Degradation of ornithine transcarbamylase in sporulating Bacillus subtilis cells

A new alkaline serine protease from alkalophilic Bacillus sp.: cloning, sequencing, and characterization of an intracellular protease

To obtain a new serine protease from alkalophilic Bacillus sp. NKS-21, shotgun cloning was carried out. As a result, a new protease gene was obtained. It encoded an intracellular serine protease (ISP-1) in which there was no signal sequence. The molecular weight was 34,624. The protease showed about 50% homology with those of intracellular serine proteases (ISP-1) from Bacillus subtilis, B. polymyxa, and alkalophilic Bacillus sp. No. 221. The amino acid residues that form the catalytic triad, Ser, His and Asp, were completely conserved in comparison with subtilisins (the extracellular proteases from Bacillus). The cloned intracellular protease was expressed in Escherichia coli, and its purification and characterization were carried out. The enzyme showed stability under alkaline condition at pH 10 and tolerance to surfactants. The cloned ISP-1 digested well nucleoproteins, clupein and salmin, for the substrates.

Alanine dehydrogenase (ald) is required for normal sporulation in Bacillus subtilis

The ski22::Tn917lac insertion mutation in Bacillus subtilis was isolated in a screen for mutations that cause a defect in sporulation but are suppressed by the presence or overexpression of the histidine protein kinase encoded by kinA (spoIIJ). The ski22::Tn917lac insertion mutation was in ald, the gene encoding alanine dehydrogenase. Alanine dehydrogenase catalyzes the deamination of alanine to pyruvate and ammonia and is needed for growth when alanine is the sole carbon or nitrogen source. The sporulation defect caused by null mutations in ald was partly relieved by the addition of pyruvate at a high concentration, indicating that the normal role of alanine dehydrogenase in sporulation might be to generate pyruvate to provide an energy source for sporulation. The spoVN::Tn917 mutation was also found to be an allele of ald. Transcription of ald was induced very early during sporulation and by the addition of exogenous alanine during growth. Expression of ald was normal in all of the regulatory mutants tested, including spo0A, spo0K, comA, sigB, and sigD mutants. The only gene in which mutations affected expression of ald was ald itself. This regulation is probably related to the metabolism of alanine.

Energy and calcium ion dependence of proteolysis during sporulation of Bacillus subtilis cells

Bacterial cells degrade intracellular proteins at elevated rates during starvation and can selectively degrade proteins by energy-dependent processes. Sporulating bacteria can degrade protein with apparent first-order rate constants of over 0.20 h-1. We have shown, with an optimized [14C]leucine-labeling and chasing procedure, in a chemically defined sporulation medium, that intracellular protein degradation in sporulating cells of Bacillus subtilis 168 (trpC2) is apparently energy dependent. Sodium arsenate, sodium azide, carbonyl cyanide m-chlorophenylhydrozone, and N,N'-dicyclohexylcarbodiimide, at levels which did not induce appreciable lysis (less than or equal to 10%) over 10-h periods of sporulation, inhibited intracellular proteolysis by 13 to 93%. Exponentially growing cells acquired arsenate resistance. In contrast to earlier reports, we found that chloramphenicol (100 micrograms/ml) strongly inhibited proteolysis (68%) even when added 6 h into the sporulation process. Restricting the calcium ion concentration (less than 2 microM) in the medium had no effect on rates or extent of vegetative growth, strongly inhibited sporulation (98%), and inhibited rates of proteolysis by 60% or more. Inhibitors of energy metabolism, at the same levels which inhibited proteolysis, did not affect the rate or degree of uptake of Ca2+ by cells, which suggested that the Ca2+ and metabolic energy requirements of proteolysis were independent. Restricting the Ca2+ concentration in the medium reduced by threefold the specific activity in cells of the major intracellular serine proteinase after 12 h of sporulation. Finally, cells of a mutant of B. subtilis bearing an insertionally inactivated gene for the Ca2(+)-dependent intracellular proteinase-1 degraded protein in chemically defined sporulation medium at a rate indistinguishable from that of the wild-type cells for periods of 8 h.

Cloning and sequencing of the major intracellular serine protease gene of Bacillus subtilis

A Bacillus subtilis 2.7-kilobase DNA fragment containing an intracellular protease gene was cloned into Escherichia coli. The transformants produced an intracellular protease of approximately 35,000 Mr whose activity was inhibited by both phenylmethylsulfonyl fluoride and EDTA. Introduction of the fragment on a multicopy vector, pUB110, into B. subtilis caused a marked increase in the level of the intracellular protease. The nucleotide sequence of the cloned fragment showed the presence of an open reading frame for a possible proenzyme of the major intracellular serine protease (ISP-I) of B. subtilis with an NH2-terminal 17- or 20-amino-acid extension. The total amino acid sequence of the protease deduced from the nucleotide sequence showed considerable homology with that of an extracellular serine protease, subtilisin. The transcriptional initiation site of the ISP-I gene was identified by nuclease S1 mapping. No typical conserved sequence for promoters was found upstream of the open reading frame. An ISP-I-negative mutant of B. subtilis was constructed by integration of artificially deleted gene into the chromosome. The mutant sporulated normally in a nutritionally rich medium but showed decreased sporulation in a synthetic medium. The chloramphenicol resistance determinant of a plasmid integrated at the ISP-I locus was mapped by PBS1 transduction and was found to be closely linked to metC (99.5%).

Activation of intracellular serine proteinase in Bacillus subtilis cells during sporulation

Cells of Bacillus subtilis 168 (trpC2) growing and sporulating in a single chemically defined medium carried out intracellular protein degradation and increased their levels of intracellular serine protease-1 in a manner very similar to what had previously been reported for cells sporulating in nutrient broth. The results were interpreted to mean that these processes are intrinsic to sporulation rather than medium dependent. To determine the cause of these increases in specific activity of proteinases, we purified the protease, prepared rabbit immunoglobulins directed against it, and monitored changes in protease antigen levels by performing rocket immunoelectrophoresis. In cells sporulating in nutrient broth, the protease antigen levels increased about 7-fold, whereas the specific activity increased about 150-fold, for an activation of about 20-fold. In cells sporulating in the single chemically defined sporulation medium, the protease antigen increased about 10-fold, whereas the specific activity increased at least 400-fold, for an activation of about 40-fold. These results were interpreted to mean that a posttranslational event activated the protease in vivo; a previously described endogenous proteinase inhibitor was confirmed to be present in the strain used. Chloramphenicol added to the cultures inhibited both the increases in antigen levels and in the specific activity of the proteinase.

Purification, characterization, and physiological function of Bacillus subtilis ornithine transcarbamylase

A procedure was developed for purification of ornithine transcarbamylase (OTCase) to near homogeneity from Bacillus subtilis 168. The purified native enzyme existed as a mixture of dimeric, tetrameric, and hexameric forms, but was converted to the dimer in the presence of 2-mercaptoethanol. The molecular weight of the subunit was 44,000. Some general kinetic properties of the enzyme were described. OTCase was repressed by arginine in growing B. subtilis cells, but the enzyme was induced by arginine at the end of exponential growth. Specific antibodies against the purified OTCase were used to show that the same enzyme was produced under all conditions. These results and studies of a mutant lacking OTCase demonstrated that B. subtilis produced only a single OTCase. OTCase was clearly required for arginine biosynthesis, but the physiological function of OTCase induction by arginine was obscure. OTCase was not induced by, or required for, growth on arginine as a carbon and nitrogen source. Absence of OTCase in a mutant did not alter the yield or arginine content of its spores in comparison to a strain containing OTCase.