Site-specific alteration of cysteine 281, cysteine 344, and cysteine 349 in the proline carrier of Escherichia coli

Cys-281, Cys-344, or Cys-349 in the proline carrier of Escherichia coli was changed to a serine residue by site-specific mutagenesis. The activities of the resultant mutants for uptake of proline were as great as that of the wild-type strain. These mutant carriers were all as sensitive as the wild-type carrier to the proline analogue azetidine 2-carboxylate. However, the mutant carriers with Ser-281 and Ser-344 were resistant to N-ethylmaleimide, whereas the mutant carrier with Ser-349 was as sensitive as the wild-type carrier to this reagent. These results indicate that these cysteine residues are not essential for proline transport and that Cys-281 and Cys-344 may be close to the substrate-binding site that contains an N-ethylmaleimide-sensitive residue.     

Organization of the multiple coenzymes and subunits and role of the covalent flavin link in the complex heterotetrameric sarcosine oxidase

Heterotetrameric (alphabetagammadelta) sarcosine oxidase from Corynebacterium sp. P-1 (cTSOX) contains noncovalently bound FAD and NAD(+) and covalently bound FMN, attached to beta(His173). The beta(His173Asn) mutant is expressed as a catalytically inactive, labile heterotetramer. The beta and delta subunits are lost during mutant enzyme purification, which yields a stable alphagamma complex. Addition of stabilizing agents prevents loss of the delta but not the beta subunit. The covalent flavin link is clearly a critical structural element and essential for TSOX activity or preventing FMN loss. The alpha subunit was expressed by itself and purified by affinity chromatography. The alpha and beta subunits each contain an NH(2)-terminal ADP-binding motif that could serve as part of the binding site for NAD(+) or FAD. The alpha subunit and the alphagamma complex were each found to contain 1 mol of NAD(+) but no FAD. Since NAD(+) binds to alpha, FAD probably binds to beta. The latter could not be directly demonstrated since it was not possible to express beta by itself. However, FAD in TSOX from Pseudomonas maltophilia (pTSOX) exhibits properties similar to those observed for the covalently bound FAD in monomeric sarcosine oxidase and N-methyltryptophan oxidase, enzymes that exhibit sequence homology with beta. A highly conserved glycine in the ADP-binding motif of the alpha(Gly139) or beta(Gly30) subunit was mutated in an attempt to generate NAD(+)- or FAD-free cTSOX, respectively. The alpha(Gly139Ala) mutant is expressed only at low temperature (t(optimum) = 15 degrees C), but the purified enzyme exhibited properties indistinguishable from the wild-type enzyme. The much larger barrier to NAD(+) binding in the case of the alpha(Gly139Val) mutant could not be overcome even by growth at 3 degrees C, suggesting that NAD(+) binding is required for TSOX expression. The beta(Gly30Ala) mutant exhibited subunit expression levels similar to those of the wild-type enzyme, but the mutation blocked subunit assembly and covalent attachment of FMN, suggesting that both processes require a conformational change in beta that is induced upon FAD binding. About half of the covalent FMN in recombinant preparations of cTSOX or pTSOX is present as a reversible covalent 4a-adduct with a cysteine residue. Adduct formation is not prevented by mutating any of the three cysteine residues in the beta subunit of cTSOX to Ser or Ala. Since FMN is attached via its 8-methyl group to the beta subunit, the FMN ring must be located at the interface between beta and another subunit that contains the reactive cysteine residue.     

Organisation of the yeast ATP synthase F(0):a study based on cysteine mutants, thiol modification and cross-linking reagents

A topological study of the yeast ATP synthase membranous domain was undertaken by means of chemical modifications and cross-linking experiments on the wild-type complex and on mutated enzymes obtained by site-directed mutagenesis of genes encoding ATP synthase subunits. The modification by non-permeant maleimide reagents of the Cys-54 of mutated subunit 4 (subunit b), of the Cys-23 in the N-terminus of subunit 6 (subunit a) and of the Cys-91 in the C-terminus of mutated subunit f demonstrated their location in the mitochondrial intermembrane space. Near-neighbour relationships between subunits of the complex were demonstrated by means of homobifunctional and heterobifunctional reagents. Our data suggest interactions between the first transmembranous alpha-helix of subunit 6, the two hydrophobic segments of subunit 4 and the unique membrane-spanning segments of subunits i and f. The amino acid residue 174 of subunit 4 is close to both oscp and the beta-subunit, and the residue 209 is close to oscp. The dimerisation of subunit 4 in the membrane revealed that this component is located in the periphery of the enzyme and interacts with other ATP synthase complexes.     

