A role for a pyridoxne derivative in the multivalent repression of the isoleucine and valine biosynthetic enzymes

Starvation of a pdx mutant of Escherichia coli strain B in the presence of repressing levels of isoleucine, valine and leucine leads to a derepression of the normally repressible ilv genes. The derepression of the ilvA gene under these conditions results in the accumulation of apothreonine deaminase. Addition of pyridoxine leads to a sudden increase in threonine deaminase activity, and to restoration of repression. The pyridoxine component needed for the repression signal is probably not threonine deaminase but, more likely, some transient (“immature”) form of the enzyme.     

Cysteine starvation, isoleucyl-tRNAIle, and the regulation of the ilvGEDA operon of Escherichia coli

The involvement of undermodified tRNA in the regulation of the ilvGEDA operon has been investigated using Escherichia coli C6, a relA-, Cys-, Met- mutant. This strain accumulates thionucleotide-deficient or methyl-deficient tRNA when starved for cysteine or methionine, respectively. The levels of threonine deaminase, the ilvA gene product, and transaminase B, the ilvE gene product, were both lower in cysteine-starved cells, as compared with either growing or methionine-starved cultures. When cysteine was added to cysteine-starved cells, growth ensued promptly and both enzyme activities returned to control levels. Treatment of recovering cultures with valine limited growth by isoleucine limitation, but did not cause a derepression of the ilvGEDA operon. Valine treatment of nonstarved or methionine-starved cells led to the expected increase in threonine deaminase and transaminase B activities. Cysteine-starved cells slowly regained the ability to derepress the operon after 3 h of recovery in complete medium. In contrast, the induction of the lac operon was normal in cysteine-starved cultures, even in the presence of valine. The loss of derepressibility of the ilvGEDA operon was correlated with the presence of a kinetically and chromatographically altered tRNAIle in cysteine-starved cells. No changes in tRNAIle were observed after methionine starvation. Using the periodate method, we found that the charging of tRNAIle increased from the normal level of 60 to 80% or greater after starvation for cysteine. Under conditions where the ilvGEDA operon was fully derepressed in nonstarved cells, the charging of tRNAIle fell to 27%. Unexpectedly, nearly identical results were obtained with cysteine-starved cells after an identical derepression test. These results suggest that factors other than the aminoacylation state of tRNAIle may be important in the regulation of this operon. In particular, modifications to tRNA which involve cysteine may be necessary for controlling the expression of the ilvGEDA operon in E. coli.     

Enzymes of the Isoleucine-Valine Pathway in Acinetobacter

Regulation of four of the enzymes required for isoleucine and valine biosynthesis in Acinetobacter was studied. A three- to fourfold derepression of acetohydroxyacid synthetase was routinely observed in two different wild-type strains when grown in minimal medium relative to cells grown in minimal medium supplemented with leucine, valine, and isoleucine. A similar degree of synthetase derepression was observed in appropriately grown isoleucine or leucine auxotrophs. No significant derepression of threonine deaminase or transaminase B occurred in either wild-type or mutant cells grown under a variety of conditions. Three amino acid analogues were tested with wild-type cells; except for a two- to threefold derepression of dihydroxyacid dehydrase when high concentrations of aminobutyric acid were added to the medium, essentially the same results were obtained. Experiments showed that threonine deaminase is subject to feedback inhibition by isoleucine and that valine reverses this inhibition. Cooperative effects in threonine deaminase were demonstrated with crude extracts. The data indicate that the synthesis of isoleucine and valine in Acinetobacter is regulated by repression control of acetohydroxyacid synthetase and feedback inhibition of threonine deaminase and acetohydroxyacid synthetase.     

Cyclic AMP can replace the relA-dependent requirement for derepression of acetohydroxy acid synthase in E. coli K-12.

Derepression of the isoleucine and valine biosynthetic enzymes was strongly impaired in a relA strain of E. coli K-12 grown in an amino acid-glucose medium. The expression of the isoleucine and valine operons during leucine starvation was markedly defective in the relA mutant as compared to an isogenic rel⁺ strain. Downshift to a poor carbon and energy source or the addition of cyclic AMP to the glucose medium allowed normal derepression in the relA mutant of one of the isoleucine and valine enzymes, acetohydroxy acid synthase. The other isoleucine and valine enzymes failed to derepress under these conditions, in contrast to the high enzyme levels in the rel⁺ parent. No increase in acetohydroxy acid synthase was found in relA cya or relA crp strains during glycerol or pyruvate downshift. Cyclic AMP allowed derepression in the relA cya mutant but not in the relA crp strain. These data strongly suggest that the relA requirement for normal expression of acetohydroxy acid synthase can be replaced by cyclic AMP.     

