Sporulation-specific translational discrimination in Bacillus subtilis

The Bacillus subtilis 30 S ribosomal subunit has been probed for sporulationspecific functions. A single site mutant with a streptomycin-resistant 30 S ribsomal subunit has been isolated; this mutation resulted in temperature-sensitive sporulation. The temperature-sensitive mutation was expressed throughout most of the sporulation sequence. Mutant cells grown at the non-permissive temperature failed to accumulate proteolytic activity, antibiotic activity, or alkaline phosphatase activity, and hence were blocked at or near stage 0 in the sporulation sequence. Pulse labeled protein synthesis profiles were deranged during postexponential growth phase in mutant cells incubated at the non-permissive temperature. These results suggest the possibility of sporulation-specific translational control.     

Ribonucleic Acid Polymerase in a Thermosensitive Sporulation Mutant (ts-4) of Bacillus subtilis

Partially synchronized cultures of a Bacillus subtilis thermosensitive sporulation mutant (ts-4) and the 168 try⁻try⁻ (168tt) parental strain were infected with the virulent phage e at various times during their growth cycle at 30 and 42 C (permissive and restrictive temperatures, respectively). It was shown that at the restrictive temperature the burst size in the parental strain was two- to threefold lower than in the ts-4 mutant. No such difference was observed at the permissive temperature. However, the time at which this difference was observed excludes a correlation between the burst size and initiation of the sporulation process. It was further found that the capacity to transcribe in vitro phage e deoxyribonucleic acid by partially purified ribonucleic acid (RNA) polymerase from both strains decreased sharply if the source of enzyme was sporulating cells instead of vegetative ones. However, a similar decrease, although to a lesser extent, was observed with the RNA polymerase isolated from stationary-phase cells of the ts-4 mutant grown at the nonpermissive temperature, or with the enzyme derived from several other zero-stage sporulation mutants. At no time was a structural modification in the β subunits of the RNA polymerase observed during growth of the sporulating bacteria. We have also shown that, in addition to the relatively low specific activity of the RNA polymerase, the level of the intracellular protease activity is about 15-fold lower in the ts-4 mutant grown at the restrictive temperature than that of the parental strain grown at the same temperature. At the permissive temperature no such difference was observed between these two strains. However, the present data do not allow us to establish a correlation among the low content of intracellular protease, the weak specific activity of the RNA polymerase, and the loss of the sporulation capacity in the ts-4 mutant grown at the restrictive temperature.     

New types of RNA polymerase mutations causing temperature-sensitive sporulation in bacillus subtilis.

A single site mutant of Bacillus subtilis with a streptovaricin-resistant RNA polymerase has been isolated; this mutation caused temperature-sensitive sporulation, but had no effect on vegetative growth. The mutant (ts710) temperature-sensitive period irreversibly affected the middle and late stages of sporulation. Mutant cells grown at the nonpermissive temperature exhibited abnormal serine protease accumulation, serine esterase accumulation, alkaline phosphatase accumulation, RNA polymerase template specificity changes, and pulse-labeled RNA synthesis profiles. The accumulation of metal protease was not affected at the nonpermissive temperature. Attempts to isolate single site mutants which were streptolydigin-resistant, and temperature-sensitive for sporulation, were unsuccessful.     

Template Specificity of Ribonucleic Acid Polymerase in Asporogenous Mutants of Bacillus subtilis

Asporogenous mutants of Bacillus subtilis were examined for the change in template specificity of ribonucleic acid (RNA) polymerase characteristic of wild-type cells undergoing sporulation. Mutants blocked at stages II, III, and IV showed a changed specificity of the enzyme after the end of growth and were in this respect indistinguishable from the wild type. The RNA polymerase of eight stage-zero mutants (out of nine tested) which possess mutations that map at six distinct loci retained the template specificity of vegetative cells.     

