Properties of detergent-solubilized and membranous (Ca2+ + Mg2+)-activated ATPase from sarcoplasmic reticulum as studied by sulfhydryl reactivity and ESR spectroscopy. Effect of protein-protein interactions

(1) Sulfhydryl reactivity and electron spin resonance spectra of nitroxide maleimide spin labels, covalently attached to sarcoplasmic reticulum ATPase, were examined on both detergent-solubilized and membranous material. Monomeric and oligomeric ATPases were prepared by the use of dodecyloctaethylene glycol monoether as a solubilizing detergent. (2) Immediately after solubilization, the reaction curve of nonomeric ATPase with 5,5'-dithiobis(2-nitrobenzoate) was characterized by positive cooperativity (S-shaped as a function of time). In contrast, the SH reactivity of both oligomeric and membranous ATPases obeyed usual first-order kinetics and could be analyzed in terms of three classes of reactive site. All enzymatically active ATPase preparations responded to addition of ADP with a decrease in SH reactivity. During enzymatic inactivation of monomeric ATPase, the SH-modification rate was dramatically enhanced with loss of cooperative features. Ca2+ removal from the high-affinity sites stimulated SH reactivity before inactivation had taken place. (3) ESR spectroscopy indicated less motional constraints on monomeric than on oligomeric and membranous ATPases. Arrhenius plots of ESR spectral parameters suggest a conformational transition in both membranous and solubilized ATPases at about 22 degrees C. The transition was also present in EGTA-, but not in heat-inactivated ATPase. Although SH reactivity of monomeric ATPase was dramatically enhanced by EGTA inactivation, the results of ESR, circular dichroism and analytical ultracentrifugation experiments indicate limited conformational changes induced by EGTA treatment. (4) The data indicate marked differences in the properties of monomeric ATPase on the one hand and oligomeric and membranous enzymes on the other hand. They are consistent with previous functional evidence for the presence of ATPase in an associated state in the membrane (M?ller, J.V., Lind, K.E. and Andersen, J.P. (1980) J. Biol. Chem. 255, 1912-1920).     

Oxidation of reactive sulfhydryl groups of sarcoplasmic reticulum ATPase

The role of reactive sulfhydryl groups of sarcoplasmic reticulum ATPase has been investigated. Incubation of ATPase with 17 mol o-iodosobenzoic acid per mol ATPase results in a 15% inhibition of Ca2+ uptake with only a 5% loss of ATPase activity. When ATPase is treated with 15 mol KMnO4 per mol ATPase, Ca2+ uptake is completely inhibited. From the measurement of remaining SH groups using 5,5'-dithiobis-(2-nitrobenzoic acid), it is found that the oxidation of approximately four SH groups per ATPase molecule with KMnO4 leads to a complete loss of Ca2+ uptake, while the oxidation of five SH groups per ATPase with o-iodosobenzoic acid results in only 15% inhibition of Ca2+ uptake. The results of amino acid analysis indicate that KMnO4 oxidizes the reactive SH groups to sulfonic acid groups. Among the five o-iodosobenzoic acid-reactive SH groups, at least one shows a distinct Ca2+ dependence. Addition of o-iodosobenzoic acid to the reaction medium containing KMnO4 does not increase the number of oxidized SH groups, indicating that both o-iodosobenzoic acid and KMnO4 oxidize the same SH groups of the enzyme. The different effects of two oxidizing agents on sarcoplasmic reticulum ATPase eliminate the possibility of direct involvement of SH group(s) in the ATPase reaction.     

