Molecular analysis of Phr peptide processing in Bacillus subtilis

In Bacillus subtilis, an export-import pathway regulates production of the Phr pentapeptide inhibitors of Rap proteins. Processing of the Phr precursor proteins into the active pentapeptide form is a key event in the initiation of sporulation and competence development. The PhrA (ARNQT) and PhrE (SRNVT) peptides inhibit the RapA and RapE phosphatases, respectively, whose activity is directed toward the Spo0F approximately P intermediate response regulator of the sporulation phosphorelay. The PhrC (ERGMT) peptide inhibits the RapC protein acting on the ComA response regulator for competence with regard to DNA transformation. The structural organization of PhrA, PhrE, and PhrC suggested a role for type I signal peptidases in the processing of the Phr preinhibitor, encoded by the phr genes, into the proinhibitor form. The proinhibitor was then postulated to be cleaved to the active pentapeptide inhibitor by an additional enzyme. In this report, we provide evidence that Phr preinhibitor proteins are subject to only one processing event at the peptide bond on the amino-terminal end of the pentapeptide. This processing event is most likely independent of type I signal peptidase activity. In vivo and in vitro analyses indicate that none of the five signal peptidases of B. subtilis (SipS, SipT, SipU, SipV, and SipW) are indispensable for Phr processing. However, we show that SipV and SipT have a previously undescribed role in sporulation, competence, and cell growth.     

Characterisation of preYvaY export reveals differences in the substrate specificities of Bacillus subtilis and Escherichia coli leader peptidases

Translocation, processing and secretion of YvaY, a Bacillus subtilis protein of unknown function, were characterised both in B. subtilis and in Escherichia coli. In its natural host B. subtilis, YvaY was transiently synthesised at the end of the exponential growth phase. It was efficiently secreted into the culture supernatant in spite of a calculated membrane spanning domain in the mature part of the protein. In E. coli, despite the high conservation of Sec-dependent transport components, processing of preYvaY was strongly impaired. To uncover which elements of E. coli and B. subtilis translocation systems are responsible for the observed substrate specificity, components of the B. subtilis Sec-system were co-expressed besides yvaY in E. coli. Expression of B. subtilis secA or secYEG genes did not affect processing, but expression of B. subtilis signal peptidase genes significantly enhanced processing of preYvaY in E. coli. While the major signal peptidases SipS or SipT had a strong stimulatory effect on preYvaY processing, the minor signal peptidases SipU, SipV or SipW had a far less stimulatory effect in E. coli. These results reveal that targeting and translocation of preYvaY is mediated by the E. coli Sec proteins but processing of preYvaY is not performed by E. coli signal peptidase LepB. Thus, differences in substrate specificities of E. coli LepB and the B. subtilis Sip proteins provide the bottleneck for export of YvaY in E. coli. Significant slower processing of preYvaY in absence of SecB indicated that SecB mediates targeting of the B. subtilis precursor.     

Distinction between major and minor Bacillus signal peptidases based on phylogenetic and structural criteria

The processing of secretory preproteins by signal peptidases (SPases) is essential for cell viability. As previously shown for Bacillus subtilis, only certain SPases of organisms containing multiple paralogous SPases are essential. This allows a distinction between SPases that are of major and minor importance for cell viability. Notably, the functional difference between major and minor SPases is not reflected clearly in sequence alignments. Here, we have successfully used molecular phylogeny to predict major and minor SPases. The results were verified with SPases from various bacilli. As predicted, the latter enzymes behaved as major or minor SPases when expressed in B. subtilis. Strikingly, molecular modeling indicated that the active site geometry is not a critical parameter for the classification of major and minor Bacillus SPases. Even though the substrate binding site of the minor SPase SipV is smaller than that of other known SPases, SipV could be converted into a major SPase without changing this site. Instead, replacement of amino-terminal residues of SipV with corresponding residues of the major SPase SipS was sufficient for conversion of SipV into a major SPase. This suggests that differences between major and minor SPases are based on activities other than substrate cleavage site selection.     

Protein traffic for secretion and related machinery of Bacillus subtilis

Gram-positive sporulating Bacillus subtilis secretes high levels of protein. Its complete genome sequence, published in 1997, encodes 4,106 proteins. Bioinformatic searches have predicted that about half of all B. subtilis proteins are related to the cell membrane through export to the extracellular medium, insertion, and attachment. Key features of the B. subtilis protein secretion machinery are the absence of an Escherichia coli SecB homolog and the presence of an SRP (signal recognition particle) that is structurally rather similar to human SRP. In addition, B. subtilis contains five type I signal peptidases (SipS, T, U, V, and W). Our in vitro assay system indicated that co-operation between the SRP-protein targeting system to the cell membrane and the Sec protein translocation machinery across the cytoplasmic membrane constitutes the major protein secretion pathway in B. subtilis. Furthermore, the function of the SRP-Sec pathway in protein localization to the cell membrane and spore was analyzed.     

