Shivendra V. Singh

Primary and secondary structural analyses of glutathione S-transferase π from human placenta☆

Abstract The primary structure of glutathione S-transferase (GST) π from a single human placenta was determined. The structure was established by chemical characterization of tryptic and cyanogen bromide peptides as well as automated sequence analysis of the intact enzyme. The structural analysis indicated that the protein is comprised of 209 amino acid residues and gave no evidence of post-translational modifications. The amino acid sequence differed from that of the deduced amino acid sequence determined by nucleotide sequence analysis of a cDNA clone (Kano, T., Sakai, M., and Muramatsu, M., 1987, Cancer Res. 47 , 5626–5630) at position 104 which contained both valine and isoleucine whereas the deduced sequence from nucleotide sequence analysis identified only isoleucine at this position. These results demonstrated that in the one individual placenta studied at least two GST π genes are coexpressed, probably as a result of allelomorphism. Computer assisted consensus sequence evaluation identified a hydrophobic region in GST π (residues 155–181) that was predicted to be either a buried transmembrane helical region or a signal sequence region. The significance of this hydrophobic region was interpreted in relation to the mode of action of the enzyme especially in regard to the potential involvement of a histidine in the active site mechanism. A comparison of the chemical similarity of five known human GST complete enzyme structures, one of π, one of μ, two of α, and one microsomal, gave evidence that all five enzymes have evolved by a divergent evolutionary process after gene duplication, with the microsomal enzyme representing the most divergent form.

Differential expression of α, μ and π classes of isozymes of glutathione S-transferase in bovine lens, cornea, and retina

Abstract Isozyme characterization of glutathione S-transferase (GST) isolated from bovine ocular tissue was undertaken. Two isozymes of lens, GST 7.4 and GST 5.6, were isolated and found to be homodimers of a Mr 23,500 subunit. Amino acid sequence analysis of a 20-residue region of the amino terminus was identical for both isozymes and was identical to GST ψ and GST μ of human liver. Antibodies raised against GST ψ cross-reacted with both lens isozymes. Although lens GST 5.6 and GST 7.4 demonstrated chemical and immunological relatedness, they were distinctly different as evidenced by their pI and comparative peptide fingerprint. A corneal isozyme, GST 7.2, was also isolated and established to be a homodimer of Mr 24,500 subunits. Sequence analysis of the amino-terminal region indicated it to be about 67% identical with the GST π isozyme of human placenta. Antibodies raised against GST π cross-reacted with cornea GST 7.2. Another corneal isozyme, GST 8.7, was found to be a homodimer of Mr 27,000 subunits. Sequence analysis revealed it to have a blocked amino-terminus. GST 8.7 immunologically cross-reacted with the antibodies raised against cationic isozymes of human liver indicating it to be of the α class. Two isozymes of retina, GST 6.8 and GST 6.3, were isolated and identified to be heterodimers of subunits of Mr 23,500 and 24,500. Amino-terminal sequence analysis gave identical results for both retina GST 6.8 and GST 6.3. The sequence analysis of the Mr 23,500 subunit was identical to that obtained for lens GSTs. Similarly, sequence analysis of the Mr 24,500 subunit was identical to that obtained for the cornea GST 7.2 isozyme. Both the retina isozymes cross-reacted with antibodies raised against human GST ψ as well as GST π. The results of these studies indicated that all three major classes of GST isozymes were expressed in bovine eye but the GST genes were differentially expressed in lens, cornea, and retina. In lens only the μ class of GST was expressed, whereas cornea expressed α and π classes and retina expressed μ and π classes of GST isozymes.

Glutathione and glutathione S-transferases in a human plasma cell line resistant to melphalan

We report the development of a melphalan-resistant HS-Sultan human plasma cell line. The melphalan-resistant [MEL(R)] cell line was 16.7-fold more resistant to melphalan in vitro than the parent cell line [MEL(S)]. The wild type and MEL(R) HS-Sultan cell lines formed localized plasmacytomas when injected into nude mice. A dose-response effect of melphalan against the drug-sensitive plasmacytomas was present in vivo. A dose of 10 mg/kg of melphalan, which caused a 90% regression of MEL(S) plasmacytomas, had no effect on the MEL(R) plasmacytomas in vivo. In contrast to previous reports, there was no increase in the levels of glutathione (GSH) in the MEL(S) and MEL(R) plasmacytomas, suggesting that the association of elevated glutathione levels and melphalan resistance may not be common to all drug-resistant lines. In the MEL(R) plasmacytomas, there was a 1.5-fold induction of a pi type glutathione S-transferase (GST) as evidenced by isoelectric focusing (IEF) and Western blotting. This GST isoenzyme was purified and, although immunochemically similar to the pi type isoenzymes induced in other drug-resistant cell lines, was noted to have different functional characteristics. These data suggest that, depending on cell type and the drug studied, functionally different GST isoenzymes may be induced and they could be of importance in the development of drug resistance.

Purification and characterization of a new form of glutathione S-transferase from human erythrocytes

Presence of a new form of glutathione S-transferase has been demonstrated in human erythrocytes. Using two different affinity ligands this enzyme has been separated from the previously characterized glutathione S-transferases rho. The new enzyme is highly basic with a pI of greater than 10. The new enzyme which represents less than 5 percent of glutathione-S-transferase activity towards 1-chloro-2,4-dinitrobenzene as substrate and about 10 percent of total glutathione S-transferase protein of erythrocytes has different amino acid composition, substrate specificities, and immunological characteristics from those of the major erythrocyte glutathione S-transferase rho. Immunological properties of the new enzyme indicate that this form may be different from other glutathione S-transferases of human tissues.

