ON THE SEPARATION OF THE TRYPTOPHAN SYNTHETASE OF ESCHERICHIA COLI INTO TWO PROTEIN COMPONENTS

Epitope localization in antigen-monoclonal-antibody complexes by small-angle X-ray scattering. An approach to domain organization in the beta 2 subunit of Escherichia coli tryptophan synthase

Each polypeptide chain of the beta 2 subunit of Escherichia coli tryptophan synthase (EC 4.2.1.20) is made of two domains, F1 (N-terminal) and F2 (C-terminal). To determine the relative position of these domains in the native protein, complexes between beta 2 and Fab fragments from two monoclonal antibodies, one specific for F1 (68-1) and the other for F2 (93-6), have been prepared and purified. Small-angle X-ray scattering measurements have been made on solutions of each complex. From the experimental scattering curves obtained, computer modeling leads to structural models of the two beta 2-Fab complexes. Though relatively low, the resolution of these models allows the localization on beta 2 of the antigenic sites recognized by the two antibodies, to show that the C-terminal F2 domains lie at the distal ends of the elongated beta 2 protein, and to show how steric hindrance prevents beta 2, though structurally and functionally dimeric, from binding more than one Fab 93-6 fragment per dimer.

Conformational effects of ligand binding on the beta 2 subunit of Escherichia coli tryptophan synthase analyzed with monoclonal antibodies

Five monoclonal antibodies recognizing five different epitopes of the native beta 2 subunit of Escherichia coli tryptophan synthase (EC 4.1.2.20) were used to analyze the conformational changes occurring upon ligand binding or chemical modifications of the enzyme. For this purpose, the affinities of each antibody for the different forms of the enzyme were determined by using an enzyme-linked immunosorbent assay which allows measurement of the dissociation constant of antigen-antibody equilibrium in solution. The fixation of the coenzyme pyridoxal 5'-phosphate and the substrate L-serine modifies the affinity constants of most of the antibodies for the enzyme, thus showing the existence of extended conformational rearrangements of the protein. The association of the alpha subunit with the beta 2 subunit, which brings about an increase of the tryptophan synthase activity and abolishes the serine deaminase activity of beta 2, is accompanied by an important conformational change of the N-terminal domain of beta 2 (F1) since none of the anti-F1 monoclonal antibodies can bind to alpha 2 beta 2. Similarly, chemical modifications of beta 2 which are known to produce significant effects on the enzymatic activities of beta 2 result in changes of the affinities of the monoclonal antibodies which can be interpreted as the acquisition of different conformational states of the enzyme.

The complete nucleotide sequence of the tryptophan operon of Escherichia coli

The tryptophan (trp) operon of Escherichia coli has become the basic reference structure for studies on tryptophan metabolism. Within the past five years the application of recombinant DNA and sequencing methodologies has permitted the characterization of the structural and functional elements in this gene cluster at the molecular level. In this summary report we present the complete nucleotide sequence for the five structural genes of the trp operon of E. coli together with the internal and flanking regions of regulatory information.

Purification and partial characterization of the B subunit of Serratia marcescens tryptophan synthetase

A trpE mutant of Serratia marcescens (E-7) was isolated, and the multimeric enzyme tryptophan synthetase (EC 4.2.1.20) was purified to homogeneity from derepressed cells. The A and B subunits were resolved, and the B subunit was partially characterized and compared with the Escherichia coli B subunit as part of a comparative evolution study of the trpB cistron of the trp operon in the Enterobacteriaceae. The S. marcescens B subunit is a dimer (beta(2)), and its molecular weight was estimated to be 89,000. The separate subunits (beta monomers) had molecular weights of approximately 43,000. The B subunit required pyridoxal phosphate for catalytic activity and had an apparent K(m) of 9 x 10(-6) M. The N terminus of the B subunit was unavailable for reaction with terminal amine reagents (blocked), whereas carboxypeptidase digestion released a C-terminal isoleucine. Using S. marcescens B antiserum in agar immunodiffusion gave an almost complete reaction of identity between the B subunits of S. marcescens and E. coli. The antiserum was used in microcomplement fixation, allowing for a comparison of the overall antigenic surface structure of the two B subunits. The index of dissimilarity for the heterologous E. coli enzyme compared with the homologous S. marcescens enzyme was 2.4, indicating extensive similarity of the two proteins at their surfaces. Comparative antiserum neutralization of B-subunit enzyme activity showed the E. coli enzyme to cross-react 85% as well as the S. marcescens enzyme. With regard to the biochemical and immunochemical parameters used in this study, the S. marcescens and E. coli B subunits were either identical or very similar. These findings support the idea that the trpB cistron of the trp operon is a relatively conserved gene in the Enterobacteriaceae.

