Physiological and enzymatic aspects of histidine-mediated control of the tryptophan pathway

Summary It would thus appear that in Saccharomyces cerevisiae there are two forms of histidine-mediated control on the tryptophan pathway. In some strains histidine increases anthranilate synthetase and indole glycerol phosphate synthetase activities, while tryptophan synthetase decreases. In other strains histidine affects coordinately all enzymatic activities involved in tryptophan biosynthesis. The two groups of strains also differ in the formation, during the growth of the enzymatic activities involved in tryptophan biosynthesis. This difference in the relative rates at which the two enzymes are formed may explain the accumulation of intermediates in the cultural media of some strains. The derepression of anthranilate synthetase and indole glycerol phosphate synthetase activities by histidine is particularly manifest in the auxotrophic his₃ strains that show these activities very depressed in histidine starvation; large amounts of this amino acid stimulate them to a considerably greater extent than in prototrophic strains.Abbreviations IGP imidazole glycerol phosphate - InGP indole glycerol phosphate - ASase anthranilate synthetase - InGPase indole-3-glycerol phosphate synthetase - TSase tryptophan synthetase - Tris tris (hydroxymethyl)-aminomethane This investigation was supported by a research grant of C.N.R. (Consiglio Nazionale delle Ricerche, Roma).     

Tryptophan synthetase in Euglena gracilis strain G

The five enzyme activities in the synthesis of l-tryptophan have been obtained in extracts of Euglena gracilis. One of these, tryptophan synthetase, has been studied in detail. The general catalytic properties of tryptophan synthetase, including the range of reactions catalyzed and its substrate and cofactor affinities, are similar to those reported for other organisms. The Euglena enzyme has two properties never previously observed for tryptophan synthetase. First, the rate of catalysis of the conversion of indole-glycerol phosphate to l-tryptophan remained at its maximal value and was unaffected by the ionic environment up to 0.3 m KCl. In contrast, the conversion of indole to tryptophan showed a sharp maximum at 0.08 m KCl. Second, the enzyme is a component of a complex that includes every enzyme in the pathway committed to tryptophan biosynthesis with the exception of anthranilate synthetase, the regulatory enzyme.     

Inactivation and partial degradation of phosphoribosylanthranilate isomerase-indoleglycerol phosphate synthetase in nongrowing cultures of Escherichia coli.

The stability of tryptophan biosynthetic enzyme activities was examined in cultures of repressor-negative (trpR) strains of Escherichia coli K-12 incubated under conditions of nutrient starvation of chloramphenicol inhibition. The results show that four of the five activities examined are stable under most nongrowing conditions, whereas one activity, indoleglycerol phosphate (InGP) synthetase, carried by the trpC protein, is unstable under most conditions tested. Phosphoribosylanthranilate (PRA) isomerase activity, which is also carried by the trpC protein, is unstable during starvation for ammonium, cysteine, or sulfate but is stable under other nongrowing conditions where InGP synthetase is not. InGP synthetase activity but not PRA isomerase activity is also diminished about twofold in cultures using glycerol as a carbon-energy source. These results indicate that one or both activities of the trpC protein is specifically inactivated under several culture conditions. Experiments with antibodies to the trpC protein show that sulfate-starved and ammonium-starved cultures contain 20 to 40% less immunologically reactive trpC protein than unstarved cultures. This indicates that the trpC protein is probably partially degraded under these conditions. During recovery from sulfate starvation or ammonium starvation, cultures slowly regain normal levels of InGP synthetase and PRA isomerase activities, suggesting that inactivation may be reversible.     

