Detergent-assisted refolding of guanidinium chloride-denatured rhodanese. The effect of lauryl maltoside

For the first time, the enzyme rhodanese (thiosulfate:cyanide sulfurtransferase; EC 2.8.1.1) has been renatured from 6 M guanidinium chloride (GdmCl) by direct dilution of the denaturant at relatively high protein concentrations. This has been made possible by using the nonionic detergent dodecyl-beta-D-maltoside (lauryl maltoside). Lauryl maltoside concentration dependence of the renaturation and reactivation time courses were studied using 50 micrograms/ml rhodanese. There was no renaturation at lauryl maltoside (less than 0.1 mg/ml), and the renaturability increased, apparently cooperatively, up to 5 mg/ml detergent. This may reflect weak binding of lauryl maltoside to intermediate rhodanese conformers. The renaturability began to decrease above 5 mg/ml lauryl maltoside and was significantly reduced at 20 mg/ml. Individual progress curves of product formation, for rhodanese diluted into lauryl maltoside 90 min before assay, showed induction phases as long as 7 min before an apparently linear steady state. The induction phase increased with lauryl maltoside concentration and could even be observed in native controls above 1 mg/ml detergent. These results are consistent with suggestions that refolding of GdmCl-denatured rhodanese involves an intermediate with exposed hydrophobic surfaces that can partition into active and inactive species. Further, lauryl maltoside can stabilize those surfaces and prevent aggregation and other hydrophobic interaction-dependent events that reduce the yield of active protein. The rhodanese-lauryl maltoside complex could also form with native enzyme, thus explaining the induction phase with this species. Finally, it is suggested that renaturation of many proteins might be assisted by lauryl maltoside or other "nondenaturing" detergents.     

Reducing sugars can induce the oxidative inactivation of rhodanese.

The enzyme rhodanese (thiosulfate sulfurtransferase, EC 2.8.1.1) is inactivated on incubation with reducing sugars such as glucose, mannose, or fructose, but is stable with non-reducing sugars or related polyhydroxy compounds. The enzyme is inactivated with (ES) or without (E) the transferable sulfur atom, although E is considerably more sensitive, and inactivation is accentuated by cyanide. Inactivation of E is accompanied by increased proteolytic susceptibility, a decreased sulfhydryl titer, a red-shift and quenching of the protein fluorescence, and the appearance of hydrophobic surfaces. Superoxide dismutase and/or catalase protect rhodanese. Inactive enzyme can be partially reactivated during assay and almost completely reactivated by incubation with thiosulfate, lauryl maltoside, and 2-mercaptoethanol. These results are similar to those observed when rhodanese is inactivated by hydrogen peroxide. These observations, as well as the cyanide-dependent, oxidative inactivation by phenylglyoxal, are explained by invoking the formation of reactive oxygen species such as superoxide or hydrogen peroxide from autooxidation of alpha-hydroxy carbonyl compounds, which can be facilitated by cyanide.     

Low concentrations of guanidinium chloride expose apolar surfaces and cause differential perturbation in catalytic intermediates of rhodanese

The conformations of sulfur-free and sulfur-containing rhodanese were followed with and without the detergent lauryl maltoside after guanidinium chloride (GdmCl) addition to 5 M to study the apparent irreversibility of denaturation. Without lauryl maltoside, sulfur-containing rhodanese denatured in a transition giving, at approximately 2.3 M GdmCl, 50% of the total denaturation induced change observed by activity, CD, or intrinsic fluorescence. Sulfur-free rhodanese gave more complex behavior by intrinsic fluorescence and CD. CD showed loss of secondary structure in a broad, complex, and apparently biphasic transition extending from 0.5 to 3 M GdmCl. The interpretation of the transition was complicated by time-dependent aggregation due to noncovalent interactions. Results with the apolar fluorescence probe 2-anilinonaphthalene-8-sulfonic acid, implicated apolar exposure in aggregation. Sulfhydryl reactivity indicated that low GdmCl concentrations induced intermediates affecting the active site conformation. Lauryl maltoside prevented aggregation with no effect on activity or any conformational parameter of native enzyme. Transitions induced by GdmCl were still observed and consistent with several phases. Even in lauryl maltoside, an increase in apolar exposure was detected by 2-anilinonaphthalene-8-sulfonic acid, and by protein adsorption to octyl-Sepharose well below the major unfolding transitions. These results are interpreted with a model in which apolar interdomain interactions are disrupted, thereby increasing active site accessibility, before the intradomain interactions.     

