Kinetic studies on ribosomal peptidyltransferase. The behaviour of the inhibitor blasticidin S

In a cell-free system derived from Escherichia coli, the reaction between Ac[3H]Phe-tRNA and puromycin (S) is inhibited by blasticidin S (I). In this reaction Ac[3H]Phe-tRNA is part of the Ac[3H]Phe-tRNA--poly(U)--ribosome complex (C). After preincubating the complex C with I and then adding S, the degree of inhibition is greater than that observed when C reacts with a mixture of S and I. Without preincubation, the inhibition is competitive giving a Ki of 2 X 10(-7) M. After preincubation the inhibition becomes of the mixed non-competitive type. A first-order kinetic analysis of the reaction between C and excess S, in the presence or in the absence of I, with or without preincubation, suggests that I acts as a modifier decreasing the catalytic rate constant of ribosomal peptidyltransferase (the putative enzyme that catalyzes the reaction between C and S). The effectiveness of I cannot be expressed by an equilibrium constant such as the above-mentioned Ki. A model is proposed which explains the results obtained. In this model, in the presence of I, C is converted to a modified species C, which is still able to react with S but with a lower catalytic rate constant. This is a novel concept, in which the ribosome can be subjected to modulation of its activity by small ligands. It can be useful in studies on translational control of protein synthesis.     

Kinetics of inhibition of peptide bond formation on bacterial ribosomes.

A cell-free system derived from Escherichia coli has been used in order to study the kinetics of inhibition of peptide bond formation with the aid of the puromycin reaction in solution. A similar study has been carried out earlier on a solid support matrix with the same inhibitors. We find that the overall pattern of the kinetics of inhibition is the same in the two systems. At low concentrations of inhibitor there is a competitive phase of inhibition, whereas at higher concentrations of inhibitor the type of inhibition becomes mixed noncompetitive. The values of Ki of the competitive phase in the system in solution are: 5.8 microM (amicetin), 0.2 microM (blasticidin S), 0.5 microM (chloramphenicol), and 0.5 microM (tevenel). The inhibitors amicetin, blasticidin S, and tevenel interact with the ribosome in a reaction which is slower than that of the substrate puromycin, showing clear-cut characteristics of slow-onset inhibition in both systems. Chloramphenicol, on the other hand does not easily show such a delay in solution. It interacts with the ribosome relatively faster than the other three antibiotics. Despite this, chloramphenicol too shows characteristics of time-dependent inhibition.     

Kinetics of inhibition of ribonuclease P activity by peptidyltransferase inhibitors – Effect of antibiotics on RNase P

A cell-free system derived from Dictyostelium discoideum has been used to study the kinetics of inhibition of RNase P by puromycin, amicetin and blasticidin S. Detailed kinetic analysis showed that the type of inhibition of RNase P activity by puromycin is simple competitive, whereas the type of inhibition by amicetin and blasticidin S is simple non-competitive. On the basis of K_i values amicetin is stronger inhibitor than puromycin and blasticidin S.     

Slow-onset inhibition of ribosomal peptidyltransferase by lincomycin.

In a system derived from Escherichia coli, we carried out a detailed kinetic analysis of the inhibition of the puromycin reaction by lincomycin. N-Acetylphenylalanyl-tRNA (Ac-Phe-tRNA; the donor) reacts with excess puromycin (S) according to reaction [1], C+S Ks <--> CS k3 --> C'+P, where C is the Ac-Phe-tRNA-poly(U)-ribosome ternary complex (complex C). The entire course of reaction [1] appears as a straight line when the reaction is analyzed as pseudo-first-order and the data are plotted in a logarithmic form (logarithmic time plot). The slope of this straight line gives the apparent ksobs = k3[S]/(Ks + [S]). In the presence of lincomycin the logarithmic time plot is not a straight line, but becomes biphasic, giving an early slope (ke = k3[S]/(Ks(1 + [I]/Ki) + [S])) and a late slope (k1 = k3[S]/(Ks(1 + [I]/K'i + [S])). Kinetic analysis of the early slopes at various concentrations of S and I shows competitive inhibition with Ki = 10.0 microM. The late slopes also give competitive inhibition with a distinct inhibition constant K'i = 2.0 microM. Excluding alternative models, the two phases of inhibition are compatible with a model in which reaction [1] is coupled with reaction [2], C+I k4 <--> k5 CI k6 <--> k7 C*I, where the isomerization step CI <--> CI* is slower than the first step C+I <--> CI, Ki = k5/k4 and K'i = Ki [k7/(k6 + k7)]. Corroborative evidence for this model comes from the examination of reaction [2] alone in the absence of S. This reaction is analyzed as pseudo-first-order going toward equilibrium with kIeq = k7 + (k6 [I]/(Ki + [I])). The plot of kIeq versus [I] is not linear. This plot supports the two-step mechanism of reaction [2] in which k6 = 5.2 min-1 and k7 = 1.3 min-1. This is the first example of slow-onset inhibition of ribosomal peptidyltransferase which follows a simple model leading to the determination of the isomerization constants k6 and k7. We suggest that lincomycin inhibits protein synthesis by binding initially to the ribosome in competition with aminoacyl-tRNA. Subsequently, as a result of a conformational change, an isomerization occurs (CI <--> C*I), after which lincomycin continues to interfere with the binding of aminoacyl-tRNA to the isomerized complex.     