Partial Characterization of Phosphoribosyl Transferase, Phosphoribosyl Anthranilate Isomerase, and Indole Glycerol Phosphate Synthase from Serratia marcescens

The molecular organization of the enzymes phosphoribosyl (PR) transferase, phosphoribosyl anthranilate (PRA) isomerase, and indole glycerol phosphate (InGP) synthase of the tryptophan biosynthetic pathway of Serratia marcescens was investigated and compared with that reported in other enteric bacteria. PRA isomerase and InGP synthase activities were found to reside in a single polypeptide chain, a situation analogous to that in Escherichia coli, Salmonella typhimurium, and Aerobacter aerogenes. This bifunctional enzyme was purified to near homogeneity. Its molecular weight was estimated to be 48,000. PR transferase was found unassociated with PRA isomerase and InGP synthase after gel filtration and ion-exchange chromatography. Whereas in other enteric organisms PR transferase has been reported to form an aggregate with anthranilate synthase, it is a distinct entity in S. marcescens.     

Studies on tryptophan synthetases from various strains of Bacillus subtilis

1. Tryptophan synthetase B of three strains of Bacillus subtilis was prepared from ;exo-protoplastic' and ;endo-protoplastic' fractions; the enzyme from ;exo-protoplastic' fraction was purified 30- to 120-fold by ammonium sulphate precipitation and DEAE-cellulose column chromatography; the latter step separated this enzyme from tryptophan synthetase A, tryptophanase and proteolytic enzymes, but the purified preparations were not stable. 2. The activity of tryptophan synthetase B did not depend on the presence of tryptophan synthetase A. 3. Tryptophan synthetases B of the strains tested differed in their utilization of 2- and 7-methylindole as compared with indole; this suggests that these tryptophan synthetases B are not identical.     

N-(5′-Phosphoribosyl)anthranilate isomerase–indol-3-ylglycerol phosphate synthetase of tryptophan biosynthesis. Relationship between the two activities of the enzyme from Escherichia coli

Further evidence is presented to confirm the previous conclusion that the enzyme from Escherichia coli catalysing the two sequential reactions in tryptophan biosynthesis, N-(5'-phosphoribosyl)anthranilic acid (PRA) --> 1-(o-carboxyphenyl-amino)-1-deoxyribulose 5-phosphate (CdRP) --> indol-3-ylglycerol phosphate (InGP)+CO(2)+H(2)O, consists of a single polypeptide chain. The kinetic properties of the enzyme demonstrate that intermediate CdRP formed from PRA must dissociate from the enzyme before it can be converted into InGP. It is concluded that there are two distinct and non-overlapping catalytic sites on the enzyme for the two reactions. The expected complementation between a mutationally altered form of the enzyme lacking the first reaction and a mutationally altered form lacking the second reaction has been demonstrated in vitro by InGP formation from PRA. This system thus exhibits intracistronic complementation with a non-oligomeric protein gene product.     

Substrate interactions with the alpha-subunit of the Escherichia coli tryptophan synthase. A study of the activity of mutant alpha-subunits.

Extracts of 19 trpA mutant strains of Escherichia coli were examined for their relative activity in the reversible aldolytic reaction catalyzed by the trpA gene product, the α-subunit of tryptophan synthase, in combination with the β-subunit of this enzyme. The specific activities in this reaction, indoleglycerol-P (InGP) ? indole + glyceraldehyde-3-P, were determined for both the forward reaction (InGP to indole) and the reverse reaction (indole to InGP). The majority of the mutant α-subunits had <10% of the wild-type activity in the forward reaction, as expected since these mutant strains were selected for defects in this reaction. In contrast, the majority of these mutant enzymes had >50% of the wild-type activity in the reverse reaction. Several had 5 to 15% of wild-type specific activity in the forward reaction but 60 to 100% of wild-type specific activity in the reverse reaction. Spontaneous revertant strains, selected for their increased ability to catalyze the forward reaction effectively, contained α-subunits with the expected higher specific activities in the forward reaction but without parallel changes in the reverse reaction activity.     