Isolation and characterization of rhodanese intermediates during thermal inactivation and their implications for the mechanism of protein aggregation

The initial steps of heat-induced inactivation and aggregation of the enzyme rhodanese have been studied and found to involve the early formation of modified but catalytically active conformations. These intermediates readily form active dimers or small oligomers, as evident from there being only a small increase in light scattering and an increase in fluorescence energy homotransfer from rhodanese labeled with fluorescein. These species are probably not the domain-unfolded form, as they show activity and increased protection of hydrophobic surfaces. Cross-linking with glutaraldehyde and fractionation by gel filtration show the predominant formation of dimer during heat incubation. Comparison between the rates of aggregate formation at 50 degrees C after preincubation at 25 or 40 degrees C gives evidence of product-precursor relationships, and it shows that these dimeric or small oligomeric species are the basis of the irreversible aggregation. The thermally induced species is recognized by and binds to the chaperonin GroEL. The unfoldase activity of GroEL subsequently unfolds rhodanese to produce an inactive conformation and forms a stable, reactivable complex. The release of 80% active rhodanese upon addition of GroES and ATP indicates that the thermal incubation induces an alteration in conformation, rather than any covalent modification, which would lead to formation of irreversibly inactive species. Once oligomeric species are formed from the intermediates, GroEL cannot recognize them. Based on these observations, a model is proposed for rhodanese aggregation that can explain the paradoxical effect in which rhodanese aggregation is reduced at higher protein concentration.     

Stable intermediates can be trapped during the reversible refolding of urea-denatured rhodanese

The enzyme rhodanese (EC 2.8.1.1) could be reversibly refolded from urea in the presence of lauryl maltoside, beta-mercaptoethanol, and sodium thiosulfate. The unfolding/folding transition monitored using intrinsic fluorescence was resolved into two two-state transitions with midpoints at 3.6 and 5.0 M urea. The analysis assumed an intermediate with an emission maximum at 345 nm. Monitoring anisotropy of intrinsic fluorescence also gave an asymmetric transition. Activity followed one two-state transition centered at 3.6 M urea with no major change of secondary structure. Without thiosulfate or mercaptoethanol, there was one two-state transition at 5.0 M urea giving a species, in dilute urea, with a fluorescence maximum at 345 nm. This intermediate slowly relaxed toward 335 nm (t1/2 = 85 min) if only thiosulfate was absent but without regaining activity. Subsequent addition of thiosulfate led to a first-order recovery of activity (t1/2 = 75 min). Thus, a possible folding intermediate can be trapped which displays increased access of water and solutes to its fluorescent tryptophans. This intermediate conformer, which is flexible, has considerable secondary structure, is inactive, has exposed hydrophobic surfaces, and requires specific reducing conditions to regain full activity. Refolding probably involves an initial, rapid, hydrophobic collapse with acquisition of secondary structure to form the intermediate, followed by slower adjustment to the native global conformation. Final reactivation requires reduction localized at the active site.     

Oxidative inactivation of the enzyme rhodanese by reduced nicotinamide adenine dinucleotide

The enzyme rhodanese (thiosulfate sulfurtransferase; EC 2.8.1.1) is inactivated with a half-time of approximately 3 min when incubated with 50 mM NADH. NAD+, however, has virtually no effect on the activity. Inactivation can be prevented by the inclusion of the substrate thiosulfate. The concentration of thiosulfate giving half-protection is 0.038 mM. In addition, NADH, but not NAD+, is a competitive inhibitor with respect to thiosulfate in the catalyzed reaction (Ki = 8.3 mM). Fluorescence studies are consistent with a time-dependent oxidation of NADH in the presence of rhodanese. The sulfur-free form of rhodanese is more rapidly inactivated than the sulfur-containing form. Spectrophotometric titrations show that inactivation is accompanied by the loss of two free SH groups per enzyme molecule. Inactivation is prevented by the exclusion of air and the inclusion of EDTA (1 mM), and the enzyme activity can be largely protected by incubation with superoxide dismutase or catalase. Rhodanese, inactivated with NADH, can be reactivated by incubation with the substrate thiosulfate (75 mM) for 48 h or more rapidly, but only partially, by incubating with 180 mM dithiothreitol. It is concluded that, in the presence of rhodanese, NADH can be oxidized by molecular oxygen and produce intermediates of oxygen reduction, such as superoxide and/or hydrogen peroxide, that can inactivate the enzyme with consequent formation of an intraprotein disulfide. In addition, NADH, but not NAD+, can reversibly bind to the active site region in competition with thiosulfate. These data are of interest in view of x-ray studies that show structural similarities between rhodanese and nucleotide binding proteins.     

