The Bacillus subtilis chromosome

Forty years in the making: understanding the molecular mechanism of peptide regulation in bacterial development

Signal transduction systems are influenced by positive and negative forces resulting in an output reflecting the sum of the opposing forces. The Rap family of regulatory protein modules control the output of two-component signal transduction systems through protein∶protein and protein∶peptide interactions. These modules and their peptide regulators are found in complex signaling pathways, including the bacterial developmental pathway to sporulation, competence, and protease secretion. Two articles published in the current issue of PLOS Biology reveal by means of crystallographic analyses how the Rap proteins of bacilli are regulated by their inhibitor Phr peptide and provide a mechanistic explanation for a genetic phenotype isolated decades earlier. The Rap-Phr module of bacterial regulators was the prototype of a family that now extends to other bacterial signaling proteins that involve the use of the tetratricopeptide repeat structural fold. The results invite speculation regarding the potential exploitation of this module as a molecular tool for applications in therapeutic design and biotechnology.

Intergenic suppression of spoO phenotypes by the Bacillus subtilis mutation rvtA

A collection of intergenic suppressors of the Bacillus subtilis spoOF221 mutation has been isolated. One of these suppressors, rvtA, has been mapped between lys-1and aroD. The rvtA suppressor restores spoOF sporulation to wild type levels and substantially improves the sporulation efficiencies of spoOB and spoOE strains. The rvtA gene does not affect the Spo phenotype of spoOH, spoOJ or spoOK mutants. The rvtA gene also prevents the induction by aliphatic alcohols of SpoO phenocopies in wild type B. subtilis cells.

Reciprocal and nonreciprocal recombination in diploid clones from Bacillus subtilis protoplast fusion: Association with the replication origin and terminus

The primary heterodiploid bacteria regenerated after Bacillus subtilis fusion, although generally noncomplementing diploids, behave in pedigree analysis as multipotential systems. Individual diploid colonies yielding complete reciprocal recombinant (RR) progeny-often accompanied by one or both parents-constitute 10-30% of the total recombinant-forming units. The RR (reciprocal for 8-11 genes) usually occur in equivalent numbers both among and within individual colonies. Novel for bacteria, they demonstrate that entire parental genomes brought together within a diploid protoplast are retained as two independent replicons able to undergo classical recombination characteristic of eukaryotic gametogenesis. Parental or recombinant genomes are also subject to multiple rounds of recombination without obligate segregation and often not reciprocal. Diploid recombinant clones, sharing streptomycin resistance but reciprocal for auxotrophic markers, have displayed a partial ability to make a facultative shift in chromosome expression. They have also produced two types of prototrophs: a stable one (presumably haploid and recombinant) and an unstable one, (diploid and temporarily complementing at low frequency). It follows that chromosome extinction may affect both parental and recombinant chromosomes and does not interfere with recombination. Analysis of the number and chromosomal distribution of crossovers in all recombinants and those from single diploid clones shows increased frequency of exchange in the regions of the replication origin and terminus, possibly a result of the association of these sites with the cell wall or membrane.

Genetic and physical maps of the Bacillus subtilis chromosome

Sequencing of the complete Bacillus subtilis chromosome revealed the presence of approximately 4100 genes, 1000 of which were previously identified and mapped by classical genetic crosses. Comparison of these experimentally determined positions to those derived from the nucleotide sequence showed discrepancies reaching up to 24 degrees (approximately 280 kb). The size of these discrepancies as a function of their position along the chromosome is not random but, apparently, reveals some periodicity. Our analyses demonstrate that the discrepancies can be accounted for by inaccurate positioning of the early reference markers with respect to which all subsequently identified loci were mapped by transduction and transformation. We conclude (i) that specific DNA sequences, such as recombination hotspots or presence of heterologous DNA, had no detectable effect on the results obtained by classical mapping, and (ii) that PBS1 transduction appears to be an accurate and unbiased mapping method in B. subtilis.

Genetic transfer of large DNA inserts to designated loci of the Bacillus subtilis 168 genome

It was found that contiguous DNA segments of up to 50 kb can be transferred between Bacillus subtilis genomes when a sufficient length of the flanking genomic region is provided for homologous recombination, although the efficiency of transfer was reduced as the insert size increased. Inserts were translocated to different loci, where appropriate integration sites were created.

Genetic characterization of forty ionizing radiation-sensitive strains of Deinococcus radiodurans: linkage information from transformation

Natural transformation was used to help define a collection of ionizing radiation-sensitive strains of Deinococcus radiodurans. Three putative rec mutations were identified, as were three pol alleles. Forty of the ionizing radiation-sensitive strains were placed into 16 linkage groups, and evidence obtained indicates that each linkage group consists of a cluster of mutations not more than 1,000 bp apart. In addition, a new class of D. radiodurans mutant was described that, although radioresistant, appears to recover from ionizing radiation-induced DNA damage slowly relative to other strains of D. radiodurans.

A Bacillus subtilis spore coat polypeptide gene, cotS

A gene, cotS, encoding a spore coat polypeptide of Bacillus subtilis, was isolated from an EcoRI fragment (5.4 kb) of the chromosome by using synthetic oligonucleotide probes corresponding to the NH2-terminal amino acid sequence of Cot40-2 previously purified from the spore coat of B. subtilis. The nucleotide sequence (2603 bp) was determined and sequence analysis suggested the presence of two contiguous ORFs, ORF X and cotS, followed by the 5'-region of an additional ORF, ORF Y, downstream of cotS. The cotS gene is 1053 nucleotides long and encodes a polypeptide of 351 amino acids with a predicted molecular mass of 41083 Da. The predicted amino acid sequence was in complete agreement with the NH2-terminal amino acid sequence of Cot40-2. The orfX gene is 1131 nucleotides long and encodes a polypeptide of 377 amino acids with a predicted molecular mass of 42911 Da. The gene product of cotS was confirmed to be identical to Cot40-2 by SDS-PAGE and immunoblotting from Escherichia coli transformed with a plasmid containing the cotS region. Northern hybridization analysis indicated that a transcript of cotS and orfX appeared at about 5 h after the onset of sporulation. The transcriptional start point determined by primer extension analysis suggested that -10 and -35 regions are present upstream of orfX and are very similar to the consensus sequence for the sigma k-dependent promoter. Terminator-like sequences were not found in the DNA fragment (2603 bp) sequenced in this paper, which suggested that the cotS locus may be part of a multicistronic operon. The cotS gene is located between dnaB and degQ at about 270-275 degrees on the genetic map. Insertional mutagenesis of the cotS gene by introducing an integrative plasmid resulted in no alteration of growth or sporulation, and had no effect on germination or resistance to chloroform.

