The human Hb (mu) class glutathione S-transferases are encoded by a dispersed gene family

The human glutathione S-transferases are products of a gene superfamily which consists of at least four gene families. The various glutathione S-transferase genes are located on different human chromosomes, and new gene(s) are still being added to the gene superfamily. We have characterized a cDNA in pGTH4 encoding human glutathione S-transferase subunit 4 (GST mu) and mapped its gene (or a homologous family member) on chromosome 1 at p31 by in situ hybridization. Genomic Southern analysis with the 3' noncoding region of the cDNA revealed at least four human DNA fragments with highly homologous sequences. Using a panel of DNAs from mouse-human somatic cell hybrids in genomic DNA hybridization we show that the Hb (or B) genes of human glutathione S-transferases are on three separate chromosomes: 1, 6, and 13. Therefore, the glutathione S-transferase B gene family, which encodes the Hb (mu) class subunits, is a dispersed gene family. The GST mu (psi) gene, whose expression is polymorphic in the human population, is probably located on chromosome 13. We propose that the GST mu (psi) gene was created by a transposition or recombination event during evolution. The null phenotype may have resulted from a lack of DNA transposition just as much as from the deletion of an inserted gene.     

Specific expression of activation-induced cytidine deaminase (AID), a novel member of the RNA-editing deaminase family in germinal center B cells.

We have identified a novel gene referred to as activation-induced deaminase (AID) by subtraction of cDNAs derived from switch-induced and uninduced murine B lymphoma CH12F3-2 cells, more than 80% of which switch exclusively to IgA upon stimulation. The amino acid sequence encoded by AID cDNA is homologous to that of apolipoprotein B (apoB) mRNA-editing enzyme, catalytic polypeptide 1 (APOBEC-1), a type of cytidine deaminase that constitutes a catalytic subunit for the apoB mRNA-editing complex. In vitro experiments using a glutathione S-transferase AID fusion protein revealed significant cytidine deaminase activity that is blocked by tetrahydrouridine and by zinc chelation. However, AID alone did neither demonstrate activity in C to U editing of apoB mRNA nor bind to AU-rich RNA targets. AID mRNA expression is induced in splenic B cells that were activated in vitro or by immunizations with sheep red blood cells. In situ hybridization of immunized spleen sections revealed the restricted expression of AID mRNA in developing germinal centers in which modulation of immunoglobulin gene information through somatic hypermutation and class switch recombination takes place. Taken together, these findings suggest that AID is a new member of the RNA-editing deaminase family and may play a role in genetic events in the germinal center B cell.     

腺苷酸脱氨酶在乳酸克鲁维酵母中构建表达

【目的】实现鼠灰链霉菌来源经密码子优化后的腺苷酸脱氨酶基因在乳酸克鲁维酵母(Kluyveromyces lactis GG799)中组成型表达。【方法】以鼠灰链霉菌(Streptomyces murinus)来源的腺苷酸脱氨酶(AMP)基因经密码子优化后作为模板,设计特异性引物,PCR扩增AMP脱氨酶基因opt-AMPD,以p KLAC1为载体构建重组表达质粒p KLAC1-opt-AMPD,经Sac II线性化后电转化法转入K.lactis GG799,筛选得到重组菌株,测定酶活,经His TrapTM HP纯化后得到AMP脱氨酶,并优化重组菌的发酵培养基。【结果】对AMP脱氨酶基因进行了密码子优化后,构建了重组K.lactis GG799/p KLAC1-opt-AMPD,实现组成型表达,密码子优化后AMP脱氨酶酶活提高到586±50 U/m L。SDS-PAGE结果显示,纯化后的AMP脱氨酶为单一条带,蛋白大小约为60 k D。优化的发酵培养基为(g/L):葡萄糖40、蛋白胨20、酵母粉15、Na Cl 8、KCl 10、Mg SO4 2,30°C、200 r/min发酵120 h,酶活达到2 100±60 U/m L。【结论】实现了密码子优化后的腺苷酸脱氨酶基因在乳酸克鲁维酵母GG799内的组成型表达,为实现腺苷酸脱氨酶的重组高效表达和发酵生产进行了有益探索。     

Nitration of tyrosine 92 mediates the activation of rat microsomal glutathione s-transferase by peroxynitrite