Time-dependent inhibition of isoprenylcysteine carboxyl methyltransferase by indole-based small molecules

Isoprenylcysteine carboxyl methyltransferase (Icmt) catalyzes the methylation of the C-terminal prenylcysteine found on prenylated proteins. Numerous studies have shown that the methylation step is important for the correct localization and function of many prenylated proteins, most notably GTPases in the Ras superfamily. We recently reported identification of a small molecule derived from an indole core as a potent, cell-active inhibitor of Icmt whose potency was increased upon preincubation with the enzyme [Winter-Vann, A. M., Baron, R. A., et al. (2005) Proc. Natl. Acad. Sci. U.S.A. 102 (12), 4336-41]. In the study presented here, we performed a kinetic characterization of this time-dependent inhibition of Icmt by 2-[5-(3-methylphenyl)-1-octyl-1H-indol-3-yl]acetamide (cysmethynil). These analyses revealed that cysmethynil is a competitive inhibitor with respect to the isoprenylated cysteine substrate and a noncompetitive inhibitor with respect to AdoMet, the methyl donor in the reaction. The Ki of cysmethynil for Icmt, which represents the dissociation constant of the initial complex with the enzyme, was 2.39 +/- 0.02 microM, and the Ki*, which is the overall dissociation constant of the inhibitor for the final complex, was 0.14 +/- 0.01 microM. The first-order rate constant for the conversion of the initial enzyme-inhibitor complex to the final high-affinity complex was 0.87 +/- 0.06 min-1, and that for the reverse process was 0.053 +/- 0.003 min-1; the latter rate constant corresponds to a half-life for the high-affinity complex of 15 min. Structure-activity relationships of a number of closely related indole compounds revealed that the hydrophobicity of the substituent on the nitrogen of the indole core was responsible for the manifestation of time-dependent inhibition. These findings markedly enhance our understanding of the mechanism of inhibition of Icmt by this indole class of compounds and should facilitate ongoing efforts to assess the potential of targeting this enzyme in anticancer drug design.     

Kinetic characterization of the pyruvate and oxoglutarate dehydrogenase complexes from human heart

The Michaelis constant values for the highly purified pyruvate dehydrogenase complex (PDC) from human heart are 25, 13 and 50 microM for pyruvate, CoA and NAD, respectively. Acetyl-CoA produces a competitive inhibition of PDC (Ki = 35 microM) with respect to CoA, whereas NADH produces the same type of inhibition with respect to NAD (Ki = 36 microM). The oxoglutarate dehydrogenase complex (OGDC) from human heart has active sites with two different affinities for 2-oxoglutarate ([S]0.5 of 30 and 120 microM). ADP (1 mM) decreases the [S]0.5 values by a half. The inhibition of OGDC (Ki = 81 microM) by succinyl-CoA is of a competitive type with respect to CoA (Km = 2.5 microM), whereas that of NADH (Ki = 25 microM) is of a mixed type with respect to NAD (Km = 170 microM).     

Inactivation of delta 5-3-oxo steroid isomerase with active-site-directed acetylenic steroids.

