Structure and regulation of the anthranilate synthase genes in Pseudomonas aeruginosa: I. Sequence of trpG encoding the glutamine amidotransferase subunit

We have determined the DNA sequence of the distal 148 codons of trpE and all of trpG in Pseudomonas aeruginosa. These genes encode, respectively, the large and small (glutamine amidotransferase) subunits of anthranilate synthase, the first enzyme in the tryptophan synthetic pathway. The sequenced region of trpE is homologous with the distal portion of E. coli and Bacillus subtilis trpE, whereas the trpG sequence is homologous to the glutamine amidotransferase subunit genes of a number of bacterial and fungal anthranilate synthases. The two coding sequences overlap by 23 bp. Codon usage in these Pseudomonas genes shows a marked preference for codons ending in G or C, thereby resembling that of trpB, trpA, and several other chromosomal loci from this species and others with a high G + C content in their DNA. The deduced amino acid sequence for the P. aeruginosa trpG gene product differs to a surprising extent from the directly determined amino acid sequence of the glutamine amidotransferase subunit of P. putida anthranilate synthase (Kawamura et al. 1978). This suggests that these two proteins are encoded by loci that duplicated much earlier in the phylogeny of these organisms but have recently assumed the same function. We have also determined 490 bp of DNA sequence distal to trpG but have not ascertained the function of this segment, though it is rich in dyad symmetries.      

An anthranilate synthase of the extreme aminase type in a species of blue-green bacteria (algae)

Anthranilate synthase of Agmenellum quadruplicatum, a unicellular species of blue-green bacteria, consists of two nonidentical subunits. A 72,000 dalton protein has aminase activity but is incapable of reaction with glutamine (amidotransferase) unless a second protein (18,000 molecular weight) is present. The small subunit was first detected through its ability to complement a partially purified aminase subunit from Bacillus subtilis to produce a hybrid complex capable of amidotransferase function. Conditions for the function of the heterologous complex were less stringent than for the homologous A. quadruplicatum complex. A reducing agent such as dithiothreitol stabilizes the A. quadruplicatum aminase subunit and is obligatory for amidotransferase function. L-Tryptophan feedback inhibits both the aminase and amidotransferase reactions of anthranilate synthase; Ki values of 6 X 10(-8) M for the amidotransferase activity and 2 X 10(-6) M for the aminase activity were obtained. The Km value calculated for ammonia (2.2 mM) was more favorable than the Km value glutamine (13 mM). Likewise, the Vmax of anthranilate synthase was greater with ammonia than with glutamine. Starvation of a tryptophan auxotroph results in a threefold derepression of the aminase subunit, but no corresponding increase in the small 18,000 M subunit occurs. While microbial anthranilate synthase complexes are remarkably similar overall, the relatively good aminase activity of the A. quadruplicatum enzyme may be of physiological significance in nature.     

Homologous and Hybrid Complexes of Anthranilate Synthase from Bacillus Species

The subunits of anthranilate synthase were separated and partially purified by Sephadex G-100 gel filtration from the following six species of Bacillus: Bacillus subtilis, Bacillus licheniformis, Bacillus alvei, Bacillus coagulans, Bacillus pumilus, and Bacillus mascerans. Our data suggest that the enzyme from B. alvei is unique among these species. First, the anthranilate synthase complexes are readily dissociated during gel filtration in the absence of glutamine into a large component (aminotransferase), subunit E, and a small component subunit X (glutamine-binding protein), whereas a higher salt concentration is required to dissociate the complex from B. alvei. Second, the aminotransferase activity from all six species is stimulated by glycerol and inhibited by tryptophan; however, only the large component from B. alvei is stimulated by 2-mercaptoethanol. Finally, the large component can be titrated with the small component to yield a complex which can utilize glutamine as a substrate (amidotransferase). The homologous complexes have an amidotransferase to aminotransferase ratio of 1.4 to 2.3, but the B. alvei complex has a ratio of 0.9. Except for complexes that involve the large component from B. alvei, hybrid complexes can be formed which have ratios as good as the homologous complexes. These data are consistent with the hypothesis that B. alvei is unique among the bacilli with respect to some enzymes in the aromatic amino acid biosynthetic pathway.     

