Early blocked asporogenous mutants of Bacillus subtilis 168. I. Isolation and characterization of mutants resistant to antibiotic(s) produced by sporulating Bacillus subtilis 168

Parallel pathways of repression and antirepression governing the transition to stationary phase in Bacillus subtilis

The AbrB protein of the spore-forming bacterium Bacillus subtilis is a repressor of numerous genes that are switched on during the transition from the exponential to the stationary phase of growth. The gene for AbrB is under the negative control of the master regulator for entry into sporulation, Spo0A-P. It has generally been assumed that derepression of genes under the negative control of AbrB is achieved by Spo0A-P-mediated repression of abrB followed by rapid degradation of the AbrB protein. Here, we report that AbrB levels do decrease during the transition to stationary phase, but that this decrease is not the entire basis by which AbrB-controlled genes are derepressed. Instead, AbrB is inactivated by the product of a uncharacterized gene, abbA (formerly ykzF), whose transcription is switched on by Spo0A-P. The abbA gene encodes an antirepressor that binds to AbrB and prevents it from binding to DNA. Combining our results with previous findings, we conclude that Spo0A-P sets in motion two parallel pathways of repression and antirepression to trigger the expression of diverse categories of genes during the transition to stationary phase.

Molecular basis for the exploitation of spore formation as survival mechanism by virulent phage phi29

Phage phi29 is a virulent phage of Bacillus subtilis with no known lysogenic cycle. Indeed, lysis occurs rapidly following infection of vegetative cells. Here, we show that phi29 possesses a powerful strategy that enables it to adapt its infection strategy to the physiological conditions of the infected host to optimize its survival and proliferation. Thus, the lytic cycle is suppressed when the infected cell has initiated the process of sporulation and the infecting phage genome is directed into the highly resistant spore to remain dormant until germination of the spore. We have also identified two host-encoded factors that are key players in this adaptive infection strategy. We present evidence that chromosome segregation protein Spo0J is involved in spore entrapment of the infected phi29 genome. In addition, we demonstrate that Spo0A, the master regulator for initiation of sporulation, suppresses phi29 development by repressing the main early phi29 promoters via different and novel mechanisms and also by preventing activation of the single late phi29 promoter.

Genes of the sbo-alb locus of Bacillus subtilis are required for production of the antilisterial bacteriocin subtilosin

Bacillus subtilis JH642 and a wild strain of B. subtilis called 22a both produce an antilisterial peptide that can be purified by anion-exchange and gel filtration chromatography. Amino acid analysis confirmed that the substance was the cyclic bacteriocin subtilosin. A mutant defective in production of the substance was isolated from a plasmid gene disruption library. The plasmid insertion conferring the antilisterial-peptide-negative phenotype was located in a seven-gene operon (alb, for antilisterial bacteriocin) residing immediately downstream from the sbo gene, which encodes the precursor of subtilosin. An insertion mutation in the sbo gene also conferred loss of antilisterial activity. Comparison of the presubtilosin and mature subtilosin sequences suggested that certain residues undergo unusual posttranslational modifications unlike those occurring during the synthesis of class I (lantibiotic) or some class II bacteriocins. The putative products of the genes of the operon identified show similarities to peptidases and transport proteins that may function in processing and export. Two alb gene products resemble proteins that function in pyrroloquinoline quinone biosynthesis. The use of lacZ-alb and lacZ-sbo gene fusions, along with primer extension analysis, revealed that the sbo-alb genes are transcribed from a major promoter, residing upstream of sbo, that is very likely utilized by the sigma(A) form of RNA polymerase. The sbo and alb genes are negatively regulated by the global transition state regulator AbrB and are also under positive autoregulation that is not mediated by the subtilosin peptide but instead requires one or more of the alb gene products.

Acquisition of certain streptomycin-resistant (str) mutations enhances antibiotic production in bacteria