There is increasing evidence that protein function can be modified by nitration of tyrosine residue(s), a reaction catalyzed by proteins with peroxidase activity, or that occurs by interaction with peroxynitrite, a highly reactive oxidant formed by the reaction of nitric oxide with superoxide. Although there are numerous reports describing loss of function after treatment of proteins with peroxynitrite, we recently demonstrated that the microsomal glutathione S-transferase 1 is activated rather than inactivated by peroxynitrite and suggested that this could be attributed to nitration of tyrosine residues rather than to other effects of peroxynitrite. In this report, the nitrated tyrosine residues of peroxynitrite-treated microsomal glutathione S-transferase 1 were characterized by mass spectrometry and their functional significance determined. Of the seven tyrosine residues present in the protein, only those at positions 92 and 153 were nitrated after treatment with peroxynitrite. Three mutants (Y92F, Y153F, and Y92F, Y153F) were created using site-directed mutagenesis and expressed in LLC-PK1 cells. Treatment of the microsomal fractions of these cells with peroxynitrite resulted in an approximately 2-fold increase in enzyme activity in cells expressing the wild type microsomal glutathione S-transferase 1 or the Y153F mutant, whereas the enzyme activity of Y92F and double site mutant was unaffected. These results indicate that activation of microsomal glutathione S-transferase 1 by peroxynitrite is mediated by nitration of tyrosine residue 92 and represents one of the few examples in which a gain in function has been associated with nitration of a specific tyrosine residue.     

The Drosophila glutathione S-transferase 1-1 is encoded by an intronless gene at 87B

The Drosophila glutathione S-transferase 1-1 is a dimer of a 209 amino acid subunit, designated DmGST1. DmGST1 is encoded by a member of a multigene family. Sequence analysis of a genomic clone for GST1 revealed that it is encoded by an intronless gene. We designate this gene and its other family members the GST D genes in the glutathione S-transferase gene superfamily. The Drosophila GST D genes are mapped by in situ hybridization to chromosome 3R at 87B of the polytene chromosome, which is flanked by the two clusters of hsp70 genes at 87A7 and 87C1. Cytogenetic data in the literature indicated that a puff occurred in this region under heat shock. We report that the glutathione S-transferase activity in Kco cells as determined by conjugation with 1-chloro-2,4-dinitrobenzene is elevated slightly to two-fold under heat shock. The implication of this finding is discussed.     

The molecular basis of two contrasting metabolic mechanisms of insecticide resistance

The esterase-based insecticide resistance mechanisms characterised to date predominantly involve elevation of activity through gene amplification allowing increased levels of insecticide sequestration, or point mutations within the esterase structural genes which change their substrate specificity. The amplified esterases are subject to various types of gene regulation in different insect species. In contrast, elevation of glutathione S-transferase activity involves upregulation of multiple enzymes belonging to one or more glutathione S-transferase classes or more rarely upregulation of a single enzyme. There is no evidence of insecticide resistance associated with gene amplification in this enzyme class. The biochemical and molecular basis of these two metabolically-based insecticide resistance mechanisms is reviewed.     

Structural studies on human glutathione S-transferase pi. Substitution mutations to determine amino acids necessary for binding glutathione.

In order to identify amino acids involved in binding the co-substrate glutathione to the human glutathione S-transferase (GST) pi enzyme, we assembled three criteria to implicate amino acids whose role in binding and catalysis could be tested. Presence of a residue in the highly conserved exon 4 of the GST gene, positional conservation of a residue in 12 glutathione S-transferase amino acid sequences, and results from published chemical modification studies were used to implicate 14 residues. A bacterial expression vector (pUC120 pi), which enabled abundant production (2-26% of soluble Escherichia coli protein) of wild-type or mutant GST pi, was constructed, and, following nonconservative substitution mutation of the 14 implicated residues, five mutants (R13S, D57K, Q64R, I68Y, L72F) showed a greater than 95% decrease in specific activity. A quantitative assay was developed which rapidly measured the ability of wild-type or mutant glutathione S-transferase to bind to glutathione-agarose. Using this assay, each of the five loss of function mutants showed a greater than 20-fold decrease in binding glutathione, an observation consistent with a recent crystal structure analysis showing that several of these residues help to form the glutathione-binding cleft.     

