Site-specific modification or rabbit muscle aldolase with fluorescent probes

The site-specific modification of rabbit muscle aldolase A by labeling of thiol residues of Cys-289 with 5-(2-((iodoacetyl)amino)ethyl)amino)naphthalene-1-sulfonic acid and Cys-239 with 5-iodoacetamidofluorescein or 4-dimethylamino-phenylazophenyl-4'-maleimide has been described. The method is based on the differences in kinetics of the chemical modification of aldolase thiols with the above reagents either in the presence or in the absence of a competitive inhibitor. The spectral properties of the doubly labeled aldolase derivatives were compared with those of the singly labeled enzyme. The doubly labeled aldolase derivatives exhibited full catalytic activity.     

Site-directed mutagenesis of human aldolase isozymes: the role of Cys-72 and Cys-338 residues of aldolase A and of the carboxy-terminal Tyr residues of aldolases A and B

In order to elucidate the role of particular amino acid residues in the catalytic activity and conformational stability of human aldolases A and B [EC 4.1.2.13], the cDNAs encoding these isoenzyme were modified using oligonucleotide-directed, site-specific mutagenesis. The Cys-72 and/or Cys-338 of aldolase A were replaced by Ala and the COOH-terminal Tyr of aldolases A and B was replaced by Ser. The three mutant aldolases A thus prepared, A-C72A, A-C338A, and A-C72,338A, were indistinguishable from the wild-type enzyme with respect to general catalytic properties, while the replacement of Tyr-363 by Ser in aldolase A (A-Y363S) resulted in decreases of the Vmax of the fructose-1, 6-bisphosphate (FDP) cleavage reaction, activity ratio of FDP/fructose-1-phosphate (F1P), and the Km values for FDP and F1P. The wild-type and all the mutant aldolase A proteins exhibited similar thermal stabilities. In contrast, the mutant aldolase A proteins were more stable than the wild-type enzyme against tryptic and alpha-chymotryptic digestions. Based upon these results it is concluded that the strictly conserved Tyr-363 of human aldolase A is required for the catalytic function with FDP as the substrate, while neither Cys-72 nor Cys-338 directly takes part in the catalytic function although the two Cys residues may be involved in maintaining the correct spatial conformation of aldolase A. Replacement of Tyr-363 by Ser in human aldolase B lowered the Km value for FDP appreciably and also diminished the stability against elevated temperatures and tryptic digestion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the structure of rabbit muscle aldolase: Amino acid sequence of cysteine-containing peptides

Five cysteine-containing peptides have been isolated in nearly stoichemometric yields from the tryptic digests of the NH₂^? and COOH-terminal BrCN peptides of rabhit muscle aldolase and their sequence determined. Peptides NS1, NS2, and NS3, from the NH₂-terminal part of the enzyme have the following sequences: NS1, Val-Asp-Pro-Cys-Ile-Gly-Gly-Val-Ile-Leu-Phe-His-Glu-Thr-Leu-Tyr-Gln-Lys; NS2, Cys-Val-Leu-Lys; NS3, Cys-Ala-Glu-Tyr-Lys. The two peptides isolated from the COOH-terminal region are: CS1, Ala-Leu-Ala-Asn-Ser-Leu-Ala-Cys-Gln-Gly-Lys and CS2, Cys-Pro-Leu-Leu-Trp-Pro-Lys-Ala-Leu-Thr-Phe-Ser-Tyr-Gly-Arg. The Lys-Ala bond in peptide CS2 was found to be resistant to tryptic hydrolysis. The results provide the basis for assigning the positions of cysteine residues in the polypeptide chain. Cys-72 in peptide NS1 and Cys-336 in peptide CS1 are the residues that form a disulfide bridge when the enzyme is inactivated by oxidation with an o-phenanthroline-Cu²⁺ complex; Cys-287 in peptide CS2 in one of the two exposed residues, while Cys-134 and Cys-149 in peptides NS2 and NS3, respectively, are buried in the native enzyme. All of eight cysteine-containing peptides of rabbit muscle aldolase have now been sequenced, and structural homology of the α and β subunits extended to these regions.     

Fructose diphosphate aldolase from Mycobacterium smegmatis. Functional similarities with rabbit muscle aldolase.