Physiological differentiation (including antibiotic production) in microorganisms usually starts when cells encounter adverse environmental conditions and is frequently accompanied by an increase in the accumulation of intracellular ppGpp. We have found that the acquisition of certain streptomycin-resistant (str) mutations enables cells to overproduce antibiotics, demonstrating an increase in productivity 5- to 50-fold greater than that of wild-type strains. The frequency of such antibiotic-overproducing strains among the str mutants was shown to range from 3 to 46%, as examined with several strains of the genera Streptomyces, Bacillus, and Pseudomonas. Analysis of str mutants from Bacillus subtilis Marburg 168 revealed that a point mutation occurred within the rpsL gene, which encodes the ribosomal protein S12, changing Lys-56 (corresponding to Lys-43 in Escherichia coli) to Asn, Arg, Thr, or Gln. Antibiotic productivity increased in a hierarchical manner depending upon which amino acid residue replaced Lys at this position. The strA1 mutation, a genetic marker frequently used for mapping, had no effect on antibiotic productivity even though it was found to result in an amino acid alteration of Lys-56 to Ile. Gene replacement experiments with the str alleles demonstrated unambiguously that the str mutation is responsible for the antibiotic overproductivity observed. These results offer a rational approach for improving the production of antibiotic (secondary metabolism) from microorganisms.

Analysis of abrB mutations, mutant proteins, and why abrB does not utilize a perfect consensus in the -35 region of its sigma A promoter

The Bacillus subtilis global regulator AbrB is a DNA-binding protein composed of six identical monomers of 96 amino acids that shows specificity to the promoter regions of its target genes including its own. We have sequenced thirteen previously uncharacterized abrB mutations. Four mutant AbrB proteins were purified, and their DNA-binding properties and multimeric structures were examined. AbrB23 (R25S) had no appreciable DNA binding activity but retained a hexameric structure, indicating that Arg25 is important in DNA interactions. Three other mutant proteins, AbrB1 (C56Y), AbrB19 (Gln83-->termination codon), and AbrB100 (L69P), showed decreased DNA binding and altered multimeric interactions. Analysis of the expression and AbrB binding affinities of mutant abrB promoters demonstrated that a consensus -35 region is incompatible with proper autoregulation of the abrB gene.

The SpoOA protein of Bacillus subtilis is a repressor of the abrB gene

The spoOA gene of Bacillus subtilis is critical for the initial stages in the developmental cycle leading to the formation of an endospore. We show that one function of the SpoOA protein is to negatively regulate another regulatory locus, abrB, which controls the expression of many genes associated with the onset of sporulation. Purified SpoOA protein binds to a specific region of the abrB promoter and functions as a repressor of transcription in an in vitro assay. The binding of the SpoOA protein is independent of the binding of the AbrB protein, which is known to autoregulate its expression. This independence mirrors the temporal sequence of events in abrB control.

AbrB, a regulator of gene expression in Bacillus, interacts with the transcription initiation regions of a sporulation gene and an antibiotic biosynthesis gene

The abrB gene of Bacillus subtilis is believed to encode a repressor that controls the expression of genes involved in starvation-induced processes such as sporulation and the production of antibiotics and degradative enzymes. Two such genes, spoVG, a sporulation gene of B. subtilis, and tycA, which encodes tyrocidine synthetase I of the tyrocidine biosynthetic pathway in Bacillus brevis, are negatively regulated by abrB in B. subtilis. To examine the role of abrB in the repression of gene transcription, the AbrB protein was purified and then tested for its ability to bind to spoVG and tycA promoter DNA. In a gel mobility shift experiment, AbrB was found to bind to a DNA fragment containing the sequence from -95 to +61 of spoVG. AbrB protein exhibited reduced affinity for DNA of two mutant forms of the spoVG promoter that had been shown to be insensitive to abrB-dependent repression in vivo. These studies showed that an upstream A + T-rich sequence from -37 to -95 was required for optimal AbrB binding. AbrB protein was also observed to bind to the tycA gene within a region between the transcription start site and the tycA coding sequence as well as to a region containing the putative tycA promoter. These findings reinforce the hypothesis that AbrB represses gene expression through its direct interaction with the transcription initiation regions of genes under its control.

The transition state transcription regulator AbrB of Bacillus subtilis is autoregulated during vegetative growth

The DNA-binding AbrB protein of Bacillus subtilis is an ambiactive transcriptional regulator of genes expressed during the transition state between vegetative growth and the onset of stationary phase and sporulation. Studies on the transcriptional control of AbrB synthesis using abrB-lacZ fusions indicated that the abrB gene was autoregulated. This was consistent with the observation that purified AbrB protein bound specifically to the promoter region of its own gene in DNase I protection experiments. The structural gene mutation abrB4 abolished the autoregulation and purified AbrB4 protein did not have the promoter binding properties associated with the wild-type protein. Both AbrB and AbrB4 proteins were shown to be hexamers of 10,500 Dalton subunits and subunit exchange occurred between the proteins in vitro. However, the presence of only one or two mutant subunits dramaticaly altered the DNA-binding ability of the multimeric protein. The results support a model in which autoregulation of the abrB gene is an important factor in preventing sporulation-associated genes from being expressed during vegetative growth.