Constitutively active glutaminase variants provide insights into the activation mechanism of anthranilate synthase

The glutamine amidotransferase (GATase) family comprises enzyme complexes which consist of glutaminase and synthase subunits that catalyze in a concerted reaction the incorporation of nitrogen within various metabolic pathways. An important feature of GATases is the strong stimulation of glutaminase activity by the associated synthase. To understand the mechanism of this tight activity regulation, we probed by site-directed mutagenesis four residues of the glutaminase subunit TrpG from anthranilate synthase that are located between the catalytic Cys-His-Glu triad and the synthase subunit TrpE. In order to minimize structural perturbations induced by the introduced exchanges, the amino acids from TrpG were substituted with the corresponding residues of the closely related glutaminase HisH from imidazole glycerol phosphate synthase. Steady-state kinetic characterization showed that, in contrast to wild-type TrpG, two TrpG variants with single exchanges constitutively hydrolyzed glutamine in the absence of TrpE. A reaction assay performed with hydroxylamine as a stronger nucleophile replacing water and a filter assay with radiolabeled glutamine indicated that the formation of the thioester intermediate is the rate-limiting step of constitutive glutamine hydrolysis. Molecular dynamics simulations with wild-type TrpG and constitutively active TrpG variants suggest that the introduced amino acid exchanges result in a distance reduction between the active site Cys-His pair, which facilitates the deprotonation of the sulfhydryl group of the catalytic cysteine and thus enables its nucleophilic attack onto the carboxamide group of the glutamine side chain. We propose that native TrpG in the anthranilate synthase complex is activated by a similar mechanism.     

Structure of Escherichia coli aminodeoxychorismate synthase: architectural conservation and diversity in chorismate-utilizing enzymes

Aminodeoxychorismate synthase is part of a heterodimeric complex that catalyzes the two-step biosynthesis of 4-amino-4-deoxychorismate, a precursor of p-aminobenzoate and folate in microorganisms. In the first step, a glutamine amidotransferase encoded by the pabA gene generates ammonia as a substrate that, along with chorismate, is used in the second step, catalyzed by aminodeoxychorismate synthase, the product of the pabB gene. Here we report the X-ray crystal structure of Escherichia coli PabB determined in two different crystal forms, each at 2.0 A resolution. The 453-residue monomeric PabB has a complex alpha/beta fold which is similar to that seen in the structures of homologous, oligomeric TrpE subunits of several anthranilate synthases of microbial origin. A comparison of the structures of these two classes of chorismate-utilizing enzymes provides a rationale for the differences in quaternary structures seen for these enzymes, and indicates that the weak or transient association of PabB with PabA during catalysis stems at least partly from a limited interface for protein interactions. Additional analyses of the structures enabled the tentative identification of the active site of PabB, which contains a number of residues implicated from previous biochemical and genetic studies to be essential for activity. Differences in the structures determined from phosphate- and formate-grown crystals, and the location of an adventitious formate ion, suggest that conformational changes in loop regions adjacent to the active site may be needed for catalysis. A surprising finding in the structure of PabB was the presence of a tryptophan molecule deeply embedded in a binding pocket that is analogous to the regulatory site in the TrpE subunits of the anthranilate synthases. The strongly bound ligand, which cannot be dissociated without denaturation of PabB, may play a structural role in the enzyme since there is no effect of tryptophan on the enzymic synthesis of aminodeoxychorismate. Extensive sequence similarity in the tryptophan-binding pocket among several other chorismate-utilizing enzymes, including isochorismate synthase, suggests that they too may bind tryptophan for structural integrity, and corroborates early ideas on the evolution of this interesting enzyme family.     

Nucleotide sequence of yeast gene CP A1 encoding the small subunit of arginine-pathway carbamoyl-phosphate synthetase. Homology of the deduced amino acid sequence to other glutamine amidotransferases

