Gene-enzyme relationships of aromatic acid biosynthesis in Bacillus subtilis

Mutants have been isolated which correspond to every step concerned with the biosynthesis of the aromatic amino acids in Bacillus subtilis. Each mutant has been characterized, and the lesion it bore was analyzed by deoxyribonucleic acid transformation and PBS-1 mediated transduction. The biochemical analysis revealed that each of the mutations appears to have affected a single enzyme, except for two groups of pleiotropic mutations. All aroF mutants (chorismic acid synthetase) lack dehydroquinic acid synthetase (aroB) activity. The gene that specifies aroB is closely linked to the gene coding for the aroF enzyme. Both genes are a part of the aro cluster. Mutants lacking chorismate mutase activity also lack d-arabino-heptulosonic acid-7-phosphate synthetase and shikimate kinase activity, presumably as a result of these three activities forming a multi-enzyme complex. Another mutant, previously undescribed, had been isolated. The affected gene codes for the tyrosine and phenylalanine aminotransferase activity. All of the mutations have been located on the B. subtilis genome except those in the genes specifying shikimate kinase activity and tyrosine-phenylalanine aminotransferase activity.     

Control of lysine biosynthesis in Bacillus subtilis: inhibition of diaminopimelate decarboxylase by lysine.

Diaminopimelate decarboxylase has been characterized in extracts of Bacillus subtilis and resolved from aspartokinases I and II. Under certain conditions, the enzyme is specifically inhibited by physiological concentrations of L-lysine, but less specificity and altered kinetics of inhibition are observed if lower ionic strengths are employed in the assay procedure. Diaminopimelate decarboxylase can be desensitized to lysine inhibition by either lowering the pH or diluting the enzyme in Tris buffer in the absence of pyridoxal phosphate. Evidence is presented to incidate that, under proper conditions, lysine inhibition involves an interaction of the amino acid with the enzyme rather than competition for available pyridoxal phosphate in the assay. Lysine, by affecting the level of meso-diaminopimelate, may thus regulate its biosynthesis through sequential feedback inhibition. Analysis of the diaminopimelate decarboxylase of 15 revertants of mutants that had originally lacked diaminopimelate decarboxylase activity indicates that as little as 5% of the specific activity of enzyme observed in the wild-type strain is sufficient to permit normal growth rates. In the growing cell, diaminopimelate decarboxylase may therefore exist largely in an inhibited state.     

An enzyme common to histidine and aromatic amino acid biosynthesis in Bacillus subtilis.

Two transaminases exist for tyrosine and phenylalanine synthesis in Bacillus subtilis. One enzyme is also responsible for the transamination of imidazole acetol phosphate to histidinol phosphate, an obligatory reaction in the synthesis of histidine. The gene involved in the synthesis of this enzyme lies in the middle of a cluster of genes, all of which are concerned with the synthesis of the aromatic amino acids. The other gene has not yet been mapped. Mutants have been isolated that lack one or the other enzyme activity. These mutants are prototrophic for tyrosine and phenylalanine. However, both classes of mutants are more sensitive than the wild-type strain to the phenylalanine analogue, fluorophenylalanine, suggesting that each of these mutants synthesizes less phenylalanine than does the wild-type strain. The two enzymes can be separated from one another by ion-exchange chromatography and glycerol-gradient centrifugation. The significance of the observation that an enzyme of histidine synthesis also plays a role in the synthesis of the aromatic acids is considered in light of cross-pathways regulation between the two pathways.     

Alleviation of feedback inhibition in Saccharomyces cerevisiae aromatic amino acid biosynthesis: quantification of metabolic impact