cis sequences involved in modulating expression of Bacillus licheniformis amyL in Bacillus subtilis: effect of sporulation mutations and catabolite repression resistance mutations on expression

Nutrient conditions which trigger sporulation also activate expression of the Bacillus licheniformis alpha-amylase gene, amyL. Glucose represses both spore formation and expression of amyL. A fusion was constructed between the B. licheniformis alpha-amylase regulatory and 5' upstream sequences (amyRi) and the Escherichia coli lacZ structural gene to identify sequences involved in mediating temporal activation and catabolite repression of the amyL gene in Bacillus subtilis. amyRi-directed expression in a variety of genetic backgrounds and under different growth conditions was investigated. A 108-base-pair sequence containing an inverted repeat sequence, ribosome-binding site, and 26 codons of the structural gene was sufficient to mediate catabolite repression of amyL. spo0 mutations (spo0A, spo0B, spo0E, and spo0H) had no significant effect on temporal activation of the gene fusion when the recipient strains were grown in nonrepressing medium. However, in glucose-grown cultures the presence of a spo0A mutation resulted in more severe repression of amyRi-lacZ. In contrast, a spo0H mutation reduced the repressive effect of glucose on amyRi-lacZ expression. The spo0A effect was relieved by an abrB mutation. Initiation of sporulation is not a prerequisite for either temporal activation or derepression of alpha-amylase synthesis. Mutations causing resistance to catabolite repression in B. subtilis GLU-47, SF33, WLN30, and WLN104 also relieved catabolite repression of amyRi-lacZ.

Structure of the gene for the transition state regulator, abrB: regulator synthesis is controlled by the spo0A sporulation gene in Bacillus subtilis

Sporulation begins coincidentally with the expression of several stationary-phase-associated gene products during the transition state of a culture from exponential to stationary phase. Mutations in the stage 0 sporulation genes prevent the expression of these gene products in addition to blocking sporulation. Suppressor mutations in the abrB gene, in a spo0 background, restore stationary-phase-associated gene expression but not sporulation. The nature of the abrB gene product was investigated by isolating and sequencing the abrB gene. The abrB gene coded for a 96-amino-acid protein (molecular weight 10773) and contained a helix-turn-helix structure common to DNA binding proteins. Analysis of expression of the abrB gene using lacZ transcription fusions and direct measurement of mRNA content by hybridization showed that the spo0A gene repressed transcription of the abrB gene. Primer extension analysis of abrB gene mRNA revealed two initiation sites. The downstream site was dramatically repressed in spo0A+ strains, while the upstream site appeared not to be regulated by spo0A. Five abrB mutant alleles were cloned and sequenced. One mutation, abrB4, resided within the structural gene and continued to overexpress abrB messenger RNA from both promoters. A promoter mutation, abrB15, reduced transcription from the downstream promoter but not the upstream promoter. Thus, the phenotype of abrB mutations results from inactivation of the abrB gene product or by prevention of its overexpression. The results suggest that the abrB gene codes for a regulator which controls several genes whose products are normally produced during the transition phase between active growth and sporulation. The level of this regulator is, in turn, controlled by the spo0A gene. The pleiotropic phenotypes of spo0A mutants result from uncontrolled overexpression of the abrB regulator.

prtR enhances the mRNA level of the Bacillus subtilis extracellular proteases

Studies were performed on the prtR gene which enhances the production of the Bacillus subtilis extracellular proteases and levansucrase, but not the alpha-amylase, RNase, and alkaline phosphatase. To investigate the mode of action of prtR, the Escherichia coli bla gene was placed under the control of two promoters. One was the promoter of the alkaline protease gene (aprE), and the other was the promoter of B. subtilis dihydrofolate reductase gene (dfrA). Expression of the bla gene was enhanced by prtR only when the apr promoter was used. From these results, it was concluded that the apr promoter or its vicinity was the target of prtR and that prtR does not affect the process after transcription. The mRNA levels of aprE and nprE (the neutral protease gene) were significantly increased by prtR, but the half-life of the aprE mRNA was not affected. These results show that the prtR gene product enhances protease production by increasing the rate of transcription initiation.