The sigma factors of Bacillus subtilis

The specificity of DNA-dependent RNA polymerase for target promotes is largely due to the replaceable sigma subunit that it carries. Multiple sigma proteins, each conferring a unique promoter preference on RNA polymerase, are likely to be present in all bacteria; however, their abundance and diversity have been best characterized in Bacillus subtilis, the bacterium in which multiple sigma factors were first discovered. The 10 sigma factors thus far identified in B. subtilis directly contribute to the bacterium's ability to control gene expression. These proteins are not merely necessary for the expression of those operons whose promoters they recognize; in many instances, their appearance within the cell is sufficient to activate these operons. This review describes the discovery of each of the known B. subtilis sigma factors, their characteristics, the regulons they direct, and the complex restrictions placed on their synthesis and activities. These controls include the anticipated transcriptional regulation that modulates the expression of the sigma factor structural genes but, in the case of several of the B. subtilis sigma factors, go beyond this, adding novel posttranslational restraints on sigma factor activity. Two of the sigma factors (sigma E and sigma K) are, for example, synthesized as inactive precursor proteins. Their activities are kept in check by "pro-protein" sequences which are cleaved from the precursor molecules in response to intercellular cues. Other sigma factors (sigma B, sigma F, and sigma G) are inhibited by "anti-sigma factor" proteins that sequester them into complexes which block their ability to form RNA polymerase holoenzymes. The anti-sigma factors are, in turn, opposed by additional proteins which participate in the sigma factors' release. The devices used to control sigma factor activity in B, subtilis may prove to be as widespread as multiple sigma factors themselves, providing ways of coupling sigma factor activation to environmental or physiological signals that cannot be readily joined to other regulatory mechanisms.

Physical mapping of stable RNA genes in Bacillus subtilis using polymerase chain reaction amplification from a yeast artificial chromosome library

A new approach for mapping genes which utilizes yeast artificial chromosome clones carrying parts of the Bacillus subtilis genome and the polymerase chain reaction technique is described. This approach was used to physically map stable RNA genes of B. subtilis. Results from over 400 polymerase chain reactions carried out with the yeast artificial chromosome clone library, using primers specific for the genes of interest and designed from published sequences, were collected. The locations of 10 known rRNA gene regions (rrnO, rrnA, rrnE, rrnD, rrnB, rrnJ-rrnW, and rrnI-rrnH-rrnG) have been determined by this method, and these results correlate with those observed by standard genetic mapping. All rRNA operons, except rrnB, are found between 0 and 90 degrees, while rrnB has been placed in the area of 270 degrees on the chromosome map. Also localized were the tRNA gene clusters associated with the following ribosomal operons: rrnB (21 tRNAs), rrnJ (9 tRNAs), rrnD (16 tRNAs), and rrnO and rrnA (2 internal tRNAs). A previously unmapped four-tRNA gene cluster, trnY, a tRNA gene region that is not associated with a ribosomal operon, was found near the origin of replication. The P-RNA gene, important for processing of tRNAs, was found between map locations 197 and 204 degrees.

Bacillus subtilis mutants defective in bacteriophage phi 29 head assembly

Virus assembly mutants of asporogenous Bacillus subtilis defective in bacteriophage phi 29 head assembly were detected by the use of antibodies that reacted strongly with the free dodecameric phi 29 portal vertex composed of gene product 10 (gp10) but weakly with the portal vertex assembled into proheads or phage. Phage adsorption and the synthesis of phage proteins, DNA-gene product 3, and prohead RNA were normal in these mutants, but prohead and phage production was greatly reduced. The assembly defect was transferred to competent B. subtilis by transformation and transduction. PBS1 transduction showed that the vam locus was linked to Tn917 located at 317 degrees on the B. subtilis chromosome.

Identification of Bacillus subtilis genes for septum placement and shape determination

The Bacillus subtilis divIVB1 mutation causes aberrant positioning of the septum during cell division, resulting in the formation of small, anucleate cells known as minicells. We report the cloning of the wild-type allele of divIVB1 and show that the mutation lies within a stretch of DNA containing two open reading frames whose predicted products are in part homologous to the products of the Escherichia coli minicell genes minC and minD. Just upstream of minC and minD, and in the same orientation, are three genes whose products are homologous to the products of the E. coli shape-determining genes mreB, mreC, and mreD. The B. subtilis mreB, mreC, and mreD genes are the site of a conditional mutation (rodB1) that causes the production of aberrantly shaped cells under restrictive conditions. Northern (RNA) hybridization experiments and disruption experiments based on the use of integrational plasmids indicate that the mre and min genes constitute a five-cistron operon. The possible involvement of min gene products in the switch from medial to polar placement of the septum during sporulation is discussed.

Cloning, sequencing, and molecular analysis of the dnaK locus from Bacillus subtilis

By using an internal part of the dnaK gene from Bacillus megaterium as a probe, a 5.2-kb HindIII fragment of chromosomal DNA of Bacillus subtilis was cloned. Downstream sequences were isolated by in vivo chromosome walking. Sequencing of 5,085 bp revealed four open reading frames in the order orf39-grpE-dnaK-dnaJ. orf39 encodes a 39-kDa polypeptide of unknown biological function with no noticeable homology to any other protein within the data bases. Alignment of the GrpE protein with those of three other bacterial species revealed a low overall homology, but a higher homology restricted to two regions which might be involved in interactions with other proteins. Alignment of the DnaK protein with six bacterial DnaK polypeptides revealed that a contiguous region of 24 amino acids is absent from the DnaK proteins of all known gram-positive species. Primer extension studies revealed three potential transcription start sites, two preceding orf39 (S1 and S2) and a third one in front of grpE (S3). S2 and S3 were activated at a high temperature. Northern (RNA) analysis led to the detection of three mRNA species of 4.9, 2.6, and 1.5 kb. RNA dot blot experiments revealed an at-least-fivefold increase in the amount of specific mRNA from 0 to 5 min postinduction and then a rapid decrease. A transcriptional fusion between dnaK and the amyL reporter gene exhibited a slight increase in alpha-amylase activity after heat induction. A 9-bp inverted repeat was detected in front of the coding region of orf39. This inverted repeat is present in a number of other heat shock operons in other microorganisms ranging from cyanobacteria to mycobacteria. The biological property of this inverted repeat as a putative key element in the induction of heat shock genes is discussed. The dnaK locus was mapped at about 223 degrees on the B. subtilis genetic map.

