around a specialized membrane known as the outer forespore membrane. Here we present evidence that the assembling coat is tethered to the outer forespore membrane by a 26-amino-acid peptide called SpoVM, which is believed to form an amphipathic helix. We show that proper localization of SpoVM is dependent on SpolVA, a morphogenetic protein that forms the basement layer of the spore coat, and conversely, that proper localization of SpoIVA is dependent on SpoVM. Genetic, biochemical and cytological evidence indicates that this mutual dependence is mediated in part by contact between an amino acid side-chain located near the extreme C-terminus of SpoIVA and an amino acid side-chain on the hydrophilic face of the SpoVM helix. Evidence is also presented that SpoVM adheres to the outer forespore membrane via hydrophobic, amino acid side-chains on the hydrophobic face of the helix. The results suggest that the SpoVM helix is oriented parallel to the membrane with the hydrophobic face buried in the lipid bilayer.     

Tissue-specific localization of heat-stress proteins during embryo development

We report on the stress-independent, tissue-specific expression of the heat-stress protein HSP17 in developing seeds of different plant species and on its intracellular localization. Though HSP17 expression during seed development seems to be a general phenomenon, the isoform patterns, the relative amounts in embryonic tissues and the intracellular localization show species-specific variations. In contrast to the results on the stressinduced protein forming large cytoplasmic aggregates (heat stress granules) the developmentally expressed HSP17 is mainly found in nuclei. But in addition, a considerable part is also detected in protein bodies of mature seeds of Lycopersicon esculentum and Vicia faba, but not of Zea mays. The mechanism of this transition into the vacuolar compartment remains to be investigated.Abbreviations 2D two-dimensional - HSE heat shock elements - HSP heat stress protein     

Septal localization of the SpoIIIE chromosome partitioning protein in Bacillus subtilis.

The 787 amino acid SpoIIIE protein of Bacillus subtilis is required for chromosome partitioning during sporulation. This process differs from vegetative chromosome partitioning in that it occurs after formation of the septum, apparently by transfer of the chromosome through the nascent septum in a manner reminiscent of plasmid conjugation. Here we show that SpoIIIE is associated with the cell membrane, with its soluble C-terminal domain located inside the cell. Immunofluorescence microscopy using affinity-purified anti-SpoIIIE antibodies shows that SpoIIIE is targeted near the centre of the asymmetric septum, in support of a direct role for SpoIIIE in transport of DNA through the septum. We also report on the isolation of a mutation affecting the N-terminal hydrophobic domain of SpoIIIE that interferes with targeting to the septum and blocks DNA transfer. This mutation also causes de-localization of the activity of the normally prespore-specific sigma factor, sigmaF, consistent with the notion that SpoIIIE can form a seal between the chromosomal DNA and the leading edge of the division septum.     

Heat-shock proteins in membrane vesicles of Bacillus subtilis

Fractionation of B. subtilis cells after heat shock, from 37 degrees C to 54 degrees C, shows an increase in synthesis of proteins localized in cell membranes and a decrease in synthesis of proteins localized in cytosol. There is no such effect of heat shock at temperature of 45 degrees C. Autoradiograms of electrophoretically separated proteins, labelled during heat shock at 54 degrees C, reveal 26 heat-shock proteins (hsps) in membrane vesicles and 11 hsps in cytosol, five of which are common to both fractions. Heat shock at 45 degrees C induces 18 hsps localized in membrane vesicles and 13 hsps localized in cytosol, six of which are common to both fractions. Results are interpreted as showing a relevant role of membrane proteins in cell response to shock at high temperature, pointing to two steps of defense against heat stress.     

c-di-AMP reports DNA integrity during sporulation in Bacillus subtilis

The bacterium Bacillus subtilis produces the DNA integrity scanning protein (DisA), a checkpoint protein that delays sporulation in response to DNA damage. DisA scans the chromosome and pauses at sites of DNA lesions. Structural analysis showed that DisA synthesizes the small molecule cyclic diadenosine monophosphate (c-di-AMP). Here, we demonstrate that the intracellular concentration of c-di-AMP rises markedly at the onset of sporulation in a DisA-dependent manner. Furthermore, exposing sporulating cells to DNA-damaging agents leads to a global decrease in the level of this molecule. This drop was associated with stalled DisA complexes that halt c-di-AMP production and with increased levels of the c-di-AMP-degrading enzyme YybT. Reduced c-di-AMP levels cause a delay in sporulation that can be reversed by external supplementation of the molecule. Thus, c-di-AMP acts as a secondary messenger, coupling DNA integrity with progression of sporulation.     

Expression of the vesicular stomatitis virus membrane glycoprotein gene in Bacillus subtilis

Abstract The molecularly cloned gene encoding the vesicular stomatitis virus (VSV) membrane glycoprotein G was modified and joined to a Bacillus subtilis secretion vector constructed from the plasmid pUB110 and containing the promoter and signal sequence regions of the α-amylase (a secretory protein) gene from Bacillus amyloliquefaciens . The regions encoding the NH₂-terminal signal peptide and the COOH-terminal hydrophobic transmembrane domains of the VSV gene were deleted to facilitate the secretion of the G protein in soluble form. The truncated G protein was found to be expressed in B. subtilis . The expression level was low, probably due to rapid proteolytic degradation of the protein and, contrary to what was expected, almost all of the protein remained cell-associated.     

Localization of membrane proteins in membrane vesicles of Bacillus subtilis.