Molecular cloning and nucleotide sequence of a DNA fragment from Bacillus natto that enhances production of extracellular proteases and levansucrase in Bacillus subtilis

A DNA fragment from Bacillus natto IFO3936 has been cloned which enhances the production of both extracellular alkaline and neutral proteases in Bacillus subtilis. The DNA sequence analysis around the gene responsible for the hyperproduction, prtR, revealed one open reading frame (comprising 60 amino acid residues) which was bounded by potential transcriptional and translational regulatory signals in its preceding and following regions. This open reading frame was not homologous to the published sequences of the structural genes of the two proteases. The calculated molecular weight (7,109) of the polypeptide predicted from the DNA sequence is much smaller than those of the two proteases, indicating that the gene product is distinct from those enzymes. In-frame fusion between the N-terminal region of the coding sequence and the lacZ gene of Escherichia coli demonstrated that the coding region was indeed translated in vivo. By deletion analysis it was suggested that prtR was the structural gene for the 60-amino-acid polypeptide. Cells carrying a prtR plasmid secreted both proteases 40 to 400 times more than the cells carrying the vector alone. Furthermore, it was found that prtR also enhanced the production of levansucrase by 1 or 2 orders of magnitude. There was no difference, however, in the amount of the other extracellular enzymes such as alpha-amylase, RNase, and alkaline phosphatase. These results indicate that prtR is specific for the hyperproduction of the proteases and levansucrase.

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.

Isolation and mapping of a new suppressor mutation of an early sporulation gene spoOF mutation in Bacillus subtilis

We constructed an spoOF deletion (spoOF delta S) mutant of Bacillus subtilis by inserting a chromosomal segment carried by plasmid pUBSF delta S. This plasmid carries a 0.7-kilobase pair deletion that removes the spoOF promoter and a part of the structural gene. We used the spoOF deletion mutant to isolate a new intergenic suppressor of the spoOF phenotype, designated sof1. The sof1 suppressor completely restores the sporulation ability of all spoOF defective mutants tested, including spoOF77, spoOF221 and spoOF delta S. The sof1 suppressor maps to the left of lys1 on the B. subtilis chromosome, in a region rich in sporulation markers and distant from the spoOF locus.

Intergenic suppressors of temperature-sensitive sporulation in Bacillus subtilis are allele non-specific

The Bacillus subtilis mutant cal1 carries a non-reverting mutation in ribosomal protein L17 (r-protein L17) that causes both resistance to the antibiotic chalcomycin (Calr) and temperature-sensitive sporulation (Spots). Second-site suppressor (rev) mutations that relieve the Spots phenotype have been isolated from cal1. Three suppressor mutations - rev4, rev10, rev11 - each increase the sporulation frequency of cal1 at the non-permissive temperature from 3% to 95% of the wild-type level. The cal1 rev strains remain resistant to chalcomycin and two-dimensional gel electrophoresis analysis indicates that they contain the same altered r-protein L17 as the original cal1 strain and no additional altered r-proteins. The three rev mutations have been mapped at a single locus between narA and sacA on the B. subtilis chromosome and recombination indexes for the rev mutations indicate that they are tightly linked to one another. Antibiotic resistance Spots mutations that cause temperature-sensitive sporulation have previously been isolated in RNA polymerase, in the 30S and 50S subunits of the ribosome, and in elongation factor G. The rev4, 10, and 11 suppressor mutations are non-specific in their action in that they restore significant levels of sporulation at the non-permissive temperature in all of the Spots strains that we have tested. This result suggests that Spots mutations in components of the B. subtilis transcription and translation systems share a common molecular basis for their sporulation-defective phenotypes.

Thermosensitive, extracellular neutral proteases in Bacillus subtilis: isolation, characterization, and genetics

Two mutants (NT02 and NT17), each producing a thermosensitive neutral protease, were isolated from Bacillus subtilis NP58, a transformant which acquired the property of hyperproduction of neutral protease from Bacillus natto IAM 1212. The neutral proteases produced by these two mutants were partially purified and enzymologically characterized. The two mutant neutral proteases displayed increased thermosensitivity as well as altered pH optima compared with those of the NP58 enzyme. In addition, the hydrolytic activity of the thermosensitive neutral proteases on synthetic peptide substrates was found to be extremely different. These results strongly suggest that the site of mutation in each of the temperature-sensitive strains is located within the structural gene for neutral protease (nprE). Previous studies indicated the existence of a specific regulator gene (nprR) in addition to the structural gene for neutral protease. Phage PBS1-mediated transduction and deoxyribonucleic acid-mediated transformation studies with the parental and mutant strains suggest that the chromosomal order of these genes is recA-pyrA-nprR-nprE-fruB-metC. Moreover, the results of these genetic analyses imply that the mutations to thermosensitivity are located proximate to each other within the nprE gene.