Fructose diphosphate aldolase of Mycobacterium smegmatis is found to be a class I type aldolase and possesses functional similarities with rabbit muscle aldolase with respect to the amino acid residues at the catalytic site. The presence of a lysine residue at the active site is indicated by the formation of a Schiff-base with the substrate. The lower degree of inactivation compared to rabbit muscle aldolase on treatment with carboxypeptidase-A suggests the absence of an essential terminal tyrosine residue. Participation of histidine residues in enzyme catalysis is suggested by the photoinactivation of the enzyme in presence of methylene blue. Finally, thiol groups do not seem to have a direct role in catalysis.     

Identification of essential amino acid residues for catalytic activity and thermostability of novel chitosanase by site-directed mutagenesis

The functional importance of a conserved region in a novel chitosanase from Bacillus sp. CK4 was investigated. Each of the three carboxylic amino acid residues (Glu-50, Glu-62, and Asp-66) was changed to Asp and Gln or Asn and Glu by site-directed mutagenesis, respectively. The Asp-66-->Asn and Asp-66-->Glu mutation remarkably decreased kinetic parameters such as Vmax and kcat to approximately 1/1,000 those of the wild-type enzyme, indicating that the Asp-66 residue was essential for catalysis. The thermostable chitosanase contains three Cys residues at positions 49, 72, and 211. The Cys-49-->Ser/Tyr and Cys-72-->Ser/Tyr mutant enzymes were as stable to thermal inactivation and denaturating agents as the wild-type enzyme. However, the half-life of the Cys-211-->Ser/Tyr mutant enzyme was less than 10 min at 80 degrees C, while that of the wild-type enzyme was about 90 min. Moreover, the residual activity of Cys-211-->Ser/Tyr enzyme was substantially decreased by 8 M urea; and it lost all catalytic activity in 40% ethanol. These results show that the substitution of Cys with any amino acid residues at position 211 seems to affect the conformational stability of the chitosanase.     

Subunit structure of rabbit brain aldolase

Rabbit brain contains a mixture of aldolase A (muscle type) and aldolase C (brain type), present largely as the hybrid forms A₃C, A₂C₂, and AC₃, with smaller amounts of the homopolymers A₄ and C₄. We have developed new procedures for the isolation of the A-C hybrid set and the aldolase C subunits and compared the structure of these subunits with those of aldolase A. The two isoenzymes differ significantly in amino acid composition, but each contains three methionine residues per subunit and yields four peptides on cleavage with cyanogen bromide. The three methionine residues appear to occupy similar positions in the polypeptide chains but the molecular weight of the aldolase C subunit is only 37,000, approximately 10% smaller than that of the subunit of aldolase A. The difference is attributable to two or more deletions, totaling 30–40 amino acid residues, in two of the four BrCN peptides. The deletions include two of the buried cysteine residues that are located in the center of the polypeptide chain in aldolase A; these residues in aldolase A are, therefore, not involved in the contacts between the subunits in the tetramer. Aldolase C also lacks several of the histidine residues that are located near the active-site lysine residue of aldolase A, thus excluding these residues from participation in the catalytic mechanism.     

Conserved residues in the putative catalytic triad of human bile acid Coenzyme A:amino acid N-acyltransferase

Human bile acid-CoA:amino acid N-acyltransferase (hBAT), an enzyme catalyzing the conjugation of bile acids with the amino acids glycine or taurine has significant sequence homology with dienelactone hydrolases and other alpha/beta hydrolases. These enzymes have a conserved catalytic triad that maps onto the mammalian BATs at residues Cys-235, Asp-328, and His-362 of the human sequence, albeit that the hydrolases contain a serine instead of a cysteine. In the present study, the function of the putative catalytic triad of hBAT was examined by chemical modification with the cysteine alkylating reagent N-ethylmaleimide (NEM) and by site-directed mutagenesis of the triad residues followed by enzymology studies of mutant and wild-type hBATs. Treatment with NEM caused inactivation of wild-type hBAT. However, preincubation of wild-type hBAT with the substrate cholyl-CoA before NEM treatment prevented loss of N-acyltransferase activity. Substitution of His-362 or Asp-328 with alanine results in inactivation of hBAT. Although substitution of Cys-235 with serine generated an hBAT mutant with lower N-acyltransferase activity, it substantially increased the bile acid-CoA thioesterase activity compared with wild type. In summary, data from this study support the existence of an essential catalytic triad within hBAT consisting of Cys-235, His-362, and Asp-328 with Cys-235 serving as the probable nucleophile and thus the site of covalent attachment of the bile acid molecule.     