A yeast DNA fragment carrying the gene CP A1 encoding the small subunit of the arginine pathway carbamoyl-phosphate synthetase has been sequenced. Only one continuous coding sequence on this fragment was long enough to account for the presumed molecular mass of CP A1 protein product. It codes for a polypeptide of 411 amino acids having a relative molecular mass, Mr, of 45 358 and showing extensive homology with the product of carA, the homologous Escherichia coli gene. CP A1 and carA products are glutamine amidotransferases which bind glutamine and transfer its amide group to the large subunits where it is used for the synthesis of carbamoyl-phosphate. A comparison of the amino acid sequences of CP A1 polypeptide with the glutamine amidotransferase domains of anthranilate and p-amino-benzoate synthetases from various sources has revealed the presence in each of these sequences of three highly conserved regions of 8, 11 and 6 amino acids respectively. The 11-residue oligopeptide contains a cysteine which is considered as the active-site residue involved in the binding of glutamine. The distances (number of amino acid residues) which separate these homology regions are accurately conserved in these various enzymes. These observations provide support for the hypothesis that these synthetases have arisen by the combination of a common ancestral glutamine amidotransferase subunit with distinct ammonia-dependent synthetases. Little homology was detected with the amide transfer domain of glutamine phosphoribosyldiphosphate amidotransferase which may be the result of a convergent evolutionary process. The flanking regions of gene CP A1 have been sequenced, 803 base pairs being determined on the 5' side and 382 on the 3' side. Several features of the 5'-upstream region of CP A1 potentially related to the control of its expression have been noticed including the presence of two copies of the consensus sequence d(T-G-A-C-T-C) previously identified in several genes subject to the general control of amino acid biosynthesis.     

p-Aminobenzoate-p-aminobenzoate.

p-Aminobenzoate (PABA) synthase from Bacillus subtilis is an aggregate composed of two nonidentical subunits and has the following properties. (i) In crude extracts this enzyme catalyzes the formation of PABA in the presence of chorismate and either glutamine (amidotransferase) or ammonia (aminase). The amidotransferase activity is about 5- to 10-fold higher than the aminase activity and is stable for at least 1 week when frozen at -70 C. (II) Although no divalent cation requirement could be demonstrated with crude extracts, 2 mM ethylene-diaminetetraacetic acid completely inhibits both activities. (iii) After ammonium sulfate fractionation both the aminase and amidotransferase activities require Mg2+ and guanosine in addition to the substrates indicated above for optimal activity. The guanosine requirement can be replaced by guanosine 5'-monophosphate, guanosine 5'-diphosphate, and guanosine 5'-triphosphate but not by guanine, adenosine 5'-triphosphate, uridine 5'-triphosphate, cytidine 5'-triphosphate, thymidine 5'-triphosphate, inorganic phosphate, and phosphoribosylpyrophosphate. Furthermore, at a pH above 7.4 or below 6.4 activity is rapidly lost a 4 C, or -60 C. (IV) The enzyme is composed of two non-identical subunits, designated subunit A and subunit X. Subunit A has an estimated molecular weight of 31,000, whereas subunit X has an estimated molecular weight of 19,000. Subunit A has aminase activity but no amidotransferase activity; a mutation at the pabA locus results in the loss of PABA synthase activity. Subunit X, which is also a component of the anthranilate synthase complex, has no PABA synthase activity itself but complexes with subunit A to give an AX aggregate that can use glutamine as a substrate. (v) The molecular weight of the AX complex has been estimated at 50,000, suggesting a 1:1 ratio of subunits. (vi) The enzyme is readily associated and dissociated.     

Expression of Escherichia coli pabA.

Escherichia coli pabA encodes the glutamine amidotransferase subunit of p-aminobenzoate synthase. p-Aminobenzoate synthase catalyzes the conversion of chorismate and glutamine to 4-amino-4-deoxychorismate, which is then converted to p-aminobenzoate by a 4-amino-4-deoxychorismate lyase. The 5'-terminal segment of pabA was previously shown to be transcribed from two different promoters, one near the pabA coding sequence (P1) and one preceding fic (P2). However, a pabA-lacZ translational fusion was expressed only from the mRNA originating at P1. We have determined that expression of a pabA-lacZ chromosomal fusion is not changed by p-aminobenzoate limitation, growth rate, catabolite repression, overexpression of either p-aminobenzoate synthase subunit, or gene dosage of pabA and pabB. The lack of pabA expression from P2 appears to be the result of a stable secondary structure in the intergenic space preceding pabA that sequesters the pabA ribosome binding site. Disruption of the secondary structure by mutation allowed expression of pabA from P2, as did translation of ribosomes into the fic-pabA intergenic region.     