Assembly of the bacteriophage T4 helicase: architecture and stoichiometry of the gp41-gp59 complex

The bacteriophage T4 59 protein (gp59) plays an essential role in recombination and replication by mediating the assembly of the gene 41 helicase (gp41) onto DNA. gp59 is required to displace the gp32 single-stranded binding protein on the lagging strand to expose a site for helicase binding. To gain a better understanding of the mechanism of helicase assembly, the architecture and stoichiometry of the gp41-gp59 complex were investigated. Both the N and C termini of gp41 were found to lie close to or in the gp41-gp41 subunit interface and interact with gp59. The site of interaction of gp41 on gp59 is proximal to Cys-215 of gp59. Binding of gp41 to gp59 stimulates a conformational change in the protein resulting in hexamer formation of gp59, and gp59 likewise stimulates oligomer formation of gp41. The gp59 subunits in this complex are arranged in a head to head orientation, such that Cys-42 of one subunit is in close proximity to Cys-42 on an adjacent subunit, and Cys-215 on one subunit is close to Cys-215 on a neighboring subunit. As the helicase is loaded onto DNA, a conformational change in the gp41-gp59 complex occurs, which may serve to displace gp32 from the lagging strand and load the hexameric helicase in its place.     

Role of cysteine residues in human NADH-cytochrome b5 reductase studied by site-directed mutagenesis. Cys-273 and Cys-283 are located close to the NADH-binding site but are not catalytically essential

Human NADH-cytochrome b5 reductase (EC 1.6.2.2) contains 4 cyteine residues (Cys-203, -273, -283, and -297). Cys-283 was previously proposed to be involved in NADH binding by chemical modification (Hackett, C. S., Novoa, W. B., Ozols, J., and Strittmatter, P. (1986) J. Biol. Chem. 261, 9854-9857). In the present study the role of cysteines in the enzyme was probed by replacing these residues by Ser, Ala, or Gly employing site-directed mutagenesis and chemical modification. Four mutants, in which 1 of the 4 Cys residues was replaced by Ser, retained comparable kcat and Km values to those of the wild type. All of these mutants were as sensitive as the wild type to treatment with SH modifiers, while a double mutant, C273S/C283S was resistant. Since inhibition by SH modifiers was protected by NADH, Cys-273 and Cys-283 were implicated to be close to the NADH-binding site. C273A and C273A/C283A mutants showed approximately one-fifth of the enzyme-FAD reduction rate of the wild type as revealed by steady-state kinetics and by stopped-flow analysis. Anaerobic titration has shown that reduction and re-oxidation processes including formation of the red semiquinone of these mutants were not significantly altered from those of the wild type. From these results it was concluded that none of the Cys residues of the enzyme are essential in the catalytic reaction, but Cys-273 conserved among the enzymes homologous to NADH-cytochrome b5 reductase homologous to NADH-cytochrome b5 reductase plays role(s) in facilitating the reaction. A difference spectrum with a peak at 317 nm, which was formerly considered to be derived from the interaction between NAD+ and Cys-283 of the reduced enzyme, appeared upon binding of NAD+ not only to the reduced wild type enzyme but also to the C273A/C283A mutant in which both of the Cys residues close to the NADH-binding site were replaced.     