Characterization of nitrite reductase from a denitrifier, Alcaligenes sp. NCIB 11015. A novel copper protein

Covalent cross-linking reaction between SH1 and SH2 groups in myosin subfragment-1 (S-1) by N,N'-p-phenylenedimaleimide (pPDM) was followed by the degree of inactivation of NH4+-EDTA ATPase activity. The rate of the cross-linking reaction decreased to less than a 20th in the presence of F-actin. The inhibitory effect of F-actin was not observed in the presence of MgATP. Binding of F-actin to S-1 was measured using ultracentrifugation. S-1 whose SH1 and SH2 were covalently cross-linked by pPDM or 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) did not bind F-actin. After the DTNB-cross-linked S-1 is reduced by dithiothreitol, the ability to bind F-actin is recovered. These results suggest that S-1 has a binding site for F-actin in the region between SH1 and SH2. This site appears to determine the high affinity of acto-S-1 complex at the rigor while decreasing the affinity more than 10(2) times in the presence of MgATP.     

Study of the modification of histidine residues, SH- and epsilon-NH2-groups of rat sarcoma-45 myosin by specific reagents

Modification of histidine residues, SH- and epsilon-NH2-groups of myosin from rat sarcoma-45 by specific reagents was studied. It was shown that diethylpyrocarbonate modifies histidine residues essential for the ATPase activity. A kinetic analysis of myosin epsilon-NH2-groups modification by 2,4,6-trinitrobenzene sulfonate revealed that myosin trinitrophenylation and its inactivation by Ca2(+)-ATPase occurs in two steps: a fast and a slow (Km = 2400 and 1.7 s-1 M-1, respectively). Two essential epsilon-NH2-groups of tumour myosin active sites react in the fast reaction. The relatively low concentrations of p-chloromercuribenzoic acid activate rat sarcoma-45 myosin Ca2(+)-ATPase and Mg2(+)-ATPase, whereas higher ones inhibit the enzyme. The data obtained suggest that two SH-groups, SH1 and SH2 are essential for the tumour myosin ATPase function.     

Studies on regulatory functions of malic enzymes. VII. Structural and functional characteristics of sulfhydryl groups in NADP-linked malic enzyme from Escherichia coli W.

NADP-linked malic enzyme from Escherichia coli W contains 7 cysteinyl residues per enzyme subunit. The reactivity of sulfhydryl (SH) groups of the enzyme was examined using several SH reagents, including 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) and N-ethylmaleimide (NEM). 1. Two SH groups in the native enzyme subunit reacted with DTNB (or NEM) with different reaction rates, accompanied by a complete loss of the enzyme activity. The second-order modification rate constant of the "fast SH group" with DTNB coincided with the second-order inactivation rate constant of the enzyme by the reagent, suggesting that modification of the "fast SH group" is responsible for the inactivation. When the enzyme was denatured in 4 M guanidine HCl, all the SH groups reacted with the two reagents. 2. Althoug the inactivation rate constant was increased by the addition of Mg2+, an essential cofactor in the enzyme reaction, the modification rate constant of the "fast SH group" was unaffected. The relationship between the number of SH groups modified with DTNB or NEM and the residual enzyme activity in the absence of Mg2+ was linear, whereas that in the presence of Mg2+ was concave-upwards. These results suggest that the Mg2+-dependent increase in the inactivation rate constant is not the result of an increase in the rate constant of the "fast FH group" modification. 3. The absorption spectrum of the enzyme in the ultraviolet region was changed by addition of Mg2+. The dissociation constant of the Mg2+-enzyme complex obtained from the Mg2+- dependent increment of the difference absorption coincided with that obtained from the Mg2+- dependent enhancement of NEM inactivation. 4. Both the inactivation rate constant and the modification rate constant of the "fast SH group" were decreased by the addition of NADP+. The protective effect of NADP+ was increased by the addition of Mg2+. Based on the above results, the effects of Mg2+ on the SH-group modification are discussed from the viewpoint of conformational alteration of the enzyme.     

Importance of SH groups in catalysis by bovine brain acid phosphatase.