The binding of indole to the alpha-subunit and beta2-subunit and to the alpha2beta2-complex of tryptophan synthase from Escherichia coli. Identification of a second indole-binding site on the alpha-subunit

The binding of indole and indolepropanol phosphate, an analogue of the substrate indoleglycerol phosphate, to the individual alpha and beta2-subunits and to the alpha2beta2-complex of tryptophan synthase was studied by equilibrium dialysis. The use of [14C]indole and indolepropanol [32P]phosphate permitted simultaneous binding studies to be carried out. Competition between indole and indolepropanol phosphate in binding to a particular site was taken as evidence for that site being part of the active site of the alpha-subunit. The binding of indole to the active site of the alpha-subunit is weak (Kd = 18mM). A second distinct site binds indole more strongly (Kd = 1.5 mM) and interacts with the active site indirectly. It is therefore designated an effector site. Furthermore, the binding of indole and/or indolepropanol phosphate appears to stabilize different conformations of the alpha-subunit. The beta2-subunit binds indole only weakly (Kd = 12 mM) to many (n = 10) sites per polypeptide chain. The alpha2beta2-complex retains one or two sites per alphabeta-equivalent of relatively high affinity (Kd = 1.2 mM). The active sites of the component alpha and beta-subunits probably belong to the second class of many (n = 40) sites of low (Kd = 30 mM) affinity for indole. These findings support conclusions from the literature that both bi-substrate reactions involving indole catalyzed by tryptophan synthase and its subunits must follow strictly ordered addition mechanisms with the respective other substrate adding first.

Tryptophan synthetase alpha(5.7-S): novel molecular species formed within Escherichia coli

A novel molecular species contributes about 5% of the total tryptophan synthetase of Escherichia coli derepressed for the trp operon enzymes. The new species is identified under conditions in which the dissociation of the two nonidentical subunits of the tryptophan synthetase complex is favored. The new species sediments at 5.7S, catalyzes the conversion of indole-3-glycerol phosphate to indole, and has been designated alpha(5.7-S). Although alpha(5.7-S) is not observed in extracts of trpA or trpB mutant strains deficient in the ability to form tryptophan synthetase alpha or beta2 subunits, respectively, a mixture of the two extracts allows the formation of alpha(5.7-S). Similar results are obtained when a homogeneous alpha protein is mixed with an extract of a trpA mutant strain, suggesting that the interaction of alpha and beta2 proteins is obligatory for alpha(5.7-S) formation. One can obtain a beta2 protein preparation that when mixed with a pure alpha protein gives no alpha(5.7-S). Therefore, the interaction of alpha and beta2 proteins alone is not sufficient for the formation of alpha(5.7-S). When a mixture of alpha and beta2 proteins devoid of alpha(5.7-S) is added to extracts of trp deletion mutants, the novel species can be reconstituted in vitro only when deletions are used that carry at least the operator-proximal part of the trpB gene. Therefore, it is concluded that the alpha(5.7-S) species of tryptophan synthetase results from the interaction of the alpha protein, the beta2 protein, and a third component, beta', specified by the deoxyribonucleic acid defined by the end points of two trp deletion mutants.

Complementation in vitro between mutationally altered beta2 subunits of Escherichia coli tryptophan synthetase