A quantitative analysis of the impact of feedback inhibition on aromatic amino acid biosynthesis was performed in chemostat cultures of Saccharomyces cerevisiae. Introduction of a tyrosine-insensitive allele of ARO4 (encoding 3-deoxy-d-arabino-heptulosonate-7-phosphate synthase) caused a three-fold increase of intracellular phenylalanine and tyrosine concentrations. These amino acids were not detected extracellularly. However, an over 100-fold increase of the extracellular levels of phenylacetate, phenylethanol and their para-hydroxyl analogues was observed. The total increase of the flux through the aromatic pathway was estimated to be over four-fold. Individual overexpression of either the wild-type or feedback insensitive allele of ARO7 (encoding chorismate mutase had no significant impact. However when they were combined with the Tyr-insensitive ARO4 allele in combination with the Tyr-insensitive ARO4 allele, extracellular concentrations of aromatic compounds were increased by over 200-fold relative to the reference strain, corresponding to a 4.5-fold increase of the flux through the aromatic amino acid biosynthesis pathway. Elimination of allosteric control on these two key reactions in aromatic amino acid metabolism significantly affected intracellular concentrations of several non-aromatic amino acids. This broader impact of amino acid biosynthesis presents a challenge in rational optimization of the production of specific amino acids and derived flavour compounds.     

Aromatic amino acid biosynthesis: gene-enzyme relationships in Bacillus subtilis

Single step mutants of Bacillus subtilis which required either one or all of the aromatic amino acids for growth were isolated. The relevant gene defect was determined for each mutant by enzyme assays in vitro. A mutant deficient in each enzyme step of aromatic amino acid biosynthesis was found with the exceptions of the shikimate kinase and the phenylalanine and tyrosine transaminases. Representative mutants carrying the defective genes were mapped by deoxyribonucleic acid mediated transformation by reference to the aromatic amino acid gene (aro) cluster and, alternately, to any of the other unlinked aro genes. The genes coding for dehydroquinate synthetase, 3-enol pyruvylshikimate 5-phosphate synthetase, one form of chorismate mutase, and prephenate dehydrogenase are linked to the aro cluster. Except for the previously identified linkage between the genes of 3-deoxy-d-arabino heptulosonic acid 7-phosphate synthetase and one species of chorismate mutase, the other genes involved in this pathway are neither linked to the aro cluster nor to each other.     

Control of teichoic acid and teichuronic acid biosynthesis in chemostat cultures of Bacillus subtilis var. niger

1. Quantitative determination of the anionic polymers present in the walls of Bacillus subtilis var. niger organisms undergoing transition, in a chemostat culture, from either Mg(2+)-limitation to PO(4) (3-)-limitation or K(+)-limitation to PO(4) (3-)-limitation showed that teichuronic acid synthesis started immediately the culture became PO(4) (3-)-limited and proceeded at a rate substantially faster than the rate of biomass synthesis. 2. Simultaneously, the cell-wall teichoic acid content diminished at a rate greater than that due to dilution by newly synthesized wall material, and fragments of teichoic acid and mucopeptide accumulated in the culture extracellular fluid. 3. Equally rapid reverse changes occurred when a PO(4) (3-)-limited B. subtilis var. niger culture was returned to being Mg(2+)-limited. 4. It is concluded that in this organism both teichoic acid and teichuronic acid syntheses are expressions of a single genotype, and a mechanism for the control of synthesis of both polymers is suggested. 5. These results are discussed with reference to the constantly changing environmental conditions that obtain in a batch culture and the variation in bacterial cell-wall composition that is reported to occur throughout the growth cycle.     

Cross pathway regulation: effect of histidine on the synthesis and activity of enzymes of aromatic acid biosynthesis in Bacillus subtilis

l-Histidine and, to a lesser degree, l-phenylalanine at concentrations of 10(-4)m inhibit the growth of leaky mutants (bradytrophs) of Bacillus subtilis that are deficient in the synthesis of p-hydroxyphenylpyruvate, the first intermediate specific to tyrosine synthesis. The inhibition can be overcome by growth factor amounts of l-tyrosine and p-hydroxyphenylpyruvate. Histidine and phenylalanine are capable of inhibiting the synthesis of tyrosine in several ways, and the major physiological effect which results in growth inhibition has not been established. Both l-histidine and l-phenylalanine inhibit the activity of prephenate dehydrogenase at concentrations about 100-fold higher than the inhibitory concentration of l-tyrosine. Histidine also appears to repress the synthesis of prephenate dehydrogenase because a histidine bradytroph growing in histidine-supplemented medium has a twofold lower level of this enzyme than the same cells growing in unsupplemented medium. These same two amino acids also inhibit the growth of a bradytroph deficient in dehydroquinate synthetase, an early enzyme in the pathway of tyrosine, phenylalanine, and tryptophan synthesis. The inhibition is overcome by a combination of tyrosine and phenylalanine. Histidine-resistant derivatives of both the prephenate dehydrogenase and dehydroquinate synthetase-deficient strains, which simultaneously have gained resistance to phenylalanine, have been isolated. Most of these resistant mutants synthesize additional tyrosine compared with the parent strain. One class of resistant mutants excretes tyrosine and has a number of enzymes of aromatic acid synthesis which are no longer repressible by any combination of the aromatic amino acids. Tyrosine inhibits the growth of histidine bradytrophs. Histidine, at growth factor levels, overcomes the inhibition.     