The rate of inactivation of acid phosphatase (EC 3.1.3.2) from bovine brain by dithiobis-(2-nitrobenzoic acid) (Nbs2) is identical to the rate of titration of one of the two SH groups of this enzyme. The rate of inactivation of the enzyme by Nbs2 is pH dependent and, at 300 mM NaCl, can be described by the reaction of a single SH group of pK 8.4. At low ionic strength the pK determined from the k inactivation vs. pH profile is 7.7 and the results deviate markedly from the predicted values at pH values less than or equal to 6. The decrease of V upon addition of salts is paralleled by the decrease of inactivation rate by Nbs2. The relevance of SH groups in catalysis by bovine brain acid phosphatase is discussed in terms of these data.     

竹红菌甲素对红细胞膜上几种酶光敏失活作用的研究

Hypocrellin A (HA)-sensitized photoinactivation of enzymes in human erythrocyte membrane, including AchE, GPDH, Na(+)-K+ ATPase, Ca2(+)-Mg2+ ATPase were studied in this paper. The sensitivity of these four enzymes inactivated by HA and light are as following order: Ca2(+)-Mg2+ ATPase greater than Na(+)-K+ ATPase greater than GPDH greater than AchE. The relationship among ATPase inactivation, sulfhydryl photoinactivation and lipid peroxidation was also investigated. Results show that SH group photooxidation probably is one of the major reasons of enzyme inactivation whereas lipid peroxidation has little effect. The isolated GPDH was less sensitive than that membrane-bound, GSH, NAD acted protectively on GPDH and ATPase respectively. The evidence of electrophoresis and protein intrinsic fluorescence showed that protein structure did not change significantly even though most activity had lost in case of GPDH.     

Sulfhydryl group reactivity of adenosine 3',5'-monophosphate dependent protein kinase from bovine heart: a probe of holoenzyme structure.

The spectrophotometric titration of SH groups in adenosine 3',5'-monophosphate (cAMP) dependent protein kinase from bovine heart muscle with 5,5'-dithiobis(2-nitrobenzoic acid)(DTNB) is described. The holoenzyme (R2C2) contains 16 SH groups, 12 of which react with DTNB in the native enzyme. The SH groups are distributed 2 per catalytic (C) and 4 per regulatory (R) subunit. The binding of cAMP to the holoenzyme or isolated R subunit prevents the reaction of one SH group per R subunit. Modification of SH groups, however, has only a small effect on cAMP binding to R. Reaction of the C subunit with DTNB results in less than 95% loss of catalytic activity. The kinetics of the DTNB reaction and the reversal of the inactivation process by treatment with dithiothreitol suggest that the inactivation is associated with SH group modification. Inactivation studies with the holoenzyme show that: (1) the R subunit inhibits DTNG inactivation of the C subunit in the absence of cAMP; (2) the rate of inactivation of the dephosphoholoenzyme in the presence of cAMP is considerably faster than that of the free catalytic subunit; and (3) the rate of inactivation of the phosphoholoenzyme in the presence of cAMP is faster than that of the C subunit but slower than the dephosphoholoenzyme. The results are interpreted as evidence for a significant interaction of the R and C subunits in the presence of saturating concentrations of cAMP. This interaction is modulated by the state of phosphorylation of R. To account for the inactivation data, a short-lived ternary complex containing R, C, and cAMP is postulated to be in rapid equilibrium with the subunits.     

Effects of adenosine triphosphate on N-ethylmaleimide-induced modification of 30S dynein from Tetrahymena cilia.

Ciliary 30S dynein of Tetrahymena was investigated with regard to modification of the ATPase activity with N-ethylmaleimide (NEM) in the presence of ATP. The elevation of enzyme activity due to the modification was largely repressed by addition of ATP at a concentration of 1 mM or more during preincubation of 20 h at 0 degrees C. The repression was highly specific for ATP, though ADP and AMPPNP showed slight repressive effects. After complete hydrolysis of ATP added to the preincubation mixture, however, elevation of 30S dynein ATPase activity occurred. It is suggested that the repression by ATP of NEM-induced elevation of 30S dynein ATPase activity is simply due to a protecting effect of ATP on certain SH group(s) (probably SH1-type group(s)) around the active center of 30S dynein. When 30S dynein was maximally activated by modification with NEM, ATP or ADP did not significantly promote the inactivation of the modified enzyme upon further treatment with NEM, indicating that 30S dynein lacks the characteristics of SH2-type groups. On the other hand, ATP also showed a protective effect against inhibition of native 30S dynein by high concentrations of NEM. High concentrations of ADP and AMPPNP were inhibitory to 30S dynein ATPase activity but inorganic phosphate did not inhibit 14S or 30S dynein ATPase activities at all.     