Different mechanisms for thermal inactivation of Bacillus subtilis signal peptidase mutants.

The type I signal peptidase SipS of Bacillus subtilis is of major importance for the processing of secretory precursor proteins. In the present studies, we have investigated possible mechanisms of thermal inactivation of five temperature-sensitive SipS mutants. The results demonstrate that two of these mutants, L74A and Y81A, are structurally stable but strongly impaired in catalytic activity at 48 degrees C, showing the (unprecedented) involvement of the conserved leucine 74 and tyrosine 81 residues in the catalytic reaction of type I signal peptidases. This conclusion is supported by the crystal structure of the homologous signal peptidase of Escherichia coli (Paetzel, M., Dalbey, R. E., and Strynadka, N. C. J. (1998) Nature 396, 186-190). In contrast, the SipS mutant proteins R84A, R84H, and D146A were inactivated by proteolytic degradation, indicating that the conserved arginine 84 and aspartic acid 146 residues are required to obtain a protease-resistant conformation. The cell wall-bound protease WprA was shown to be involved in the degradation of SipS D146A, which is in accord with the fact that SipS has a large extracytoplasmic domain. As WprA was not involved in the degradation of the SipS mutant proteins R84A and R84H, we conclude that multiple proteases are responsible for the thermal inactivation of temperature-sensitive SipS mutants.     

Signal peptidase I of Bacillus subtilis: patterns of conserved amino acids in prokaryotic and eukaryotic type I signal peptidases.

Signal peptidases (SPases) remove signal peptides from secretory proteins. The sipS (signal peptidase of subtilis) gene, which encodes an SPase of Bacillus subtilis, was cloned in Escherichia coli and was also found to be active in E.coli. Its overproduction in B.subtilis resulted in increased rates of processing of a hybrid beta-lactamase precursor. The SipS protein consisted of 184 amino acids (mol. wt 21 kDa). The protein showed sequence similarity with the leader peptidases of E.coli and Salmonella typhimurium, and the mitochondrial inner membrane protease I of Saccharomyces cerevisiae. Patterns of conserved amino acids present in these four proteins were also detected in the Sec11 subunit of the SPase complex of S.cerevisiae and the 18 and 21 kDa subunits of the canine SPase complex. Knowledge of the sequence of SipS was essential for the detection of these similarities between prokaryotic and eukaryotic SPases. The data suggest that these proteins, which have analogous functions, belong to one class of enzymes, the type I SPases.     

Functional analysis of the Streptomyces lividans type I signal peptidases

Type I signal peptidases are responsible for the proteolytic cleavage of the signal peptide of secreted proteins. In the gram-positive bacterium Streptomyces lividans, four adjacent genes (sipW, sipX, sipY and sipZ) were isolated encoding putative type I signal peptidases. In this work, the different sip genes were cloned and expressed. Subsequently, the Sip proteins were purified to raise antibodies. Although the four Sip proteins share a low degree of sequence similarity and differ significantly in size and pI, anti-Sip antibodies cross-reacted intensively. Functional signal peptidase processing activity for each of these Sip proteins was shown both in vitro and in vivo. The different Sip proteins did not exhibit the same cleavage efficiency on the Bacillus subtilis pre-chitosanase.     

Expression of Bacillus amyloliquefaciens amylase and Vibrio alginolyticus protease A fusion genes.

Previously we reported [Deane, S. M., Maharaj, R., Robb, F. T. & Woods, D. R. (1987) Journal of General Microbiology 133, 2295-2302] that the production of a Vibrio alginolyticus SDS-resistant alkaline serine protease (Pro A) cloned in Escherichia coli was characterized by a 12 h delay between the synthesis of an inactive precursor and secretion of active Pro A. Replacement of the V. alginolyticus promoter region by the alpha-amylase promoter region from Bacillus amyloliquefaciens resulted in the simultaneous synthesis and secretion of Pro A in E. coli. The V. alginolyticus pro A gene cloned on a shuttle vector did not produce active Pro A in Bacillus subtilis. Although Pro A has a typical Gram-positive signal sequence, it was not functional in B. subtilis. Replacement of the Pro A signal sequence with the alpha-amylase signal sequence resulted in the production of active Pro A in B. subtilis.     