Chaperonin cpn60 from Escherichia coli protects the mitochondrial enzyme rhodanese against heat inactivation and supports folding at elevated temperatures.

The chaperonin protein cpn60 from Escherichia coli protects the monomeric, mitochondrial enzyme rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) against heat inactivation. The thermal inactivation of rhodanese was studied for four different states of the enzyme: native, refolded, bound to cpn60 in the form of a binary complex formed from unfolded rhodanese, and a thermally perturbed state. Thermal stabilization is observed in a range of temperatures from 25 to 48 degrees C. Rhodanese that had been inactivated by incubation at 48 degrees C, in the presence of cpn60 can be reactivated at 25 degrees C, upon addition of cpn10, K+, and MgATP. A recovery of about 80% was achieved after 1 h of the addition of those components. Thus, the enzyme is protected against heat inactivation and kept in a reactivable form if inactivation is attempted using the binary complex formed between rhodanese folding intermediate(s) and cpn60. The chaperonin-assisted refolding of urea-denatured rhodanese is dependent on the temperature of the refolding reaction. However, optimal chaperonin assisted refolding of rhodanese observed at 25 degrees C, which is achieved upon addition of cpn10 and ATP to the cpn60-rhodanese complex, is independent of the temperature of preincubation of the complex, that was formed previously at low temperature. The results are in agreement with a model in which the chaperonin cpn60 interacts with partly folded intermediates by forming a binary complex which is stable to elevated temperatures. In addition, it appears that native rhodanese can be thermally perturbed to produce a state different from that achieved by denaturation that can interact with cpn60.     

Acceptor substrate-potentiated inactivation of bovine liver rhodanese

The interaction of bovine liver rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) with the acceptor substrates, dithiothreitol or cyanide, was studied. When incubated in the presence of cyanide or dithiothreitol, rhodanese was inactivated in a time-dependent process. This inactivation was detectable only at low enzyme concentrations; the rate and degree of inactivation could be modulated by varying the substrate concentration or the system pH. Activity measurements and fluorescence spectroscopy techniques were used in examining the inactivation phenomenon. Sulfur transfer to dithiothreitol was measured by direct assay and was shown to involve the dequenching of enzymic intrinsic fluorescence that had been previously observed only with cyanide as the acceptor substrate. Substrate-potentiated inactivation of rhodanese (with cyanide) has been reported before, but the cause and nature of this interaction were unexplained. The results presented here are consistent with an explanation invoking oxidation of rhodanese in the course of inactivation.     

Reversible folding of rhodanese. Presence of intermediate(s) at equilibrium

For the first time completely reversible unfolding was achieved for guanidinium chloride-denatured rhodanese using a systematically defined protocol. These conditions included beta-mercaptoethanol, lauryl maltoside, and sodium thiosulfate. All components were required to get more than the previous best reactivation with lauryl maltoside of 17% (Tandon, S., and Horowitz, P. (1986) J. Biol. Chem. 261, 15615-15681). Non-coincidental transition curves were obtained by monitoring different parameters including: (i) variation in the activity, (ii) shifts of the fluorescence wavelength maximum, and (iii) variation in ellipticity at 220 nm. The transition followed by the fluorescence wavelength maximum was asymmetric and resolvable into two separate transitions. A thermodynamic analysis was used to define the energetics of the two processes. Studies with the fluorescent "apolar" probe 1,8ANS are consistent with the appearance of organized hydrophobic surfaces following the first transition. Near UV CD measurements indicated that the first transition is associated with a loss of dyssymmetry around at least some of the tryptophans. Thus, the unfolding of rhodanese is complex, and there are detectable intermediate(s) during the process. These results suggest that reversible unfolding occurs in two discrete stages: 1) loss of tertiary interactions and activity, with retention of secondary structure, and 2) loss of secondary structure. The available x-ray structure suggests that the first transition can be associated with changes in the domain interactions, which may modulate the effectiveness of helix dipoles in lowering the pKa of the active site sulfhydryl.     

Micelle-assisted protein folding. Denatured rhodanese binding to cardiolipin-containing lauryl maltoside micelles results in slower refolding kinetics but greater enzyme reactivation.