Gene localization, size, and physical map of the chromosome of Streptococcus pneumoniae

A physical map of the Streptococcus (Diplococcus) pneumoniae chromosome, which is circular and 2,270 kbp in circumference, has been constructed. The restriction enzymes ApaI, SmaI, and SacII were used to digest intact chromosomes, and the fragments were resolved by field inversion gel electrophoresis (FIGE). The digests produced 22, 20, and 29 fragments, respectively. The order of the fragments was deduced from Southern blot hybridization of isolated labeled fragments to separated fragments of the various restriction digests. Genetic markers were correlated with the physical map by transformation of recipient cells with FIGE-isolated DNA fragments derived from genetically marked S. pneumoniae strains. In addition, markers were mapped by the hybridization of cloned genes to FIGE-separated restriction fragments. Six rRNA gene (rrn) clusters were mapped by hybridization to rrn-containing fragments of Haemophilus influenzae.

Cloning, nucleotide sequence, and expression of the Bacillus subtilis ans operon, which codes for L-asparaginase and L-aspartase

L-Aspartase was purified from Bacillus subtilis, its N-terminal amino acid sequence was determined to construct a probe for the aspartase gene, and the gene (termed ansB) was cloned and sequenced. A second gene (termed ansA) was found upstream of the ansB gene and coded for L-asparaginase. These two genes were in an operon designated the ans operon, which is 80% cotransformed with the previously mapped aspH1 mutation at 215 degrees. Primer extension analysis of in vivo ans mRNA revealed two transcription start sites, depending on the growth medium. In wild-type cells in log-phase growth in 2x YT medium (tryptone-yeast extract rich medium), the ans transcript began at -67 relative to the translation start site, while cells in log-phase growth or sporulating (t1 to t4) in 2x SG medium (glucose nutrient broth-based moderately rich medium) had an ans transcript which began at -73. The level of the -67 transcript was greatly increased in an aspH mutant grown in 2x YT medium; the -67 transcript also predominated when this mutant was grown in 2x SG medium, although the -73 transcript was also present. In vitro transcription of the ans operon by RNA polymerase from log-phase cells grown in 2x YT medium and log-phase or sporulating cells grown in 2x SG medium yielded only the -67 transcript. Depending on the growth medium, the levels of asparaginase and aspartase were from 2- to 40-fold higher in an aspH mutant than in wild-type cells, and evidence was obtained indicating that the gene defined by the aspH1 mutation codes for a trans-acting transcriptional regulatory factor. In wild-type cells grown in 2x SG medium, the levels of both aspartase and asparaginase decreased significantly by t0 of sporulation but then showed a small increase, which was mirrored by changes in the level of beta-galactosidase from an ansB-lacZ fusion. The increase in the activities of ans operon enzymes between t2 and t5 of sporulation was found primarily in the forespore, and the great majority of the increased was found in the mature spore. However, throughout sporulation the only ans transcript detected was the -73 form, and no sporulation-specific RNA polymerase tested yielded a -73 transcript in vitro.

Gene encoding two alkali-soluble components of the spore coat from Bacillus subtilis

We report the cloning and characterization of a gene called cotF from Bacillus subtilis that encodes alkali-soluble polypeptides of 5 and 8 kDa that are components of the spore coat. The 5- and 8-kDa polypeptides are generated by proteolytic cleavage of the primary product of the cotF gene, which is 160 codons in length and is capable of encoding a polypeptide of 19 kDa. Amino acid sequence analysis indicates that the 5-kDa species is derived from the NH2-terminal portion of the primary gene product and that the 8-kDa species is derived from the COOH-terminal portion. A mutant bearing an in vitro-constructed cotF null mutation produced normal-looking spores that contained an apparently complete set of coat proteins except for the absence of the 5- and 8-kDa polypeptides. The map position of cotF is 349 degrees. Transcription of cotF commenced coincidently (during h 6 of sporulation) with genes known to be under the control of sporulation transcription factor sigma kappa.

Genetic analysis of fusion recombinants in Bacillus subtilis: function of the recE gene

Bacillus subtilis protoplast fusion allows the study of the genetic recombination of an entire procaryotic genome. Protoplasts from bacterial strains marked genetically by chromosomal mutations were fused using polyethylene glycol and the regenerated cells analyzed. Recombinants represent 19.3% of heterozygotic cells; they are haploids. Individual characterization of clones show a unique particular phenotype in each colony suggesting that recombination takes place immediately after fusion, probably before the first cellular division. Recombination occurs in the whole chromosome; in one-third of the cases both reciprocal recombinants could be shown in the colony. The genetic interval that includes the chromosome replication origin shows the highest recombination level. Our results suggest that the RecE protein accounts for most of the fused protoplast recombination; however, some "replication origin-specific" recombination events were independent of the recE gene product.

Independent genes for two threonyl-tRNA synthetases in Bacillus subtilis

With the exception of Escherichia coli lysyl-tRNA synthetase, the genes coding for the different aminoacyl-tRNA synthetases in procaryotes are always unique. Here we report on the occurrence and cloning of two genes (thrSv and thrS2), both encoding functional threonyl-tRNA synthetase in Bacillus subtilis. The two proteins share only 51.5% identical residues, which makes them almost as distinct from each other as each is from E. coli threonyl-tRNA synthetase (42 and 47%). Both proteins complement an E. coli thrS mutant and effectively charge E. coli threonyl tRNA in vitro. Their genes have been mapped to 250 degrees (thrSv) and 344 degrees (thrS2) on the B. subtilis chromosome. The regulatory regions of both genes are quite complex and show structural similarities. During vegetative growth, only the thrSv gene is expressed.