Tryptophan Synthase and Production of l-Tryptophan in Regulatory Mutants

A 5-fluorotryptophan-resistant mutant of Brevibacterium flavum, No. 187, accumulated 2.6 g of indole 3-glycerol (InG) in addition to 8.0 g of l-tryptophan per liter in the culture medium. The addition of l-serine to the medium decreased the accumulation of InG and increased that of l-tryptophan up to a concentration of 10.3 g/liter, while the addition of l-tryptophan increased the InG accumulation, suggesting that InG was formed by hydrolysis of indole 3-glycerol phosphate (InGP), the substrate of tryptophan synthase (TS) which catalyzed the final step reaction of tryptophan biosynthesis. Then, in order to examine the mechanism of the InG accumulation, TS was purified from tryptophan auxotroph, TA-60. The reaction mechanism of TS was Ordered Bi Bi with Km’s of 0.63 and 0.038 mm for serine and InGP, respectively. Tryptophan, a product of the TS reaction, inhibited TS competitively with respect to serine and the Ki for tryptophan was estimated to be 2.0 mm. On the other hand, anthranilate synthase (AS), the first enzyme in the tryptophan biosynthetic pathway, was much less sensitive to the feedback inhibition by tryptophan in strain No. 187 than in the wild strain. The tryptophan concentration giving 50% inhibition of AS in strain No. 187 was estimated to be 2.4 mm, almost comparable to that of TS, 7.7 mm. From these results, it was concluded that the accumulation of InG in strain No. 187 would result from the product inhibition of TS by the tryptophan accumulated.     

Enzymatic Basis for Overproduction of Tryptophan and Its Metabolites in Hansenula polymorpha Mutants

3-Deoxy-d-arabinoheptulosonate 7-phosphate (DAHP) synthetase and anthranilate synthetase are key regulatory enzymes in the aromatic amino acid biosynthetic pathway. The DAHP synthetase activity of Hansenula polymorpha was subject to additive feedback inhibition by phenylalanine and tyrosine but not by tryptophan. The synthesis of DAHP synthetase in this yeast was not repressed by exogenous aromatic amino acids, singly or in combinations. The activity of anthranilate synthetase was sensitive to feedback inhibition by tryptophan, but exogenous tryptophan did not repress the synthesis of this enzyme. Nevertheless, internal repression of anthranilate synthetase probably exists, since the content of this enzyme in H. polymorpha strain 3-136 was double that in the wild-type and less sensitive 5-fluorotryptophan-resistant strains. The biochemical mechanism for the overproduction of indoles by the 5-fluorotryptophan-resistant mutants was due primarily to a partial desensitization of the anthranilate synthetase of these strains to feedback inhibition by tryptophan. These results support the concept that inhibition of enzyme activities rather than enzyme repression is more important in the regulation of aromatic amino acid biosynthesis in H. polymorpha.     

Production L-tryptophan by Escherichia coli cells

Whole cells of Escherichia coli B 10 having high tryptophan synthetase activity were used directly as an enzyme source to produce L-tryptophan from indole and L- or D,L-serine. This strain is tryptophan auxotrophic, which is tryptophanase negative and, in addition, L- and D-serine deaminase negative under production conditions. To avoid inhibition of tryptophan synthetase by a high concentration of indole, nonaqueous organic solvents, Amberlite XAD-2 adsorbent, and nonionic detergents were used as reservoirs of indole in the reaction mixture for the production of L-tryptophan. As a result, different effects were observed on the production of L-tryptophan. Particularly, among the nonionic detergents, Triton X-100 was very efficient. Using Triton X-100 for production of L-tryptophan from indole and L- or D,L-serine by whole cells of Escherichia coli B 10, 14.14 g/100 mL and 14.2 g/100 mL of L-tryptophan were produced at 37 degrees C for 60 h.     

Synthesis of l-Tryptophan from Indole and dl-Serine by Tryptophan Synthetase Entrapped in Fibres

Optimal culture conditions for microbial production of tryptophan synthetase were studied. It was found that on cultivation of Escherichia coli 476, a tryptophan auxotroph, in a medium containing 5g/liter glycerol as C source, supplemented with 1 g/liter of acid-treated peptone, cells with high tryptophan synthetase activity could be obtained.