Several steroid analogues containing conjugated acetylenic ketone groups as part of a seco-ring structure or as substituents on the intact steroid system are irreversible inhibitors of delta 5-3-oxo steroid isomerase (EC 5.3.3.1) from Pseudomonas testosteroni. Thus 10 beta-(1-oxoprop-2-ynyl)oestr-4-ene-3,17-dione (I), 5,10-seco-oestr-4-yne-3,10,17-trione (II), 17 beta-hydroxy-5,10-seco-oestr-4-yne-3,10-dione (III) and 17 beta-(1-oxoprop-2-ynyl)androst-4-en-3-one (IV) irreversibly inactivate isomerase in a time-dependent manner. In all cases saturation kinetics are observed. Protection against inactivation is afforded by the powerful competitive inhibitor 19-nortestosterone. The inhibition constants (Ki) for 19-nortestosterone obtained from such experiments are in good agreement with those determined from conventional competitive-inhibition studies of enzyme activity. These compounds thus appear to be active-site directed. In every case the inactivated enzyme could be dialysed without return of activity, indicating that a stable covalent bond probably had formed between the steroid and enzyme. Compound (I) is a very potent inhibitor of isomerase [Ki = 66.0 microM and k+2 = 12.5 x 10(-3) s-1 (where Ki is the dissociation constant of the reversible enzyme-inhibitor complex and k+2 is the rate constant for the inactivation reaction of the enzyme-inhibitor complex)] giving half-lives of inactivation of 30-45 s at saturation. It is argued that the basic-amino-acid residue that abstracts the intramolecularly transferred 4 beta-proton in the reaction mechanism could form a Michael-addition product with compound (I). In contrast, although compound (IV) has a lower inhibition constant (Ki = 14.5 microM), it is a relatively poor alkylating agent (k+2 = 0.13 x 10(-3) s-1). If the conjugated acetylenic ketone groups are replaced by alpha-hydroxyacetylene groups, the resultant analogues of steroids (I)-(IV) are reversible competitive inhibitors with Ki values in the range 27-350 microM. The enzyme binds steroids in the C19 series with functionalized acetylenic substituents at C-17 in preference to steroids in the C18 series bearing similar groups in the ring structure or as C-10 substituents. In the 5,10-seco-steroid series the presence of hydroxy groups at both C-3 and C-17 is deleterious to binding by the enzyme.     

Inhibition of soybean lipoxygenase and mouse skin tumor promotion by onion and garlic components

Onion and garlic essential oils were previously shown to inhibit mouse skin tumor promotion, as were the enzymes, lipoxygenase, and cyclooxygenase. In the present study, the inhibition of soybean lipoxygenase (EC 1.13.11.12) by onion and garlic components and related compounds was investigated. The IC50 values as well as the kinetic inhibition constants were determined for the most active compounds. Di-(1-propenyl) sulfide, an analog of the substrate moiety required for oxygenase action, was the only irreversible inhibitor observed with Ki = 59 microM and k3 = 0.53/min. Inhibition in the presence of substrate was uncompetitive at 88 and 132 microM linoleic acid with Ki = 129 microM. At 173 microM linoleic acid, however, inhibition was competitive with Ki = 66 microM. Dially trisulfide, allyl methyl trisulfide, and diallyl disulfide were competitive inhibitors, while 1-propenylpropyl sulfide and (E, Z)-4,5,9-trithiadodeca-1,6,11-triene 9-oxide (ajoene) were mixed inhibitors. Nordihydroguaiaretic acid (NDGA), the most potent lipoxygenase inhibitor, was a competitive inhibitor with Ki = 0.29 microM. The results indicate a relative potency of inhibition for structural features in the following order: di(1-propenyl) sulfide greater than an alkenyl trisulfide greater than an alkenyl disulfide. Di(n-propyl) disulfide, a major onion oil component, inhibited neither lipoxygenase nor promotion. Di(1-propenyl) sulfide and ajoene inhibited both. This suggests that the inhibition of lipoxygenase may be involved in antipromotion.     

Kinetic characterization of the rotenone-insensitive internal NADH: ubiquinone oxidoreductase of mitochondria from Saccharomyces cerevisiae