A forespore checkpoint for mother cell gene expression during development in B. subtilis

Gene expression in the mother cell compartment of sporulating cells of B. subtilis is partly governed by the mother cell RNA polymerase sigma factor sigma K. Paradoxically, sigma K-directed gene expression also depends on sigma G, the product of the forespore compartment regulatory gene spoIIIG, and on other forespore regulatory proteins. We now identify mutations in the genes bofA and bofB that relieve the dependence of mother cell gene expression on forespore regulatory proteins but not on sigma K. We establish that the dependence of mother cell gene expression on the forespore regulatory proteins is mediated at the level of the conversion of pro-sigma K to its mature, active form. We propose that the bofA and/or bofB proteins govern this conversion in response to a signal generated by the forespore. Activation of pro-sigma K could be a checkpoint for coordinating gene expression between the mother cell and forespore compartments of the developing sporangium.

The Bacillus subtilis gene for the development transcription factor sigma K is generated by excision of a dispensable DNA element containing a sporulation recombinase gene

The structural gene (sigK) for the mother-cell RNA polymerase sigma-factor sigma K in Bacillus subtilis is a composite of two truncated genes, named spoIVCB and spoIIIC, which are brought together by site-specific recombination during sporulation. We now show that the recombination event is compartmentalized in that the mother cell, but not the forespore chromosome, undergoes rearrangement. We also show that spoIIIC (encoding the carboxy-terminal portion of sigma K) lies approximately 42 kb downstream of spoIVCB (encoding the amino-terminal portion) and that the joining of the truncated coding sequences is a reciprocal recombination event in which intervening DNA is deleted from the chromosome as a circle. The rearrangement is governed by the product of a gene named spoIVCA located in the excised DNA, as demonstrated by the observations (1) that the product of spoIVCA, but not the product of any other stage-IV sporulation gene tested, is required for the rearrangement, and (2) that the presence of a cloned copy of the rearranged sigK gene in the chromosome bypasses the requirement for the spoIVCA gene product in sporulation. Because cells engineered to contain an intact copy of sigK sporulate normally, we conclude that the sigK rearrangement is not essential for the control of gene expression during sporulation, and we infer the existence of an additional mechanism for restricting sigma K-directed transcription to the mother-cell chamber of the sporangium. Finally, the construction of a strain deleted for the entire sigK intervening sequence shows that the 42-kb element contains no genes essential for viability.

Bacillus subtilis mutant allele sup-3 causes lysine insertion at ochre codons: use of sup-3 in studies of translational attenuation

The mutation sup-3 in Bacillus subtilis suppresses ochre (TAA) mutations at each of three codons in the 5' end of the cat-86 coding sequence. The suppressor is shown to insert lysine at ochre codons. The efficiency of suppression by sup-3 is about 15%, as determined by changing a cat-86 Lys codon (codon 12) to an ochre codon and measuring the level of CAT in the suppressor-containing strain. The results obtained are discussed in light of previous observations that ochre mutations at cat leader codons 2 and 3 can be phenotypically suppressed by sup-3, whereas ochre mutations at leader codons 4 and 5 cannot. Translation of the cat leader is essential to inducible expression of cat. Our data support the interpretation that the nature of amino acids 2 through 5 of the leader peptide contributes to determining whether chloramphenicol can stall a ribosome in the leader, which in turn leads to induction of cat expression.

Induction of cat-86 by chloramphenicol and amino acid starvation in relaxed mutants of Bacillus subtilis

The chloramphenicol acetyltransferase gene cat-86 is induced through a mechanism that is a variation of classical attenuation. Induction results from the destabilization of an RNA stem-loop that normally sequesters the cat-86 ribosome-binding site. Destabilization of the stem-loop is due to the stalling of a ribosome in the leader region of cat-86 mRNA at a position that places the A site of the stalled ribosome at leader codon 6. Two events can stall ribosomes at the correct location to induce cat-86 translation: addition of chloramphenicol to cells and starvation of cells for the amino acid specified by leader codon 6. Induction by amino acid starvation is an anomaly because translation of the cat-86 coding sequence requires all 20 amino acids. To explain this apparent contradiction we postulated that amino acid starvation triggers intracellular proteolysis, thereby providing levels of the deprived amino acid sufficient for cat-86 translation. Here we show that a mutation in relA, the structural gene for stringent factor, blocks intracellular proteolysis that is normally triggered by amino acid starvation. The relA mutation also blocks induction of cat-86 by amino acid starvation, but the mutation does not interfere with chloramphenicol induction. Induction by amino acid starvation can be demonstrated in relA mutant cells if the depleted amino acid is restored at very low levels (e.g., 2 micrograms/ml). A mutation in relC, which may be the gene for ribosomal protein L11, blocks induction of cat-86 by either chloramphenicol or amino acid starvation. We believe this effect is due to a structural alteration of the ribosome resulting from the relC mutation and not to the relaxed phenotype of the cells.

Cloning and characterization of a Bacillus subtilis transcription unit involved in ATP-dependent DNase synthesis

By insertional mutagenesis, 36 transformation-deficient, mitomycin C-sensitive Bacillus subtilis mutants were isolated, 16 of which were ATP-dependent DNase (ADD) deficient. PBS1 transduction showed that the mutations were closely linked to the metD marker and weakly linked to the glyB marker. With the aid of one of the mutants, a transcription unit involved in ADD synthesis was cloned. The chromosomal location of the transcription unit was established at the restriction site level by determining the presence or absence of ADD in transformants of wild-type cells obtained with various DNA fragments inserted in pUC derivatives. The transcription unit complemented a mutant in which the add transcription unit had been deleted.

Genetic analysis of Bacillus subtilis spo mutations generated by Tn917-mediated insertional mutagenesis

Mutations that cause sporulation defects (spo mutations) often identify developmentally regulated transcription units or genes whose products are required for the expression of sporulation-specific regulons. We report here the isolation, genetic analysis and phenotypic characterization of spo mutations produced by insertional mutagenesis with transposon Tn917, a form of mutagenesis that facilitates genetic and physical manipulation of mutated genes in many ways. Twenty-four insertional spo mutations were studied in detail. On the basis of transformation-mediated and transduction-mediated linkage analysis and a range of phenotypic tests, these mutations were assigned to 20 distinct loci, at least 9 of which are different from the 40 previously described spo loci. The insertional mutations caused blocks at a variety of different stages of sporulation, and therefore probably identify genes active at different times during sporulation. In addition to increasing substantially the total of known spo loci, we anticipate that this collection will include representatives of many of the temporally regulated sets of genes that comprise the overall program of sporulation-specific gene activation in Bacillus subtilis. Given the kinds of manipulations that are possible with genes disrupted by Tn917 insertions, this should significantly facilitate efforts to understand the regulation of these gene sets.