Anthranilate synthase of Neurospora crassa: reaction and labeling with glutamine analogs

The multifunctional enzyme complex, anthranilate synthase from Neurospora crassa, irreversibly loses its glutamine-dependent anthranilate synthase activity on exposure to the reactive glutamine analogs DON and azaserine. Inactivation depends on the presence of the substrate chorismate, is enhanced by the cofactor Mg⁺², and is antagonized by glutamine. Inactivation correlates well with the incorporation of [¹⁴C]DON into the protein with modification localized to the β subunit (M_r 84,000) of the complex, demonstrating directly that the β subunit provides the glutamine binding site for the glutamine-dependent anthranilate synthase reaction. The slower and less extensive loss of ammonia-dependent anthranilate synthase activity indicates that maximum expression of the ammonia-dependent anthranilate synthase activity by the α subunit also depends on the interaction with an active glutamine amidotransferase domain of the β subunit.     

Nucleotide sequence of Escherichia coli pabB indicates a common evolutionary origin of p-aminobenzoate synthetase and anthranilate synthetase.

Biochemical and immunological experiments have suggested that the Escherichia coli enzyme p-aminobenzoate synthetase and anthranilate synthetase are structurally related. Both enzymes are composed of two nonidentical subunits. Anthranilate synthetase is composed of proteins encoded by the genes trp(G)D and trpE, whereas p-aminobenzoate synthetase is composed of proteins encoded by pabA and pabB. These two enzymes catalyze similar reactions and produce similar products. The nucleotide sequences of pabA and trp(G)D have been determined and indicate a common evolutionary origin of these two genes. Here we present the nucleotide sequence of pabB and compare it with that of trpE. Similarities are 26% at the amino acid level and 40% at the nucleotide level. We propose that pabB and trpE arose from a common ancestor and hence that there is a common ancestry of genes encoding p-aminobenzoate synthetase and anthranilate synthetase.     

Mapping of the tryptophan genes of Acinetobacter calcoaceticus by transformation

Auxotrophs of Acinetobacter calcoaceticus blocked in each reaction of the synthetic pathway from chorismic acid to tryptophan were obtained after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. One novel class was found to be blocked in both anthranilate and p-aminobenzoate synthesis; these mutants (trpG) require p-aminobenzoate or folate as well as tryptophan (or anthranilate) for growth. The loci of six other auxotrophic classes requiring only tryptophan were defined by growth, accumulation, and enzymatic analysis where appropriate. The trp mutations map in three chromosomal locations. One group contains trpC and trpD (indoleglycerol phosphate synthetase and phosphoribosyl transferase) in addition to trpG mutations; this group is closely linked to a locus conferring a glutamate requirement. Another cluster contains trpA and trpB, coding for the two tryptophan synthetase (EC 4.2.1.20) subunits, along with trpF (phosphoribosylanthranilate isomerase); this group is weakly linked to a his marker. The trpE gene, coding for the large subunit of anthranilate synthetase, is unlinked to any of the above. This chromosomal distribution of the trp genes has not been observed in other organisms.     

Rapid Regulation of an Anthranilate Synthase Aggregate by Hysteresis

The anthranilate synthase aggregate from Bacillus subtilis is composed of two nonidentical subunits, denoted E and X, which are readily associated or dissociated. A complex of subunit E and X can utilize glutamine or ammonia as substrates in the formation of anthranilate. Partially purified subunit E is capable of using only ammonia as the amide donor in the anthranilate synthase reaction. The stability of the EX complex is strongly influenced by glutamine and by the concentrations of the subunits. Glutamine stabilizes the aggregate as a molecular species in which the velocity of the glutamine-reactive anthranilate synthase is a linear function of protein concentration. In the absence of glutamine the aggregate is readily dissociated following dilution of the extract; that is, velocity concaves upward as a function of increasing protein concentration. Reassociation of the EX complex is characterized by a velocity lag (or hysteretic response) before steady-state velocity for the glutamine-reactive anthranilate synthase is reached. We propose that association and dissociation of the anthranilate synthase aggregate may be physiologically significant and provide a control mechanism whereby repression or derepression causes disproportionate losses or gains in activity by virtue of protein-protein interactions between subunits E and X.     

Evolutionary differences in chromosomal locations of four early genes of the tryptophan pathway in fluorescent pseudomonads: DNA sequences and characterization of Pseudomonas putida trpE and trpGDC.