Effects of sulfhydryl reagents on the ATPase activity of solubilized 14S and 30S dyneins and on whole ciliary axonemes as a function of pH

The effects of five sulfhydryl (SH) reagents – N-ethylmaleimide (NEM), a spin-labeled maleimide (SLM), N-N′-phenylenedimaleimide (PPDM), bis(4-fluoro-3-nitrophenyl)sulfone (FNS), and carboxypyridine disulfide (CPDS) – on glycerol-treated, Triton X-100-demembranated ciliary axonemes of Tetrahymena, on the 30S and 14S dyneins extracted from such axonemes, and on the residual ATPase activity remaining associated with axonemes that have been extracted twice with Tris-EDTA have been examined as a function of pH in the range 6.9–8.6. Preincubation of axonemes and of solubilized 30S dynein with low concentrations of each of the five SH reagents, at 0°C and at 25°C, caused enhancement of the latent ATPase activity. PPDM was the most effective reagent, causing half-maximal enhancement (after 18 h at 0°C) at ～ 0.5 μM, corresponding to 0.19 moles/10⁵ g axonemal protein. The rate constants, k_a, for the enhancement reaction at 0°C depended on whether the 30S dynein was in situ or solubilized; the ratio k_a (in situ) /k_a (solubilized) was > 1 for NEM, ～ 1 for PPDM, and < 1 for FNS. For each SH reagent except CPDS, k_a (at 0°C) increased markedly with increasing pH in the range pH 6.9–8.6; for CPDS k_a increased only about fourfold. At long times of preincubation and high concentrations of NEM, SLM, PPDM, and CPDS, the enhancement of ATPase activity was followed by a loss of activity. The values of k_L, the rate constants for loss of ATPase activity from the peak enhanced level, were much lower than the corresponding values for k_a, and increased with increasing pH. With SLM and PPDM, inhibition continued until the ATPase activity was almost completely inhibited. With NEM, however, the initial rate of loss from the peak enhanced value decreased as the ATPase activity returned toward the control (unmodified) level, and further inhibition was very slow. The differences in degree of inhibition obtained with SLM as compared to NEM suggest that there are at least two classes of inhibitory SH groups on 30S dynein. The ATPase activity of 14S dynein was only inhibited by preincubation with NEM, SLM, PPDM, and, to a lesser extent, CPDS; k_L increased with increasing pH. Preincubation of 14S dynein with FNS yielded conflicting results when the reaction was “stopped” by adding dithiothreitol. When 14S dynein was preincubated at 0 C with FNS and the ATPase activity was then assayed at 25°C, a biphasic pattern of enhancement followed by inhibition was obtained. The residual ATPase activity of twice-extracted axomenes was relatively insensitive to each of the SH reagents studied; an initial rapid loss of some 20–40% of the ATPase activity occurred, followed by a very slow further loss of activity. Increasing the pH increased this slow rate of inhibition. The residual ATPase activity of unmodified twice-extracted axonemes decreased slightly with increasing pH, in contrast to the slight increase observed with increasing pH for the ATPase activity of axonemes and of solubilized 30S and 14S dyneins. The presence of ATP during preincubation of axonemes with PPDM at O°C prevented the enhancement of ATPase activity; only a slow loss of ATPase activity was observed. This rate of loss of ATPase activity was slower than the rate of loss observed (after peak enhancement of activity was reached) when PPDM reacted with axonemes in the absence of ATP. In these properties the SH groups of 30s dynein responsible for the enhancement of latent ATPase activity and for the inhibition of ATPase activity do not resemble the SH1 and SH2 groups of myosin, respectively, since the presence of ATP increases the rates of reaction of SH1 and SH₂ of myosin with SH reagents.     