The pentafunctional arom enzyme of Saccharomyces cerevisiae is a mosaic of monofunctional domains

The nucleotide sequence of the Saccharomyces cerevisiae ARO1 gene which encodes the arom multifunctional enzyme has been determined. The protein sequence deduced for the pentafunctional arom polypeptide is 1588 amino acids in length and has a calculated Mr of 174555. Functional regions within the polypeptide chain have been identified by comparison with the sequences of the five monofunctional Escherichia coli enzymes whose activities correspond with those of the arom multifunctional enzyme. The observed homologies demonstrate that the arom polypeptide is a mosaic of functional domains and are consistent with the hypothesis that the ARO1 gene evolved by the linking of ancestral E. coli-like genes.

Genetic mapping by means of protoplast fusion in Bacillus subtilis

A new mapping method involving protoplast fusion in Bacillus subtilis is described. Protoplasts from an isogenic standard marker strain containing purA and from a strain containing both purB and the marker, "x", to be mapped were fused with polyethylene glycol, and purA+ purB+ fusants were selected. After isolation of single colonies and determination of unselected markers, marker x was mapped between two standard markers. This method was fully applicable to PBS1-resistant strains (e.g., lyt strains). The results obtained by protoplast fusion, conventional transformation and/or lysed protoplast transformation indicated that a lyt strain, Ni15, contained two new autolysin-minus mutations (lyt-151 and lyt-152). The properties of lyt-15 are also discussed.

Gene for the alpha subunit of Bacillus subtilis RNA polymerase maps in the ribosomal protein gene cluster

We isolated the gene encoding the alpha subunit of Bacillus subtilis RNA polymerase from a lambda gt11 expression vector library by using anti-alpha antibody as a probe. Four unique clones were isolated, one carrying a lacZ-alpha gene fusion and three carrying the entire alpha coding region together with additional sequences upstream. The identity of the cloned alpha gene was confirmed by the size and immunological reactivity of its product expressed in Escherichia coli. Further, a partial DNA sequence found the predicted NH2 terminus of alpha homologous with E. coli alpha. By plasmid integration and PBS1 transduction, we mapped alpha near rpsE and within the major ribosomal protein gene cluster on the B. subtilis chromosome. Additional DNA sequencing identified rpsM (encoding S13) and rpsK (encoding S11) upstream of alpha, followed by a 180-base-pair intercistronic region that may contain two alpha promoters. Although the organization of the alpha region resembles that of the alpha operon of E. coli, the putative promoters and absence of rpsD (encoding S4) immediately preceding the B. subtilis alpha gene suggest a different regulation.

Integration of vector-containing Bacillus subtilis chromosomal DNA by a Campbell-like mechanism

Using plasmid pHV60, which contains a chloramphenicol resistance (Cmr) gene that is expressed in Bacillus subtilis, a set of transformation-deficient strains of B. subtilis was isolated by insertional mutagenesis. When chromosomal DNA from these mutants was used to transform a transformation-proficient B. subtilis strain, almost all of the Cmr transformants had the mutant phenotype as expected. However, with a frequency of approximately 3 X 10(-4) atypical transformants with the wild-type phenotype were produced. Data concerning amplification of the DNA containing the Cmr marker and duplication of DNA sequences are presented that suggest that these atypical transformants are the result of a Campbell-like integration of the chromosomal DNA containing the integrated plasmid. Transductional mapping showed that in the atypical transformants the vector-containing DNA had a strong tendency to integrate at sites adjacent to the original site of integration, although integration at sites elsewhere on the chromosome was also observed. The production of atypical transformants is explained on the basis of integration of chromosomal DNA by a Campbell-like mechanism. Circularization of vector-containing chromosomal DNA is thought to occur through joining of the extremities of single-stranded DNA molecules by fortuitous base pairing with an independently entered single-stranded DNA molecule.

Gene sequence encoding early enzymes of arginine synthesis within a cluster in Bacillus subtilis, as revealed by cloning in Escherichia coli

From a partial Sau3A gene library of Bacillus subtilis chromosomal DNA in the expression plasmid pRK9, four hybrid plasmids were isolated carrying overlapping segments of the argA-argF-cpa cluster. The complementation patterns within Escherichia coli arginine auxotrophs of these hybrids and deletion derivatives provided the gene order argC-argA-argE-argB-argD-cpa-argF.

Complementation and characterization of chemotaxis mutants of Bacillus subtilis

A set of chemotaxis mutants of Bacillus subtilis was complemented by using SP beta c2 transducing bacteriophage either containing cloned segments of DNA or derived from abnormal excision of SP beta c2 dl2::Tn917 inserted into the chemotaxis region. Representative mutants were characterized in capillary assays for chemotaxis toward four amino acids and mannitol and in tethered-cell experiments for addition and removal of two attractants and two repellents. Twenty complementation groups were identified, in addition to the cheR previously characterized. All were found to be defective in chemotaxis toward all chemoeffectors. They were assigned the names cheA through cheU. The large number of general chemotaxis genes in B. subtilis, in contrast to the six in Escherichia coli, suggests fundamental differences in the mechanism of chemotaxis in the two species.

Genetic mapping of rpoD implicates the major sigma factor of Bacillus subtilis RNA polymerase in sporulation initiation

We have mapped the chromosomal locus of rpoD, which encodes the major sigma factor of Bacillus subtilis RNA polymerase. The rpoD locus lay between aroD and lys, tightly linked to dnaE and inseparable from crsA. Marker order in this region was acf-aroD-dnaE-rpoD(crsA)-spoOG-lys. By transformation using cloned donor DNA from the rpoD region, we identified the gene immediately upstream of rpoD as dnaE, which coded for a 62,000 dalton protein essential for DNA replication. Both dnaE and rpoD were transcribed in the same direction, counterclockwise on the chromosome. The gene functions and organization in the rpoD region are thus similar to those of the E. coli sigma operon. We also used transformation to identify crsA47 as a mutation within the sigma coding region itself. The crsA alteration of sigma renders the sporulation process insensitive to glucose catabolite repression, and also restores sporulation ability to strains carrying early-blocked spoOE, spoOF, and spoOK mutations. Thus the major sigma factor and these spoO gene products directly or indirectly affect the same cellular function.