Regulation of branched-chain amino acid transport in Escherichia coli.

The repression and derepression of leucine, isoleucine, and valine transport in Escherichia coli K-12 was examined by using strains auxotrophic for leucine, isoleucine, valine, and methionine. In experiments designed to limit each of these amino acids separately, we demonstrate that leucine limitation alone derepressed the leucine-binding protein, the high-affinity branched-chain amino acid transport system (LIV-I), and the membrane-bound, low-affinity system (LIV-II). This regulation did not seem to involve inactivation of transport components, but represented an increase in the differential rate of synthesis of transport components relative to total cellular proteins. The apparent regulation of transport by isoleucine, valine, and methionine reported elsewhere was shown to require an intact leucine, biosynthetic operon and to result from changes in the level of leucine biosynthetic enzymes. A functional leucyl-transfer ribonucleic acid synthetase was also required for repression of transport. Transport regulation was shown to be essentially independent of ilvA or its gene product, threonine deaminase. The central role of leucine or its derivatives in cellular metabolism in general is discussed.     

Die Bildung höherer Alkohole bei Aminosäuremangelmutanten von Saccharomyces cerevisiae

1. The influence of varying amounts of amino acids on the uptake of threonine, isoleucine, valine and leucine and their degradation to higher alcohols was investigated using a mutant strain of Saccharomyces cerevisiae, mating type a, genetic markers ade2, hom2, thr4, ilv2, leu1.
2. The cell mass is increased by increasing concentrations of threonine, isoleucine, valine and leucine, the latter two resulting in a higher dry weight. The amino acids are completely utilised at low concentrations. At higher contents up to 20% of the amino acids remain in the medium. The uptake of threonine, isoleucine, valine and leucine depends on the relative amounts of the concentrations of these amino acids in the medium. A greater amount of an amino acid is taken up if its concentration is comparatively higher than those of the other amino acids. There is a competition between the amino acids for the uptake into the cells.

Higher amounts of intracellular isoleucine and leucine are converted to 2-and 3-methylbutanol when compared with the degradation of valine and threonine to isobutanol and n-propanol-1, isoleucine and leucine up to 90%, valine up to 24% and threonine up to 20%. There is a competition between the four amino acids for their degradation to the corresponding higher alcohols. This behaviour confirms the earlier assumption of a degradation of the four amino acids by unspecific enzymes.     

Threonyl-transfer ribonucleic acid synthetase and the regulation of the threonine operon in Escherichia coli.

Two threonine-requiring mutants with derepressed expression of the threonine operon were isolated from an Escherichia coli K-12 strain containing two copies of the thr operon. One of them carries a leaky mutation in ilvA (the structural gene for threonine deaminase), which creates an isoleucine limitation and therefore derepression of the thr operon. In the second mutant, the enzymes of the thr operon were not repressed by threonine plus isoleucine; the threonyl-transfer ribonucleic acid(tRNA) synthetase from this mutant shows an apparent Km for threonine 200-fold higher than that of the parental strain. The gene, called thrS, coding for threonyl-tRNA synthetase was located around 30 min on the E. coli map. The regulatory properties of this mutant imply the involvement of charged threonyl-tRNA or threonyl-tRNA synthetase in the regulation of the thr operon.     

Isoleucine and valine metabolism in Escherichia coli. XIX. Inhibition of isoleucine biosynthesis by glycyl-leucine

The inhibition of growth of the K-12 strain of Escherichia coli by glycyl-l-leucine observed originally by Simmonds and co-workers was investigated. The inhibition was reversed by isoleucine and those precursors of isoleucine beyond threonine in the biosynthetic pathway. Threonine reversed the inhibition poorly. With heavy cell suspensions, the inhibition was transient: the onset of growth followed the disappearance of the dipeptide from the medium and the appearance of glycine and leucine. Glycyl-leucine was shown to be an inhibitor of threonine deaminase (EC 4.2.1.16 l-threonine hydro-lyase [deaminating]). One kind of glycyl-leucine-resistant mutant had a threonine deaminase that was resistant to isoleucine and glycyl-leucine inhibition. The pattern of glycyl-leucine inhibition is compared with those of inhibition by isoleucine and by the weaker inhibitors leucine and valine.     