竹红菌甲素对红细胞膜上几种酶光敏失活作用的研究

本文比较了竹红菌甲素对人红细胞膜AchE,GPDH,Na~ -K~ ATPase和Ca~(2 )-Mg~(2 )ATPase的光敏失活能力,结果表明甲素对Ca~(2 )-Mg~(2 )ATPase作用最强,Na~ -K~ ATPase次之,GPDH再次之,AchE最不敏感,甲素还引起膜蛋白巯基氧化,膜脂质过氧化。其中,巯基氧化可能是ATPase光敏失活的主要原因,而脂质过氧化对ATPase活力损伤作用不大。游离GPDH不如与膜结合的GPDH敏感。GSH,NAD分别对ATPase,GPDH有保护作用。膜蛋白的电泳及内源荧光证据表明:在GPDH活力受到严重损伤时,酶结构并未发生剧烈改变。     

Differential effect of thiol oxidants on the chloroplast H+-ATPase in the light and in the dark

The effect of thiol oxidants on the light-activated H+-ATPase has been studied in freshly broken and intact chloroplasts. The following observations were made: (i) in chloroplasts which are osmotically shocked after light activation, ferricyanide stimulates the deactivation of the enzyme in the dark, but has little effect in the light; (ii) similarly, o-iodosobenzoate is a most efficient deactivator of the ATPase in intact chloroplasts in the dark but not in the light; (iii) the activated ATPase becomes sensitive to oxidants in the light upon the addition of an uncoupler; (iv) the oxidant-induced deactivation in the dark dominates the stabilizing effect of pyrophosphate or ADP plus Mg2+; (v) full deactivation of the ATPase by dark adaptation or by oxidants does not affect the rate of photophosphorylation under saturating conditions. A model is suggested in which two kinds of conformational changes are involved in the regulation of the ATPase: those induced by the trans-membrane-proton gradient and those by oxidation-reduction of the enzyme. These changes result in the preferential interaction with thiol reductants in the light but with thiol oxidants in the dark.     

A fluorescence probe study of the phosphorylation reaction of the calcium ATPase of sarcoplasmic reticulum

The fluorescent thiol reagent N-(1-anilinonaphthyl-4)maleimide (ANM) reacts covalently with the Ca2+ ATPase moiety of fragmented sarcoplasmic reticulum in two phases as determined by the increase of fluorescence intensity and optical density at 350 nm. In the rapid phase, 5.5 nmol of ANM reacts with 1 mg of fragmented sarcoplasmic reticulum protein. Assuming that 55% of the total membrane protein is the Ca2+ ATPase, this is equivalent to 1 mol of SH/10(5) g of ATPase, designated as SH1-ANM. ANM reacts with the second SH (SH2-ANM) at a much slower rate. Reaction of ANM with both SH1-ANM and SH2-ANM produces no inhibition of phosphoenzyme (EP) formation. Upon addition of Mg . ATP in the micromolar range, at [Ca2+] = 1 microM there is an increase in the fluorescence intensity of ANM attached to SH2-ANM, while the ANM attached to SH1-ANM does not respond to Mg . ATP. Under conditions in which there is no EP formation, there is no fluorescence change. Furthermore, the enhancement of ANM fluorescence produced by Mg . ATP is reversed by ADP as it reacts with EP to form ATP. Thus, it appears that the Mg . ATP-induced fluorescence increase reflects changes of enzyme conformation produced by EP formation.     

Functional integrity of the SH1 site in myosin from hypertrophied myocardium.