Genetic analysis of spo0A and spo0C mutants of Bacillus subtilis with a phi 105 prophage merodiploid system

An 8.0-kilobase chromosomal fragment of Bacillus subtilis which contained an intact spo0A gene was recloned onto temperate phage phi 105 from the rho 11dspo0A+-1 transducing phage. A specialized transducing phage, phi 105-dspo0A+-1, was constructed and used to transduce the spo0A12 mutant strain 1S9. A Spo+ transductant which was a single lysogen of the phi 105dspo0A+-1 transducing phage was isolated. From competent cells of this Spo+ transductant was isolated a Spo- (Spo0A) strain which was immune to phi 105. It was used to prepare a lysate of the phi 105dspo0A12 phage. Transduction of the spo0C9V recE4 strain with the phi 105dspo0A12 and phi 105dspo0A+-1 phages was carried out. The phi 105dspo0A+-1 phage gave rise to a large number of heat-resistant cells, but the phi 105dspo0A12 phage formed no heat-resistant cells. These results indicate that the spo0A12 and spo0C9V mutant genes do not complement each other in the ability to sporulate and that the spo0C9V mutation is located within the spo0A gene. Although the spo0C9V strain was completely asporogenous, the spo0C9V/spo0C9V diploid strain produced heat-resistant cells at a frequency of ca. 10(-3) in the sporulation medium. This result indicates that two copies of the spo0C9V mutant gene partially restore the ability of these cells to sporulate.

Genetic heterogeneity in the cysA-fus region of the Bacillus subtilis chromosome: identification of the hos gene

We identified a new gene, hos, which exerts different sporulation phenotypes in Bacillus subtilis strains with different genetic backgrounds. The hos+ gene showed normal sporulation in the genetic background of JH642 but showed temperature-sensitive sporulation in that of the Tano-oka W. The hos gene was mapped between cysA and rpoB.

Cloning and expression in Escherichia coli of sdhA, the structural gene for cytochrome b558 of the Bacillus subtilis succinate dehydrogenase complex

Bacillus subtilis cytochrome b558 is a transmembrane protein which anchors succinate dehydrogenase (SDH) to the cytoplasmic membrane and is reduced by succinate. The structural gene for this cytochrome was cloned and expressed in Escherichia coli. Random BamHI or BglII fragments of B. subtilis 168 DNA were cloned in the BamHI site of plasmid pHV32. The derived plasmids were used to transform B. subtilis SDH mutants to chloramphenicol resistance by integration of the plasmid via DNA homology. Of some 3,000 transformants tested, 6 were SDH positive and had pHV32 integrated close to the sdh operon. Two plasmids, pKIM2 and pKIM4, with an insert of B. subtilis DNA of 5.7 and 3.4 kilobases, respectively, were generated by transforming E. coli with DNA from the SDH-positive transformants after cleavage with EcoRI or BglII and ligation. In E. coli carrying either of the two plasmids, about 4% of total membrane protein was B. subtilis cytochrome b558. E. coli (pKIM2) also contained antigen which reacted with antibodies specific for the flavoprotein and the iron-sulfur protein subunit of B. subtilis SDH. Enzymatically active, membrane-bound B. subtilis SDH could not be demonstrated in E. coli (pKIM2). The B. subtilis DNA insert in pKIM2 could transform B. subtilis sdhA (cytochrome b558), sdhB (flavoprotein), and sdhC (iron-sulfur protein) mutants to the wild type. The results suggest that pKIM2 carries the whole B. subtilis sdh operon. The data confirm the gene order and the proposed direction of transcription of the B. subtilis sdh operon. Most likely the sdh genes in E. coli(pKIM2) are controlled by their natural promoter.

Bacillus subtilis sigma factor sigma 29 is the product of the sporulation-essential gene spoIIG

Evidence is presented that the sporulation-essential locus spoIIG codes for both sigma 29 and a structurally related protein, P31. This demonstrates that at least one specific Bacillus subtilis RNA polymerase binding protein provides a critical function in endospore formation. spoIIG-specific RNA is present in B. subtilis cultures that are synthesizing P31 and sigma 29 and is absent in those that are not. A monoclonal antibody specific for an antigenic determinant on P31/sigma 29 detected crossreacting proteins (P25/P21) but not P31 or sigma 29 in a Spo- B. subtilis strain with a mutation at the spoIIG locus (spoIIG41). The appearance of P25 and P21 occurs in this mutant at a time when P31 and sigma 29 would normally appear and suggests that they are homologous proteins. Transformation of the spoIIG41 strain with plasmid DNA carrying the structural gene for spoIIG complements the Spo- phenotype and results in the synthesis of P31, sigma 29, P25, and P21 at the appropriate times during sporulation. In Escherichia coli, the cloned spoIIG sequence encoded a protein that reacted with the anti-P31/sigma 29 monoclonal antibody and had the electrophoretic mobility of authentic P31.

Nucleotide sequences of the sporulation gene spo0A and its mutant genes of Bacillus subtilis

We have determined the nucleotide sequence of a 2375-base-pair DNA fragment, which contained the sporulation gene spo0A cloned from Bacillus subtilis. The sequence had only one long open reading frame consisting of 239 codons, which was found to correspond to the spo0A gene by comparing the nucleotide sequence of the wild-type gene with those of the mutant alleles. The calculated molecular weight of the product of the wild-type spo0A gene was 26,500. We found also a new mutation, sgi, which maps within the spo0A gene. This mutation relieves the growth inhibition of the host cells caused by a multicopy plasmid carrying the spo0A gene. The mutations spo0A12, spo0C9V, and sgi-1 were found to be an amber mutation at the 62nd codon, a missense at the 229th codon, and a frame-shift at the 223rd codon of the spo0A gene, respectively.

Isolation and characterization of a cis-acting mutation conferring catabolite repression resistance to alpha-amylase synthesis in Bacillus subtilis

Bacillus subtilis 168GR10 was shown to contain a mutation, gra-10, which allowed normal temporal activation of alpha-amylase synthesis in the presence of a concentration of glucose that is inhibitory to activation of amylase synthesis in the parent strain, 168. The gra-10 mutation was mapped by phage PBS-1-mediated transduction and by transformation to a site between lin-2 and aroI906, very tightly linked to amyE, the alpha-amylase structural gene. The gra-10 mutation did not pleiotropically affect catabolite repression of sporulation or of the synthesis of extracellular proteases or RNase and was unable to confer glucose-resistance to the synthesis of chloramphenicol acetyltransferase encoded by the cat-86 gene driven by the amyE promoter region (amyR1) inserted into the promoter-probe plasmid pPL603B. It therefore appears that gra-10 defines a cis-regulatory site for catabolite repression, but not for temporal activation, of amyE expression. The evidence shows that temporal activation and glucose-mediated repression of alpha-amylase synthesis in B. subtilis 168 are distinct phenomena that can be separated by mutation.