Role for Free Isoleucine or Glycyl-Leucine in the Repression of Threonine Deaminase in Escherichia coli

In Escherichia coli, the three branched-chain amino acid activating enzymes appear to be essential for multivalent repression of the isoleucine- and valine-forming enzymes. The results of experiments with a mutant, strain CU18, having an altered threonine deaminase, indicate that free isoleucine and some form of threonine deaminase (the product of the ilvA gene) are also involved in multivalent repression. This strain exhibits abnormally high derepressibility but normal repressibility of its ilv gene products, and its threonine deaminase is inhibited only by high concentrations of isoleucine. In strain CU18, the isoleucine analogue, thiaisoleucine, is incapable of replacing isoleucine in the multivalent repression of the ilv genes, whereas the analogue can fully replace the natural amino acid in repression in other strains examined. The dipeptide, glycyl-leucine, which, like isoleucine, is a heterotropic negative effector of threonine deaminase but is not a substrate for isoleucyl-transfer ribonucleic acid synthetase, can completely prevent the accumulation of threonine deaminase-forming potential during isoleucine starvation in strains with normal threonine deaminases. It can not, however, prevent such accumulation in strain CU18 or in other strains in which threonine deaminase is insensitive to any concentration of isoleucine.     

Na+-Dependent Transport of Amino Acids and Its Significance for Growth of a Lysine-producing Bacterium

A lysine-producing mutant Brevibacterium flavum HUT 8052, a threonine plus methionine (or threonine plus homoserine) auxotroph, grew rapidly as nearly as the wild strain in a medium supplemented with NaCl (60 µg/ml), threonine (100 µg/ml), and methionine (33.3 µg/ml). With NaCl concentrations less than 20 µg/ml, the mutant grew little or very slowly, The peculiar growth behavior of the mutant including the above phenomenon could be reasonably explained by the finding of Na⁺-dependent amino acids transport and the feedback inhibition of homoserine dehydrogenase by threonine in the bacterium.

The threonine transport was stimulated by Na⁺ and Li⁺. though the latter being less effective. The transport of threonine was inhibited by serine. The uptake of serine, isoleucine, leucine and valine was also stimulated by Na⁺     

Multivalent regulation of isoleucine-valine transaminase in an Escherichia coli K-12 ilvA deletion strain.

In a strain of Escherichia coli K-12 lacking threonine deaminase, the enzyme converting alpha-ketoisovalerate and alpha-keto-beta-methylvalerate to valine and isoleucine, respectively, was multivalently repressed by valine, isoleucine, and leucine. This activity was due to transaminase B, specified by the ilvE structural gene.     

O-Methylthreonine Inhibition of Growth and of Threonine Deaminase in Escherichia coli

O-methylthreonine (OMT), an isosteric analogue of isoleucine, markedly inhibited growth of Escherichia coli 15. This inhibition was overcome most effectively by addition of isoleucine, valine, or leucine to the medium and less effectively by addition of threonine. The dipeptide, valylleucine, also relieved the OMT-induced inhibition but only after a lag period, suggesting that valine and leucine, liberated by dipeptidase action, compete with OMT for entry into the cell. OMT was activated and transferred to transfer ribonucleic acid (RNA) by isoleucyl-RNA synthetase in vitro. The rate of OMT incorporation into protein of intact cells was comparable to that of isoleucine. In contrast to isoleucine, very high concentrations of OMT were required to inhibit threonine deaminase, and the inhibition was strictly competitive with threonine. In addition, OMT inhibited a threonine deaminase preparation desensitized to isoleucine inhibition.     

Enhancement of isoleucine hydroxamate-mediated growth inhibition and improvement of isoleucine-producing strains of Serratia marcescens.

Growth inhibition by isoleucine hydroxamate in Serratia marcescens was significantly enhanced by adding valine plus leucine and by using glycerol as the carbon source. Isoleucine hydroxamate-resistant mutants were isolated under conditions in which growth inhibition was enhanced. One of the mutants, strain GIHVLr2179, lacked both feedback inhibition and repression of threonine deaminase. An alpha-aminobutyric acid-resistant mutant derived from strain GIHVLr2179, strain GIHVLAr2795, produced 12 mg of isoleucine per ml in the medium containing glucose and urea as carbon and nitrogen sources (a twofold increase over prior reports). This strain had increased activities of threonine deaminase, acetohydroxy acid synthase, aspartokinase, and homoserine dehydrogenase.     