The enzyme was extracted from cells and 3-fold purified by heat treatment and ammonium sulfate precipitation. The overall yield of the isolation procedure was 60%.

The partially purified tryptophan synthetase was entrapped in cellulose triacetate fibres. Under storage conditions, in refrigerator, the entrapped enzyme was stable at least for 6 months. The activity of the entrapped enzyme was about 75% with respect to the free enzyme.

Similar behaviour for the free and entrapped enzyme was observed as to the effect of temperature and pH on the enzymic activity. The operational stability of the entrapped tryptophan synthetase was very good (activity unchanged after 50 days) provided the accumulation of indole on the fibres was avoided.     

On the specificity of cytochrome c synthetase in recognition of the amino acid sequence of apocytochrome c

Two forms of yeast cytochrome c synthetases with different specificities were resolved, one (synthetase I), solubilized from mitochondria or the cell debris with Triton X-100, recognizing not horse apocytochrome c but yeast apo-iso-1-cytochrome c as a substrate and the other (synthetase II) still bound with the particulate fraction from mitochondria after treatment with Triton, recognizing both horse and yeast apocytochromes c. The activity with labeled yeast apo-iso-1-cytochrome c as a substrate of cytochrome c synthetase I can be quantitatively inhibited by nonlabeled Candida krusei apocytochrome c and partially by nonlabeled tuna apocytochrome c but not by nonlabeled horse apocytochrome c indicating a specific amino acid sequence being recognized. However, an enzyme similarly solubilized from beef heart mitochondria recognized both horse apocytochrome c and yeast apo-iso-1-cytochrome c for attachment of heme. In view of the fact that the yeast synthetase II and the beef synthetase can both utilize either horse apocytochrome c or yeast apo-iso-1-cytochrome c as substrates, we suggest that these enzymes may also be involved in biosynthesis of cytochrome c1, that is, the ability to attach heme to apocytochrome c and apocytochrome c1 may have been conserved in eucaryotic cells, and that both synthetases may therefore be homologous.     

Altered Protein Formation as a Result of Suppression in Neurospora Crassa

The mutant td201 of Neurospora crassa is mutated in the trp-3 locus and forms an altered tryptophan synthetase. A suppressor mutation, su2-6, in this mutant, unlinked to the trp-3 locus, results in the production of wild-type tryptophan synthetase activity, which accounts for the alleviation of the tryptophan or indole requirement. This enzyme activity is associated with a protein physically dissimilar to the wild-type enzyme. A second altered protein, a serologically cross-reacting material is also formed in the suppressed mutant, in addition to the altered enzyme normally formed by the td201 mutant. Normal growth, equivalent to that of wild type, is not restored in the suppressed mutant even with tryptophan supplementation. The relationship of the data to possible mechanisms of suppression is discussed.     

Serine modulates substrate channeling in tryptophan synthase. A novel intersubunit triggering mechanism