Residue cysteine 232 is important for substrate transport of neutral amino acid transporter,SNAT4

SNAT4 is a system A type amino acid transporter that primarily expresses in liver and mediates the transport of L-alanine. To determine the critical amino acid residue(s) involved in substrate transport function of SNAT4, we used hydrosulfate cross-linking MTS reagents - MMTS and MTSEA. These two reagents caused inhibition of L-alanine transport by wild-type SNAT4. There are 5 cysteine residues in SNAT4 and among them; residues Cys-232 and Cys-345 are located in the transmembrane domains. Mutation of Cys-232, but not Cys-345, inhibited transport function of SNAT4 and also rendered SNAT4 less sensitive to the cross-linking by MMTS and MTSEA. The results suggested that TMD located Cys-232 is an aqueous accessible residue, likely to be located close to the core of substrate binding site. Mutation of Cys-232 to serine similarly attenuated the transport of L-alanine substrate. Biotinylation analysis showed that C232A mutant of SNAT4 was equally capable as wild-type SNAT4 of expressing on the cell surface. Moreover, single site mutant, C232A was also found to be more resistant to MTS inhibition than double mutant C18A,C345A, further confirming the aqueous accessibility of Cys-232 residue. We also showed that mutation of Cys-232 to alanine reduced the maximal velocity (Vmax), but had minimal effect on binding affinity (Km). Together, these data suggest that residue Cys-232 at 4^th transmembrane domain of SNAT4 has a major influence on substrate transport capacity, but not on substrate binding affinity.     

Evidence for two different classes of redox-active cysteines in ribonucleotide reductase of Escherichia coli

The large subunit of ribonucleotide reductase from Escherichia coli contains redox-active cysteine residues. In separate experiments, five conserved and 2 nonconserved cysteine residues were substituted with alanines by oligonucleotide-directed mutagenesis. The activities of the mutant proteins were determined in the presence of three different reductants: thioredoxin, glutaredoxin, or dithiothreitol. The results indicate two different classes of redox-active cysteines in ribonucleotide reductase: 1) C-terminal Cys-754 and Cys-759 responsible for the interaction with thioredoxin and glutaredoxin; and 2) Cys-225 and Cys-439 located at the nucleotide-binding site. Our classification of redox-active cysteines differs from the location of the active site cysteines in E. coli ribonucleotide reductase suggested previously (Lin, A.-N. I., Ashley, G. W., and Stubbe, J. (1987) Biochemistry 26, 6905-6909).     

NAD-binding mode and the significance of intersubunit contact revealed by the crystal structure of Mycobacterium tuberculosis NAD kinase-NAD complex

NAD kinase is a key enzyme in NADP biosynthesis. We solved the crystal structure of polyphosphate/ATP-NAD kinase from Mycobacterium tuberculosis (Ppnk) complexed with NAD (Ppnk-NAD) at 2.6A resolution using apo-Ppnk structure solved in this work, and revealed the details of the structure and NAD-binding site. Superimposition of tertiary structures of apo-Ppnk and Ppnk-NAD demonstrated a substantial conformational difference in a loop (Ppnk-flexible loop). As a quaternary structure, these Ppnk structures exhibited tetramer as in solution condition. Notably, the Ppnk-flexible loop was involved in the intersubunit contact and probably related to the NAD-binding of the other subunit. Furthermore, the two residues (Asp189, His226) substantially contributed to creating NAD-binding site on the other subunit. The two residues and the residues involved in NAD-binding were conserved. However, residues corresponding to the Ppnk-flexible loop were not conserved, making us to speculate that the Ppnk-flexible loop may be Ppnk-specific.     

Role of cysteine 41 of the A subunit of pertussis toxin

The 2 cysteine residues present in the A subunit of pertussis toxin form a disulfide bond in the conformation of the toxin secreted from the bacteria. Previous studies have shown that reduction of this bond is necessary for activation of the enzyme. We have found that reduction of this bond also alters the conformation of the A subunit such that it no longer readily associates with the B oligomer of the toxin, a finding which may have implications concerning the form of the toxin found within the eukaryotic cell. In addition, we have demonstrated that reduction of the disulfide bond of the purified A subunit followed by treatment with sulfhydryl-modifying reagents such as N-ethylmaleimide or 5,5'-dithiobis-(2-nitrobenzoic acid) results in inhibition of the NAD glycohydrolase activity of the protein. When a tryptic fragment of the A subunit which contains only 1 of the cysteine residues (Cys-41) of the native protein was reacted with N-ethylmaleimide, the NAD glycohydrolase activity of this fragment was substantially reduced. These data indicate that Cys-41 may be in a region of the molecule which is critical for the enzymatic activity of the toxin.     