Impediment to replication fork movement in the terminus region of the Bacillus subtilis chromosome

The terminus regions of the chromosomes of three strains of Bacillus subtilis 168 were radioactively labelled by supplying [3H]thymine towards the end of a round of replication. These strains lacked or contained the prophage SP beta c2. Following restriction endonuclease digestion of the purified DNA and fluorography, an SP beta c2-related perturbation of the terminus-labelling profile was observed, which was completely consistent with the previously suggested existence of an impediment to replication fork movement (terC) within a BamHI 24.8 X 10(3) base fragment (Weiss & Wake, 1983). The present data suggest that terC is located within the 11.4 X 10(3) base BamHI + SalI double-digest portion of this BamHI fragment.

Nucleotide sequence of the spo0B gene of Bacillus subtilis and regulation of its expression

The spo0B gene is one of the genes involved in initiation of sporulation of Bacillus subtilis. This gene, previously cloned into the pHV33 shuttle vector, is expressed in Escherichia coli and B. subtilis. We have determined the sequence of 1118 base pairs (bp) of the DNA insert carrying the spo0B gene. The promoter sequence of this gene shows the canonical T-A-T-A-A-T region at 10 bp from the transcriptional start (-10 region) but an unusual sequence, T-T-T-T-C-T-, in the -35 region. The nucleotide sequence shows an open reading frame encoding a 192-amino-acid polypeptide of Mr 22,542, which is close to the molecular weight of the spo0B product synthesized in E. coli minicells. To investigate the regulation of the spo0B gene under a variety of physiological conditions, we constructed an in-frame fusion between the spo0B promoter proximal region and the lacZ gene of E. coli. This hybrid gene was subsequently integrated into the B. subtilis chromosome, and the beta-galactosidase activity was measured. It was found that the spo0B gene is preferentially expressed during exponential growth; it is not induced by exhaustion of the growth medium nor repressed by glucose.

Cloning of a Bacillus subtilis restriction fragment complementing auxotrophic mutants of eight Escherichia coli genes of arginine biosynthesis

Following shotgun cloning of EcoRI fragments of Bacillus subtilis 168 chromosomal DNA in pBR322 a hybrid plasmid, pUL720, was isolated which complements Escherichia coli K12 mutants defective for argA, B, C, D, E, F/I, carA and carB. Restriction analysis revealed that the insert of pUL720 comprises four EcoRI fragments, of sizes 12.0, 6.0, 5.0 and 0.8 kbp. Evidence was obtained from subcloning, Southern blot hybridisation, enzyme stability studies and transformation of B. subtilis arginine auxotrophs that the 12 kbp EcoRI fragment carries all the arg genes. It proved impossible to subclone the intact fragment in isolation in the multicopy vectors pBR322, pBR325 or pACYC184, and although it could be subcloned in the low copy vector pGV1106, propagation of the hybrid rapidly resulted in the selection of stable derivatives carrying, near one end, an insertion of 1 kbp of DNa originating from the E. coli chromosome. These and other stable derivatives resulting from subcloning the 12 kbp EcoRI fragment have lost only the ability to complement for E. coli argC, and it is suggested that sequences located close to the equivalent of argC are involved in destabilising plasmids bearing the 12 kbp fragment in E. coli in a copy number dependent manner.

Transcription analysis of a Bacillus subtilis arg gene following cloning in Escherichia coli in an initially unstable hybrid plasmid

Following shotgun cloning of EcoRI fragments of Bacillus subtilis DNA in pBR322, a hybrid plasmid pUL710 was isolated which complements argC but no other auxotrophs of E. coli K12. Restriction mapping, Southern blotting and other evidence suggest that pUL710 carries an insert of 1.6 kbp, and derives, by deletion of both vector and insert sequences, from a larger but unstable initial hybrid which carried a 12 kbp EcoRI fragment from the B. subtilis chromosome. RecE-dependent integration of pUL710 into the B. subtilis chromosome demonstrated homology between the insert DNA and the argO locus of B. subtilis. pUL710 was found to confer appreciable tetracycline resistance even though the deletion presumed to stabilise the hybrid had inactivated the tet promoter. The results of analysis by Tn5 mutagenesis, transcriptional fusions and run-off in vitro transcription suggest that both the cloned argC gene and the tetracycline gene in pUL710 are expressed from a B. subtilis promoter located very close to the EcoRI cloning site.

Construction of a promoter-probe vector for a Bacillus subtilis host by using the trpD+ gene of Bacillus amyloliquefaciens

The trp gene cluster of Bacillus amyloliquefaciens was found to be structurally similar to that of the Enterobacteriaceae. The translation termination codon of the putative trpE gene and the initiation codon for the putative trpD gene overlap at the trpE-trpD junction, and a promoter for the putative trpC gene is suggested to exist. A promoter-probe vector of Bacillus subtilis, pFTB281, was constructed with a DNA fragment of B. amyloliquefaciens, complementing the trpC and trpD mutations of B. subtilis, a 42-base-pair DNA fragment of M13mp7, and the larger EcoRI-PvuII fragment of pUB110, which confers an autonomous replication function and the kanamycin-resistance phenotype to the chimeric plasmid. pFTB281 has BamHI, EcoRI, and SalI cloning sites in the 5'-upstream portion of the protein-coding region of the putative trpD gene, and the insertion of a certain DNA fragment at any of these sites allowed the plasmid to transform a trpD mutant of B. subtilis to the TrpD+ phenotype. DNA fragments showing the promoter function for the trpD gene were obtained from B. amyloliquefaciens and Saccharomyces cerevisiae chromosomes and rho 11 and lambda phage DNAs, but rarely from the DNAs of Escherichia coli and pBR322.

