Nucleotide sequence of class-alpha glutathione S-transferases from chicken liver

Aflatoxin B1 in poultry liver: Toxic mechanism

Aflatoxin B1 (AFB1) is the most common carcinogenic toxin in livestock and poultry feed, seriously endangering poultry production and public health. Liver is the most important organ for the metabolism of exogenous and endogenous substances in the body. AFB1 produces toxicity under the biotransformation of cytochrome P450 microparticle oxidase (CYP450). Hepatocytes are the most important cells for synthesizing CYP450 enzymes, so that AFB1 has the most significant effect on the liver. AFB1 can induce liver cell damage in poultry through a variety of molecular mechanisms, and the main of damage mechanisms have been discovered so far include oxidative damage, promoting apoptosis, influencing hepatocyte gene expression, interfering with hepatocyte autophagy, pyroptosis and necroptosis. This article reviewed the molecular mechanism of AFB1 inducing liver injury in poultry, hopefully, to provid a new direction and theoretical basis for the development of a new AFB1 detoxification method.

Aflatoxin B1 in poultry: toxicology, metabolism and prevention

Aflatoxins (AF) are ubiquitous in corn-based animal feed and causes hepatotoxic and hepatocarcinogenic effects. The most important AF in terms of toxic potency and occurrence is aflatoxin B1 (AFB1). Poultry, especially turkeys, are extremely sensitive to the toxic and carcinogenic action of AFB1, resulting in millions of dollars in annual losses to producers due to reduced growth rate, increased susceptibility to disease, reduced egg production and other adverse effects. The extreme sensitivity of turkeys and other poultry to AFB1 is associated with efficient hepatic cytochrome P450-mediated bioactivation and deficient detoxification by glutathione S-transferases (GST). Discerning the biochemical and molecular mechanisms of this extreme sensitivity of poultry to AFB1, will contribute in the development of novel strategies to increase aflatoxin resistance. Since AFB1 is an unavoidable contaminant of corn-based poultry feed, chemoprevention strategies aimed at reducing AFB1 toxicity in poultry and in other animals have been the subject of numerous studies. This brief review summarizes many of the key recent findings regarding the action of aflatoxins in poultry.

Cloning and expression of alpha class glutathione S-transferase gene from the small hermaphroditic fish Rivulus marmoratus (Cyprinodontiformes, Rivulidae)

In order to assess its potential as a biomarker of aquatic pollution, an alpha class glutathione S-transferase gene (GSTalpha gene) was cloned from the small hermaphroditic fish Rivulus marmoratus. The R. marmoratus GSTalpha gene spanned 1.3 kb, consisting of 6 exons encoding 221 amino acid residues. It showed high similarity to zebrafish GST. We named this R. marmoratus GSTalpha gene as rm-GSTalpha. The cDNA of the rm-GSTalpha gene was also investigated for its phylogeny, tissue-specific and chemical-induced expression. Rm-GSTalpha was subcloned into a 6 x His-tagged pCRT7 TOPO TA expression vector to produce the recombinant 6 x His-tagged rm-GST protein. This will be used in future to raise an rm-GSTalpha antibody for use in the study of phase II metabolism involved in detoxification. We also exposed R. marmoratus to 300 microg/l of 4-nonylphenol in water, and found approximately 4-fold induction of R. marmoratus GSTalpha mRNA in the treated animals. In this paper, we discuss the characteristics of the R. marmoratus GSTalpha gene as well as its potential use in relation to environmental pollution.

Human glutathione transferase A4-4 crystal structures and mutagenesis reveal the basis of high catalytic efficiency with toxic lipid peroxidation products

The oxidation of lipids and cell membranes generates cytotoxic compounds implicated in the etiology of aging, cancer, atherosclerosis, neurodegenerative diseases, and other illnesses. Glutathione transferase (GST) A4-4 is a key component in the defense against the products of this oxidative stress because, unlike other Alpha class GSTs, GST A4-4 shows high catalytic activity with lipid peroxidation products such as 4-hydroxynon-2-enal (HNE). The crystal structure of human apo GST A4-4 unexpectedly possesses an ordered C-terminal alpha-helix, despite the absence of any ligand. The structure of human GST A4-4 in complex with the inhibitor S-(2-iodobenzyl) glutathione reveals key features of the electrophilic substrate-binding pocket which confer specificity toward HNE. Three structural modules form the binding site for electrophilic substrates and thereby govern substrate selectivity: the beta1-alpha1 loop, the end of the alpha4 helix, and the C-terminal alpha9 helix. A few residue changes in GST A4-4 result in alpha9 taking over a predominant role in ligand specificity from the N-terminal loop region important for GST A1-1. Thus, the C-terminal helix alpha9 in GST A4-4 provides pre-existing ligand complementarity rather than acting as a flexible cap as observed in other GST structures. Hydrophobic residues in the alpha9 helix, differing from those in the closely related GST A1-1, delineate a hydrophobic specificity canyon for the binding of lipid peroxidation products. The role of residue Tyr212 as a key catalytic residue, suggested by the crystal structure of the inhibitor complex, is confirmed by mutagenesis results. Tyr212 is positioned to interact with the aldehyde group of the substrate and polarize it for reaction. Tyr212 also coopts part of the binding cleft ordinarily formed by the N-terminal substrate recognition region in the homologous enzyme GST A1-1 to reveal an evolutionary swapping of function between different recognition elements. A structural model of catalysis is presented based on these results.

