Flexible loop that is novel catalytic machinery in a ligase. Atomic structure and function of the loopless glutathione synthetase

Sequential backbone resonance assignments of the E. coli dihydrofolate reductase Gly67Val mutant: folate complex

Occasionally, a mutation in an exposed loop region causes a significant change in protein function and/or stability. A single mutation Gly67Val of E. coli dihydrofolate reductase (DHFR) in the exposed CD loop is such an example. We have carried out the chemical shift assignments for H(N), N(H), C(α) and C(β) atoms of the Gly67Val mutant of E. coli DHFR complexed with folate at pH 7.0, 35 °C, and then evaluated the H(N), N(H), C(α) and C(β) chemical shift changes caused by the mutation. The result indicates that, while the overall secondary structure remains the same, the single mutation Gly67Val causes site-specific conformational changes of the polypeptide backbone restricted around the adenosine-binding subdomain (residues 38-88) and not in the distant catalytic domain.

Probing the origins of glutathione biosynthesis through biochemical analysis of glutamate-cysteine ligase and glutathione synthetase from a model photosynthetic prokaryote

Glutathione biosynthesis catalysed by GCL (glutamate-cysteine ligase) and GS (glutathione synthetase) is essential for maintaining redox homoeostasis and protection against oxidative damage in diverse eukaroytes and bacteria. This biosynthetic pathway probably evolved in cyanobacteria with the advent of oxygenic photosynthesis, but the biochemical characteristics of progenitor GCLs and GSs in these organisms are largely unexplored. In the present study we examined SynGCL and SynGS from Synechocystis sp. PCC 6803 using steady-state kinetics. Although SynGCL shares ~15% sequence identity with the enzyme from plants and α-proteobacteria, sequence comparison suggests that these enzymes share similar active site residues. Biochemically, SynGCL lacks the redox regulation associated with the plant enzymes and functions as a monomeric protein, indicating that evolution of redox regulation occurred later in the green lineage. Site-directed mutagenesis of SynGCL establishes this enzyme as part of the plant-like GCL family and identifies a catalytically essential arginine residue, which is structurally conserved across all forms of GCLs, including those from non-plant eukaryotes and γ-proteobacteria. A reaction mechanism for the synthesis of γ-glutamylcysteine by GCLs is proposed. Biochemical and kinetic analysis of SynGS reveals that this enzyme shares properties with other prokaryotic GSs. Initial velocity and product inhibition studies used to examine the kinetic mechanism of SynGS suggest that it and other prokaryotic GSs uses a random ter-reactant mechanism for the synthesis of glutathione. The present study provides new insight on the molecular mechanisms and evolution of glutathione biosynthesis; a key process required for enhancing bioenergy production in photosynthetic organisms.

The Ω-loop lid domain of phosphoenolpyruvate carboxykinase is essential for catalytic function

Phosphoenolpyruvate carboxykinase (PEPCK) is an essential metabolic enzyme operating in the gluconeogenesis and glyceroneogenesis pathways. Recent studies have demonstrated that the enzyme contains a mobile active site lid domain that undergoes a transition between an open, disorded conformation and a closed, ordered conformation as the enzyme progresses through the catalytic cycle. The understanding of how this mobile domain functions in catalysis is incomplete. Previous studies showed that the closure of the lid domain stabilizes the reaction intermediate and protects the reactive intermediate from spurious protonation and thus contributes to the fidelity of the enzyme. To more fully investigate the roles of the lid domain in PEPCK function, we introduced three mutations that replaced the 11-residue lid domain with one, two, and three glycine residues. Kinetic analysis of the mutant enzymes demonstrates that none of the enzyme constructs exhibit any measurable kinetic activity, resulting in a decrease in the catalytic parameters of at least 10(6). Structural characterization of the mutants in complexes representing the catalytic cycle suggests that the inactivity is due to a role for the lid domain in the formation of the fully closed state of the enzyme that is required for catalytic function. In the absence of the lid domain, the enzyme is unable to achieve the fully closed state and is rendered inactive despite possessing all of the residues and substrates required for catalytic function. This work demonstrates how enzyme catalytic function can be abolished through the alteration of conformational equilibria despite all the elements required for chemical conversion of substrates to products remaining intact.