Regulation of leucine biosynthesis in Bacillus subtilis

The biosynthesis of alpha-isopropylmalate (alphaIPM) synthetase, IPM isomerase, and betaIPM dehydrogenase in Bacillus subtilis can be derepressed in leucine auxotrophs by limiting them for leucine. The derepression of the three enzymes is apparently coordinate. A class of mutants resistant to 4-azaleucine excretes leucine and has derepressed levels of all three enzymes. The azaleucine-resistance mutations may lie in a gene (azlA) encoding a repressor. Efforts to find mutations characteristic of a constitutive operator have been unsuccessful. No polar mutations have been found among nine leucine auxotrophs that have characteristics of frameshift mutations. The enzyme catalyzing the first step in leucine biosynthesis, alphaIPM synthetase, is sensitive to feedback inhibition by leucine. We conclude that leucine biosynthesis is controlled by the inhibition of the activity of the first biosynthetic enzyme by leucine, and by the repression of the synthesis of the first three biosynthetic enzymes by leucine. The repression of the three enzymes may be under the control of a single repressor and a single operator, or of a single repressor and a separate operator for each structural gene.     

Control of tryptophan biosynthesis by the methyltryptophan resistance gene in Bacillus subtilis

5-Methyltryptophan-resistant mutants derived from Bacillus subtilis strain 168 synthesize all of the tryptophan biosynthetic enzymes constitutively and excrete tryptophan. These mutants can be divided into three classes: class 1, low enzyme level and low rate of tryptophan excretion; class 2, high enzyme level and intermediate rate of tryptophan excretion; and class 3, high enzyme level and high rate of tryptophan excretion. A bradytrophic requirement for phenylalanine is correlated with the rate of tryptophan excretion. The phenylalanine requirement is relieved when the rate of tryptophan excretion is reduced by either (i) lowering the level of the tryptophan enzymes, (ii) reducing the supply of a tryptophan precursor (chorismate), or (iii) stopping tryptophan synthesis by a mutational block in the pathway. All of the mutants map in a region of the chromosome previously reported as the mtr locus. Our data show that synthesis of the tryptophan enzymes is controlled through the mtr locus but not influenced by precursors of tryptophan.     

Serine biosynthesis and its regulation in Bacillus subtilis

Cell-free extracts of Bacillus subtilis strains GSY and 168 convert (14)C-phosphoglycerate to (14)C-serine phosphate and (14)C-serine. These reactions indicate a functional phosphorylated pathway for serine biosynthesis in these cells. The addition of serine to the incubation mixture inhibited the formation of both radioactive products. Extracts of mutant strains that require serine for growth lacked the capacity to synthesize serine phosphate, confirming that the phosphorylated pathway was the only functional pathway available for serine synthesis. Serine phosphate phosphatase and phosphoglycerate dehydrogenase activity were demonstrated in cell extracts, and the phosphoglycerate dehydrogenase was shown to be inhibited specifically by l-serine. The extent of serine inhibition increased when the temperature was raised from 25 to 37 C, and the thermal stability of the enzyme was enhanced by the presence of the inhibitor serine or the coenzyme reduced nicotinamide adenine dinucleotide. At 37 C the curve representing the relationship between phosphoglycerate concentration and enzyme velocity was biphasic, and the serine inhibition which was competitive at low substrate concentrations became noncompetitive at higher concentrations.     