Saccharomyces cerevisiae mitochondria contain an NADH:Q6 oxidoreductase (internal NADH dehydrogenase) encoded by NDI1 gene in chromosome XIII. This enzyme catalyzes the transfer of electrons from NADH to ubiquinone without the translocation of protons across the membrane. From a structural point of view, the mature enzyme has a single subunit of 53 kDa with FAD as the only prosthetic group. Due to the fact that S. cerevisiae cells lack complex I, the expression of this protein is essential for cell growth under respiratory conditions. The results reported in this work show that the internal NADH dehydrogenase follows a ping-pong mechanism, with a Km for NADH of 9.4 microM and a Km for oxidized 2,6-dichorophenolindophenol (DCPIP) of 6.2 microM. NAD+, one of the products of the reaction, did not inhibit the enzyme while the other product, reduced DCPIP, inhibited the enzyme with a Ki of 11.5 microM. Two dead-end inhibitors, AMP and flavone, were used to further characterize the kinetic mechanism of the enzyme. AMP was a linear competitive inhibitor of NADH (Ki = 5.5 mM) and a linear uncompetitive inhibitor of oxidized DCPIP (Ki = 11.5 mM), in agreement with the ping-pong mechanism. On the other hand, flavone was a partial inhibitor displaying a hyperbolic uncompetitive inhibition regarding NADH, and a hyperbolic noncompetitive inhibition with respect to oxidized DCPIP. The apparent intercept inhibition constant (Kii = 5.4 microM) and the slope inhibition constant (Kis = 7.1 microM) were obtained by non linear regression analysis. The results indicate that the ternary complex F-DCPIPox-flavone catalyzes the reduction of DCPIP, although with lower efficiency. The effect of pH on Vmax was studied. The Vmax profile shows two groups with pKa values of 5.3 and 7.2 involved in the catalytic process.     

Propyl gallate inhibition of iodide and tetramethylbenzidine oxidation catalyzed by human thyroid peroxidase

The kinetic characteristics (kcat, Km, and their ratio) for oxidation of iodide (I-) at 25 degrees C in 0.2 M acetate buffer, pH 5.2, and tetramethylbenzidine (TMB) at 20 degrees C in 0.05 M phosphate buffer, pH 6.0, with 10% DMF catalyzed by human thyroid peroxidase (HTP) and horseradish peroxidase (HRP) were determined. The catalytic activity of HRP in I- oxidation was about 20-fold higher than that of HTP. The kcat/Km ratio reflecting HTP efficiency was 35-fold higher in TMB oxidation than that in I- oxidation. Propyl gallate (PG) effectively inhibited all four peroxidase processes and its effects were characterized in terms of inhibition constants Ki and the inhibitor stoichiometric coefficient f. For both peroxidases, inhibition of I- oxidation by PG was characterized by mixed-type inhibition; Ki for HTP was 0.93 microM at 25 degrees C. However, in the case of TMB oxidation the mixed-type inhibition by PG was observed only with HTP (Ki = 3.9 microM at 20 degrees C), whereas for HRP it acted as a competitive inhibitor (Ki = 42 microM at 20 degrees C). A general scheme of inhibition of iodide peroxidation containing both enzymatic and non-enzymatic stages is proposed and discussed.     

Mechanism for slow-binding inhibition of human leukocyte elastase by valine-derived benzoxazinones

Valine-derived benzoxazinones have been synthesized and found to be competitive, slow-binding inhibitors of human leukocyte elastase (HLE). Steady-state inhibition constants Ki are dependent on aryl substitution and reach a maximum of potency of 0.5 nM with the 5-Cl compound 6. UV-spectral data for the interaction of HLE and the unsubstituted inhibitor 3 indicate that the stable complex formed between enzyme and inhibitor is an acyl-enzyme that can either undergo ring closure, to reform intact benzoxazinone, or hydrolysis, to liberate an N-acylanthranilic acid. "Burst" kinetic data, derived from the direct observation of the interaction of HLE and 3, are consistent with results of the inhibition of catalysis experiments.     

Interaction of pseudomonic acid A with Escherichia coli B isoleucyl-tRNA synthetase.

Sodium pseudomonate was shown to be a powerful competitive inhibitor of Escherichia coli B isoleucyl-tRNA synthetase (Ile-tRNA synthetase). The antibiotic competitively inhibits (Ki 6 nM; cf. Km 6.3 microM), with respect top isoleucine, the formation of the enzyme . Ile approximately AMP complex as measured by the pyrophosphate-exchange reaction, and has no effect on the transfer of [14C]isoleucine from the enzyme . [14C]Ile approximately AMP complex to tRNAIle. The inhibitory constant for the pyrophosphate-exchange reaction was of the same order as that determined for the inhibition of the overall aminoacylation reaction (Ki 2.5 nM; cf. Km 11.1 microM). Sodium [9'-3H]pseudomonate forms a stable complex with Ile-tRNA synthetase. Gel-filtration and gel-electrophoresis studies showed that the antibiotic is only fully released from the complex by 5 M-urea treatment or boiling in 0.1% sodium dodecyl sulphate. The molar binding ratio of sodium [9'-3H]pseudomonate to Ile-tRNA synthetase was found to be 0.85:1 by equilibrium dialysis. Aminoacylation of yeast tRNAIle by rat liver Ile-tRNA synthetase was also competitively inhibited with respect to isoleucine, Ki 20 microM (cf. Km 5.4 microM). The Km values for the rat liver and E. coli B enzymes were of the same order, but the Ki for the rat liver enzyme was 8000 times the Ki for the E. coli B enzyme. This presumably explains the low toxicity of the antibiotic in mammals.     