Deregulation of allosteric response of Lactococcus lactis prolidase and its effects on enzyme activity

The allosteric behaviour of Lactococcus lactis prolidase (Xaa-Pro dipeptidase) of this proline-specific peptidase was investigated where it was hypothesized that intersubunit interactions between a loop structure and three residues near the active site contributed to this behaviour. Seven mutant prolidases were constructed, and it was observed that the loopless mutant and His303 substitution inactivated the enzyme. Ser307 substitution revealed that this residue influenced the substrate binding, as judged from its kinetic constants and substrate specificity; however, this residue did not contribute to allostery of prolidase. R293S mutation resulted in the disappearance of the allosteric behaviour yielding a Hill constant of 0.98 while the wild type had a constant of 1.58. In addition, the R293S mutation suppressed the substrate inhibition that was observed in other mutants and wild type. The K(m) value of R293S was 2.9-fold larger and V(max) was approximately 50% less as compared to the wild type. The results indicated that Arg293 increased the affinity for substrates while introducing allosteric behaviour and substrate inhibition. Computer modelling suggested that negative charges on the loop structure interacted with Arg293 and Ser307 to maintain these characteristics. It was, therefore, concluded that Arg293, His303, Ser307 and the loop contributed to the enzyme's allosteric characteristics.

Evolution of tRNA nucleotidyltransferases: a small deletion generated CC-adding enzymes

CCA-adding enzymes are specialized polymerases that add a specific sequence (C-C-A) to tRNA 3' ends without requiring a nucleic acid template. In some organisms, CCA synthesis is accomplished by the collaboration of evolutionary closely related enzymes with partial activities (CC and A addition). These enzymes carry all known motifs of the catalytic core found in CCA-adding enzymes. Therefore, it is a mystery why these polymerases are restricted in their activity and do not synthesize a complete CCA terminus. Here, a region located outside of the conserved motifs was identified that is missing in CC-adding enzymes. When recombinantly introduced from a CCA-adding enzyme, the region restores full CCA-adding activity in the resulting chimera. Correspondingly, deleting the region in a CCA-adding enzyme abolishes the A-incorporating activity, also leading to CC addition. The presence of the deletion was used to predict the CC-adding activity of putative bacterial tRNA nucleotidyltransferases. Indeed, two such enzymes were experimentally identified as CC-adding enzymes, indicating that the existence of the deletion is a hallmark for this activity. Furthermore, phylogenetic analysis of identified and putative CC-adding enzymes indicates that this type of tRNA nucleotidyltransferases emerged several times during evolution. Obviously, these enzymes descend from CCA-adding enzymes, where the occurrence of the deletion led to the restricted activity of CC addition. A-adding enzymes, however, seem to represent a monophyletic group that might also be ancestral to CCA-adding enzymes. Yet, experimental data indicate that it is possible that A-adding activities also evolved from CCA-adding enzymes by the occurrence of individual point mutations.

Characterization of recombinant prolidase from Lactococcus lactis- changes in substrate specificity by metal cations, and allosteric behavior of the peptidase

The Lactococcus lactis NRRL B-1821 prolidase gene was cloned and overexpressed in Escherichia coli. Under suboptimum growth conditions, recombinant soluble and active prolidase was produced; in contrast, inclusion bodies were formed under conditions preferred for cell growth. Recombinant prolidase retained more than half its full activity between 30 and 60 degrees C, and was completely inactivated after 30 min at 70 degrees C. CD analysis confirmed that prolidase was inactivated at 67 degrees C. The enzyme was active under weak alkali to weak acidic conditions, and showed maximum activity at pH 7.0. Although these characteristics are similar to those for other reported prolidases, this prolidase was distinctive for two kinetic characteristics. Firstly, different substrate specificity was observed for its two preferred metal cations, zinc and manganese: Leu-Pro was preferred with zinc, whereas Arg-Pro was preferred with manganese. Secondly, the enzyme showed an allosteric response to changes in substrate concentrations, with Hill constants of 1.53 for Leu-Pro and 1.57 for Arg-Pro. Molecular modeling of this prolidase suggests that these unique characteristics may be attributed to a loop structure near the active site.