Preferential amplification of rearranged sequences near amplified adenylate deaminase genes.

In a previous study of three independent families of mutants selected for overproduction of adenylate deaminase (AMPD), we were not able to isolate a cDNA probe for the gene and so could not demonstrate its amplification directly. In addition to overproduction of AMPD, four proteins of unknown function, designated W, X, Y1, and Y2, accumulated, and by using the corresponding cDNA probes, we demonstrated amplification of all four genes. In independent mutant clones, sometimes all and sometimes only a subset of these genes were amplified. Assuming that all five genes are linked, the pattern of their coamplification suggested a genetic map in which AMPD lies between W and Y1. We show here that a two-step chromosome walk joins the W and Y1 genes, that the AMPD gene is the only expressed sequence between them, and that its amplification is indeed responsible for overproduction of the AMPD protein. In the course of this work, we cloned and studied two novel joints which mark rearrangements on either side of the AMPD gene. Each joint was generated independently in a single first-step mutant at single or low copy number. Remarkably, each joint was amplified preferentially in every second- and third-step mutant derived from the first-step line in which it was originally present, suggesting that the two independent rearrangements each generated amplification-prone structures.     

Glucocorticoid, androgen, and retinoic acid regulation of glutathione S-transferase gene expression in hamster smooth muscle tumor cells.

A mu class glutathione S-transferase gene (hGSTYBX) is expressed in the DDT1MF-2 hamster smooth muscle tumor cell line. This gene is glucocorticoid responsive, and near maximal induction was found to occur within 24 h. The induced mRNA was very stable with a half-life of more than 48 h. Serum had no effect on either constitutive or glucocorticoid induced hGSTYBX expression. Although dibutyryl cAMP, phenobarbital, and 12-O-tetradecanoylphorbol-13-acetate did not alter hGSTYBX expression, testosterone and retinoic acid were each able to increase hGSTYBX expression in a concentration dependent manner. These results demonstrate a unique pattern of responsiveness of the hamster gene compared to the glutathione S-transferase genes of other species.     

Glutathione S-transferases in human prostate

A number of human prostatic tissue biopsies have been analyzed for glutathione S-transferase activity, using 1-chloro-2,4-dinitrobenzene (CDNB) as a substrate. Samples from nine patients (age range 61-90) with benign prostatic hypertrophy who had received no prior chemotherapy had a mean glutathione S-transferase activity of 137 +/- 44 nmol/min per mg with a range of 97-237. A qualitative comparison of the glutathione S-transferase of normal prostate and benign prostatic hypertrophy samples was carried out. Approximately 260-fold purification was achieved using glutathione-Sepharose affinity chromatography, with glutathione S-transferase accounting for approximately 0.19-0.33% of the total protein. Substrate specificity determinations suggested similar, but not identical, glutathione S-transferase subunits in normal prostate and benign prostatic hypertrophy. One- and two-dimensional electrophoresis (isoelectric focusing and 12.5% SDS-polyacrylamide gel electrophoresis) identified at least seven stained polypeptides in the purified glutathione S-transferase preparations. These ranged in Mr from approximately 24,000 to 28,500 and in pI from near neutral to basic. Western blot analysis using polyclonal antibodies raised against rat liver glutathione S-transferase suggested crossreactivity with five of the human isoenzymes in both normal prostate and benign prostatic hypertrophy. One of the glutathione S-transferases, present in both normal prostate and benign prostatic hypertrophy, had an Mr of approx. 24,000 and a near-neutral pI and crossreacted immunologically with a polyclonal antibody raised against human placental glutathione S-transferase (Yf, subunit 7 or pi). These data suggest that four glutathione S-transferases are expressed in human prostate, with subunits from each of the major classes alpha, mu and pi. These are characterized as Ya, Yb, Yb' and Yf (analogous alternative nomenclature subunits 1, 3, 4 and 7).     