Inhibition of mammalian collagenases by thiol-containing peptides

The following thiol-containing peptide analogues of the carboxyl side of the collagenase-sensitive bond of collagen were synthesized and tested as inhibitors of collagenases partially purified from homogenates of rabbit V-2 tumor and culture medium of pig synovium: HSCH2CH(CH3)CO-Ala-OEt (I), HSCH2CH(CH2Ph)CO-Ala-OEt (II), HSCH2CH[CH2CH(CH3)2]CO-Ala-OEt (III); HSCH2 CH-[CH2CH(CH3)2]CO-Ala-Gly-OEt (IV); HSCH2CH[CH2CH(CH3)2]CO-Ala-Gly-Gln (V). The compounds are listed in order of their inhibitory potency when assayed with nonfibrillar-acid-soluble calf skin collagen at pH 7.6, 35 degrees C. The best inhibitor (III) gave 50% inhibition between 1 and 4 microM. II was a competitive inhibitor with a Ki value of 75 microM. The enzymes preferred an isobutyl side chain at the 2-carbon position, and, where tested (III, IV), did not discriminate strongly between stereoisomers at the chiral 2-carbon. Increasing the length of the inhibitor did not markedly increase potency.     

Calculation of inhibitor Ki and inhibitor type from the concentration of inhibitor for 50% inhibition for Michaelis-Menten enzymes

The use of I50 (concentration of inhibitor required for 50% inhibition) for enzyme or drug studies has the disadvantage of not allowing easy comparison among data from different laboratories or under different substrate conditions. Modifications of the Michaelis-Menten equation for treatment of inhibitors can allow both the determination of the type of inhibition (competitive, noncompetitive, and uncompetitive) and the Ki for the inhibitor. For competitive and uncompetitive inhibitors when the assay conditions are [S] = Km, then Ki = I50/2. For different conditions of [S] there is a divergence between competitive and uncompetitive inhibitors that may be used to identify the type of inhibitor. The equation for Ki also differs. For noncompetitive inhibitors the Ki = I50 and this relationship is valid with changing [S]. The equations developed require a single substrate, reversible-type inhibitors, and kinetics of the Michaelis-Menten type. Examples of the use of the equations are illustrated with experimental data from scientific publications.     

On porcine pancreatic alpha-amylase action: kinetic evidence for the binding of two maltooligosaccharide molecules (maltose, maltotriose and o-nitrophenylmaltoside) by inhibition studies. Correlation with the five-subsite energy profile

Hydrolysis of small substrates (maltose, maltotriose and o-nitrophenylmaltoside) catalysed by porcine pancreatic alpha-amylase was studied from a kinetic viewpoint over a wide range of substrate concentrations. Non-linear double-reciprocal plots are obtained at high maltose, maltotriose and o-nitrophenylmaltoside concentrations indicating typical substrate inhibition. These results are consistent with the successive binding of two molecules of substrate per enzyme molecule with dissociation constants Ks1 and Ks2. The Hill plot, log [v/(V-v)] versus log [S], is clearly biphasic and allows the dissociation constants of the ES1 and ES2 complexes to be calculated. Maltose and maltotriose are inhibitors of the amylase-catalysed amylose and o-nitrophenylmaltoside hydrolysis. The inhibition is of the competitive type. The (apparent) inhibition constant Kiapp varies with the inhibitor concentration. These results are also consistent with the successive binding of at least two molecules of maltose or maltotriose per amylase molecule with the dissociation constants Ki1 and Ki2. These inhibition studies show that small substrates and large polymeric ones are hydrolysed at the same catalytic site(s). The values of the dissociation constants Ks1 and Ki1 of the maltose-amylase complexes are identical. According to the five-subsite energy profile previously determined, at low concentration, maltose (as substrate and as inhibitor) binds to the same two sites (4,5) or (3,4), maltotriose (as substrate and as inhibitor) and o-nitrophenyl-maltoside (as substrate) bind to the same three subsites (3,4,5). The dissociation constants Ks2 and Ki2 determined at high substrate and inhibitor concentration are consistent with the binding of the second ligand molecule at a single subsite. The binding mode of the second molecule of maltose (substrate) and o-nitrophenylmaltoside remains uncertain, very likely because of the inaccuracy due to simplifications in the calculations of the subsite binding energies. No binding site(s) outside the catalytic one has been taken into account in this model.     