Reaction mechanism of glutathione synthetase from Arabidopsis thaliana: site-directed mutagenesis of active site residues

Glutathione is essential for maintaining the intracellular redox environment and is synthesized from gamma-glutamylcysteine, glycine, and ATP by glutathione synthetase (GS). To examine the reaction mechanism of a eukaryotic GS, 24 Arabidopsis thaliana GS (AtGS) mutants were kinetically characterized. Within the gamma-glutamylcysteine/glutathione-binding site, the S153A and S155A mutants displayed less than 4-fold changes in kinetic parameters with mutations of Glu-220 (E220A/E220Q), Gln-226 (Q226A/Q226N), and Arg-274 (R274A/R274K) at the distal end of the binding site resulting in 24-180-fold increases in the K(m) values for gamma-glutamylcysteine. Substitution of multiple residues interacting with ATP (K313M, K367M, and E429A/E429Q) or coordinating magnesium ions to ATP (E148A/E148Q, N150A/N150D, and E371A) yielded inactive protein because of compromised nucleotide binding, as determined by fluorescence titration. Other mutations in the ATP-binding site (E371Q, N376A, and K456M) resulted in greater than 30-fold decreases in affinity for ATP and up to 80-fold reductions in turnover rate. Mutation of Arg-132 and Arg-454, which are positioned at the interface of the two substrate-binding sites, affected the enzymatic activity differently. The R132A mutant was inactive, and the R132K mutant decreased k(cat) by 200-fold; however, both mutants bound ATP with K(d) values similar to wild-type enzyme. Minimal changes in kinetic parameters were observed with the R454K mutant, but the R454A mutant displayed a 160-fold decrease in k(cat). In addition, the R132K, R454A, and R454K mutations elevated the K(m) value for glycine up to 11-fold. Comparison of the pH profiles and the solvent deuterium isotope effects of A. thaliana GS and the Arg-132 and Arg-454 mutants also suggest distinct mechanistic roles for these residues. Based on these results, a catalytic mechanism for the eukaryotic GS is proposed.

Catalytic loop motion in human glutathione synthetase: A molecular modeling approach

Conformational changes of three flexible loops (G, A, and S) in human glutathione synthetase (hGS) arise to accommodate the substrates inside the active site. The crystal structure of hGS, a member of the ATP-grasp superfamily, has been reported only for the product-enzyme complex. To study the function of the hGS loops, molecular dynamics simulations are performed on three different conformational models: unbound enzyme, reactant-enzyme, and product-enzyme complex of hGS. The conformational changes among the three models are analyzed and the roles of the loops during the catalytic process are described. The modeled structures of hGS show that the central portions of the G- and A-loop have a double role in the reactant complex conformation: they bind the substrates and simultaneously interact with each other through an extensive network of hydrogen bonds. The present study proposes that these favorable loop-ligand and loop-loop interactions are required for opening and closing of the active site of hGS. Additionally, this research identifies important amino acid residues and explains their function within the catalytic loops of hGS.

Characterization of the Bifunctional γ-Glutamate-cysteine Ligase/Glutathione Synthetase (GshF) of Pasteurella multocida