Enhancement of isoleucine hydroxamate-mediated growth inhibition and improvement of isoleucine-producing strains of Serratia marcescens.

Growth inhibition by isoleucine hydroxamate in Serratia marcescens was significantly enhanced by adding valine plus leucine and by using glycerol as the carbon source. Isoleucine hydroxamate-resistant mutants were isolated under conditions in which growth inhibition was enhanced. One of the mutants, strain GIHVLr2179, lacked both feedback inhibition and repression of threonine deaminase. An alpha-aminobutyric acid-resistant mutant derived from strain GIHVLr2179, strain GIHVLAr2795, produced 12 mg of isoleucine per ml in the medium containing glucose and urea as carbon and nitrogen sources (a twofold increase over prior reports). This strain had increased activities of threonine deaminase, acetohydroxy acid synthase, aspartokinase, and homoserine dehydrogenase.     

Overproduction of noncanonical amino acids by <Emphasis Type="Italic">Escherichia coli</Emphasis> cells

Overproduction of noncanonical amino acids norvaline and norleucine by Escherichia coli with inactivated acetohydroxy acid synthases was demonstrated. The cultivation conditions for the overproduction of noncanonical amino acids were studied. The effect of the restoration of acetohydroxy acid synthase activity, increased expression of the leuABCD operon, and inactivation of the biosynthetic threonine deaminase on norvaline and norleucine synthesis was studied. When grown under valine limitation, E. coli cells with inactivated acetohydroxy acid synthases and an elevated level of expression of the valine operon were shown to accumulate norvaline and norleucine (up to 0.8 and 4 g/l, respectively). These results confirm the existing hypothesis of norvaline and norleucine formation from 2-ketobutyrate by leucine biosynthesis enzymes.     

Amino Acid Metabolism of Lemna minor L. : I. Responses to Methionine Sulfoximine

When Lemna minor L. is supplied with the potent inhibitor of glutamine synthetase, methionine sulfoximine, rapid changes in free amino acid levels occur. Glutamine, glutamate, asparagine, aspartate, alanine, and serine levels decline concomitantly with ammonia accumulation. However, not all free amino acid pools deplete in response to this inhibitor. Several free amino acids including proline, valine, leucine, isoleucine, threonine, lysine, phenylalanine, tyrosine, histidine, and methionine exhibit severalfold accumulations within 24 hours of methionine sulfoximine treatment. To investigate whether these latter amino acid accumulations result from de novo synthesis via a methionine sulfoximine insensitive pathway of ammonia assimilation (e.g. glutamate dehydrogenase) or from protein turnover, fronds of Lemna minor were prelabeled with [¹⁵N]H₄⁺ prior to supplying the inhibitor. Analyses of the ¹⁵N abundance of free amino acids suggest that protein turnover is the major source of these methionine sulfoximine induced amino acid accumulations. Thus, the pools of valine, leucine, isoleucine, proline, and threonine accumulated in response to the inhibitor in the presence of [¹⁵N]H₄⁺, are ¹⁴N enriched and are not apparently derived from ¹⁵N-labeled precursors. To account for the selective accumulation of amino acids, such as valine, leucine, isoleucine, proline, and threonine, it is necessary to envisage that these free amino acids are relatively poorly catabolized in vivo. The amino acids which deplete in response to methionine sulfoximine (i.e. glutamate, glutamine, alanine, aspartate, asparagine, and serine) are all presumably rapidly catabolized to ammonia, either in the photorespiratory pathway or by alternative routes.     