Extended amino acid sequences around the active-site lysine residue of class-I fructose 1,6-bisphosphate aldolases from rabbit muscle, sturgeon muscle, trout muscle and ox liver.

1. Amino acid sequences covering the region between residues 173 and 248 [adopting the numbering system proposed by Lai, Nakai & Chang (1974) Science 183, 1204-1206] were derived for trout (Salmo trutta) muscle aldolase and for ox liver aldolase. A comparable sequence was derived for residues 180-248 of sturgeon (Acipenser transmontanus) muscle aldolase. The close homology with the rabbit muscle enzyme was used to align the peptides of the other aldolases from which the sequences were derived. The results also allowed a partial sequence for the N-terminal 39 residues for the ox liver enzyme to be deduced. 2. In the light of the strong homology evinced for these enzymes, a re-investigation of the amino acid sequence of rabbit muscle aldolase between residues 181 and 185 was undertaken. This indicated the presence of a hitherto unsuspected -Ile-Val-sequence between residues 181 and 182 and the need to invert the sequence -Glu-Val- to -Val-Glx- at positions 184 and 185. 3. Comparison of the available amino acid sequences of these enzymes suggested an early evolutionary divergence of the genes for muscle and liver aldolases. It was also consistent with other evidence that the central region of the primary structure of these enzymes (which includes the active-site lysine-227) forms part of a conserved folding domain in the protein subunit. 4. Detailed evidence for the amino acid sequences proposed has been deposited as Suy Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1978) 169, 5.     

Chloroplast and Cytoplasmic Enzymes: VIII. Amino Acid Composition of the Pea Leaf Aldolases

Pea leaf chloroplast aldolase contains seven more aspartyl (asx) residues and four fewer leucine and isoleucine residues than the cytoplasmic enzyme. The two forms are therefore primary isoenzymes, differing in amino acid sequence.     

Affinity labeling of a previously undetected essential lysyl residue in class I fructose bisphosphate aldolase.

The affinity label N-bromoacetylethanolamine phosphate (BrAcNHEtOP) has been used previously at pH 6.5 to identify His-359 of rabbit muscle aldolase as an active site residue. We now find that the specificity of the reagent is pH-dependent. At pH 8.5, alkylation with 14C-labeled BrAcNHEtOP abolishes both fructose-1,6-P2 cleavage activity and transaldolase activity. The stoichiometry of incorporation, the kinetics of inactivation, and the protection against inactivation afforded by a competitive inhibitor or dihydroxyacetone phosphate are consistent with the involvement of an active site residue. A comparison of 14C profiles obtained from chromatography on the amino acid analyzer of acid hydrolysates of inactivated and protected samples reveals that inactivation results from the alkylation of lysyl residues. The major peptide in tryptic digests of the inactivated enzyme has been isolated. Based on its amino acid composition and the known sequence of aldolase, Lys-146 is the residue preferentially alkylated by the reagent. Aldolase modified at His-359 is still subject to alkylation of lysine; thus Lys-146 and His-359 are not mutually exclusive sites. However, aldolase modified at Lys-146 is not subject to alkylation of histidine. One explanation of these observations is that modification of Lys-146 abolishes the binding capacity of aldolase for substrates and substrate analogs (BrAcNHEtOP), whereas modification of his-359 does not. Consistent with this explanation is the ability of aldolase modified at His-359 to form a Schiff base with substrate and the inability of aldolase modified at Lys-146 to do so. Therefore, Lys-146 could be one of the cationic groups that functions in electrostatic binding of the substrate's phosphate groups.     

Re-evaluation of the role of thiol groups in rabbit muscle aldolase A

Exposed thiol groups of rabbit muscle aldolase A were modified by 5,5'-dithiobis(2-nitrobenzoic) acid with concomittant loss of enzyme activity. When 5-thio-2-nitrobenzoate residues bound to enzyme SH groups were replaced by small and uncharged cyanide residues the enzyme activity was restored by more than 50%. The removal of a bulky C-terminal tyrosine residue from the active site of aldolase A resulted in enzyme which was inhibited by 5,5'-dithiobis(2-nitrobenzoic) acid only by 50% and its activity was nearly unchanged after modification of its thiol groups with cyanide. The results obtained show directly that rabbit muscle aldolase A does not possess functional cysteine residues and that the inactivation of the enzyme caused by sulfhydryl group modification reported previously can be attributed most likely to steric hindrance of a catalytic site by modifying agents.     