Glutamate-cysteine ligase (gamma-ECL) and glutathione synthetase (GS) are the two unrelated ligases that constitute the glutathione biosynthesis pathway in most eukaryotes, purple bacteria, and cyanobacteria. gamma-ECL is a member of the glutamine synthetase family, whereas GS enzymes group together with highly diverse carboxyl-to-amine/thiol ligases, all characterized by the so-called two-domain ATP-grasp fold. This generalized scheme toward the formation of glutathione, however, is incomplete, as functional steady-state levels of intracellular glutathione may also accumulate solely by import, as has been reported for the Pasteurellaceae member Haemophilus influenzae, as well as for certain Gram-positive enterococci and streptococci, or by the action of a bifunctional fusion protein (termed GshF), as has been reported recently for the Gram-positive firmicutes Streptococcus agalactiae and Listeria monocytogenes. Here, we show that yet another member of the Pasteurellaceae family, Pasteurella multocida, acquires glutathione both by import and GshF-driven biosynthesis. Domain architecture analysis shows that this P. multocida GshF bifunctional ligase contains an N-terminal gamma-proteobacterial gamma-ECL-like domain followed by a typical ATP-grasp domain, which most closely resembles that of cyanophycin synthetases, although it has no significant homology with known GS ligases. Recombinant P. multocida GshF overexpresses as an approximately 85-kDa protein, which, on the basis of gel-sizing chromatography, forms dimers in solution. The gamma-ECL activity of GshF is regulated by an allosteric type of glutathione feedback inhibition (K(i) = 13.6 mM). Furthermore, steady-state kinetics, on the basis of which we present a novel variant of half-of-the-sites reactivity, indicate intimate domain-domain interactions, which may explain the bifunctionality of GshF proteins.

Enzyme inhibitors as chemical tools to study enzyme catalysis: rational design, synthesis, and applications

Carefully designed molecules that are intimately related to the reaction mechanism of enzymes are often highly selective and potent inhibitors that serve as extremely useful chemical probes for understanding the reaction mechanism and structure of enzymes. This article describes the design, synthesis, and applications of specific inhibitors of two mechanistically distinct groups of enzymes, ATP-dependent amide ligases and Ser- and Thr-hydrolases. Our strategy is based on the premise that stable analogues of the transition state (transition-state analogues) are highly potent inhibitors that serve as good mechanistic probes, and that a key structure of a good inhibitor of one enzyme is also utilized for the inhibitors of other enzymes that share the same chemistry in their catalyzed reactions, irrespective of the degree of structural similarity and evolutionary link between the enzymes. According to these principles, we designed and synthesized a series of phosphinate- and sulfoximine-based transition-state analogue inhibitors of glutathione synthetase, gamma-glutamylcysteine synthetase and asparagine synthetase. For the second group of enzymes, we synthesized a gamma-monofluorophosphono glutamate analogue for mechanism-based affinity labeling of gamma-glutamyltranspeptidase and fluorescent phosphonic acid esters for the active-site titration of lipase. These inhibitors were used successfully as ligands for detailed kinetic analyses, X-ray crystallography, and mass analysis of the enzymes to identify the key amino acid residues responsible for catalysis and substrate recognition in the transition state.

Trypanothione synthesis in crithidia revisited

In Crithidia fasciculata the biosynthesis of trypanothione (N(1),N(8)-bis(glutathionyl)spermidine; reduced trypanothione), a redox mediator unique to and essential for pathogenic trypanosomatids, was assumed to be achieved by two distinct enzymes, glutathionylspermidine synthetase and trypanothione synthetase (TryS), and only the first one was adequately characterized. We here report that the TryS of C. fasciculata, like that of Trypanosoma species, catalyzes the entire synthesis of trypanothione, whereas its glutathionylspermidine synthetase appears to be specialized for Gsp synthesis. A gene (GenBanktrade mark accession number AY603101) implicated in reduced trypanothione synthesis of C. fasciculata was isolated from genomic DNA and expressed in Escherichia coli as His-tagged or Nus fusion proteins. The expression product proved to be a trypanothione synthetase (Cf-TryS) that also displayed a glutathionylspermidine synthetase, an amidase, and marginal ATPase activity. The dual specificity of the Cf-TryS preparations was not altered by removal of the tags. Steady-state kinetic analysis of Cf-TryS yielded a pattern that was compatible with a concerted substitution mechanism, wherein the enzyme forms a ternary complex with Mg(2+)-ATP and GSH to phosphorylate GSH and then ligates the glutathionyl residue to glutathionylspermidine. Limiting K(m) values for GSH, Mg(2+)-ATP, and glutathionylspermidine were 407, 222, and 480 microm, respectively, and the k(cat) was 8.7 s(-1) for the TryS reaction. Mutating Arg-553 or Arg-613 to Lys, Leu, Gln, or Glu resulted in marked reduction or abrogation (R553E) of activity. Limited proteolysis with factor Xa or trypsin resulted in cleavage at Arg-556 that was accompanied by loss of activity. The presence of substrates, in particular of ATP and GSH alone or in combination, delayed proteolysis of wild-type Cf-TryS and Cf-TryS R553Q but not in Cf-TryS R613Q, which suggests dynamic interactions of remote domains in substrate binding and catalysis.