Electrons can be transferred to the respiratory chain in whole cells and in membrane vesicles of Bacillus subtilis W 23 by the membrane impermeable electron donor reduced 5-N-methyl-phenazonium-3-sulfonate as efficiently as by the membrane permeable electron donor reduced 5-N-methyl-phenazonium methyl-sulfate, indicating that the respiratory chain is accessible from the outside of the membrane.Succinate is oxidized by whole cells and membrane vesicles at a low rate and does not energize transport of l-glutamate. In the presence of 5-N-methyl-phenazonium-3-sulfonate or 5-N-methyl-phenazonium methyl-sulfate, the oxidation rate and the rate of l-glutamate transport are increased considerably. The electrons are transferred directly from succinic dehydrogenase to these acceptors. Succinic dehydrogenase must therefore be exposed to the outside surface of the membrane in both membrane vesicles and whole cells. The exposure of succinic dehydrogenase to the outside is also indicated by the observations that only a 5% increase in the oxidation rates of succinate-5-N-methyl-phenazonium methylsulfate and succinate-5-N-methyl-phenazonium-3-sulfonate is observed upon solubilization of the membrane with the nonionic detergent Brij-58. Furthermore, treatment of membrane vesicles with trypsin decreases by more than 95% these oxidation rates.NADH is oxidized at a high rate and energizes transport of l-glutamate in whole cells and membrane vesicles effectively. The NADH-oxidation is not effected by trypsin treatment of the vesicles indicating that the oxidation occurs at the inside-surface of the membrane. Trypsin treatment of the vesicles, however, significantly decreases the rate of l-glutamate transport driven by NADH. Therefore component(s) of the transport system for l-glutamate must be effected by trypsin treatment. No apparent differences could be observed in the localization of membrane-bound functions between membrane vesicles and whole cells. This strongly supports the contention that the vesicle membrane of B. subtilis has the same orientation as the cytoplasmic membrane of whole cells.     

Incompatibility of outer membrane proteins OmpA and OmpF of Escherichia coli with secretion in Bacillus subtilis: Fusions with secretable peptides

The secretion of the outer membrane proteins OmpA and OmpF of Escherichia coli has previously been found to be blocked at an early intracellular step, when these proteins were fused to a bacillar signal sequence and expressed in Bacillus subtilis. We have now fused these proteins to long secretable polypeptides, the amino-terminal portions of alpha-amylase or beta-lactamase. In spite of this, no secretion of the fusion proteins was detected in B. subtilis. With the exception of a small fraction of the beta-lactamase fusion, the proteins were cell-bound with uncleaved signal sequences. Protease accessibility indicated that the fusion proteins were not even partially exposed on the outer surface of the cytoplasmic membrane. Thus there was no change of the location compared to the OmpA or OmpF fused to the signal sequence only. We conclude that, like OmpA and OmpF, the fusion proteins fold into an export-incompatible conformation in B. subtilis before the start of translocation, which we postulate to be a late post-translational event.     

Several distinct localization patterns for penicillin-binding proteins in Bacillus subtilis

Bacterial cell shape is determined by a rigid external cell wall. In most non-coccoid bacteria, this shape is also determined by an internal cytoskeleton formed by the actin homologues MreB and/or Mbl. To gain further insights into the topological control of cell wall synthesis in bacteria, we have constructed green fluorescent protein (GFP) fusions to all 11 penicillin-binding proteins (PBPs) expressed during vegetative growth of Bacillus subtilis. The localization of these fusions was studied in a wild-type background as well as in strains deficient in FtsZ, MreB or Mbl. PBP3 and PBP4a localized specifically to the lateral wall, in distinct foci, whereas PBP1 and PBP2b localized specifically to the septum. All other PBPs localized to both the septum and the lateral cell wall, sometimes with irregular distribution along the lateral wall or a preference for the septum. This suggests that cell wall synthesis is not dispersed but occurs at specific places along the lateral cell wall. The results implicate PBP3, PBP5 and PBP4a, and possibly PBP4, in lateral wall growth. Localization of PBPs to the septum was found to be dependent on FtsZ, but the GFP-PBP fluorescence patterns were not detectably altered in the absence of MreB or Mbl.     

The Regulation of Bacillus intermedius Glutamyl Endopeptidase Biosynthesis in the Recombinant Bacillus subtilis Strain AJ73 during Sporulation

The growth of the recombinant Bacillus subtilis strain AJ73 carrying the Bacillus intermedius 3-19 glutamyl endopeptidase gene on a multicopy plasmid and the effect of some nutrients on the efficiency of extracellular glutamyl endopeptidase production in the stationary growth phase were studied. In this phase, the concentration of glutamyl endopeptidase in the culture liquid peaked at the 48th and 78th hours of cultivation and depended on the composition of the cultivation medium. Unlike the synthesis of glutamyl endopeptidase in the trophophase (i.e., during vegetative growth), which was suppressed by glucose, the synthesis of this enzyme during sporulation was resistant to glucose present in the cultivation medium. A multifactorial experimental design allowed optimal proportions between the concentrations of major nutrients (peptone and inorganic phosphate) to be determined. Inorganic phosphate and ammonium ions augmented the production of glutamyl endopeptidase by 30–150%, and complex organic substrates, such as casein and gelatin, enhanced the production of glutamyl endopeptidase by 50–100%. During sporulation, the production of glutamyl endopeptidase was stimulated by some bivalent cations (Ca²⁺, Mg²⁺, and Co²⁺) and inhibited by others (Zn²⁺, Fe²⁺, and Cu²⁺). The inference is drawn that the regulatory mechanisms of glutamyl endopeptidase synthesis during vegetative growth and sporulation are different.