Tryptophan synthase, an alpha 2 beta 2 complex, is a classic example of an enzyme that is thought to "channel" a metabolic intermediate (indole) from the active site of the alpha subunit to the active site of the beta subunit. We now examine the kinetics of substrate channeling by tryptophan synthase directly by chemical quench-flow and stopped-flow methods. The conversion of indole-3-glycerol phosphate (IGP) to tryptophan at the active site proceeds at a rate of 24 s-1, which is limited by the rate of cleavage of IGP to produce indole (alpha reaction). In a single turnover experiment monitoring the conversion of radiolabeled IGP to tryptophan, only a trace of indole is detectable (less than or equal to 1% of the IGP), implying that the reaction of indole to form tryptophan must be quite fast (greater than or equal to 1000 s-1). The rate of reaction of indole from solution is much too slow (40 s-1 under identical conditions) to account for the negligible accumulation of indole in a single turnover. Therefore, the indole produced at the alpha site must be rapidly channeled to the beta site, where it reacts with serine to form tryptophan: channeling and the reaction of indole to form tryptophan must each occur at rates greater than or equal to 1000 s-1. Steady-state turnover is limited by the slow rate of tryptophan release (8 s-1). In the absence of serine, the cleavage of IGP to indole is limited by a change in protein conformation at a rate of 0.16 s-1. When the alpha beta reaction is initiated by mixing enzyme with IGP and serine simultaneously, there is a lag in the cleavage IGP and formation of tryptophan. The kinetics of the lag correspond to the rate of formation of the aminoacrylate in the reaction of serine with pyridoxal phosphate at the beta site, measured by stopped-flow methods (45 s-1). There is also a change in protein fluorescence, suggestive of a change in protein conformation, occurring at the same rate. Substitution of cysteine for serine leads to a longer lag in the kinetics of IGP cleavage and a correspondingly slower rate of formation of the aminoacrylate (6 s-1). Thus, the reaction of serine at the beta site modulates the alpha reaction such that the formation of the aminoacrylate leads to a change in protein conformation that is transmitted to the alpha site to enhance the rate of IGP cleavage 150-fold.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction of indoleacetic Acid synthetases in tobacco pith explants

Formation of indoleacetic acid synthetases in tobacco pith explants was determined by following the growth of tissue cultures under conditions of indole-3-acetic acid (IAA) deprivation and by measuring the enzymatic conversion of tryptophan to IAA in the cultures. The pith explants obtained from the parent plant (Nicotiana glauca) and from basal regions of the tumor-prone hybrid (N. glauca × N. langsdorffii) both show a requirement for exogenous IAA for growth initiation in culture. The parent pith requires the constant presence of added IAA for continued growth, but hybrid pith, after initial treatment with IAA, will grow without further additions. IAA synthetases are detected in the cell homogenates of hybrid pith explants cultured with either continuous or initial IAA addition. These observations indicate that IAA may induce its own production. In contrast, IAA synthetases are not found in the parent pith under comparable culture conditions. Besides IAA, nonhormonal compounds such as indole and tryptophan are also capable of stimulating growth of hybrid pith, possibly through the induction of IAA synthetases needed for IAA formation. Indole and tryptophan are, however, inactive in growth promotion of the parent pith. These results suggest that the genomic expression of IAA synthetase formation is more stringently controlled in N. glauca than in the tumorprone hybrid.     

Isoleucyl-tRNA synthetase from Escherichia coli MRE 600. Different pathways of the aminoacylation reaction depending on presence of pyrophosphatase, order of substrate addition in the pyrophosphate exchange, and substrate specificity with regard to ATP analogs

The substrate specificity of isoleucyl-tRNA synthetase from Escherichia coli MRE 600 with regard to ATP analogs has been compared with the results obtained with isoleucyl-tRNA synthetase from yeast. The enzyme from E. coli is less specific, the two enzymes exhibit different topographies of their active centres. The order of substrate addition to isoleucyl-tRNA synthetase from E. coli MRE 600 has been investigated by bisubstrate kinetics, product inhibition and inhibition by substrate analogs. The inhibition studies were done in the aminoacylation and in the pyrophosphate exchange reaction, the aminoacylation was investigated in the absence and presence of inorganic pyrophosphatase. As found for isoleucyl-tRNA synthetase from yeast, the results of the pyrophosphate exchange studies indicate the possibility of formation of E . Ile-AMP . ATP complexes by random addition of one ATP and one isoleucine molecule, followed by adenylate formation, release of pyrophosphate and subsequent addition of a second molecule of ATP. For the aminoacylation in the absence of pyrophosphatase, a rapid-equilibrium random ter addition of the substrates is found whereas the enzyme from yeast exhibits a steady-state ordered ter-ter mechanism; in the presence of pyrophosphatase the mechanism is bi-uni uni-bi ping-pong similarly as observed for the yeast enzyme. A comparison of inhibition patterns obtained with N(6)-benzyladenosine 5'-triphosphate under different assay conditions (spermine or magnesium ions, addition of pyrophosphatase) indicates that even more than two pathways of the aminoacylation may exist. The catalytic cycles of the two mechanisms derived from the observed orders of substrate addition and product release include the same enzyme substrate complex (E . tRNA . Ile-AMP) for the aminoacyl transfer reaction. The kcat values, however, are considerably different: kcat of the sequential pathway is about 40% lower than kcat of the ping-pong mechanism.     