Function of conserved residues of human glutathione synthetase: implications for the ATP-grasp enzymes

Glutathione synthetase is an enzyme that belongs to the glutathione synthetase ATP-binding domain-like superfamily. It catalyzes the second step in the biosynthesis of glutathione from gamma-glutamylcysteine and glycine in an ATP-dependent manner. Glutathione synthetase has been purified and sequenced from a variety of biological sources; still, its exact mechanism is not fully understood. A variety of structural alignment methods were applied and four highly conserved residues of human glutathione synthetase (Glu-144, Asn-146, Lys-305, and Lys-364) were identified in the binding site. The function of these was studied by experimental and computational site-directed mutagenesis. The three-dimensional coordinates for several human glutathione synthetase mutant enzymes were obtained using molecular mechanics and molecular dynamics simulation techniques, starting from the reported crystal structure of human glutathione synthetase. Consistent with circular dichroism spectroscopy, our results showed no major changes to overall enzyme structure upon residue mutation. However, semiempirical calculations revealed that ligand binding is affected by these mutations. The key interactions between conserved residues and ligands were detected and found to be essential for enzymatic activity. Particularly, the negatively charged Glu-144 residue plays a major role in catalysis.

Tetramerization and ATP binding by a protein comprising the A, B, and C domains of rat synapsin I

Synapsins are multidomain proteins that are critical for regulating neurotransmitter release in vertebrates. In the present study, two crystal structures of the C domain of rat synapsin I (rSynI-C) in complex with Ca(2+) and ATP reveal that this protein can form a tetramer and that a flexible loop (the "multifunctional loop") contacts bound ATP. Further experiments were carried out on a protein comprising the A, B, and C domains of rat synapsin I (rSynI-ABC). An ATP-stabilized tetramer of rSynI-ABC is observed during velocity sedimentation and size-exclusion chromatographic experiments. These hydrodynamic results also indicate that the A and B domains exist in an extended conformation. Calorimetric measurements of ATP binding to wild-type and mutant rSynI-ABC demonstrate that the multifunctional loop and a cross-tetramer contact are important for ATP binding. The evidence supports a view of synapsin I as an ATP-utilizing, tetrameric protein made up of monomers that have a flexible, extended N terminus.

Mutation of tyrosine 332 to phenylalanine converts dopa decarboxylase into a decarboxylation-dependent oxidative deaminase

A flexible loop (residues 328-339), presumably covering the active site upon substrate binding, has been revealed in 3,4-dihydroxyphenylalanine decarboxylase by means of kinetic and structural studies. The function of tyrosine 332 has been investigated by substituting it with phenylalanine. Y332F displays coenzyme content and spectroscopic features identical to those of the wild type. Unlike wild type, during reactions with l-aromatic amino acids under both aerobic and anaerobic conditions, Y332F does not catalyze the formation of aromatic amines. However, analysis of the products shows that in aerobiosis, l-aromatic amino acids are converted into the corresponding aromatic aldehydes, ammonia, and CO(2) with concomitant O(2) consumption. Therefore, substitution of Tyr-332 with phenylalanine results in the suppression of the original activity and in the generation of a decarboxylation-dependent oxidative deaminase activity. In anaerobiosis, Y332F catalyzes exclusively a decarboxylation-dependent transamination of l-aromatic amino acids. A role of Tyr-332 in the Calpha protonation step that catalyzes the formation of physiological products has been proposed. Furthermore, Y332F catalyzes oxidative deamination of aromatic amines and half-transamination of d-aromatic amino acids with k(cat) values comparable with those of the wild type. However, for all the mutant-catalyzed reactions, an increase in K(m) values is observed, suggesting that Y --> F replacement also affects substrate binding.

