Immunological evidence for a conformational difference between recombinant bovine rhodanese and rhodanese purified from bovine liver

Rhodanese has been utilized as a model enzyme for the study of protein structure-function relationships. The enzyme has recently been cloned and the recombinant enzyme is now available for investigation. However, prior to use in structure-function studies, the recombinant enzyme must be shown to have the same structure and activity as the bovine liver enzyme used in the previous studies. An immunological study of the conformations of these enzyme conformers is described. Three antibodies (two monoclonal and one polyclonal, site-directed antibody) were shown to detect distinct and nonoverlapping epitopes. The epitopes of the monoclonal antirhodanese antibodies (R207 and MAB11) were mapped to the same CNBr digest fragment of the amino terminal domain of rhodanese, and the epitope of the site-directed antibody prepared against the interdomain tether sequence of rhodanese (PAT-T1) was mapped to that region of rhodanese (residues 142–156). The rhodanese conformers were studied by monitoring the accessibility of the epitopes recognized by each antibody in each conformer using an indirect ELISA. None of the antibodies could detect its epitope on the purified liver enzyme. Two of the antibodies (R207 and PAT-T1) could also not detect their epitopes on the recombinant enzyme. However, MAB11 did detect a conformational difference between the natural and recombinant rhodanese conformers, indicating the conformational difference is localized in the first 73 amino acids of rhodanese. This difference presumably reflects the difference in the histories of the two enzymes and may be due to differences in enzyme folding, differences in the purification procedures, and differences in storage conditions—all of which could influence the final conformation of the enzyme.     

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.     

New crystalline derivatives of bovine liver rhodanese

Mitochondrial bovine liver rhodanese (thiosulfate:cyanide sulfurtransferase) has been crystallized in the form deprived of the transferable sulfur. The essential condition for crystallization was the removal of oxygen. Crystals of the sulfur-free enzyme are isomorphous with the previously characterized crystals of the sulfur-substituted enzyme. The new crystal species can react with either thiosulfate or selenosulfate to form the catalytic intermediate and, subsequently, with cyanide to form the corresponding product. Furthermore, the enzyme active site can be alkylated by iodoacetic acid.     

Studies on rhodanese synthesis in bovine adrenocortical cells

The synthesis of adrenodoxin, a mitochondrial iron-sulfur protein required for adrenocortical steroidogenesis, is known to be regulated chronically by ACTH. Rhodanese, also a mitochondrial enzyme, is thought to be required for synthesis of iron-sulfur centers, such as those contained in adrenodoxin. In this study it has been found that rhodanese synthesis and activity are not regulated by ACTH, under the same conditions whereby ACTH induces adrenodoxin synthesis. In addition, unlike adrenodoxin, rhodanese is found to be synthesized in the mature form rather than as a higher molecular weight precursor protein.     

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.     

Acid pH-induced conformational changes in bovine liver rhodanese.

The enzyme rhodanese is greatly stabilized in the range pH 4-6, and samples at pH 5 are fully active after several days at 23 degrees C. This is very different from results at pH greater than 7, where there is significant loss of activity within 1 h. A pH-dependent conformational change occurs below pH 4 in a transition centered around pH 3.25 that leads slowly to inactive rhodanese at pH 3 (t 1/2 = 22 min at pH3). The inactive rhodanese can be reactivated by incubation under conditions required for detergent-assisted refolding of denatured rhodanese. The inactive enzyme at pH 3 has the maximum of its intrinsic fluorescence spectrum shifted to 345 nm from 335 nm, which is characteristic of native rhodanese at pH greater than 4. At pH 3, rhodanese shows increased exposure of organized hydrophobic surfaces as measured by 1,1'-bis(4-anilino)naphthalene-5,5'-disulfonic acid binding. The secondary structure is maintained over the entire pH range studied (pH 2-7). Fluorescence anisotropy measurements of the intrinsic fluorescence provide evidence suggesting that the pH transition produces a state that does not display greatly increased average flexibility at tryptophan residues. Pepsin digestibility of rhodanese follows the pH dependence of conformational changes reported by activity and physical methods. Rhodanese is resistant to proteolysis above pH 4 but becomes increasingly susceptible as the pH is lowered. The form of the enzyme at pH 3 is cleaved at discrete sites to produce a few large fragments. It appears that pepsin initially cleaves close to one end of the protein and then clips at additional sites to produce species of a size expected for the individual domains into which rhodanese is folded. Overall, it appears that in the pH range between pH 3 and 4, titration of groups on rhodanese leads to opening of the structure to produce a conformation resembling, but more rigid than, the molten globule state that is observed as an intermediate during reversible unfolding of rhodanese.     

The differential functional stability of various forms of bovine liver rhodanese

Bovine liver rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) was prepared in dilute solutions and subjected to conditions that led to a time-dependent loss of enzyme activity. The rate of this activity loss was found to be dependent upon the sulfur substitution state of the enzyme, and the presence or absence of the substrates, thiosulfate and cyanide. In the absence of excess substrates, free enzyme (E), and the covalent intermediate form of the enzyme bearing a divalent sulfur atom in the active site (ES), are of approximately equal functional stability. In comparison, E, in the presence of excess cyanide, was markedly more labile, while ES, supported by 10-50 mM thiosulfate, showed no significant loss of activity under any of the conditions tested. All the enzyme solutions were shown to be losing assayable protein from solution. However, it was demonstrated that, for rhodanese in the E form, the amount of protein lost was insufficient to account for the activity lost, and a marked decline in specific activity was observed. Enzyme in the ES form, whether supported by additional thiosulfate or not, did not decline in the specific activity, though comparable protein loss did occur from these solutions. Intrinsic fluorescence measurements of rhodanese in the ES form, before and after removal of the persulfide sulfur through the addition of cyanide, indicated that loss of enzymic activity was not accompanied by loss of the bound sulfur atom. Therefore, the stabilizing effect observed with thiosulfate could not be explained simply by its ability to maintain enzyme in the sulfur-substituted state. Since the concentration of thiosulfate employed in these experiments was insufficient to maintain all the enzyme in ES.S2O3 form, thiosulfate was acting as a chemical reagent rather than a substrate in stabilizing enzyme activity.     