Cross-reacting beta(2) subunits (CRMs) were purified from eight trpB missense mutants to test for complementation in vitro after urea dissociation and reaggregation. One CRM (B290, demonstrating "repairability," i.e., the appearance of enzymatic activity on combination with alpha subunits) was clearly positive with four others, all "non-repairable" CRMs resulting from mutations at three different but neighboring sites. One complementing pair, B290-B248, was studied in more detail and found, upon mixing purified proteins, to give complementation in the absence of denaturants. Complementation activity was low in each case. To study the mechanism of the modest increases in activity, we used a reduced beta(2) subunit as an artificial CRM to form hybrids where both the amount of activity due to complementation and the amount of hybrid could be measured. (In a reduced beta(2) subunit, the two pyridoxal phosphate cofactors have been chemically reduced by sodium borohydride and are covalently attached to lysine residues. This abolishes activity in the tryptophan synthetic reaction and causes the protein to migrate much faster than normal in acrylamide gel electrophoresis.) Reduced beta(2) subunit formed hybrid dimers with the non-repairable CRMs B244 and B248 at pH 6.0, but no enzymatic activity appeared. On the other hand, when reduced beta(2) subunit was mixed with B290 CRM at pH 6.0 to 6.6, an activity increase was seen that was proportional to the amount of hybrid. We conclude that hybrid formation is essential for complementation and that the mechanism of complementation in this system is the correction of a repairable active site on the B290 beta chain by a conformational change occuring when hybrid dimer is formed. This type of complementation must be restricted to a small class of CRMs having a conformationally deformed active site. From the amount of hybrid present and the increase in activity, a specific activity of 50 U/mg was calculated for the hybrid containing reduced and B290 beta chains. This value is slightly less than but close to the activity of the hybrid formed between reduced and normal beta chains, shown earlier to have half the specific activity of the normal dimer.

Mutant strains of Escherichia coli K-12 exhibiting enhanced sensitivity to 5-methyltryptophan

Eighteen mutants (designated MT(s)), isolated in Escherichia coli K-12, showed increased sensitivity to inhibition of growth by 5-methyltryptophan. All mutants were also much more sensitive to 4-methyltryptophan and 7-azatryptophan but exhibited near normal sensitivity to 5-fluorotryptophan and 6-fluorotryptophan. All of the mutations were linked to the trp operon. Their locations within the trp operon were established by deletion mapping. There was good agreement between the map position of an MT(s) mutation and a lowered activity of one of the tryptophan pathway enzymes. Three mutants, one of which contained a mutation that mapped within the trpE gene, were deficient in their ability to use glutamine as an amino donor in the formation of anthranilic acid. Another trpE mutation led to the production of an anthranilate synthetase with an increased sensitivity to feedback inhibition by tryptophan.

Comparative immunological and enzymatic study of the tryptophan synthetase beta 2 subunit in the Enterobacteriaceae

The beta(2) subunits of tryptophan synthetase, formula alpha(2)beta(2), from Escherichia coli, Shigella dysenteriae, Enterobacter aerogenes, Salmonella typhimurium, and Serratia marcescens were compared by three criteria. (i) alphabeta association constants for the various beta(2) subunits and E. coli alpha subunit varied between 3.6 x 10(8)m(-1) for E. coli and 0.33 x 10(8)m(-1) for S. marcescens; values for the other organisms were intermediate. (ii) Antiserum neutralization of the beta(2) subunit enzyme activity using anti-E. coli beta(2) serum showed significant cross-reaction among the organisms (E. coli, 1.0; S. dysenteriae, 0.98; S. typhimurium, 0.67; E. aerogenes, 0.61; S. marcescens, 0.42). (iii) Quantitative microcomplement fixation showed E. coli beta(2) and S. marcescens beta(2) subunits to have an index of dissimilarity of 1.8 while the other organisms had intermediate indexes. Similar complement fixation data were obtained with antisera from separate rabbits and from first course and boost sera. These findings suggest that the general surface structure and the respective alpha subunit binding site of the beta(2) subunits from these Enterobacteriaceae have been strongly conserved.

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.

Pseudomonas putida tryptophan synthetase

The two protein components of Pseudomonas putida tryptophan synthetase have been purified to homogeneity. Although there is general similarity between the Pseudomonas enzyme and that of the enteric bacteria, many differences were found. Components from Escherichia coli and P. putida do not stimulate each other enzymatically, and the enzymes differ in their response to monovalent cations. Serine deamination occurs best with the intact enzyme of P. putida, not with the beta(2) subunit alone as in E. coli. The amino acid compositions of the alpha subunits differ appreciably. These findings extend earlier studies showing differences between enteric organisms and pseudomonads in the regulation and genetic organization of the enzymes of the tryptophan pathway.