Structural basis of hematopoietic prostaglandin D synthase activity elucidated by site-directed mutagenesis

Hematopoietic prostaglandin (PG) D synthase (PGDS) is the first identified vertebrate ortholog in the Sigma class of the glutathione S-transferase (GST) family and catalyzes both isomerization of PGH(2) to PGD(2) and conjugation of glutathione to 1-chloro-2, 4-dinitrobenzene. We introduced site-directed mutations of Tyr(8), Arg(14), Trp(104), Lys(112), Tyr(152), Cys(156), Lys(198), and Leu(199), which are presumed to participate in catalysis or PGH(2) substrate binding based on the crystallographic structure. Mutants were analyzed in terms of structure, GST and PGDS activities, and activation of the glutathione thiol group. Of all the mutants, only Y8F, W104I, K112E, and L199F showed minor but substantial differences in their far-UV circular dichroism spectra from the wild-type enzyme. Y8F, R14K/E, and W104I were completely inactive. C156L/Y selectively lost only PGDS activity. K112E reduced GST activity slightly and PGDS activity markedly, whereas K198E caused a selective decrease in PGDS activity and K(m) for glutathione and PGH(2) in the PGDS reaction. No significant changes were observed in the catalytic activities of Y152F and L199F, although their K(m) for glutathione was increased. Using 5,5'-dithiobis(2-nitrobenzoic acid) as an SH-selective agent, we found that only Y8F and R14E/K did not accelerate the reactivity of the glutathione thiol group under the low reactivity condition of pH 5.0. These results indicate that Lys(112), Cys(156), and Lys(198) are involved in the binding of PGH(2); Trp(104) is critical for structural integrity of the catalytic center for GST and PGDS activities; and Tyr(8) and Arg(14) are essential for activation of the thiol group of glutathione.     

Invited Commentary Potential Contribution of the Glutathione S-Transferase Supergene Family to Resistance to Oxidative Stress

The glutathione S-transferase (GST) supergene family comprises gene families that encode isoenzymes that are widely expressed in mammalian tissue cytosols and membranes. Both cytosolic (particularly the isoenzymes encoded by the alpha, mu and theta gene families) and microsomal GST catalyse the conjugation of reduced glutathione (GSH) with a wide variety of electrophiles which include known carcinogens as well as various compounds that are products of oxidative stress including oxidised DNA and lipid. Indeed, several lines of evidence suggest certain of these isoenzymes play a pivotal role in protecting cells from the consequences of such stress. An assessment of the importance of these GST in humans is presently difficult however, because the number of alpha and theta class genes is not known and, the catalytic preferences of even identified isoforms is not always clear.     

Invited Commentary Potential Contribution of the Glutathione S-Transferase Supergene Family to Resistance to Oxidative Stress

The glutathione S-transferase (GST) supergene family comprises gene families that encode isoenzymes that are widely expressed in mammalian tissue cytosols and membranes. Both cytosolic (particularly the isoenzymes encoded by the alpha, mu and theta gene families) and microsomal GST catalyse the conjugation of reduced glutathione (GSH) with a wide variety of electrophiles which include known carcinogens as well as various compounds that are products of oxidative stress including oxidised DNA and lipid. Indeed, several lines of evidence suggest certain of these isoenzymes play a pivotal role in protecting cells from the consequences of such stress. An assessment of the importance of these GST in humans is presently difficult however, because the number of alpha and theta class genes is not known and, the catalytic preferences of even identified isoforms is not always clear.     

Segregation and rearrangement of coamplified genes in different lineages of mutant cells that overproduce adenylate deaminase.

Four genes encoding proteins designated as W, X, Y1, and Y2 were found previously to be amplified at different levels in a Chinese hamster fibroblast mutant line selected for overproduction of adenylate deaminase. To gain information on the molecular mechanisms responsible, we studied the levels of amplification and the structures of these four genes in several lineages of mutant cells with comparable activities of adenylate deaminase, the selected enzyme. Only the W gene was amplified in all the lines. In one line, the X, Y1, and Y2 genes were coamplified, while in others either the Y1 gene or the pair X and Y2 were coamplified. The results were consistent with linkage of all the genes--in a particular order--in an amplifiable sequence with variable endpoints. Novel joints with a nonrandom distribution were observed. We frequently detected rearranged copies of the W gene, but very few novel joints were present in the other three genes in the six highly amplified lines examined. Some of the novel joints in gene W were highly amplified; they were generated by reamplification of a rearrangement that appeared at an early selection step. In some lines, reamplification was accompanied by deletion or mass correction of preexisting units. We discuss mechanisms which might account for these observations.     

Glutathione S-transferase in chemotherapy resistance and in carcinogenesis.