Vitamin B 6 biosynthesis in Bacillus subtilis]

1) A vitamin-B6-producing mutant, BA 1, was selected by treatment of Bacillus subtilis with N-methyl-N'-nitro-N-nitrosoguanidine. Using gradient plates supplemented with the vitamin B6 antagonist isonicotinohydrazide, three mutants of BA 1 were isolated, which excrete 2-5 mg of vitamin B6/l of growth medium. 2) Mutation of the three vitamin-B6-producing strains BA 1, BA 11 and L 71 led to the isolation of 49 vitamin-B6 deficient mutants. All mutants are able to grow with pyridoxine, pyridoxal, pyridoxamine, and even with 4'-deoxypyridoxine. Glycolaldehyde or nicotinic acid do not support growth of the mutants. Some of these vitamin-B6-deficient mutants can also grow in the absence of vitamin B6, providing isoleucine is present. Others show a growth stimulation, when isoleucine is added to a medium containing a vitamin B6 compound. Isoleucine can be replaced by 3-methyl-2-oxovalerate. Cross-feeding experiments indicated a division of the mutants into two groups. Using chromatographic methods, substances which support growth of the mutants were purified, but have not yet been identified. Following the addition of 4'-deoxypyridoxine, 4'-deoxypyridoxine 5'-phosphate was isolated from the growth medium of a vitamin B6-deficient mutant. 3) Threonine dehydratase, transaminase B and transaminase C from wild-type Bacillus subtilis were compared with the enzymes from vitamin-B6-producing strains and with the enzymes from vitamin-B6-deficient mutants. Both the vitamin-B6-producing and the vitamin B6-deficient mutants show higher specific activities than wild type. In the mutant strains no multivalent repression of the threonine dehydratase and transminase B by isoleucine, leucine and valine could be demonstrated. Leucine dehydrogenase, the first enzyme of the isoleucine catabolic pathway, is constitutively produced in the vitamin-B6-producing and in the vitamin-B6-deficient mutants. In the vitamin-B6-deficient mutants, there is a correlation between growth yield in the presence of isoleucine and the specific activity of leucine dehydrogenase. In the crude extract of Bacillus subtilis no pyridoxamine-phosphate oxidase activity could be demonstrated, whereas pyridoxal kinase was readily detectable.     

Regulated enzymes of aromatic amino acid synthesis: control, isozymic nature, and aggregation in Bacillus subtilis and Bacillus licheniformis

Several regulated enzymes involved in aromatic amino acid synthesis were studied in Bacillus subtilis and B. licheniformis with reference to organization and control mechanisms. B. subtilis has been previously shown (23) to have a single 3-deoxy-d-arabinoheptulosonate 7-phosphate (DAHP) synthetase but to have two isozymic forms of both chorismate mutase and shikimate kinase. Extracts of B. licheniformis chromatographed on diethylaminoethyl (DEAE) cellulose indicated a single DAHP synthetase and two isozymic forms of chorismate mutase, but only a single shikimate kinase activity. The evidence for isozymes has been supported by the inability to find strains mutant in these activities, although strains mutant for the other activities were readily obtained. DAHP synthetase, one of the isozymes of chorismate mutase, and one of the isozymes of shikimate kinase were found in a single complex in B. subtilis. No such complex could be detected in B. licheniformis. DAHP synthetase and shikimate kinase from B. subtilis were feedback-inhibited by chorismate and prephenate. DAHP synthetase from B. licheniformis was also feedback-inhibited by these two intermediates, but shikimate kinase was inhibited only by chorismate. When the cells were grown in limiting tyrosine, the DAHP synthetase, chorismate mutase, and shikimate kinase activities of B. subtilis were derepressed in parallel, but only DAHP synthetase and chorismate mutase were derepressible in B. licheniformis. Implications of the differences as well as the similarities between the control and the pattern of enzyme aggregation in the two related species of bacilli were discussed.     

重组枯草芽胞杆菌不对称还原产d-伪麻黄碱

为了实现羰基还原酶基因mldh在枯草芽胞杆菌Bacillus subtilis中的表达并通过细胞内的葡萄糖脱氢酶完成辅酶的再生,以枯草芽胞杆菌rpsD基因的启动子PrpsD和终止子TrpsD为表达元件,将羰基还原酶基因mldh连接至构建好的质粒(pHY300plk-PrpsD-TrpsD上,得到质粒pHY300plk-PrpsD-mldh-TrpsD;进一步将重组质粒转化入B. subtilis Wb600中获得重组菌B. subtilis Wb600 (pHY300plk-PrpsD-mldh-Trps