X-ray crystal structure of aminoimidazole ribonucleotide synthetase (PurM), from the Escherichia coli purine biosynthetic pathway at 2.5 A resolution

BACKGROUND

The purine biosynthetic pathway in procaryotes enlists eleven enzymes, six of which use ATP. Enzymes 5 and 6 of this pathway, formylglycinamide ribonucleotide (FGAR) amidotransferase (PurL) and aminoimidazole ribonucleotide (AIR) synthetase (PurM) utilize ATP to activate the oxygen of an amide within their substrate toward nucleophilic attack by a nitrogen. AIR synthetase uses the product of PurL, formylglycinamidine ribonucleotide (FGAM) and ATP to make AIR, ADP and P(i).

RESULTS

The structure of a hexahistidine-tagged PurM has been solved by multiwavelength anomalous diffraction phasing techniques using protein containing 28 selenomethionines per asymmetric unit. The final model of PurM consists of two crystallographically independent dimers and four sulfates. The overall R factor at 2.5 A resolution is 19.2%, with an R(free) of 26.4%. The active site, identified in part by conserved residues, is proposed to be a long groove generated by the interaction of two monomers. A search of the sequence databases suggests that the ATP-binding sites between PurM and PurL may be structurally conserved.

CONCLUSIONS

The first structure of a new class of ATP-binding enzyme, PurM, has been solved and a model for the active site has been proposed. The structure is unprecedented, with an extensive and unusual sheet-mediated intersubunit interaction defining the active-site grooves. Sequence searches suggest that two successive enzymes in the purine biosynthetic pathway, proposed to use similar chemistries, will have similar ATP-binding domains.

Aromatic L-amino acid decarboxylase: conformational change in the flexible region around Arg334 is required during the transaldimination process

Aromatic L-amino acid decarboxylase (AADC) catalytic mechanism has been proposed to proceed through two consecutive intermediates (i.e., Michaelis complex and the external aldimine). Limited proteolysis of AADC that preferentially digested at the C-terminal side of Arg334 was slightly retarded in the presence of dihydroxyphenyl acetate that formed a stable Michaelis complex. On the contrary, AADC was scarcely digested in the presence of L-dopa methyl ester that formed a stable external aldimine. Similar protection by the substrate analogs was observed in the chemical modification experiment. From these results, we concluded that the region around Arg334 must be exposed and flexible in the unliganded state, and forming the Michaelis complex generated a subtle conformational change, then underwent marked conformational change during the subsequent transaldimination process prerequisite to forming the external aldimine. For further analyses, we constructed a mutant gene encoding in tandem the two peptides of AADC cleaved at the Asn327-Met328 bond inside the putative flexible region. The gene product, fragmentary AADC, was still active with L-dopa as substrate, but its k(cat) value was decreased 57-fold, and the Km value was increased 9-fold compared with those of the wild-type AADC. The absorption spectra of the fragmentary AADC in the presence of L-dopa methyl ester showed shift in the equilibrium of the transaldimination from the external aldimine to the Michaelis complex. Tryptic digestion of the fragmentary AADC removed seven amino acid residues, Met328-Arg334, and resulted in complete inactivation. Susceptibility of the fragmentary enzyme to trypsin was not changed by L-dopa methyl ester revealing the loss of appropriate conformational change in the flexible region induced by substrate binding. From these results we propose that the conformational change in the flexible region is required during the transaldimination process.

Inhibitors of the bacterial cell wall biosynthesis enzyme MurD

A series of transition-state analog inhibitors of the D-glutamic acid-adding enzyme (MurD) of bacterial peptidoglycan biosynthesis has been synthesized and evaluated for inhibition of the E. coli enzyme.