Regulation of the formation of isoleucyl-tRNA-synthetase and the level of isoleucine biosynthetic enzymes in E. coli K12

Summary During derepression of threonine deaminase and acetolactate synthetase due to valine deficiency—initiated by -aminobutyric acid limited growth of E. coli K12 or by limited valine supply to an ilv/leu auxotroph of E. coli K12—no alteration of the specific activity of isoleucyl-tRNA-synthetase occurs. Leucine limited growth of the auxotroph, leading to an even higher derepression of the isoleucine biosynthetic enzymes, also does not affect the specific activity of isoleucyl-tRNA-synthetase. However, under growth conditions where the same degree of derepression of threonine deaminase is due to isoleucine deficiency, as in E. coli K12B or two valine resistant mutants thereof grown in the presence of valine, or in the auxotroph during growth-limiting isoleucine supply, a specific two- to three-fold derepression of the isoleucyl-tRNA-synthetase takes place. But there is no strict correlation between the degree of derepression of threonine deaminase due to isoleucine deficiency and the degree of derepression of isoleucyl-tRNA-synthetase, as especially shown in case of the valine resistant mutant Val R4 and Val R5 grown in the presence of valine.These results demonstrate that the rate of formation of isoleucyl-tRNA-synthetase and of threonine deaminase are not regulated by the same molecular devices and that a certain degree of isoleucine deficiency is a prerequisite for a derepression of isoleucyl-tRNA-synthetase.     

Dual autogenous regulatory role of threonine deaminase in Escherichia coli K-12.

Summary We describe the regulatory properties of two strains carrying either the ilvA624 or the ilvA625 mutations, located in the structural gene for threonine deaminase. Crude extracts of both these strains possess a threonine deaminase activity migrating on polyacrylamide gels, differently from the wild type enzyme. Growth studies demonstrate that these mutations do not cause a limitation of isoleucine biosynthesis, suggesting normal catalytic activity of deaminase.A regulatory consequence of the ilvA624 allele is a derepression of the isoleucine-valine biosynthetic enzymes, which is recessive to an ilvA ⁺ allele. The ilvA625 mutation causes a derepression which is dominant in an ilvA625/ilvA ⁺ diploid. We interpret these data assuming that threonine deaminase, previously shown to be an autogenous regulator of the ilv genes, lacks a repressor function in the ilvA624 mutant, while in the ilvA625 mutant it is a better activator than wild type threonine deaminase.The data are discussed in terms of a model requiring that threonine deaminase, or a precursor of it, is in equilibrium between two forms, one being an activator of gene expression and the other being a repressor.     

Cysteine and growth inhibition of Escherichia coli: threonine deaminase as the target enzyme.

Cysteine has been shown to inhibit growth in Escherichia coli strains C6 and HfrH 72, but not M108A. Growth inhibition was overcome by inclusion of isoleucine, leucine, and valine in the medium. Isoleucine biosynthesis was apparently affected, since addition of this amino acid alone could alter the inhibitory effects of cysteine. Homocysteine, mercaptoethylamine, and mercaptoethanol inhibited growth to varying degrees in some strains, these effects also being prevented by addition of branched-chain amino acids. Cysteine, mercaptoethylamine, and homocysteine were inhibitors of threonine deaminase but not transaminase B, two enzymes of the ilvEDA operon. Cysteine inhibition of threonine deaminase was reversed by threonine, although the pattern of inhibition was mixed. These results suggest a relationship between the growth-inhibitory effects of cysteine and other sulfur compounds and the inhibition of isoleucine synthesis at the level of threonine deaminase.     

Branched-Chain Amino Acid Biosynthesis in Salmonella typhimurium: a Quantitative Analysis

We report here the first quantitative study of the branched-chain amino acid biosynthetic pathway in Salmonella typhimurium LT2. The intracellular levels of the enzymes of the pathway and of the 2-keto acid intermediates were determined under various physiological conditions and used for estimation of several of the fluxes in the cells. The results led to a revision of previous ideas concerning the way in which multiple acetohydroxy acid synthase (AHAS) isozymes contribute to the fitness of enterobacteria. In wild-type LT2, AHAS isozyme I provides most of the flux to valine, leucine, and pantothenate, while isozyme II provides most of the flux to isoleucine. With acetate as a carbon source, a strain expressing AHAS II only is limited in growth because of the low enzyme activity in the presence of elevated levels of the inhibitor glyoxylate. A strain with AHAS I only is limited during growth on glucose by the low tendency of this enzyme to utilize 2-ketobutyrate as a substrate; isoleucine limitation then leads to elevated threonine deaminase activity and an increased 2-ketobutyrate/2-ketoisovalerate ratio, which in turn interferes with the synthesis of coenzyme A and methionine. The regulation of threonine deaminase is also crucial in this regard. It is conceivable that, because of fundamental limitations on the specificity of enzymes, no single AHAS could possibly be adequate for the varied conditions that enterobacteria successfully encounter.