Effect of peptidyltransferase inhibitors on ribonuclease P activity from Dictyostelium discoideum – Effect of antibiotics on RNase P

The effect of several peptidyltransferase inhibitors on ribonuclease P activity from Dictyostelium discoideum was investigated. Among the inhibitors tested puromycin, amicetin and blasticidin S revealed a dose-dependent inhibition of tRNA maturation. Blasticidin S and amicetin do not compete with puromycin for the same site on the enzyme, suggesting the existence of distinct antibiotic binding sites on D. discoideum RNase P. Inhibition experiments further indicate that binding sites for blasticidin S and amicetin overlap.     

5'-Haloacetamido-5'-deoxythymidines: novel inhibitors of thymidylate synthase

5'-Bromoacetamido-5'-deoxythymidine (BAT), 5'-iodoacetamido-5'-deoxythymidine (IAT), 5'-chloroacetamido-5'-deoxythymidine (CAT) and [14C]BAT were synthesized and their interactions with thymidylate synthase purified from L1210 cells were investigated. The inhibitory effects of these compounds on thymidylate synthase were in the order BAT greater than IAT greater than CAT, which is in agreement with their cytotoxic effects in L1210 cells. In the presence of substrate during preincubation, the concentration required for 50% inhibition of the enzyme activity by these inhibitors was 4-8-fold higher than it was in the absence of dUMP. The I50 values for BAT were 1 X 10(-5) M and 1.2 X 10(-6) M in the presence and absence, respectively, of dUMP during preincubation. These results were in agreement with the observed inhibition of thymidylate synthase by BAT in intact L1210 cells. A Lineweaver-Burk plot revealed that BAT behaved as a competitive inhibitor. The Km for the enzyme was 9.2 microM, and the Ki determined for competitive inhibition by BAT was 5.4 microM. Formation of a tight, irreversible complex is inferred from the finding that BAT-inactivation of thymidylate synthase was not reversible on prolonged dialysis and that the enzyme-BAT complex was nondissociable by gel filtration through a Sephadex G-25 column or by TSK-125 column chromatography. Incubation of thymidylate synthase with BAT resulted in time-dependent, irreversible loss of enzyme activity by first-order kinetics. The rate constant for inactivation was 0.4 min-1, and the steady-state constant of inactivation, Ki, was estimated to be 6.6 microM. The 5'-haloacetamido-5'-deoxythymidines provide specific inhibitors of thymidylate synthase that may also serve as reagents for studying the enzyme mechanism.     

Carbonyl sulfide inhibition of CO dehydrogenase from Rhodospirillum rubrum

Carbonyl sulfide (COS) has been investigated as a rapid-equilibrium inhibitor of CO oxidation by the CO dehydrogenase purified from Rhodospirillum rubrum. The kinetic evidence suggests that the inhibition by COS is largely competitive versus CO (Ki = 2.3 microM) and uncompetitive versus methylviologen as electron acceptor (Ki = 15.8 microM). The data are compatible with a ping-pong mechanism for CO oxidation and COS inhibition. Unlike the substrate CO, COS does not reduce the iron-sulfur centers of dye-oxidized CO dehydrogenase and thus is not an alternative substrate for the enzyme. However, like CO, COS is capable of protecting CO dehydrogenase from slow-binding inhibition by cyanide. A true binding constant (KD) of 2.2 microM for COS has been derived on the basis of the saturable nature of COS protection against cyanide inhibition. The ability of CO, CO2, COS, and related CO/CO2 analogues to reverse cyanide inhibition of CO dehydrogenase is also demonstrated. The kinetic results are interpreted in terms of two binding sites for CO on CO dehydrogenase from R. rubrum.