Isolation and characterization of temperature-sensitive mutations in the gene (rpb3 ) for subunit 3 of RNA polymerase II in the fission yeast Schizosaccharomyces pombe

Subunit 3 (Rpb3) of eukaryotic RNA polymerase II is a homologue of the α subunit of prokaryotic RNA polymerase, which plays a key role in subunit assembly of this complex enzyme by providing the contact surfaces for both β and β′ subunits. Previously we demonstrated that the Schizosaccharomyces pombe Rpb3 protein forms a core subassembly together with Rpb2 (the β homologue) and Rpb11 (the second α homologue) subunits, as in the case of the prokaryotic α₂β complex. In order to obtain further insight into the physiological role(s) of Rpb3, we subjected the S. pombe rpb3 gene to mutagenesis. A total of nine temperature-sensitive (Ts) and three cold-sensitive (Cs) S. pombe mutants have been isolated, each (with the exception of one double mutant) carrying a single mutation in the rpb3 gene in one of the four regions (A–D) that are conserved between the homologues of eukaryotic subunit 3. The three Cs mutations were all located in region A, in agreement with the central role of the corresponding region in the assembly of prokaryotic RNA polymerase; the Ts mutations, in contrast, were found in all four regions. Growth of the Ts mutants was reduced to various extents at non-permissive temperatures. Since the metabolic stability of most Ts mutant Rpb3 proteins was markedly reduced at non-permissive temperature, we predict that these mutant Rpb3 proteins are defective in polymerase assembly or the mutant RNA polymerases containing mutant Rpb3 subunits are unstable. In accordance with this prediction, the Ts phenotype of all the mutants was suppressed to varying extents by over-expression of Rpb11, the pairing partner of Rpb3 in the core subassembly. We conclude that the majority of rpb3 mutations affect the assembly of Rpb3, even though their effects on subunit assembly vary depending on the location of the mutation considered.     

Effects of degU32(Hy), degQa and degR Pleiotropic Regulatory Genes on the Growth and Protease Fermentation of Bacillus Subtilis Ki-2-132

Effects of degU32 (Hy), degR genes from Bacillus subtilis 168 and deg Qa gene from Bacillus amyloliquefaciens on Bacillus subtilis Ki-2-132 cell growth, sporulation and protease fermentation were investigated by introducing these genes into B. subtilis Ki-2-132 chromosome and/or cytoplasm. Although the genes come from different species and strains, they showed pleiotropic effects in B. subtilis Ki-2-132. B. subtilis Ki-2-132degU32 (Hy) showed increased protease production, and when cooperating with deg Qa either in plasmid or in chromosome, further altered cell growth, increased protease production and affected the spore formation in a glucose and dosage dependent manner. By contrast, degR did not significantly affect the protease productivity in degU32 (Hy) mutant, consisting with that DegR was used to stabilise DegU-phosphate, which in degU32 (Hy) strain no longer further amplify the DegU-phosphate effect.     

Behavioural and Electroantennogram Responses of Male Cigarette Beetle (Lasioderma serricorne F.) to Optically Active Serricornins

Pievious work with MAPI, a serine protease inhibitor, has shown that inactivation of membrane bound protease by MAPI resulted in inhibition of normal sporulation of Bacillus subtilis IFO 3027 [Shimizu et al, Agric. Biol. Chem., 48, 365 (1984)]. In the cells cultured with MAPI, the cellular amount of IP-I, a cytoplasmic serine protease which is sensitive to EDTA was lower than the control cells. An endogenous proteinaceous inhibitor having specific inhibitory activity against IP-I was produced during the sporulation and its amount in the MAPI-treated cells was higher than that of control cells. The proteinaceous inhibitor was inactivated only by membrane bound protease. Consequently, IP-I was activated through degradation of proteinaceous inhibitor by membrane bound protease. It seems probable that the proteinaceous inhibitor and membrane bound protease are involved in the regulation of a protease system in sporulating cells of B. subtilis.     

Screening,selection and development of Bacillus subtilis apr-IBL04 for hyper production of macromolecule alkaline protease

Bacillus subtilis microbe is commonly found in soil and produces proteases on nitrogen and carbon-containing sources and increases the fertility rate by degrading nitrogenous organic materials. The present study was aimed to develop hyper producing mutant strain of B. subtilis for the production of proteases, to improve the process variables by the response surface methodology (RSM) under central composite design (CCD) and the production of protease by the particular mutant strain in a liquid state fermentation media. The mutation of the strain was carried out using ethidium bromide. Pure B. subtilis strain was collected and screened for hyper-production of protease. The production of protease by mutant B. subtilis strain was optimized by varying temperature, inoculum size, pH and incubation time under liquid state fermentation. The CCD model were found to be reliable with r² of 0.999. The maximum enzyme activity of B. subtilis IBL-04 mutant with 3 mL/100 mL inoculum size, 72 h fermentation time, pH 8, and 45 °C temperature was developed with enzyme activity 631.09 U/mL, indicates 1–7-fold increase in enzyme activity than the parent strain having 82.32 U/mL activity. These characteristics render its potential use in industries for pharmaceutical and dairy formulation.     