Unfolded (inactive) rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) can be reactivated in the presence of detergents, e.g. lauryl maltoside (LM). Here, we report the reactivation of urea-unfolded rhodanese in the presence of mixed micelles containing LM and the anionic mitochondrial phospholipid, cardiolipin (CL). Reactivation times increased as the number of CL molecules/micelle was increased. A maximum of 94% of the activity was recovered at 2.2 CL/micelle. Only 71% of the activity was recovered in the absence of CL. The major zwitterionic mitochondrial phospholipid, phosphatidylcholine (PC), had no effect on the LM-assisted reactivation of rhodanese. Size exclusion chromatography showed that denatured, but not native, rhodanese apparently binds to micellar amounts of LM and CL/LM, but not to PC/LM micelles. The lifetime of the enzyme-micelle complex increased with the number of CL molecules/micelle. Furthermore, chromatographic fractions containing micelle-bound enzyme had no activity, while renatured rhodanese-containing fractions were active. These results suggest that transient complexes form between enzyme and both LM and CL/LM micelles, and that this complex formation may be necessary for reactivation. For CL/LM micelles, interactions may occur between the positively charged amino-terminal sequence of rhodanese and the negatively charged CL phosphate. Finally, this work shows that there are similarities between "micelle-assisted" and chaperonin-assisted rhodanese refolding.     

Purification and Some Properties of Trametes sanguinea Rhodanese

A fungal rhodanese from the spray-dried powder of a culture filtrate of Trametes sanguinea was purified to 142-fold by ammonium sulfate precipitation and DEAE-cellulose and Sephadex G–100 column chromatography. The purified rhodanese (pI 5.10) showed a single band on disc electrophoresis, and its molecular weight was estimated to be 51,700 by gel filtration technique. The enzyme had a broad pH optimum between 7.5 and 8.5 and was stable at pH values from 4 to 8 at 30°C for 44 hr. Its activity was inhibited by p-chloromercuribenzoate at pH 9.5, but not at pH 8.0, and was inhibited by cysteine, β-mercaptoethanol and sodium borohydride at pH 8.0. Both thiosulfate and cyanide showed substrate inhibition at high concentrations. Dihydrolipoate and benzenethiosulfonate were also good substrates.     

A chaperone-mimetic effect of serum albumin on rhodanese

Reactivation of denatured rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) was found to be aided by the presence of serum albumin. Both the rate and the extent of reactivation of the urea-denatured enzyme were optimal at low rhodanese and moderate serum albumin concentrations. Similarly, stabilization of the sulfurtransferase activity of rhodanese that had been partially unfolded at 40°C was aided by the presence of serum albumin. All the observations are in accord with a model in which enzyme that has been partially refolded from the urea-denatured state or partially unfolded thermally interacts directly with serum albumin in a way that prevents rhodanese self-association. Serum albumin thus acts as a molecular chaperone in these systems.     

Detergent-assisted refolding of guanidinium chloride-denatured rhodanese. The effects of the concentration and type of detergent

We have established the generality of using detergents for facilitating the reactivation of 6 M guanidinium chloride-denatured rhodanese that was recently described for the nonionic detergent lauryl maltoside (LM) (Tandon, S., and Horowitz, P. (1986) J. Biol. Chem. 261, 15615-15618). We report here that not only LM but other nonionic as well as ionic and zwitterionic detergents also have favorable effects in reactivating the denatured enzyme. Not all detergents are useful, and the favorable effects occur over a limited concentration range. Above and below that range there is little or no effect. Zwittergents, which represent a homologous series with varying critical micelle concentrations (CMCs) are effective only above their CMCs. Induction phases occur in the progress curves of rhodanese refolded in the presence of the effective detergents, suggesting the presence of refolding intermediates that are apparently stabilized by detergent interactions. Gel filtration chromatography of rhodanese with and without LM suggests that even though the renaturation of the denatured enzyme requires detergent at concentrations above its CMC, the enzyme does not bind an amount of detergent equivalent to a micelle. It is suggested that renaturation of other proteins might also be assisted by inclusion of "nondenaturing" detergents, although the optimal conditions will have to be determined for each individual case.     