Cytosolic glutathione S-transferases are composed of two monomeric subunits. These monomers are the products of different gene families designated alpha, mu, and pi. Dimerization yields either homodimeric or heterodimeric holoenzymes within the same family. The members of this complex group of proteins have been linked to the detoxification of environmental chemicals and carcinogens, and have been shown to be overexpressed in normal and tumor cells following exposure to cytotoxic drugs. They also are overexpressed in carcinogen-induced rat liver preneoplastic nodules in rat liver. In all of these cases, the changes in expression of glutathione S-transferases are paralleled by increased resistance to cytotoxic chemicals. The degree of resistance is related to the substrate specificity of the isozyme. The relationship of the glutathione S-transferase genes to drug resistance has been directly demonstrated by gene transfer studies, where cDNAs encoding the various subunits of glutathione S-transferase have been transfected into a variety of cell types. This review discusses the results of numerous studies that associate resistance to alkylating agents with overexpression of protective detoxifying glutathione S-transferase enzymes.     

Site-directed mutagenesis of glutathione S-transferase YaYa. Important roles of tyrosine 9 and aspartic acid 101 in catalysis.

The roles of tyrosine 9 and aspartic acid 101 in the catalytic mechanism of rat glutathione S-transferase YaYa were studied by site-directed mutagenesis. Replacement of tyrosine 9 with phenylalanine (Y9F), threonine (Y9T), histidine (Y9H), or valine (Y9V) resulted in mutant enzymes with less than 5% catalytic activity of the wild type enzymes. Kinetic studies with purified Y9F and Y9T mutants demonstrated poor catalytic efficiencies which were largely due to a drastic decrease in kcat. The estimated pK alpha values of the sulfhydryl group of glutathione bound to Y9F and Y9T mutant enzymes were 8.5 to 8.7, similar to the chemical reaction, in contrast to the estimated pK alpha value of 6.7 to 6.8 for the glutathione enzyme complex of wild type glutathione S-transferase. These results indicate that tyrosine 9 is directly responsible for the lowering of the pKa of the sulfhydryl group of glutathione, presumably due to the stabilization of the thiolate anion through hydrogen bonding with the hydroxyl group of tyrosine. To examine the role of aspartic acid in the binding of glutathione to YaYa, 4 conserved aspartic acid residues at positions 61, 93, 101, and 157 were changed to glutamic acid and asparagine. All mutant enzymes retained either full or partial activity except D157N, which was virtually inactive. Kinetic studies with four mutant enzymes (D93E, D93N, D101E, and D101N) indicate that only D101N exhibited a 5-fold increase in Km toward glutathione. Also, the binding of this mutant to the affinity column was greatly reduced. These results demonstrate that aspartic acid 101 plays an important role in glutathione interaction to YaYa. The role of aspartic acid 157 in catalysis remains to be determined.     

用GAP启动子在Pichia pastoris GS115中组成型表达鼠灰链霉菌腺苷酸脱氨酶

【目的】构建产AMP脱氨酶的重组毕赤酵母(Pichia pastoris GS115)菌株,并初步优化其发酵条件。【方法】以鼠灰链霉菌(Streptomyces murinus)基因组为模板PCR扩增获得腺苷酸脱氨酶基因AMPD,以pGAP9K为载体构建重组表达质粒pGAP9K-AMPD并通过电转化法转入Pichia pastoris GS115,筛选转化子对其酶活进行测定,并初步优化其发酵条件。【结果】构建了毕赤酵母重组菌,通过分光光度法测定,显示重组菌有明显的酶活;初步优化发酵条件为:该重组菌最适发酵培养基为:甘油2%,蛋白胨2%,酵母膏1%,KH2PO40.5%,MgSO4·7H2O0.05%,pH 6.0;发酵条件为:接种龄24 h,转接量3%,30°C﹑200 r/min培养96 h,取发酵上清液测定酶活,重组菌腺苷酸脱氨酶酶活达到2 230±60 U/mL。【结论】构建了一株产AMP脱氨酶活性较高的重组毕赤酵母菌株,并通过优化发酵条件使其酶活达到2 230±60 U/mL。为AMP脱氨酶工业化生产奠定了一定的基础。     

Cooperative binding of the class I major histocompatibility complex cytoplasmic domain and human immunodeficiency virus type 1 Nef to the endosomal AP-1 complex via its mu subunit