The alpha subunit of tryptophan synthase. Evidence that aspartic acid 60 is a catalytic residue and that the double alteration of residues 175 and 211 in a second-site revertant restores the proper geometry of the substrate binding site

Our studies, which are aimed at understanding the catalytic mechanism of the alpha subunit of tryptophan synthase from Salmonella typhimurium, use site-directed mutagenesis to explore the functional roles of aspartic acid 60, tyrosine 175, and glycine 211. These residues are located close to the substrate binding site of the alpha subunit in the three-dimensional structure of the tryptophan synthase alpha 2 beta 2 complex. Our finding that replacement of aspartic acid 60 by asparagine, alanine, or tyrosine results in complete loss of activity in the reaction catalyzed by the alpha subunit supports a catalytic role for aspartic acid 60. Since the mutant form with glutamic acid at position 60 has partial activity, glutamic acid 60 may serve as an alternative catalytic base. The mutant form in which tyrosine 175 is replaced by phenylalanine has substantial activity; thus the phenolic hydroxyl of tyrosine 175 is not essential for catalysis or substrate binding. Yanofsky and colleagues have identified many missense mutant forms of the alpha subunit of tryptophan synthase from Escherichia coli. Two of these inactive mutant forms had either tyrosine 175 replaced by cysteine or glycine 211 replaced by glutamic acid. Surprisingly, a second-site revertant which contained both of these amino acid changes was partially active. These results indicated that the second mutation must compensate in some way for the first. We now extend the studies of the effects of specific amino acid replacements at positions 175 and 211 by two techniques: 1) characterization of several mutant forms of the alpha subunit from S. typhimurium prepared by site-directed mutagenesis and 2) computer graphics modeling of the substrate binding site of the alpha subunit using the x-ray coordinates of the wild type alpha 2 beta 2 complex from S. typhimurium. We conclude that the restoration of alpha subunit activity in the doubly altered second-site revertant results from restoration of the proper geometry of the substrate binding site.     

Crystal structure of UDP-galactose 4-epimerase from the hyperthermophilic archaeon Pyrobaculum calidifontis

The crystal structure of a highly thermostable UDP-galactose 4-epimerase (GalE) from the hyperthermophilic archaeon Pyrobaculum calidifontis was determined at a resolution of 1.8 Å. The asymmetric unit contained one subunit, and the functional dimer was generated by a crystallographic two-fold axis. Each monomer consisted of a Rossmann-fold domain with NAD bound and a carboxyl terminal domain. The overall structure of P. calidifontis GalE showed significant similarity to the structures of the GalEs from Escherichia coli, human and Trypanosoma brucei. However, the sizes of several surface loops were markedly smaller in P. calidifontis GalE than the corresponding loops in the other enzymes. Structural comparison revealed that the presence of an extensive hydrophobic interaction at the subunit interface is likely the main factor contributing to the hyperthermostability of the P. calidifontis enzyme. Within the NAD-binding site of P. calidifontis GalE, a loop (NAD-binding loop) tightly holds the adenine ribose moiety of NAD. Moreover, a deletion mutant lacking this loop bound NAD in a loose, reversible manner. Thus the presence of the NAD-binding loop in GalE is largely responsible for preventing the release of the cofactor from the holoenzyme.     

Alteration of aspartate 101 in the active site of Escherichia coli alkaline phosphatase enhances the catalytic activity

The function of aspartic acid residue 101 in the active site of Escherichia coli alkaline phosphatase was investigated by site-specific mutagenesis. A mutant version of alkaline phosphatase was constructed with alanine in place of aspartic acid at position 101. When kinetic measurements are carried out in the presence of a phosphate acceptor, 1.0 M Tris, pH 8.0, both the kcat and the Km for the mutant enzyme increase by approximately 2-fold, resulting in almost no change in the kcat/Km ratio. Under conditions of no external phosphate acceptor and pH 8.0, both the kcat and the Km for the mutant enzyme decrease by approximately 2-fold, again resulting in almost no change in the kcat/Km ratio. The kcat for the hydrolysis of 4-methyl-umbelliferyl phosphate and p-nitrophenyl phosphate are nearly identical for both the wild-type and mutant enzymes, as is the Ki for inorganic phosphate. The replacement of aspartic acid 101 by alanine does have a significant effect on the activity of the enzyme as a function of pH, especially in the presence of a phosphate acceptor. At pH 9.4 the mutant enzyme exhibits 3-fold higher activity than the wild-type. The mutant enzyme also exhibits a substantial decrease in thermal stability: it is half inactivated by treatment at 49 degrees C for 15 min compared to 71 degrees C for the wild-type enzyme. The data reported here suggest that this amino acid substitution alters the rates of steps after the formation of the phospho-enzyme intermediate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activation of aspartase by site-directed mutagenesis