Template specificity changes of DNA-dependent RNA polymerase in B. subtilis during sporulation

Previous work has indicated that loss of ability of DNA dependent RNA polymerase, from stationary phase cultures of $\text{B. subtilis}$, to transcribe phage øe DNA was a $\text{sine qua non}$ for sporulation. To ascertain if this change in template specificity was sporulation-specific, we repeated these experiments using a defined sporulation medium. The changes observed previously did not occur in the defined medium although sporulation was normal. The ability of the enzyme to transcribe other DNA templates was also examined. Similar studies were carried out using a polymerase from a rifamycin-resistant, sporulation conditional mutant. The significance of these findings with regard to the regulation of sporulation in $\text{B. subtilis}$ is discussed.     

Erythromycin resistant mutations in Bacillus subtilis cause temperature sensitive sporulation.

Summary All of several hundred erythromycin resistant (ery^R) single site mutants ofBacillus subtilis W168 are temperature sensitive for sporulation (spo^ts). The mutants and wild type cells grow vegetatively at essentially the same rates at both permissive (30° C) and nonpermissive (47° C) temperatures. In addition, cellular protein synthesis, cell mass increases and cell viabilities are similar in mutant and wild type strains for several hours after the end of vegetative growth (47° C). In the mutants examined, the temperature sensitive periods begin when the sporulation process is approximately 40% completed, and end when the process is 90% complete. At nonpermissive temperatures, the mutants produce serine and metal proteases at 50% of the wild type rate, accumulate serine esterase at 16% of the wild type rate, and do not demonstrate a sporulation related increase in alkaline phosphatase activity.The ery^R and spo^ts phenotypes cotransform 100%, and cotransduce 100% using phage PBS1. Revertants selected for ability to sporulate normally at 47° C (spo⁺), simultaneously regain parental sensitivity to erythromycin. No second site revertants are found.Ribosomes from ery^R spo^ts strains bind erythromycin at less than 1% of the wild type rate. A single 50S protein (L17) from mutant ribosomes shows an altered electrophoretic mobility. Ribosomes from spo⁺ revertants bind erythromycin like parental ribosomes and their proteins are electrophoretically identical to wild type. These data indicate that the L17 protein of the 50S ribosomal subunit fromBacillus subtilis may participate specifically in the sporulation process.     

Effects of the sinR and degU32 (Hy) mutations on the regulation of the aprE gene in Bacillus subtilis

The aprE gene of Bacillus subtilis codes for the serine alkaline protease known as subtilisin. Its expression is regulated by a complex network of activators and repressors that includes the products of hpr, degU and sinR. In order to understand the effect of these gene products on subtilisin expression, strains carrying combinations of the degU32(Hy), hpr2 and sinR null mutations, were constructed. We found that in all the genetic backgrounds tested, the sinR null mutation decreased aprE expression. Also, by measuring alkaline phosphatase synthesis and the formation of heat-resistant spores, as indicators of sporulation, we found that some of the mutant strains showed alterations in the sporulation process. These results suggest that these alterations are partially responsible for some of the observed changes in aprE expression.     

Bacterial Sporulation and Regulation of Dihydrodipicolinate Synthase in Ribonucleic Acid Polymerase Mutants of Bacillus subtilis

The activity of dihydrodipicolinate synthase increased late in sporulation in Bacillus subtilis. Mutants blocked at several stages of sporulation due to having an altered ribonucleic acid polymerase failed to exhibit this increase.     

Deoxyribonucleic Acid Polymerase Activity in a Deoxyribonucleic Acid Polymerase I-Deficient Mutant of Bacillus subtilis Infected with Temperate Bacteriophage SPO2

Increased deoxyribonucleic acid (DNA) polymerase activity is found in soluble extracts from a polymerase I-negative mutant of Bacillus subtilis after infection with temperate phage SPO2, or after induction of SPO2 prophage in lysogenic derivatives of this mutant. No increased enzyme activity is found after SPO2 infection in the presence of chloramphenicol. Infection of the polymerase-negative mutant with the DNA-negative sus mutant SPO2 L244 gives no increased enzyme activity, whereas infection with DNA-negative sus mutant SPO2 J385 gives enzyme activities comparable to those found in wild-type infected cells. These findings suggest that SPO2 determines a DNA polymerase activity essential for synthesis of phage DNA.