The enzymatic synthesis of L-tryptophan analogues

A convenient method for the synthesis of l-tryptophan analogues is described. The method utilizes E. coli tryptophan synthetase, which catalyses the condensation of indole and l-serine to yield l-tryptophan. It is found that several indole analogues will replace indole as substrate for the enzyme to give the corresponding l-tryptophan analogues in good yield. By using [¹⁴C]serine, analogues can be prepared radioactively labeled in the side-chain carbon atoms.     

Terbium(III) luminescence study of the spatial relationship of tryptophan residues to the two metal ion binding sites of Escherichia coli glutamine synthetase.

The luminescence of Tb(III) was used to explore the topography of the metal ion sites of Escherichia coli glutamine synthetase and the relationship between these sites and tryptophan residues of the enzyme. By irradiation of tryptophan residues at 295 nm and measurement of the resulting Tb(III) luminescence at 544 nm, a biphasic curve was obtained upon titrating apoenzyme with Tb(III) indicating sequential binding of Tb(III) ions to the two binding sites of glutamine synthetase. The luminescence intensity was greater in the second region of the titration curve which is mostly due to energy transfer from Trp-158 to the second Tb(III) binding site of the enzyme. By use of the F?rster equation for energy transfer from donor Trp to acceptor Tb(III), distances from Trp-57 to Tb(III) at the n1 and n2 sites were calculated, by using a mutant enzyme in which Trp-158 was replaced by Ser, to be 16.4 and 15.7 A, respectively; distances from Trp-158 to Tb(III) at the n1 and n2 sites were calculated, by using a mutant enzyme in which Trp-57 was replaced by Leu, to be 16.8 and 9.5 A, respectively. All the distances are in reasonably good agreement with the crystal structure distances from Salmonella typhimurium glutamine synthetase except the distance from Trp-158 to the second Tb(III) binding site. The discrepancies may result from a slightly different conformation of glutamine synthetase in solution and in the crystal and/or a slightly different conformation for trivalent Ln(III) binding compared to divalent Mn(II) binding.     

谷氨酰胺高效酶法转化条件研究

谷氨酰胺合成酶是生物体氮代谢的中心酶之一,在消耗ATP的情况下,谷氨酰胺合成酶催化由谷氨酸和NH4+向谷氨酰胺的转化,Toch ikura提出了将酵母发酵与纯化酶结合生产谷氨酰胺(G ln)的方法,本实验通过建立酶法合成L-G ln与酵母酒精发酵的能量偶联体系,研究了在此偶联体系中各因素对谷氨酰胺酶转化效率的影响,为工业上利用酶法生产G ln提供理论依据。     

Biochemical identification of a tryptophan auxotroph in Rhodospirillum rubrum.

A tryptophan auxotroph of aerobically grown Rodospirillum rubrum was isolated after mutagenesis and replica plating. The mutant grows on tryptophan or indole, accumulates indole glycerol phosphate, lacks the capacity to convert indole glycerol phosphate to indole glycerol phosphate to indole, and finally is defective in photosynthetic growth. The strain is, therefore, analogous to a Trp A mutant which is defective in the alpha-subunit structural gene of tryptophan synthetase.