The hypothesis that an alteration in the SH1 site of hypertrophy myosin is reponsible for the reduced Ca2+-stimulated ATPase activity is examined.The functional integrity of the SH1 site was evaluated by measurement of the (K+)-EDTA-stimulated and Mg2+-inhibited ATPase activities. Neither activity differed from control although the Ca2+-stimulated ATPase of the same preparations was significantly reduced. The reduction in Ca2+-activated ATPase was independent of ionic strength. Titration with N-ethylmaleimide elevated the Ca2+-stimulated ATPase of hypertrophy myosin to the same peak activity as control. Actin-stimulated ATPase activity of hypertrophy myosin was also reduced. The results indicate that the SH1 of hypertrophy myosin is functionally intact for (K+)EDTA-stimulated ATPase and Mg2+ inhibition, but functionally deficient with regard to Ca2+-stimulated and actin-activated ATPase activities. This implies a partition of the functional aspects of SH1.     

Studies on the reactivity of the essential sulfhydryl groups as a conformational probe for the fatty acid synthetase of chicken liver. Inactivation by 5,5'-dithiobis-(2-nitrobenzoic acid) and intersubunit cross-linking of the inactivated enzyme

Fatty acid synthetase of chicken liver is rapidly and reversibly inactivated by 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) at a rate (k2 = 132 mM-1 S-1 in 3 mM EDTA, 1% (v/v) glycerol, pH 7.0, at 25 degrees C) up to 2200 times higher than the reaction of this reagent with simple thiol compounds. The inactivation is caused by the reaction of the phosphopantetheine SH group, since it is protected competitively by either acetyl- or malonyl-CoA, and since the inactivated enzyme is unreactive with the phosphopantetheine label chloroacetyl-CoA but reactive with the cysteine reagent 1,3-dibromopropanone. Moreover, chloroacetyl-CoA prevents the modification of the rapidly reacting essential SH group by DTNB. The number of SH groups involved in inactivation was determined by correlating activity loss with the extent of reaction and by stopped-flow analysis of substrate (or chloroacetyl-CoA) protection. Values between 0.91 and 1.15 SH groups/dimer were obtained, indicating the presence of substoichiometric amounts of the prosthetic group in the fatty acid synthetase preparations used in this study. Inactivation of the synthetase by DTNB is strongly inhibited by increasing salt concentration and protected noncompetitively by NADP+ and NADPH. Treatment of the enzyme inactivated at low salt by salt, NADP+, or NADPH also effectively reduced cross-linking between enzyme subunits. The parallel effects of these treatments on the reaction with DTNB and subsequent dimerization are consistent with a minimum model of two discreet conformation states for fatty acid synthetase. In the low salt conformer, the phosphopantetheine and cysteine SH groups are juxtaposed, and the DTNB reaction (k2 approximately 132 mM-1 S-1) and dimerization are both facilitated. Transition to the high salt conformer by the above treatments is accompanied by an approximately 20-fold reduction of reactivity with DTNB (k2 = 6.8 mM-1 S-1) and reduced dimerization, due to spatial separation of the SH groups. During palmitate synthesis, the enzyme may oscillate between these conformation states to permit the reaction of intermediates at different active sites. Results obtained by studies on the effect of pH on DTNB inactivation implicate a pK of 5.9-6.1 for the essential SH group independent of salt concentration. This value is 1.5-1.8 pH units lower than the pK of 7.6-7.7 for CoA and may explain the 23-fold increase of the rate constant from a value of 0.3 mM-1 S-1 for CoA to that of the high salt conformer.     