Elimination of a reactive thiol group from the active site of chloramphenicol acetyltransferase.

1. The type III variant of chloramphenicol acetyltransferase (CATIII) is resistant to inactivation by ionizable modifying reagents such as 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) and iodoacetate, whereas it is sensitive to inhibition by similar but uncharged reagents, including 4,4'-dithiodipyridine, methyl methanethiolsulphonate (MMTS) and iodoacetamide. The target for these thiol-modifying reagents has been postulated to be Cys-31. This residue is situated within a part of the chloramphenicol-binding site formed largely from the side chains of hydrophobic amino acid residues, which might be expected to discriminate against the access of ionized ligands to Cys-31. 2. The substitution of Cys-31 by alanine, serine, threonine or methionine yields an enzyme that is resistant to inactivation by thiol-specific reagents. Replacement of Cys-31 by alanine, serine or threonine results in increased Km values for chloramphenicol with only small changes in kcat.. In contrast, the Cys-31----Met substitution mainly affects kcat. values. Although the kcat. for chloramphenicol acetylation is decreased 13-fold compared with wild-type CAT, the kcat. for the acetyl-CoA hydrolysis reaction, which occurs in the absence of chloramphenicol, is increased 2.7-fold. 3. MMTS modification of cysteine residues results in an adduct (-CH2-S-S-CH3) that is structurally similar to the side chain of a methionine residue (-CH2-CH2-S-CH3). The kinetic properties of MMTS-modified CATIII closely resemble those of [Met31]CAT.     

Evidence for an essential arginine residue in the active site of Escherichia coli 2-keto-4-hydroxyglutarate aldolase. Modification with 1,2-cyclohexanedione

Treatment of homogeneous preparations of Escherichia coli 2-keto-4-hydroxyglutarate aldolase with 1,2-cyclohexanedione, 2,3-butanedione, phenylglyoxal, or 2,4-pentanedione results in a time- and concentration-dependent loss of enzymatic activity; the kinetics of inactivation are pseudo-first order. Cyclohexanedione is the most effective modifier; a plot of log (1000/t 1/2) versus log [cyclohexanedione] gives a straight line with slope = 1.1, indicating that one molecule of modifier reacts with each active unit of enzyme. The kinetics of inactivation are first order with respect to cyclohexanedione, suggesting that the loss of activity is due to modification of 1 arginine residue/subunit. Controls establish that this inactivation is not due to modifier-induced dissociation or photoinduced structural alteration of the aldolase. The same Km but decreased Vmax values are obtained when partially inactivated enzyme is compared with native. Amino acid analyses of 95% inactivated aldolase show the loss of 1 arginine/subunit with no significant change in other amino acid residues. Considerable protection against inactivation is provided by the substrates 2-keto-4-hydroxyglutarate and pyruvate (75 and 50%, respectively) and to a lesser extent (40 and 35%, respectively) by analogs like 2-keto-4-hydroxybutyrate and 2-keto-3-deoxyarabonate. In contrast, formaldehyde or glycolaldehyde (analogs of glyoxylate) under similar conditions show no protective effect. These results indicate that an arginine residue is required for E. coli 2-keto-4-hydroxyglutarate aldolase activity; it most likely participates in the active site of the enzyme by interacting with the carboxylate anion of the pyruvate-forming moiety of 2-keto-4-hydroxyglutarate.     