Glutathione: an overview of biosynthesis and modulation

Glutathione (GSH; gamma-glutamylcysteinylglycine) is ubiquitous in mammalian and other living cells. It has several important functions, including protection against oxidative stress. It is synthesized from its constituent amino acids by the consecutive actions of gamma-glutamylcysteine synthetase and GSH synthetase. gamma-Glutamylcysteine synthetase activity is modulated by its light subunit and by feedback inhibition of the end product, GSH. Treatment with an inhibitor, buthionine sulfoximine (BSO), of gamma-glutamylcysteine synthetase leads to decreased cellular GSH levels, and its application can provide a useful experimental model of GSH deficiency. Cellular levels of GSH may be increased by supplying substrates and GSH delivery compounds. Increasing cellular GSH may be therapeutically useful.

Nicked multifunctional loop of glutathione synthetase still protects the catalytic intermediate

A derivative of glutathione synthetase (GSHase) with the multifunctional loop cleaved (nicked GSHase) was compared to both a deletion mutant of the loop (loopless GSHase) and wild-type with the intact loop (wild-type GSHase). The loop had been shown to be in a closed state in order to protect a catalytic intermediate and accelerate the reaction. Data indicated that cleavage of the loop resulted in a drastic decrease in glutathione synthetic activity which was similar to the results for the loop deletion. Kinetic analyses indicated that the manipulations of the loop impaired the substrate affinity, especially for glycine, and also catalytic efficiency. The nicked loop did not accelerate the reaction as fast as the intact loop; however, the catalytic intermediate was protected from hydrolysis by the cleaved loop as effectively as by the intact loop. These results suggest that the fragmental loop assumed the closed state. High concentrations of ATP showed some inhibitory effects on wild-type GSHase, while both nicked and loopless GSHase were not inhibited, indicating that the fragments of the nicked loop functioned independently. In conclusion, it is postulated that the two fragments of the nicked loop independently assumed the closed state to protect the catalytic intermediate and have lost the ability to accelerate glutathione synthesis.

Identification of a putative flexible loop in Arabidopsis glutathione synthetase

Glutathione synthetase catalyses the ATP-dependent ligation of gamma-glutamylcystene with glycine to form glutathione. Amino acid sequence comparisons between the Arabidopsis and the Escherichia coli proteins suggested that a region, identified as a small flexible loop that covers the active site of the E. coli protein, might be conserved in the eukaryotic protein. Three site-directed mutations in the Arabidopsis protein were generated to test this hypothesis. Two mutations within the conserved region (Lys367/ Pro368-->Asn/Ser and Gly374-->Val) inactivated the enzyme in an in vivo assay based on cadmium resistance in S. pombe, and in an in vitro assay of the activity of the enzyme expressed in E. coli. A third mutation outside of this conserved region (Leu363-->Glu) had a smaller effect in both assays. These results are consistent with the idea that this glycine-rich loop in the Arabidopsis and E. coli proteins might serve the same function in covering the active site of the enzyme.

Identification of an essential cysteine residue in human glutathione synthase

Glutathione is essential for a variety of cellular functions, and is synthesized from gamma-glutamylcysteine and glycine by the action of glutathione synthase (EC 6.3.2.3). Human glutathione synthase is a dimer of two identical subunits, each composed of 474 amino acids. Little is known about the structure-function relationships of mammalian glutathione synthases and, in order to gain a greater understanding of this critical enzyme, we have probed the role of cysteine residues by chemical modification and site-directed mutagenesis. Preincubation with thiol reagents such as p-chloromercuribenzoate, N-ethylmaleimide, iodoacetate and 5,5'-dithiobis-(2-nitrobenzoate) resulted in significant inhibition of recombinant human glutathione synthase. Each subunit contains cysteine residues at positions 294, 409 and 422, and we have prepared four different mutants by replacing individual cysteine residues, or all of the cysteine residues, with alanine. The C294A and C409A cysteine mutants retained significant residual activity, indicating that these two cysteine residues are not essential for activity. In contrast, substantial decreases in enzymic activity were detected with the C422A and cysteine-free mutants. This suggests that Cys-422 may play a significant structural or functional role in human glutathione synthase.