Pseudomonas putida possesses seven structural genes for enzymes of the tryptophan pathway. All but one, trpG, which encodes the small (beta) subunit of anthranilate synthase, have been mapped on the circular chromosome. This report describes the cloning and sequencing of P. putida trpE, trpG, trpD, and trpC. In P. putida and Pseudomonas aeruginosa, DNA sequence analysis as well as growth and enzyme assays of insertionally inactivated strains indicated that trpG is the first gene in a three-gene operon that also contains trpD and trpC. In P. putida, trpE is 2.2 kilobases upstream from the trpGDC cluster, whereas in P. aeruginosa, they are separated by at least 25 kilobases (T. Shinomiya, S. Shiga, and M. Kageyama, Mol. Gen. Genet., 189:382-389, 1983). The DNA sequence in P. putida shows an open reading frame on the opposite strand between trpE and trpGDC; this putative gene was not characterized. Evidence is also presented for sequence similarities in the 5' untranslated regions of trpE and trpGDC in both pseudomonads; the function of these regions is unknown, but it is possible that they play some role in regulation of these genes, since all the genes respond to repression by tryptophan. The sequences of the anthranilate synthase genes in the fluorescent pseudomonads resemble those of p-aminobenzoate synthase genes of the enteric bacteria more closely than the anthranilate synthase genes of those organisms; however, no requirement for p-aminobenzoate was found in the Pseudomonas mutants created in this study.     

Role of the hinge loop linking the N- and C-terminal domains of the amidotransferase subunit of carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of ATP. The enzyme consists of a large synthetase subunit and a small amidotransferase subunit. The small subunit is structurally bilobal. The N-terminal domain is unique compared to the sequences of other known proteins. The C-terminal domain, which contains the direct catalytic residues for the amidotransferase activity of CPS, is homologous to other members of the Triad glutamine amidotransferases. The two domains are linked by a hinge-like loop, which contains a type II beta turn. The role of this loop in the hydrolysis of glutamine and the formation of carbamoyl phosphate was probed by site-directed mutagenesis. Based upon the observed kinetic properties of the mutants, the modifications to the small subunit can be separated into two groups. The first group consists of G152I, G155I, and Delta155. Attempts to disrupt the turn conformation were made by the deletion of Gly-155 or substitution of the two glycine residues with isoleucine. However, these mutations only have minor effects on the kinetic properties of the enzyme. The second group includes L153W, L153G/N154G, and a ternary complex consisting of the intact large subunit plus the separate N- and C-terminal domains of the small subunit. Although the ability to synthesize carbamoyl phosphate is retained in these enzymes, the hydrolysis of glutamine is partially uncoupled from the synthetase reaction. It is concluded that the hinge loop, but not the type-II turn structure of the loop per se, is important for maintaining the proper interface interactions between the two subunits and the catalytic coupling of the partial reactions occurring within the separate subunits of CPS.     

Replacement by site-directed mutagenesis indicates a role for histidine 170 in the glutamine amide transfer function of anthranilate synthase

Anthranilate synthase is a glutamine amidotransferase that catalyzes the first reaction in tryptophan biosynthesis. Conserved amino acid residues likely to be essential for glutamine-dependent activity were identified by alignment of the glutamine amide transfer domains in four different enzymes: anthranilate synthase component II (AS II), p-aminobenzoate synthase component II, GMP synthetase, and carbamoyl-P synthetase. Conserved amino acids were mainly localized in three clusters. A single conserved histidine, AS II His-170, was replaced by tyrosine using site-directed mutagenesis. Glutamine-dependent enzyme activity was undetectable in the Tyr-170 mutant, whereas the NH3-dependent activity was unchanged. Affinity labeling of AS II active site Cys-84 by 6-diazo-5-oxonorleucine was used to distinguish whether His-170 has a role in formation or in breakdown of the covalent glutaminyl-Cys-84 intermediate. The data favor the interpretation that His-170 functions as a general base to promote glutaminylation of Cys-84. Reversion analysis was consistent with a proposed role of His-170 in catalysis as opposed to a structural function. These experiments demonstrate the application of combining sequence analyses to identify conserved, possibly functional amino acids, site-directed mutagenesis to replace candidate amino acids, and protein chemistry for analysis of mutationally altered proteins, a regimen that can provide new insights into enzyme function.     