A Saccharomyces cerevisiae mutant defective in saturated fatty acid biosynthesis

The isolation and biochemical characterization of a Saccharomyces cerevisiae mutant, which grows only when emulsified myristic, palmitic, stearic, or oleic acid is added to the growth medium, is described. The mutant contains an enzymatically inactive fatty acid synthetase complex. The gene affected, preliminarily designated by the symbol fas, exhibits a 2:2 nuclear inheritance pattern. The formation of fatty acid synthetase in yeast is constitutive and not subject to repression by long chain fatty acids. After extensive purification, the mutant fatty acid synthetase was obtained as an essentially homogeneous protein with a sedimentation constant identical to that of the wild type enzyme. A systematic study of the seven reaction steps involved in fatty acid biosynthesis revealed that the enzyme catalyzing the condensation of acetate and malonate to acetoacetate was completely inactive in the mutant. The other six component enzymes had identical specific activities in the mutant and in the wild type fatty acid synthetase complexes. It is concluded that the mutant described harbors a missense mutation in the structural genes of either the condensing enzyme of the "acyl carrier protein" component of the fatty acid synthetase complex.

Specificity in the assembly of multisubunit proteins

The recoveries of activity in the presence of mixtures of several enzymes and a cellular debris were compared with the recoveries of the pure enzymes. In the acid-dissociation experiments, no interference from foreign proteins was observed nor were any cross hybrids between subunits of different enzymes found. This suggests that the intersubunit binding sites are highly specific and have been selected over evolutionary time for correct assembly. In the urea experiments, cross hybridization and decreased yields were observed in a few cases but in most cases the "foreign" unfolded chains did not influence the recovery of the test enzyme. The results suggest that compartmentalization, temporal or spatial, will not be required as far as assembly of subunits of cytoplasmic enzymes is concerned. The results suggest some cross reaction might occur if all peptide chains were unfolding together. If folding occurs during or immediately after translation, this difficulty would be avoided.

Genetic and biochemical studies of partially active tryptophan synthetase mutants of Saccharomyces cerevisiae

Approximately 20% of the tryptophan synthetase mutants (tr(5)) of Saccharomyces cerevisiae retain activity in one of the half reactions catalyzed by this enzyme and have been identified as indole-accumulating or indole-utilizing tr(5) mutants by complementation tests. Ten indole-accumulating and six indole-utilizing mutants have been studied. For the half reactions they catalyze, these partially active mutants have from about one-half to twice the specific activities of the wild-type enzyme. Indole-accumulating mutant enzymes showed varying responses to pyridoxal phosphate and serine in the assay mixture. The partially active mutants were further characterized by their patterns of allelic complementation and their distribution on the fine-structure map of the locus. It was concluded that these mutants define two distinct functional regions of the tr(5) locus, corresponding to the two half reactions.

Immunochemical and enzymatic comparisons of the tryptophan synthase alpha subunits from five species of Enterobacteriaceae

The reactive surface structures of alpha subunits of tryptophan synthase from Escherichia coli, Shigella dysenteriae, Salmonella typhimurium, Aerobacter aerogenes, and Serratia marcescens were compared by measuring (i) their reactivities in micro-complement-fixation assays with antibodies directed specifically to E. coli wild-type alpha subunit, (ii) their reactivities in enzyme neutralization assays with the same antibodies, and (iii) their binding affinities for tryptophan synthase beta(2) subunits. The enzymes from the four heterologous species cross-reacted in the microcomplement-fixation assays with the anti-E. coli alpha subunit antibodies, each to a different degree. However, neutralization titers of the antibodies reacting with the various alpha subunits were comparatively similar, and the beta(2) subunit-binding and -stimulating abilities of the alpha subunits were even more closely alike. The results suggested that the tertiary structure of the beta(2) subunit-binding site of the alpha subunit has been conserved, relative to the rest of the molecule, during the evolutionary divergence of the species of Enterobacteriaceae.

Two mechanisms of allelic complementation among tryptophan synthetase mutants of Saccharomyces cerevisiae

Two different types of allelic complementation were observed in tryptophan synthetase mutants of the yeast Saccharomyces cerevisiae. Each type is associated with a different mechanism for the enzymatic conversion of indole-3-glycerol phosphate (InGP) to tryptophan. Mechanism I is utilized by a hybrid tryptophan synthetase that resembles, but is not identical with, the wild-type enzyme. Mechanism II is due to a sequential conversion of InGP to free indole, and indole to tryptophan. Two partially active mutant enzymes rather than a single hybrid enzyme catalyze the sequential reaction steps. This is an example of intracellular cross-feeding. The quantitative evaluation of mechanism II leads to the conclusion that tryptophan synthetase in yeast is most likely a dimer of two identical subunits.