Differential roles of multiple signal peptidases in the virulence of Listeria monocytogenes

Most bacteria contain one type I signal peptidase (Spase I) for cleavage of signal peptides from exported and secreted proteins. Here, we identified a locus encoding three contiguous Spase I genes in the genome of Listeria monocytogenes. The deduced Sip proteins (denoted SipX, SipY and SipZ) are significantly similar to SipS and SipT, the major SPase I proteins of Bacillus subtilis (38% to 44% peptidic identity). We studied the role of these multiple signal peptidases in bacterial pathogenicity by constructing a series of single- and double-chromosomal knock-out mutants. Inactivation of sipX did not affect intracellular multiplication of L. monocytogenes but significantly reduced bacterial virulence (approximately 100-fold). Inactivation of sipZ impaired the secretion of phospholipase C (PC-PLC) and listeriolysin O (LLO), restricted intracellular multiplication and almost abolished virulence (LD(50) of 10(8.3)), inactivation of sipY had no detectable effects. Most importantly, a mutant expressing only SipX was impaired in intracellular survival and strongly attenuated in the mouse (LD(50) of 10(7.2)), whereas, a mutant expressing only SipZ behaved like wild-type EGD in all the assays performed. The data establish that SipX and SipZ perform distinct functions in bacterial pathogenicity and that SipZ is the major Spase I of L. monocytogenes. This work constitutes the first report on the differential role of multiple Spases I in a pathogenic bacterium and suggests a possible post-translational control mechanism of virulence factors expression.     

Quantitation of the capacity of the secretion apparatus and requirement for PrsA in growth and secretion of alpha-amylase in Bacillus subtilis

Regulated expression of AmyQ alpha-amylase of Bacillus amyloliquefaciens was used to examine the capacity of the protein secretion apparatus of B. subtilis. One B. subtilis cell was found to secrete maximally 10 fg of AmyQ per h. The signal peptidase SipT limits the rate of processing of the signal peptide. Another limit is set by PrsA lipoprotein. The wild-type level of PrsA was found to be 2 x 10(4) molecules per cell. Decreasing the cellular level of PrsA did not decrease the capacity of the protein translocation or signal peptide processing steps but dramatically affected secretion in a posttranslocational step. There was a linear correlation between the number of cellular PrsA molecules and the number of secreted AmyQ molecules over a wide range of prsA and amyQ expression levels. Significantly, even when amyQ was expressed at low levels, overproduction of PrsA enhanced its secretion. The finding is consistent with a reversible interaction between PrsA and AmyQ. The high cellular level of PrsA suggests a chaperone-like function. PrsA was also found to be essential for the viability of B. subtilis. Drastic depletion of PrsA resulted in altered cellular morphology and ultimately in cell death.     

The endogenous Bacillus subtilis (natto) plasmids pTA1015 and pTA1040 contain signal peptidase-encoding genes: identification of a new structural module on cryptic plasmids

Various strains of Bacillus subtilis ( natto ) contain small cryptic plasmids that replicate via the rolling-circle mechanism. Like plasmids from other Gram-positive bacteria, these plasmids are composed of several distinct structural modules. A new structural module was identified on the B. subtilis plasmids pTA1015 and pTA1040. It is composed of two genes: one specifies an unidentified protein with a putative signal peptide; and the other ( sipP ) specifies a functional type I signal peptidase (SPase). The homologous, but non-identical, sipP genes of the two plasmids are the first identified plasmid-specific SPase-encoding genes. With respect to structure and activity, the corresponding enzymes (denoted SipP) are highly similar to the chromosomally encoded SPase, SipS, of B. subtilis and several newly identified SPases of other bacilli. Our findings suggest that plasmid-encoded SPases have evolved because, under certain conditions, SPase can be a limiting factor for protein secretion in B. subtilis .     

Mapping and cloning of the gene coding for beta-glucanase from various bacilli

Beta-glucanase gene from Bacillus subtilis 168 has been mapped by bacteriophage pBS1 transduction technique between sacA and purA genes. The stimulating effect of pleiotropic mutations pap, amyB and sacUh on beta-glucanase production in Bacillus subtilis and Bacillus amyloliquefaciens has been described. Beta-glucanase gene from Bacillus amyloliquefaciens has been cloned ona Charon 4A vector. Expression of the gene in E. coli cells depended on the orientation of the cloned DNA on a pBR322 vector plasmid. Maximal enzymatic activity was registered in periplasm. Beta-glucanase gene was recloned in Bacillus subtilis cells. Bacillus subtilis strain, harbouring pBG1, produces 500 times more beta-glucanase as compared with the wild type strain of Bacillus subtilis.     