Oxidative inactivation of rhodanese by hydrogen peroxide produces states that show differential reactivation

Controlled conditions have been found that give complete reactivation and long term stabilization of rhodanese (EC 2.8.1.1) after oxidative inactivation by hydrogen peroxide. Inactivated rhodanese was completely reactivated by reductants such as thioglycolic acid (TGA) (100 mM) and dithiothreitol (DTT) (100 mM) or the substrate thiosulfate (100 mM) if these reagents were added soon after inactivation. Reactivability fell in a biphasic first order process. At pH 7.5, in the presence of DTT inactive rhodanese lost 40% of its reactivability in less than 5 min, and the remaining 60% was lost more gradually (t 1/2 = 3.5 h). TGA reactivated better than DTT, and the rapid phase was much less prominent. If excess reagents were removed by gel filtration immediately after inactivation, there was time-independent and complete reactivability with TGA for at least 24 h, and the resulting samples were stable. Reactivable enzyme was resistant to proteolysis and had a fluorescence maximum at 335 nm, just as the native protein. Oxidized rhodanese, Partially reactivated by DTT, was unstable and lost activity upon further incubation. This inactive enzyme was fully reactivated by 200 mM TGA. Also, the enzyme could be reactivated by arsenite and high concentrations of cyanide. Addition of hydrogen peroxide (40-fold molar excess) to inactive rhodanese after column chromatography initiated a time-dependent loss of reactivability. This inactivation was a single first order process (t 1/2 = 25 min). Sulfhydryl titers showed that enzyme could be fully reactivated after the loss of either one or two sulfhydryl groups. Irreversibly inactivated enzyme showed the loss of one sulfhydryl group even after extensive reduction with TGA. The results are consistent with a two-stage oxidation of rhodanese. In the first stage there can form sulfenyl and/or disulfide derivative(s) at the active site sulfhydryl that are reducible by thioglycolate. A second stage could give alternate or additional oxidation states that are not easily reducible by reagents tried to date.     

Interaction of rhodanese with intermediates of oxygen reduction

Cyanide-promoted inactivation of the enzyme rhodanese [thiosulfate sulfurtransferase (EC 2.8.1.1)] in the presence of ketoaldehydes is caused by reduced forms of molecular oxygen generated during autoxidation of the reaction products. The requirement of both catalase and superoxide dismutase to prevent rhodanese inactivation indicates that hydroxyl radical could be the most efficient inactivating agent. Rhodanese, also in the less stable sulfur-free form, shows a different sensitivity towards oxygen activated species. While the enzyme is unaffected by superoxide radical, it is rapidly inactivated by hydrogen peroxide. The extent of inactivation depends on the molar ratio between sulfur-free enzyme and oxidizing agent. Fully inactive enzyme is reactivated by reduction with its substrate thiosulfate.     

Purification of yeast cytochrome c oxidase with a subunit composition resembling the mammalian enzyme.

Yeast cytochrome c oxidase has been isolated by ion exchange chromatography using lauryl maltoside (n-dodecyl beta-D-maltoside) as the solubilizing detergent. The enzyme prepared in this way has a heme aa3 concentration of 8-9 nmol/mg of protein and a turnover number in the range of 180-210 s-1 at pH 6.2 in 0.01% lauryl maltoside at 20 degrees C. Yeast cytochrome c oxidase prepared by any of several previously published methods which use Triton X-100 contains nine subunits. The enzyme isolated in lauryl maltoside contains these same nine different polypeptides and three others, including homologues of subunits VIa and VIb of the mammalian enzyme.     

Kinetics of Denaturation of Rabbit Skeletal Muscle Glycogen Phosphorylase b by Guanidine Hydrochloride

The kinetics of denaturation and aggregation of rabbit muscle glycogen phosphorylase b in the presence of guanidine hydrochloride (GuHCl) have been studied. The curve of inactivation of phosphorylase b in time includes a region of the fast decline in the enzymatic activity,an intermediate plateau,and a part with subsequent decrease in the enzymatic activity. The fact that the shape of the inactivation curves is dependent on the enzyme concentration testifies to the dissociative mechanism of inactivation. The dissociation of phosphorylase b dimers into monomers in the presence of GuHCl is supported by sedimentation data. The rate of phosphorylase b aggregation in the presence of GuHCl rises as the denaturant concentration increases to 1.12 M; at higher concentration of GuHCl, suppression of aggregation occurs. At rather low concentration of the protein (0.25 mg/ml), the terminal phase of aggregation follows the kinetics of a monomolecular reaction (the reaction rate constant is equal to 0.082 min^–1;1 M GuHCl, 25°C). At higher concentration of phosphorylase b (0.75 mg/ml), aggregation proceeds as a trimolecular reaction.     

Chaperonins facilitate the in vitro folding of monomeric mitochondrial rhodanese.