Isolation of acetyl esterase mutants of Bacillus subtilis 168

Five mutants of Bacillus subtilis 168 defective in an intracellular esterase activity were identified. By polyacrylamide gel electrophoresis, four of the mutants were shown to lack esterase B activity, and the fifth lacked esterase A activity. All of the back-crossed esterase mutants were able to sporulate at wild-type frequency and produce exoprotease(s) and antibiotic(s). No difference in motility could be attributed to the esterase mutation. PBS1 transduction analysis showed all the esterase B mutations to be linked to the hisA marker.

Motility of Bacillus subtilis during growth and sporulation

The change of motility and the presence of flagella were followed throughout growth and sporulation in a standard sporulating strain and in 19 cacogenic sporulation mutants of Bacillus subtilis. For the standard strain, the fraction of motile cells decreased during the developmental period to less than 10% at T4. Motility was lost well before the cells lose their flagella. Conditions reducing the decrease of motility also reduced sporulation: motile cells never contained spores. The decrease of motility was not coupled with a decrease in the cellular concentration of adenosine 5'-triphosphate or a decline in oxygen consumption, but an uncoupling agent immediately destroyed motility at any time. Apparently, motility decreased during development because it became increasingly uncoupled from the energy generating systems of the cell. The motility of sporulation mutants decreased after the end of growth at the same time as or earlier than the motility of the standard strain; the early decrease of motility in an aconitase mutant, but not that in an alpha-ketoglurate dehydrogenase mutant, could be avoided by addition of L-glutamate. Sporulation or related events such as extracellular antibiotic or protease production were not needed for the motility decline.

Alteration of tyrosine isoaccepting transfer ribonucleic acid species in wild-type and asporogenous strains of Bacillus subtilis

The relative amounts of two isoacceping species of tyrosine transfer ribonucleic acid, tRNATyrI and tRNATyrII, determined from reversed phase 5 profiles of tyrosyl-tRNA, prepared from Bacillus subtilis strain W168, were growth phase and medium dependent. The growth phase-dependent alterations in the relative amounts of tRNATyr species were also demonstrated in 11 asporogenous strains of B. subtilis. The proportion of tRNA-Tyr species and the extent of the alteration in their relative amounts during the transition from the exponential to the stationary phase of growth of these strains was not directly correlated with the formation of spores by strain W168 grown in various media or the stage at which the asporogenous strains are blocked in the process of sporulation.

Bacteriophage interference in Bacillus subtilis 168

Strains of Bacillus subtilis lysogenic for temperate bacteriophage SPO2 inhibit the development of bacteriophage phi1. After infection by bacteriophage phi1, DNA and RNA synthesis in the lysogenic host terminates, culminating in cell death. Bacteriophage SPO2 also prevents the production of bacteriophage phi105. Mechanisms for these two types of bacteriophage interference are discussed.

Phenotypes of pleiotropic-negative sporulation mutants of Bacillus subtilis

The phenotypic properties of representatives of the five genetic classes of pleiotropic-negative sporulation mutants have been investigated. Protease production, alkaline and neutral proteases, was curtailed in spoA mutants, but the remainder of mutant classes produced both proteases, albeit at reduced levels. The spoA and spoB mutants plaqued phi2 and phi15 at high efficiency, but the efficiency of plating of these phages on spoE, spoF, and spoH mutants was drastically reduced. Antibiotic was produced by the spoH mutants and to a degree by some spoF mutants, but the other classes did not produce detectable activity. The spoA mutants were less responsive to catabolite repression of histidase synthesis by glucose than was the wild type. Severe catabolite repression could be induced in spoA mutants by amino acid limitation, suggesting that the relaxation of catabolite repression observed is not due to a defect in the mechanism of catabolite repression. Although others have shown a perturbation in cytochrome regulation in spoA and spoB mutants, the primary dehydrogenases, succinate dehydrogenase and reduced nicotinamide adenine dinucleotide dehydrogenase, leading to these cytochromes are unimpaired in all mutant classes. A comparison of the structural components of cell walls and membranes of spoA and the wild type is made. The pleiotropic phenotypes of these mutants are discussed.