Complementation and genetic inactivation: two alternative mechanisms leading to prototrophy in diploid bacterial clones

Evidence for diploidy at loci located all around the Bacillus subtilis chromosome previously led us to refer to the prototrophic bacterial clones produced by fusion of polyauxotrophic protoplasts as complementing diploid clones (Lévi-Meyrueis et al. 1980; Sanchez-Rivas 1982). In this paper, evidence is presented that gene inactivation may occur in such clones, as judged from the unequal expression of three unselected markers and their low transforming activity in cell lysates, an established property of inactivated genes (Bohin et al. 1982). The insensitivity to protease treatment of the lysates and also the low transforming activity observed with purified DNA may indicate that chromosome inactivation does not necessarily result from the mere attachment of proteins to DNA. Cotransfer by transformation of similarly expressed genes, initially located on separate chromosomes, suggests that genetic recombination has taken place, resulting in the reassortment of active and inactive genes on separate chromosomes. Several genetic structures compatible with the observations are presented which illustrate that prototrophy may result from such reassortment as well as from functional complementation.

Identification of the sporulation gene spoOA product of Bacillus subtilis

A 2.4-kilobase fragment of the Bacillus subtilis chromosome containing the wild-type spoOA gene derived from the phi 105dspoOA+-Bc-1 transducing phage was cloned onto plasmid pBR322 in Escherichia coli. A recombinant plasmid harboring the mutant spoOA12 allele on the 2.4-kilobase insert was also constructed from the phi 105dspoOA12-1 phage DNA and pBR322. Protein products synthesized in response to plasmid DNA in a DNA-directed cell-free system derived from E. coli were analyzed by sodium dodecyl sulfate-polyacryl-amide gel electrophoresis. A protein of approximately 27,500 daltons synthesized with the recombinant plasmid DNA harboring the wild-type spoOA gene as template was not formed with the recombinant plasmid DNA harboring the spoOA12 allele. Since the spoOA12 mutation is a nonsense mutation, we conclude that the 27.5-kilodalton protein is the product of the spoOA gene.

Identification of mutations associated with macrofiber formation in Bacillus subtilis

A search was made for the genes responsible for the production of helical macrofibers in the original collection of macrofiber-producing strains of B. subtilis. Two loci were identified: fibA, located between hisA and tag-1, and fibB, linked to cysB. fibA governs a short-lived division suppression phenomenon associated with the production of rudimentary fibers, whereas fibB appears to be responsible for a persistent division suppression and a more highly organized helical macrofiber. Both mutations are recovered from each of the original macrofiber-producing strains which also carried the div IV-B1 mutation responsible for minicell production. The latter mutation by itself is not sufficient, however, for the production of macrofibers. Other known mutations leading to division suppression that map in the same region are shown not to be allelic to fibA or fibB. Neither fib locus appears to be responsible for helix hand determination.

New mutation affecting the synthesis of some membrane proteins and sporulation in Bacillus subtilis

A new mutation, mpo, which affects the synthesis of some membrane proteins and sporulation in Bacillus subtilis was identified. The mpo mutation was tightly linked to the overproduction of membrane proteins MP32 and MP18 (molecular weights of 32,000 and 18,000, respectively) and the temperature-sensitive sporulation phenotype. Genetic analysis showed that the mpo mutation maps between the spoIIIB and lys loci.

Selective expression of a plasmid cat gene at a late stage of Bacillus subtilis sporulation

The cat-86 gene in plasmid pPL603 specifies chloramphenicol acetyltransferase (CAT) and is selectively expressed in Bacillus subtilis at a stage in sporulation in which internal spores are first observed (approximately T8). The gene is unexpressed in vegetatively growing cells. cat-86 expression and spore formation are both blocked when cells are grown in excess glucose. cat-86 expression at T8 is due to selective transcription of the gene, since cat-86 mRNA is undetectable in vegetatively growing cells but is readily demonstrated in sporulating cells. The transcription start site for cat-86 mRNA from sporulating cells is within a 203-base-pair restriction fragment designated P1, which is located upstream from the cat coding region on pPL603 . Deletion of P1 from pPL603 eliminates the sporulation -associated expression of cat-86. Host sporulation genes, whose function is absolutely required for cat-86 expression at T8, include six early sporulation, spo0 , genes and spoIIE . Therefore, pPL603 provides a novel system in which the in vivo expression of a known, plasmid-linked gene is dependent on sporulation-specific changes in B. subtilis.

Cloning of sporulation gene spoIIG in Bacillus subtilis

Two specialized transducing phages carrying a sporulation gene, spoIIG , of Bacillus subtilis were constructed from B. subtilis temperate phages p11 and phi 105 by the "prophage transformation" method. Restriction enzyme analysis and transformation experiments showed that the spoIIG gene was present on a 6.2 X 10(6)-dalton (6.2-Md) EcoRI fragment in both transducing phage genomes. Further analysis showed that spoIIG + transforming activity resides on a 2.25-Md EcoRI-BamHI fragment within the 6.2-Md EcoRI fragment. The 2.25-Md fragment was subcloned into the region between the EcoRI and BamHI sites of pUB110, and deletion plasmids lacking PstI or HindIII fragments within the 2.25-Md fragment were constructed. The recombinant plasmid carrying the intact spoIIG gene restored sporulation of strain HU1002 ( spoIIG41 recE4 ) to a frequency of 10(4) spores per ml and inhibited sporulation of strain 4309 ( spo + recE4 ) to a level of 10(3) spores per ml.

Chromosomal mapping of Bacillus thuringiensis by transduction

Three groups of linked markers were mapped in Bacillus thuringiensis 4042B by using two-, three-, and four-factor crosses mediated by the temperate bacteriophages TP-13 and TP-18. The order of markers was (trp-11, trp-2)-(leu-1, leu-2)-his-1-(lys-1, lys-2)-cys-1 in the first group; met-1-(argCl, argOl)-met-2-(pyr-1, pyrA2) in the second group; and met-3-pur-1-(nal-1, nal-2)-str-1-(pur-2, pur-4)-pur-3 in the third group. Electron microscopic measurements of head sizes suggested that the volume of the TP-13 phage head is seven times greater than that of the TP-18 phage head. The TP-18 genome was shown by DNA restriction analysis to have a molecular mass of 36 megadaltons. TP-13 was useful for scanning large segments of the B. thuringiensis chromosome, and TP-18 was effective for ordering markers too closely linked for simple resolution with TP-13.