In vitro refolding of the monomeric mitochondrial enzyme, rhodanese (thiosulfate sulfurtransferase; EC 2.8.1.1) is facilitated by molecular chaperonins. The four components: two proteins from Escherichia coli, chaperonin 60 (groEL) and chaperonin 10 (groES), MgATP, and K+, are necessary for the in vitro folding of rhodanese. These were previously shown to be necessary for the in vitro folding of ribulose-1,5-bisphosphate carboxylase at temperatures in excess of 25 degrees C (Viitanen, P. V., Lubben, T. H., Reed, J., Goloubinoff, P., O'Keefe, D. P., and Lorimer, G. H. (1990) Biochemistry 29, 5665-5671). The labile folding intermediate, rhodanese-I, which rapidly aggregates at 37 degrees C in the absence of the chaperonins, can be stabilized by forming a binary complex with chaperonin 60. The discharge of the binary chaperonin 60-rhodanese-I complex, results in the formation of active rhodanese, and requires the presence of chaperonin 10. Optimal refolding is associated with a K(+)-dependent hydrolysis of ATP. At lower protein concentrations and 25 degrees C, where aggregation is reduced, a fraction of the rhodanese refolds to an active form in the absence of the chaperonins. This spontaneous refolding can be arrested by chaperonin 60. There is some refolding (approximately equal to 20%) when ATP is replaced by nonhydrolyzable analogs, but there is no refolding in the presence of ADP or AMP. ATP analogs may interfere with the interaction of rhodanese-I with the chaperonins. Nondenaturing detergents facilitate rhodanese refolding by interacting with exposed hydrophobic surfaces of folding intermediates and thereby prevent aggregation (Tandon, S., and Horowitz, P. (1986) J. Biol. Chem. 261, 15615-15618). The chaperonin proteins appear to play a similar role in as much as they can replace the detergents. Consistent with this view, chaperonin 60, but not chaperonin 10, binds 2-3 molecules of the hydrophobic fluorescent reporter, 1,1'-bi(4-anilino)naphthalene-S,5'-disulfonic acid, indicating the presence of hydrophobic surfaces on chaperonin 60. The number of bound probe molecules is reduced to 1-2 molecules when chaperonin 10 and MgATP are added. The results support a model in which chaperonins facilitate folding, at least in part, by interacting with partly folded intermediates, thus preventing the interactions of hydrophobic surfaces that lead to aggregation.     

Inactivation of rhodanese by pyridoxal 5'-phosphate.

Pyridoxal 5'-phosphate and other aromatic aldehydes inactivate rhodanese. The inactivation reaches higher extents if the enzyme is in the sulfur-free form. The identification of the reactive residue as an amino group has been made by spectrophotometric determination of the 5'-phosphorylated pyridoxyl derivative of the enzyme. The inactivation increases with pyridoxal 5'-phosphate concentration and can be partially removed by adding thiosulfate or valine. Prolonged dialysis against phosphate buffer also leads to the enzyme reactivation. The absorption spectra of the pyridoxal phosphate - rhodanese complex show a peak at 410 nm related to the Schiff base and a shoulder in the 330 nm region which is probably due to the reaction between pyridoxal 5'-phosphate and both the amino and thiol groups of the enzyme that appear reasonably close to each other. The relationship betweenloss of activity and pyridoxal 5'-phosphate binding to the enzyme shows that complete inactivation is achieved when four lysyl residues are linked to pyridoxal 5'-phosphate.     

Purification of bovine liver rhodanese by low-pH column chromatography

We report a purification of bovine liver rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) using column chromatography under conditions that take advantage of recent information regarding the structure and stability of this enzyme. At low pH (e.g., pH 4-6), rhodanese is stabilized against inactivation processes. By maintaining rhodanese at low pH, column chromatography, and especially ion-exchange chromatography, becomes practical, without loss of enzymatic activity. A purification method involving the sequential use of cation-exchange, size-exclusion, and hydrophobic-interaction chromatography was developed, and rhodanese was purified with good yield to electrophoretic purity and high specific activity. Previous methods for purifying bovine liver rhodanese employ repeated ammonium sulfate fractionations and crystallization of the rhodanese. In these methods, it is difficult to separate rhodanese from yellow-brown contaminants in the final stages of the procedures. Here, yellow-brown contaminants, which copurify with rhodanese on the first two columns, are completely resolved by hydrophobic interaction chromatography. This method can be readily scaled up, requires no special equipment, eliminates the variability inherent in previous methods, and is less dependent upon experience.