To elucidate the role of sulfhydryl groups in the enzymatic reaction of the aspartase from Escherichia coli, we used site-directed mutagenesis which showed that the enzyme was activated by replacement of Cys-430 with a tryptophan. This mutation produced functional alterations without appreciable structural change: The kcat values became 3-fold at pH 6.0; the Hill coefficient values became higher under both pH conditions; the dependence of enzyme activity on divalent metal ions increased; and hydroxylamine, a good substrate for the wild-type enzyme, proved a poor substrate for the mutant.     

Role of cysteine residues in glutathione synthetase from Escherichia coli B. Chemical modification and oligonucleotide site-directed mutagenesis

Escherichia coli B glutathione synthetase is composed of four identical subunits; each subunit contains 4 cysteine residues (Cys-122, -195, -222, and -289). We constructed seven different mutant enzymes containing 3, 2, or no cysteine residues/subunit by replacement of cysteine codons with those of alanine in the gsh II gene using site-directed mutagenesis. Three mutant enzymes, Ala289, Ala222/289, Cys-free (Ala122/195/222/289), in which cysteine at residue 289 was replaced with alanine, were not inactivated by 5,5'-dithiobis(2-nitrobenzoate) (DTNB), while the other four mutants retaining Cys-289 were inactivated at the wild-type rate. From these selective inactivations of mutant enzymes by DTNB, the sulfhydryl group modified by DTNB was unambiguously identified as Cys-289. In this way, Cys-289 was found to be also a target of modification with 2-nitrothiocyanobenzoate and N-ethylmaleimide, while Cys-195 was of p-chloromercuribenzoate. These results suggest that both Cys-195 and Cys-289 were not essential for the activity of the glutathione synthetase, but chemical modification of either one of the two sulfhydryl groups resulted in complete loss of the activity. Replacement of Cys-122 to Ala-122 enhanced the reactivity of Cys-289 with sulfhydryl reagents.     

Site-specific alteration of cysteine 176 and cysteine 234 in the lactose carrier of Escherichia coli

In the present study, Cys-176 and Cys-234 in the lactose carrier have been modified to serine residues via site-specific mutagenesis. The resultant mutants have been characterized with regard to galactoside transport activity and sulfhydryl reagent sensitivity. The mutant proteins (in which Cys-176 or Cys-234 had been replaced with serine) are able to effectively transport galactosides, although the transport rates for lactose and methyl-beta-D-galactopyranoside are slightly reduced compared to the normal lactose carrier. In addition, both mutants are less sensitive than the wild-type to high concentrations of two different sulfhydryl reagents, N-ethylmaleimide and p-hydroxymercuribenzoate. Overall, the data are consistent with the idea that Cys-176 and Cys-234 are close to the substrate recognition site. However, neither residue appears to be essential for galactoside transport by providing an ionizable group near the active site or by forming a disulfide bond.     

Effects of lysine-to-glycine mutations in the ATP-binding consensus sequences in the AddA and AddB subunits on the Bacillus subtilis AddAB enzyme activities.

The N-terminal regions of both subunits AddA and AddB of the Bacillus subtilis AddAB enzyme contain amino acid sequences, designated motif I, which are commonly found in ATP-binding enzymes. The functional significance of the motif I regions was studied by replacing the highly conserved lysine residues of the regions in both subunits by glycines and by examination of the resulting mutant enzymes with respect to their enzymatic properties. This study shows that the mutation in subunit AddB hardly affected the ATPase, helicase, and exonuclease activities of the AddAB enzyme. However, the mutation in subunit AddA drastically reduced these activities, as well as the kcat for ATP hydrolysis. The apparent Km for ATP in ATP hydrolysis did not significantly deviate from that of the wild-type enzyme. These results suggest that the lysine residue in motif I of subunit AddA of the AddAB enzyme is not essential for the binding of the nucleotide but has a role in ATP hydrolysis, which is required for the exonuclease and helicase activities of the enzyme.     