Use of plasmid pTV1 in transposon mutagenesis and gene cloning in Bacillus amyloliquefaciens

The plasmid pTV1, constructed in Bacillus subtilis as a tool for insertional mutagenesis by the transposon Tn917, has been transferred to Bacillus amyloliquefaciens by transduction with the phage PBS1. Insertional mutants containing Tn917 were observed in the new host. Southern blot analysis of such mutants indicated no preference for insertion sites. The copy numbers of pTV1 in B. amyloliquefaciens and B. subtilis were found to be 1.4 and 14, respectively; the plasmid is less stable against loss in B. amyloliquefaciens. The overall transposition rate in B. amyloliquefaciens is nevertheless comparable to that in B. subtilis and large numbers of mutants are readily obtained. The yield of auxotrophs was about 0.7% of all mutants, but the preponderance of glutamate auxotrophs seen in B. subtilis was not observed. A number of auxotrophs were identified as to nutritional requirements and those tested were found to be stable. Mutants deficient in extracellular proteases, amylase, and ribonuclease (barnase) were also found and the inactivated barnase gene has been cloned in Escherichia coli. It seems likely, therefore, that any B. amyloliquefaciens gene for which there is a functional test could be cloned by this technique.     

The pathogenicity of Aeromonas strains relative to genospecies and phenospecies identification

A high yield of Escherichia coli outer membrane proteins OmpA (about 200 mg/l) and OmpF (about 100 mg/l) was obtained in Bacillus subtilis when produced intracellularly. The yield was more than 100-fold higher than the yield of these proteins by a similar vector containing the complete signal sequence of alpha-amylase of B. amyloliquefaciens. Both proteins isolated after breakage of the B. subtilis cells by low-speed centrifugation were about 70% pure and could be solubilized by Sarkosyl, SDS and guanidine hydrochloride.     

Inefficient translation of T7 late mRNA by Bacillus subtilis ribosomes. Implications for species-specific translation

Bacillus subtilis 30 S subunits inefficiently recognize initiation sites in mRNAs from Gram-negative bacteria, but they are able to efficiently recognize initiation sites in mRNA derived from Gram-positive bacteria. McLaughlin et al. (McLaughlin, J. R., Murray, C. L., and Rabinowitz, J. C. (1981) J. Biol. Chem. 256, 11283-11291) have suggested that B. subtilis ribosomes require a strong Shine-Dalgarno sequence for translation initiation. To test whether this criterion is sufficient to explain the translational specificity of B. subtilis ribosomes, T7 late mRNA, which contains strong Shine-Dalgarno sequences before many of the late genes (Dunn, J. J., and Studier, F. W. (1983) J. Mol. Biol. 166, 477-535), was translated in vitro with both Escherichia coli and B. subtilis ribosomes. The identification of several of the in vitro products upon gel electrophoresis indicated that B. subtilis ribosomes recognize correct translation initiation sites in late T7 mRNA, but they do not translate these products efficiently. Competition experiments demonstrated that late T7 mRNA does not inhibit B. subtilis ribosomal translation of B. subtilis derived mRNA (from the bacteriophage phi 29). It is concluded that strong Shine-Dalgarno sequences may be necessary in B. subtilis translation initiation sites; however, additional determinants of initiation which differ from those found in the translation initiation sites of E. coli mRNAs must exist.     

Unrelatedness of Bacillus amyloliquefaciens and Bacillus subtilis

Eight strains of highly amylolytic, sporeforming bacilli (hereafter referred to as Bacillus amyloliquefaciens) were compared with respect to their taxonomic relationship to B. subtilis. The physiological-biochemical properties of these two groups of organisms showed that B. amyloliquefaciens differed from B. subtilis by their ability to grow in 10% NaCl, characteristic growth on potato plugs, increased production of alpha-amylase, and their ability to ferment lactose with the production of acid. The base compositions of the deoxyribonucleic acid (DNA) of the B. subtilis strains consistently fell in the range of 41.5 to 43.5% guanine + cytosine (G + C), whereas that of the B. amyloliquefaciens strains was in the 43.5 to 44.9% G + C range. Hybrid formation between B. subtilis W23 and B. amyloliquefaciens F DNA revealed only a 14.7 to 15.4% DNA homology between the two species. Transducing phage, SP-10, was able to propagate on B. subtilis W23 and B. amyloliquefaciens N, and would transduce B. subtilis 168 (indole(-)) and B. amyloliquefaciens N-10 (arginine(-)) to prototrophy with a frequency of 3.9 x 10(-4) and 2.4 x 10(-5) transductants per plaque-forming unit, respectively. Attempts to transduce between the two species were unsuccessful. These data show that Bacillus amyloliquefaciens is a valid species and should not be classified as a strain or variety of B. subtilis.