Substrate Specificity, Substrate Channeling, and Allostery in BphJ: An Acylating Aldehyde Dehydrogenase Associated with the Pyruvate Aldolase BphI

BphJ, a nonphosphorylating acylating aldehyde dehydrogenase, catalyzes the conversion of aldehydes to form acyl-coenzyme A in the presence of NAD(+) and coenzyme A (CoA). The enzyme is structurally related to the nonacylating aldehyde dehydrogenases, aspartate-β-semialdehyde dehydrogenase and phosphorylating glyceraldehyde-3-phosphate dehydrogenase. Cys-131 was identified as the catalytic thiol in BphJ, and pH profiles together with site-specific mutagenesis data demonstrated that the catalytic thiol is not activated by an aspartate residue, as previously proposed. In contrast to the wild-type enzyme that had similar specificities for two- or three-carbon aldehydes, an I195A variant was observed to have a 20-fold higher catalytic efficiency for butyraldehyde and pentaldehyde compared to the catalytic efficiency of the wild type toward its natural substrate, acetaldehyde. BphJ forms a heterotetrameric complex with the class II aldolase BphI that channels aldehydes produced in the aldol cleavage reaction to the dehydrogenase via a molecular tunnel. Replacement of Ile-171 and Ile-195 with bulkier amino acid residues resulted in no more than a 35% reduction in acetaldehyde channeling efficiency, showing that these residues are not critical in gating the exit of the channel. Likewise, the replacement of Asn-170 in BphJ with alanine and aspartate did not substantially alter aldehyde channeling efficiencies. Levels of activation of BphI by BphJ N170A, N170D, and I171A were reduced by ≥3-fold in the presence of NADH and ≥4.5-fold when BphJ was undergoing turnover, indicating that allosteric activation of the aldolase has been compromised in these variants. The results demonstrate that the dehydrogenase coordinates the catalytic activity of BphI through allostery rather than through aldehyde channeling.     

Role of strategic cysteine residues in oxidative damage to the yeast plasma membrane H<Superscript>+</Superscript>-ATPase caused by Fe- and Cu-containing fenton reagents

Damage caused to Saccharomyces cerevisiae SY4 plasma membrane H(+)-ATPase by Fe- and Cu-Fenton reagents was determined in secretory vesicles containing enzyme in which Cys residues were replaced singly or in pairs by Ala. Cys-221 situated in a beta-sheet domain between M2 and M3 segments, phosphorylation domain-located Cys-409 and Cys-532 situated at the ATP-binding site play a role in the inactivation. In the presence of all three residues the enzyme exhibited a certain basic inactivation, which did not change when Cys-532 was replaced with Ala. In mutants having intact Cys-532 but lacking one or both other cysteines, replacement of Cys-221 with Ala led to lower inactivation, suggesting that Cys-221 may serve as a target for metal-catalyzed oxidation and intact Cys-532 promotes this target role of Cys-221. In contrast, the absence of Cys-409 caused higher inactivation by Fe-Fenton. Cys-532 thus seems to serve as a target for Fe-Fenton, intact Cys-409 causing a conformational change that makes Cys-532 less accessible to oxidation. The mutant lacking both Cys-221 and Cys-409 is more sensitive to Fe-Fenton than to Cu-Fenton and the absence of both Cys residues thus seems to expose presumable extra Fe-binding sites. These data and those on protection by ATP, ADP, 1,4-dithiothreitol and deferrioxamine B point to complex interactions between individual parts of the enzyme molecule that determine its sensitivity towards Fenton reagents. ATPase fragmentation caused by the two reagents differed in that the Fe-Fenton reagent produced in Western blot "smears" whereas the Cu-Fenton reagent produced defined fragments.     

Nitrilase from Rhodococcus rhodochrous J1. Sequencing and overexpression of the gene and identification of an essential cysteine residue.

The amino acid sequences of the NH2 terminus and internal peptide fragments of a Rhodococcus rhodochrous J1 nitrilase were determined to prepare synthetic oligonucleotides as primers for the polymerase chain reaction. A 750-base DNA fragment thus amplified was used as the probe to clone a 5.4-kilobase PstI fragment coding for the whole nitrilase. The nitrilase gene modified in the sequence upstream from the presumed ATG start codon was expressed to approximately 50% of the total soluble protein in Escherichia coli. The predicted amino acid sequence of the nitrilase gene showed similarity to that of the bromoxynil nitrilase from Klebsiella ozaenae. The 5,5'-dithiobis(2-nitrobenzoic acid) modification of the nitrilase from R. rhodochrous J1 resulted in inactivation with the loss of one sulfhydryl group/enzyme subunit. Of 4 cysteine residues in the Rhodococcus nitrilase, only Cys-165 is conserved in the Klebsiella nitrilase. Mutant enzymes containing Ala or Ser instead of Cys-165 did not exhibit nitrilase activity. These findings suggest that Cys-165 plays an essential role in the function of the active site.     