Expression of a full-length cDNA encoding bovine adrenal cytochrome P450C21

Two full-length cDNA clones encoding bovine adrenocortical P450C21 have been constructed in a eukaryotic expression vector using partial-length cDNAs whose structures have been previously reported. Following expression of these cDNAs in COS 1 cells, the substrate specificity of P450C21 was determined. Of the 18 steroids tested, progesterone, 17 alpha-hydroxyprogesterone, and 11 beta,17 alpha-dihydroxyprogesterone were found to be the only steroids to serve as substrates for this adrenal enzyme, a much higher degree of substrate specificity than has been reported for a hepatic 21-hydroxylase. The Vmax for 17 alpha-hydroxyprogesterone was 2.5 times greater than that for progesterone, whereas delta 5-steroids were unable to serve as substrate for this enzyme. A difference between the two cDNAs is located at amino acid 401 where one resultant enzyme contains tyrosine while the other contains histidine. This amino acid difference appears to have no effect on the kinetic properties of adrenal P450C21.     

Genome-wide epigenetic alterations in cloned bovine fetuses

To gain a better understanding of global methylation differences associated with development of nuclear transfer (NT)-generated cattle, we analyzed the genome-wide methylation status of spontaneously aborted cloned fetuses, cloned fetuses, and adult clones that were derived from transgenic and nontransgenic cumulus, genital ridge, and body cell lines. Cloned fetuses were recovered from ongoing normal pregnancies and were morphologically normal. Fetuses generated by artificial insemination (AI) were used as controls. In vitro fertilization (IVF) fetuses were compared with AI controls to assess effects of in vitro culture on the 5-methylcytosine content of fetal genomes. All of the fetuses were female. Skin biopsies were obtained from cloned and AI-generated adult cows. All of the adult clones were phenotypically normal and lactating and had no history of health or reproductive disorders. Genome-wide cytosine methylation levels were monitored by reverse-phase HPLC, and results indicated reduced levels of methylated cytosine in NT-generated fetuses. In contrast, no differences were observed between adult, lactating clones and similarly aged lactating cows produced by AI. These data imply that survivability of cloned cattle may be closely related to the global DNA methylation status. This is the first report to indicate that global methylation losses may contribute to the developmental failure of cloned bovine fetuses.     

Pathogenicity of molecularly cloned bovine leukemia virus.

To delineate the mechanisms of bovine leukemia virus (BLV) pathogenesis, four full-length BLV clones, 1, 8, 9, and 13, derived from the transformed cell line FLK-BLV and a clone construct, pBLV913, were introduced into bovine spleen cells by microinjection. Microinjected cells exhibited cytopathic effects and produced BLV p24 and gp51 antigens and infectious virus. The construct, pBLV913, was selected for infection of two sheep by inoculation of microinjected cells. After 15 months, peripheral blood mononuclear cells from these sheep served as inocula for the transfer of infection to four additional sheep. All six infected sheep seroconverted to BLV and had detectable BLV DNA in peripheral blood mononuclear cells after amplification by polymerase chain reaction. Four of the six sheep developed altered B/T-lymphocyte ratios between 33 and 53 months postinfection. One sheep died of unrelated causes, and one remained hematologically normal. Two of the affected sheep developed B lymphocytosis comparable to that observed in animals inoculated with peripheral blood mononuclear cells from BLV-infected cattle. This expanded B-lymphocyte population was characterized by elevated expression of B-cell surface markers, spontaneous blastogenesis, virus expression in vitro, and increased, polyclonally integrated provirus. One of these two sheep developed lymphocytic leukemia-lymphoma at 57 months postinfection. Leukemic cells had the same phenotype and harbored a single, monoclonally integrated provirus but produced no virus after in vitro cultivation. The range in clinical response to in vivo infection with cloned BLV suggests an important role for host immune response in the progression of virus replication and pathogenesis.     

Binding of metal cyanide complexes to bovine liver rhodanese in the crystalline state

Bovine liver rhodanese, which catalyzes the transfer of sulfur atoms between a variety of sulfur donor and sulfur acceptor substrates, is inhibited by metal cyanide complexes [Volini, M., Van Sweringen, B., & Chen, F.-Sh. (1978) Arch. Biochem. Biophys. 191, 205-215]. Crystallographic studies are described which reveal the binding mode of four different metal cyanides to bovine liver rhodanese: Na[Au(CN2], K2[Pt(CN)4], K2[Ni(CN)4], and K2[Zn(CN)4]. It appears that these complexes bind at one common site at the entrance of the active site pocket, interacting with the positively charged side chains of Arg-186 and Lys-249. This observation explains the inhibition of rhodanese by this class of compounds. For the platinum and nickel cyanide complexes virtually no other binding sites are observed. The gold complex binds, however, to three additional cysteine residues, thereby also displacing the extra sulfur atom which was bound to the essential Cys-247 in the sulfur-rhodanese complex. The zinc complex binds to completely different additional sites and forms complexes with the side chains of Asp-101 and His-203. Possible reasons for these different binding modes are discussed in terms of the preference for "hard" and "soft" ligands of these four metal ions.     

体细胞克隆牛产品安全分析

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