A novel dinitrophenylglutathione-stimulated ATPase is present in human erythrocyte membranes.

Vesicles prepared from human erythrocyte membranes were found to catalyze ATP hydrolysis that was stimulated by dinitrophenylglutathione (Dnp‐SG). This activity was dependent on temperature and Me2+ and independent of ion pump ATPases present in erythrocyte membranes. The activity was a linear function of protein and time up to 60 min. The K m values of ATPase for Dnp‐SG and ATP were found to be 49 μM and 1.67 mM, respectively. This suggests that in erythrocytes, the transport of Dnp‐SG requires direct enzymatic hydrolysis of ATP and both Dnp‐SG‐stimulated ATPase activity and the ATP‐dependent efflux of Dnp‐SG from erythrocytes represent different activities of the same protein.

Evidence for different transport systems for oxidized glutathione and S-dinitrophenyl glutathione in human erythrocytes

The effect of oxidized glutathione (GSSG) on the ATP-dependent transport of S-dinitrophenyl glutathione (Dnp-SG) by inside-out vesicles prepared from human erythrocytes and by intact erythrocytes has been studied. It is demonstrated that the transport of Dnp-SG is not inhibited by GSSG in either intact erythrocytes or in inside-out vesicles. These results suggest that Dnp-SG and GSSG are transported out of human erythrocytes by separate systems.

Purification and characterization of unique glutathione S-transferases from human muscle.

Results of studies designed to investigate the origin of the diversity of glutathione S-transferase (GST) isozymes in human tissues indicated that human muscle has at least three forms of GST with pI values of 5.0, 5.1, and 5.2 that are distinct from GST isozymes characterized so far. The major muscle isozyme which was expressed in all the six samples analyzed in this study was a unique GST of pI 5.2 that was designated as GST zeta. It had a blocked N-terminal and did not correspond to any of the known three classes (alpha, mu, or pi) of human GST as evidenced by its immunological properties and substrate specificities. The N-terminal regions of human muscle GST 5.1 and 5.0 had identical amino acid sequences except at residue 5, but demonstrated significant differences in amino acid composition and substrate specificities. These two isozymes showed homology with the mu class of human GST in their N-terminal region and were also immunologically related to the mu class of human GST although their subunit molecular weight values (Mr 23,000) were lower than that reported for GST psi. The substrate specificities of these isozymes were also significantly different from those of other human GST isozymes characterized so far. Significantly, muscle tissue did not express the alpha class of GST isozymes; however, two other isozymes were identified, GST 4.8 and GST 4.5, which had identical N-terminal amino acid sequences that were similar to that reported for the pi class of human GST. GST 4.8 was present in all six samples analyzed in this study whereas GST 4.5 was present in only two of these samples, indicating a possibility of polymorphism at the GST3 locus. This study indicated the occurrence of at least three distinct isozymes in muscle tissue, providing further evidence for tissue specific expression of GST isozymes in humans.

Purification and characterization of glutathione S-transferases in human retina.

Human retina has two forms of glutathione (GSH) S-transferases. These forms having pI 4.5 and greater than 10 have been purified and their kinetic, structural and immunological characteristics are described. Both the enzymes of human retina do not express glutathione peroxidase II activity. The anionic enzyme (pI 4.5) of retina cross reacts with the antibodies raised against the anionic GSH S-transferases of human lung and placenta but does not cross react with the antibodies raised against the cationic enzymes of human liver. On the other hand, the cationic enzyme (pI greater than 10) of human retina cross reacts with the antibodies raised against the cationic GSH S-transferases of human liver but not with antibodies raised against the anionic enzymes of lung and placenta. Differences in the kinetic characteristics of the two forms of human retinal GSH S-transferases are also indicated. Results of these studies suggest that the anionic enzyme of retina may be similar to the anionic enzymes of lung and placenta. However, the cationic form appears to be different from all other GSH S-transferases of human tissues characterized so far. Human retina has selenium dependent glutathione peroxidase I and in this respect is different from bovine retina which has no glutathione peroxidase I as demonstrated in earlier studies.

Evidence for the involvement of histidine at the active site of glutathione S-transferase ψ from human liver

The inhibition of catalytic activity of glutathione S-transferase psi (pI 5.5) of human liver by diethylpyrocarbonate (DEPC) has been studied. It is demonstrated that DEPC causes a concentration dependent inactivation of GST psi with a concomitant modification of 1-1.3 histidyl residues/subunit of the enzyme. This inactivation of GST psi could be reversed by treatment with hydroxylamine. Glutathione afforded complete protection to the enzyme from inactivation by DEPC. It is suggested that a functional histidyl residue is essential for the catalytic activity of the enzyme and that this residue is most likely to be present at or near the glutathione binding site (G-site).

Subunit structure of human and rat glutathione S-transferases

In rat tissues different forms of glutathione (GSH) S-transferases represent various dimeric combinations of at least four different classes of subunits categorized on the basis of their Mr values as seen on polyacrylamide gels. These subunit types represent heterogeneous populations and the actual number of subunits in rat GSH S-transferases may be far more than is known at present. Human GSH S-transferases arise from dimeric combinations of at least four immunologically and functionally distinct subunits which can be classified into three types, A (Mr 26,500), B (Mr 24,500) and C (Mr 22,500). There is evidence for considerable charge heterogeneity in each of these subunit types.