para-aminobenzoate synthesis from chorismate occurs in two steps

Escherichia coli p-aminobenzoate synthase is composed of two nonidentical subunits encoded by pabA and pabB and has been assumed to be the sole enzyme responsible for p-aminobenzoate biosynthesis from chorismate and glutamine. Plasmids were constructed that overproduce the p-aminobenzoate synthase subunits 250-500-fold. Partial purification of the subunits revealed that they form a diffusible intermediate that is subsequently converted to p-aminobenzoate by a second enzyme (Mr = 49,000) temporarily designated enzyme X.     

Cloning and sequencing analysis of Trp1 gene of Flammulina velutipes

The genomic TRP1 gene from basidiomycete Flammulina velutipes was cloned by complementation of yeast Saccharomyces cerevisiae trp1 mutation. Sequencing analysis revealed that the TRP1 gene encoded a single protein consisting of three catalytic functional domains; glutamine amidotransferase, indole-3-glycerol phosphate synthase ) and N-(5'-phosphoribosyl) anthranilate isomerase, in order of NH2-glutamine amidotransferase-indole-3-glycerol phosphate synthase N-(5'-phosphoribosyl) anthranilate isomerase-COOH. The coding sequence of the TRP1 gene was interrupted by a single intron of 48 bases, the position and flanking sequences of which were highly homologous to those of basidiomycete Phanerochaete chrysosporium trpC.     

Suppression of a deletion mutation in the glutamine amidotransferase region of the Salmonella typhimurium trpD gene by mutations in pheA and tyrA.

Prototrophic revertants of a trpD deletion mutant that lacks the glutamine amidotransferase domain of the bifunctional component II subunit of the anthranilate synthetase-phosphoribosyltransferase complex have been found to arise by the occurrence of sublethal missense mutations in either the pheA or tyrA loci. Such suppressor mutations were obtained directly by mutation of the wild-type pheA gene as well as indirectly by partial reversion of a variety of nonleaky pheA and tyrA mutations. The suppressor strains have only a portion of the normal level of the pheA or tyrA enzyme activity and thus experience a partial limitation in the synthesis of phenylalanine or tyrosine. This limitation leads to a relaxation of end-product regulation of the phenylalanine- or tyrosine-specific enzymes of the common aromatic pathway and to the overproduction of the branch point intermediate, chorismic acid, which is one of the substrates of the anthranilate synthetase reaction. It is proposed that the high intracellular level of chorismic acid acts to elevate the non-physiological NH3-dependent anthranilate synthetase activity of the component I subunit, thereby eliminating the need for the glutamine amidotransferase activity of the component II subunit. Consistent with this is the finding that phenylalanine and tyrosine are specific inhibitors of growth of the pheA and tyrA suppressor strains, respectively, causing a shutdown of the overproduction of chorismic acid by reestablishing normal end-product control of the common pathway.     

Modification of Serratia marcescens anthranilate synthase with pyridoxal 5′-phosphate

The glutamine-dependent activity of Serratia marcescens anthranilate synthase was inactivated by pyridoxal 5′-phosphate and sodium cyanide. The reaction was specific in that the ammonia-dependent activity of the enzyme was unaffected. The inactivation was stable to dilution or dialysis but was reversed by dithiothreitol. The enzyme contains dissimilar subunits designated anthranilate synthase components I (AS I) and II (AS II). Incorporation of [¹⁴C]NaCN demonstrates that modification was limited to one to two residues per AS I · AS II protomer. An active site cysteine is involved in the glutamine-dependent activity. Modification by pyridoxal 5′-phosphate and NaCN blocked affinity labeling of the active site cysteine by the glutamine analog 6-diazo-5-oxo-l-norleucine and reduced alkylation of the active site cysteine by iodoacetamide. These results suggest modification is at the glutamine active site. Initial modification by iodoacetamide did not prevent pyridoxal 5′-phosphate-dependent incorporation of ¹⁴CN showing that the pyridoxal 5′-phosphate modification did not involve the essential cysteinyl residue. These results suggest that modification of a lysyl residue in the glutamine active site of anthranilate synthase reduces the reactivity of the essential cysteinyl residue resulting in the loss of the amidotransferase activity.