Effects of mercury on myosin ATPase in the ventricular myocardium of the rat

Mercury reduces twitch and tetanic force development in isolated rat papillary muscles, and a putative toxic effect on the contractile machinery has been suggested. Based on that, the actions of HgCl2 on the myosin ATPase activity of the left ventricular myocardium were investigated. Samples for assay of myosin ATPase activity were obtained from rats' left ventricles. Increasing concentrations of HgCl2 reduced dose-dependently the activity of the myosin ATPase. This reduction was observed even at very small concentrations, 50 nM HgCl2. This effect was dependent on the presence of SH groups in the myosin molecule since DTT and glutathione protected the myosin ATPase against toxic effects of mercury; full activity being restored by using 500 nM DTT or 500 nM glutathione. Results also suggested that the metal acts as an uncompetitive inhibitor with a Ki of 200 nM HgCl2. Our results suggest that mercury reduces the activity of the myosin ATPase by an uncompetitive mechanism at a very low dose that does not depress force. DTT and glutathione are effective for protection against the actions of mercury suggesting that SH groups might be the sites of action of the metal on the myosin molecule.     

Involvement of sulfhydryl groups in the activation mechanism of the ATPase activity of chloroplast coupling factor 1

Activation of the ATPase activity and the exposition of a new adenine nucleotide binding site of chloroplast coupling factor 1 (CF1) by dithioerythritol at 25 degrees C were reversed by oxidants. The ATPase activity elicited by heat (63 degrees C, 4 min) was slightly inhibited by oxidants and was partially additive with the activity induced by dithioerythritol. Titration of the thiols of CF1 and determination of their subunit distribution before and after activation by dithioerythritol show an increase of the free groups from 8 to 10 with the appearance of the 2 new thiols on the gamma subunit. These thiols were available to reagents in nondenatured enzyme and were reoxidized to a disulfide bond by iodosobenzoate or CuCl2. It is concluded that the mechanisms of CF1 activation by dithioerythritol and by heat are different and that the former involves a net reduction of a disulfide bond of the gamma subunit.     

Evidence for the proximity of two sulfhydryl groups at the active site of 6-phosphogluconate dehydrogenase

The reaction between 6-phosphogluconate dehydrogenase from Candida utilis and 5,5′-dithiobis(2-nitrobenzoate) results in the inactivation of the enzyme. At pH 6.0 the inactivation can be correlated with the modification of only one SH group per enzyme subunit. The modified SH group can react with another SH group forming an intramolecular disulfide bridge. Since the modified enzymes, either with an SH group modified or with a cystine disulfide bridge, are still able to bind the substrate and the coenzyme, gross conformational changes seem unlikely to have occurred. The results obtained suggest that the SH groups of two cysteine residues are located close to each other in the three-dimensional structure of the active site of the enzyme.     

Chemical modification of tryptophanase by chloramine T: a possible involvement of the methionine residue in enzyme activity

Tryptophanase purified from Escherichia coli B/1t7-A was irreversibly inactivated by chloramine T (sodium N-chloro-p-toluenesulfonamide). The mode of inactivation was rather complex and did not follow pseudo-first-order kinetics. The inactivation of the apoenzyme was much faster than that of the holoenzyme. The Km value for the synthetic substrate S-o-nitrophenyl-L-cysteine (SOPC) increased concomitantly with the modification. In contrast, the Km value for the coenzyme, pyridoxal 5'-phosphate (PLP), was not altered. L-Serine, another substrate, and L-alanine, a competitive inhibitor, protected the enzyme from inactivation. Determination of SH groups in the enzyme protein with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) showed that modification of two SH groups per enzyme subunit resulted in a complete inactivation. When the enzyme was subjected to chloramine T-modification following the SH group modification with DTNB, further inactivation was still observed, even after the addition of dithiothreitol. The SH-blocked enzyme preparation thus obtained, however, exhibited less pH dependency of inactivation by chloramine T than that of the native enzyme. The amino acid analysis of the chloramine T-modified enzyme showed that modification of four or five methionine residues among the 16 residues per subunit proceeded concomitantly with the complete inactivation. Modification of the enzyme with chloramine T quenched the absorption peak near 500 nm, characteristic of a quinoidal structure formed by labilization of the alpha-proton. These results suggest the possibility that chloramine T modifies not only the SH groups, but also methionine residues important for the catalytic activity of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)