Human immunodeficiency virus type 1 Nef provides immune evasion by decreasing the expression of major histocompatibility complex class I (MHC-I) at the surfaces of infected cells. The endosomal clathrin adaptor protein complex AP-1 is a key cellular cofactor for this activity, and it is recruited to the MHC-I cytoplasmic domain (CD) in the presence of Nef by an uncharacterized mechanism. To determine the molecular basis of this recruitment, we used an MHC-I CD-Nef fusion protein to represent the MHC-I CD/Nef complex during protein interaction assays. The MHC-I CD had no intrinsic ability to bind AP-1, but it conferred binding activity when fused to Nef. This activity was independent of the canonical leucine-based AP-binding motif in Nef; it required residue Y320 in the MHC-I CD and residues E62-65 and P78 in Nef, and it involved the mu but not the gamma/sigma subunits of AP-1. The impaired binding of mutants encoding substitutions of E62-65 or P78 in Nef was rescued by replacing the Y320SQA sequence in the MHC-I CD with YSQL, suggesting that Nef allows the YSQA sequence to act as if it were a canonical mu-binding motif. These data identify the mu subunit of AP-1 (mu1) as the key target of the MHC-I CD/Nef complex, and they indicate that both Y320 in the MHC-I CD and E62-65 in Nef interact directly with mu1. The data support a cooperative binding model in which Nef functions as a clathrin-associated sorting protein that allows recognition of an incomplete, tyrosine-based mu-binding signal in the MHC-I CD by AP-1.     

The subunit structure of a major glutathione S-transferase form, MT, in rat testis. Evidence for a heterodimer consisting of subunits with different isoelectric points

A major glutathione S-transferase form (pI 5.7) in rat testis (MT) purified by S-hexyl-glutathione affinity chromatography, followed by chromatofocusing, showed two polypeptide of pI 6.7 (Yn1) and 6.0 (Yn2), having apparently the same molecular mass of 26 kDa on two-dimensional gel electrophoresis. Rechromatofocusing of the MT preparation after 4 M guanidine hydrochloride treatment revealed two additional protein peaks (pI 6.2 and 5.4). These were identified as the two homodimers consisting of the subunits of MT, Yn1Yn1 and Yn2Yn2, respectively. Furthermore, MT could be reconstituted from Yn1Yn1 and Yn2Yn2. These results indicate that MT is a heterodimer, Yn1Yn2, consisting of subunits with very similar molecular masses but different isoelectric points. The Yn1Yn1 form had glutathione S-transferase activities towards 1-chloro-2,4-dinitrobenzene and 1,2-dichloro-4-nitrobenzene. However, the Yn2Yn2 form had no activity towards any of the substrates examined. N-terminal amino acid sequences of subunits Yn1 and Yn2 revealed differences at two positions in the first 20 residues; the amino acid compositions of these subunits were also similar but not identical, indicating that these two subunits are different in the primary structure. Subunits Yn1 and Yn2 are immunologically related to each other and also to subunits 3 (Yb1) and 4 (Yb2) but they are not identical. These four subunits also showed a high degree of similarity in N-terminal amino acid sequences. Subunits Yn1 and Yn2 seem to belong to the rat GST 3-4 family or class mu. Subunits Yn1 and 4 can make a heterodimer, which is detectable not only in rat testis, but also in the heart, kidney and lung. The Yn1Yn1 form was not detected in the testis, but is present in rat brain [Tsuchida et al. (1987) Eur. J. Biochem. 170, 159-164]. The Yn2Yn2 form seemed to differ from GST 5-5 and may be a new form of rat glutathione S-transferase.     

Cloning and partial characterization of a Boophilus microplus (Acari: Ixodidae) glutathione S-transferase

A cDNA of glutathione S-transferase (GST) was isolated from a cDNA library of salivary glands of Boophilus microplus. The recombinant protein was purified by glutathione affinity chromatography and assayed upon the chromogenic substrate CDNB. The 864 bp cloned fragment was sequenced and showed an open reading frame coding for a protein of 220 amino acids. Expression of the GST gene was tested by RT-PCR in tick tissues and larvae mRNA. Comparison of the deduced amino acid sequence with GSTs from other species revealed that the enzyme is closely related to the mammalian class mu GSTs.