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.     

Aldehyde dehydrogenases: widespread structural and functional diversity within a shared framework.

Sequences of 16 NAD and/or NADP-linked aldehyde oxidoreductases are aligned, including representative examples of all aldehyde dehydrogenase forms with wide substrate preferences as well as additional types with distinct specificities for certain metabolic aldehyde intermediates, particularly semialdehydes, yielding pairwise identities from 15 to 83%. Eleven of 23 invariant residues are glycine and three are proline, indicating evolutionary restraint against alteration of peptide chain-bending points. Additionally, another 66 positions show high conservation of residue type, mostly hydrophobic residues. Ten of these occur in predicted beta-strands, suggesting important interior-packing interactions. A single invariant cysteine residue is found, further supporting its catalytic role. A previously identified essential glutamic acid residue is conserved in all but methyl malonyl semialdehyde dehydrogenase, which may relate to formation by that enzyme of a CoA ester as a product rather than a free carboxylate species. Earlier, similarity to a GXGXXG segment expected in the NAD-binding site was noted from alignments with fewer sequences. The same region continues to be indicated, although now only the first glycine residue is strictly conserved and the second (usually threonine) is not present at all, suggesting greater variance in coenzyme-binding interactions.     

Role of Cys-295 on subunit interactions and allosteric regulation of phosphofructokinase-2 from Escherichia coli

In a previous work, chemical modification of Cys-238 of Escherichia coli Pfk-2 raised concerns on the importance of the dimeric state of Pfk-2 for enzyme activity, whereas modification of Cys-295 impaired the enzymatic activity and the MgATP-induced tetramerization of the enzyme. The results presented here demonstrate that the dimeric state of Pfk-2 is critical for the stability and the activity of the enzyme. The replacement of Cys-238 by either Ala or Phe shows no effect on the kinetic parameters, allosteric inhibition, dimer stability and oligomeric structure of Pfk-2. However, the mutation of Cys-295 by either Ala or Phe provokes a decrease in the k(cat) value and an increment in the K(m) values for both substrates. We suggest that the Cys-295 residue participates in intersubunit interactions in the tetramer since the Cys-295-Phe mutant exhibits higher tetramer stability, which in turn results in an increase in the fructose-6-P concentration required for the reversal of the MgATP inhibition relative to the wild type enzyme.     

Chemical modification of 3 alpha,20 beta-hydroxysteroid dehydrogenase with diethyl pyrocarbonate. Evidence for an essential, highly reactive, lysyl residue

Diethyl pyrocarbonate inactivated the tetrameric 3 alpha,20 beta-hydroxysteroid dehydrogenase with second-order rate constants of 1.63 M-1 s-1 at pH 6 and 25 degrees C or 190 M-1 s-1 at pH 9.4 and 25 degrees C. The activity was slowly and partially restored by incubation with hydroxylamine (81% reactivation after 28 h with 0.1 M hydroxylamine, pH 9, 25 degrees C). NADH protected the enzyme against inactivation with a Kd (10 microM) very close to the Km (7 microM) for the coenzyme. The ultraviolet difference spectrum of inactivated vs. native enzyme indicated that a single histidyl residue per enzyme subunit was modified by diethyl pyrocarbonate, with a second-order rate constant of 1.8 M-1 s-1 at pH 6 and 25 degrees C. The histidyl residue, however, was not essential for activity because in the presence of NADH it was modified without enzyme inactivation and modification of inactivated enzyme was rapidly reversed by hydroxylamine without concomitant reactivation. Progesterone, in the presence of NAD+, protected the histidyl residue against modification, and this suggests that the residue is located in or near the steroid binding site of the enzyme. Diethyl pyrocarbonate also modified, with unusually high reaction rate, one lysyl residue per enzyme subunit, as demonstrated by dinitrophenylation experiments carried out on the treated enzyme. The correlation between inactivation and modification of lysyl residues at different pHs and the protection by NADH against both inactivation and modification of lysyl residues indicate that this residue is essential for activity and is located in or near the NADH binding site of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)