Human skeletal-muscle aldolase: N-terminal sequence analysis of CNBr- and o-iodosobenzoic acid-cleavage fragments

Fructose-1,6-bisphosphate aldolase was purified from human skeletal-muscle by affinity elution chromatography. Four CNBr-cleavage fragments were purified by gel filtration, and their N-terminal amino acid sequences were determined. Cleavage with o-iodosobenzoic acid at the three tryptophan residues also yielded fragments suitable for N-terminal sequence analysis. Thus, the sequence of 272 of the 363 residues was established. These sequence results allow many of the discrepancies between the two published rabbit skeletal-muscle aldolase sequences to be resolved. The human aldolase sequence reported here is 96% identical to a "consensus" rabbit aldolase sequence. A comparison with a partial sequence of Drosophila aldolase (103 residues) shows 80% identity. The determination of the amino acid sequence of human aldolase is important for the interpretation of the crystal structure of this enzyme.     

Evidence that cysteine 298 is in the active site of tryptophan indole-lyase

Escherichia coli tryptophan indole-lyase (tryptophanase) mutants, with cysteine residues 294 and 298 selectively replaced by serines, have been prepared by site-directed mutagenesis. Both mutant enzymes are highly active for beta-elimination reactions measured with both L-tryptophan and S-(o-nitrophenyl)-L-cysteine. The Cys-294----Ser mutant enzyme is virtually identical to the wild type with respect to pyridoxal phosphate binding (KCO = 2 microM), cofactor absorption spectrum (lambda max = 420 and 337 nm) and pH dependence (pK alpha = 7.3), pH profile for catalysis, and rate of bromopyruvic acid inactivation. In contrast, the Cys-298----Ser mutant enzyme exhibits a reduced affinity for pyridoxal phosphate (KCO = 6 microM), a shift in the cofactor absorption spectrum to 414 nm and an altered pK alpha = 8.5, an alkaline shift in the pH profile for catalysis, and resistance to inactivation of the apoenzyme by bromopyruvic acid. The C298S mutant enzyme (wherein cysteine 298 is altered to serine) also undergoes an isomerization to an unreactive state upon storage at 4 degrees C. These results demonstrate that the sulfhydryl groups of Cys-294 and Cys-298 are catalytically nonessential. However, these data suggest that Cys-298 is located within or very near the active site of the enzyme and is the reactive cysteine residue previously observed by others.     

Recombinant rat liver guanidinoacetate methyltransferase: reactivity and function of sulfhydryl groups

Rat liver guanidinoacetate methyltransferase, produced in Escherichia coli by recombinant DNA technique, possesses five cysteine residues per molecule. No disulfide bond is present. Analysis of the chymotryptic peptides derived from the iodo[14C]acetate-modified enzyme shows that Cys-90, Cys-15, Cys-219, and Cys-207 are alkylated by the reagent in order of decreasing reactivity. Incubation of the enzyme with excess 5,5'-dithiobis(2-nitrobenzoate) (DTNB) in the absence and presence of cystamine [2,2'-dithiobis(ethylamine)] causes the appearance of 4 and 5 mol of 2-nitro-5-mercaptobenzoate/mol of enzyme, respectively. Reaction of the methyltransferase with an equimolar amount of DTNB results in an almost quantitative disulfide cross-linking of Cys-15 and Cys-90 with loss of a large portion of the activity. The methyltransferase is completely inactivated by iodoacetate following nonlinear kinetics. Comparison of the extent of inactivation with that of modification of cysteine residues and the experiment with the enzyme whose Cys-15 and Cys-90 are cross-linked suggest that alkylation of Cys-15 and Cys-90 results in a partially active enzyme and that carboxymethylation of Cys-219 completely eliminates enzyme activity. The inactivation of guanidinoacetate methyltransferase by iodoacetate or DTNB is not protected by substrates. Furthermore, disulfide cross-linking of Cys-15 and Cys-90 or carboxymethylation of Cys-219 does not impair the enzyme's capacity to bind S-adenosylmethionine. Thus, these cysteine residues appear to occur outside the active-site region, but their integrity is crucial for the expression of enzyme activity.