Sequence, catalytic properties and expression of chicken glutathione-dependent prostaglandin D2 synthase, a novel class Sigma glutathione S-transferase

The Expressed Sequence Tag database has been screened for cDNA clones encoding prostaglandin D2 synthases (PGDSs) by using a BLAST search with the N-terminal amino acid sequence of rat GSH-dependent PGDS, a class Sigma glutathione S-transferase (GST). This resulted in the identification of a cDNA from chicken spleen containing an insert of approx. 950 bp that encodes a protein of 199 amino acid residues with a predicted molecular mass of 22732 Da. The deduced primary structure of the chicken protein was not only found to possess 70% sequence identity with rat PGDS but it also demonstrated more than 35% identity with class Sigma GSTs from a range of invertebrates. The open reading frame of the chicken cDNA was expressed in Escherichia coli and the purified protein was found to display high PGDS activity. It also catalysed the conjugation of glutathione with a wide range of aryl halides, organic isothiocyanates and alpha,beta-unsaturated carbonyls, and exhibited glutathione peroxidase activity towards cumene hydroperoxide. Like other GSTs, chicken PGDS was found to be inhibited by non-substrate ligands such as Cibacron Blue, haematin and organotin compounds. Western blotting experiments showed that among the organs studied, the expression of PGDS in the female chicken is highest in liver, kidney and intestine, with only small amounts of the enzyme being found in chicken spleen; in contrast, the rat has highest levels of PGDS in the spleen. Collectively, these results show that the structure and function, but not the expression, of the GSH-requiring PGDS is conserved between chicken and rat.

Identification of cDNAs encoding two human alpha class glutathione transferases (GSTA3 and GSTA4) and the heterologous expression of GSTA4-4

The Expressed Sequence Tag database has been searched for examples of previously undescribed human Alpha class glutathione transferases. An incomplete transcript of the previously described GSTA3 gene was identified in a cDNA library derived from 8-9 week placenta. This indicates that the GSTA3 gene is functional and is possibly under specific developmental regulation. A second cDNA, termed GSTA4, was identified in a brain cDNA library. The encoded GSTA4-4 enzyme was expressed in Escherichia coli and was found to be immunologically distinct from GSTA1-1 and to have high activity with alk-2-enals. Although GSTA4-4 appears to be functionally similar to the mouse GST5.7 and rat GST8-8 Alpha class enzymes, sequence comparisons and phylogenetic analysis suggest that GSTA4-4 may be a member of a distinct Alpha class subgroup.

Characterization of chicken-liver glutathione S-transferase (GST) A1-1 and A2-2 isoenzymes and their site-directed mutants heterologously expressed in Escherichia coli: identification of Lys-15 and Ser-208 on cGSTA1-1 as residues interacting with ethacrynic acid

Escherichia coli-expressed chicken-liver glutathione S-transferase, cGSTA1-1, displays high ethacrynic acid (EA)-conjugating activity. Molecular modelling of cGSTA1-1 with EA in the substrate binding site reveals that the side chain of Phe-111 protrudes into the substrate binding site and possibly interacts with EA. Replacement of Phe-111 with alanine resulted in an enzyme (F111A mutant) with a 4.5-fold increase in EA-conjugating activity (9.2 mmol/min per mg), and an incremental Gibbs free energy (DeltaDeltaG) of 4.0 kJ/mol lower than that of the wild-type cGSTA1-1. Two other amino acid residues that possibly interact with EA are Ser-208 and Lys-15. Substitution of Ser-208 with methionine generated a cGSTA1-1(F111AS208M) double mutant that has low EA-conjugating activity (2.0 mmol/min per mg) and an incremental Gibbs free energy of +3.9 kJ/mol greater than the cGSTA1-1(F111A) single mutant. The cGSTA1-1(F111A) mutant, with an additional Lys-15-to-leucine substitution, lost 90% of the EA-conjugating activity (0.55 mmol/min per mg). The Km values of the cGSTA1-1(F111A) and cGSTA1-1(F111AK15L) mutants for EA are nearly identical. The wild-type cGSTA2-2 isoenzyme has a low EA-conjugating activity (0.56 mmol/min per mg). The kcat of this reaction can be increased 2. 5-fold by substituting Arg-15 and Glu-104 with lysine and glycine respectively. The KmEA of the cGSTA2-2(R15KE104G) double mutant is nearly identical with that of the wild-type enzyme. Another double mutant, cGSTA2-2(E104GL208S), has a KmEA that is 3.3-fold lower and a kcat that is 1.8-fold higher than that of the wild-type enzyme. These results, taken together, illustrate the interactions of Lys-15 and Ser-208 on cGSTA1-1 with EA.

Comparative mapping of the chicken genome using the East Lansing reference population

The annotation of known genes on linkage maps provides an informative framework for synteny mapping. In comparative gene mapping, conserved synteny is broadly defined as groups of two or more linked markers that are also linked in two or more species. Although many anonymous markers have been placed on the chicken genome map, locating known genes will augment the number of conserved syntenic groups and consolidate linkage groups. In this report, 21 additional genes have been assigned to linkage groups or chromosomes; five syntenic groups were identified. Ultimately, conserved syntenic groups may help to pinpoint important quantitative trait loci.

Characterization of a marsupial glutathione transferase, a class Alpha enzyme from Brown Antechinus (Antechinus stuartii)

The major form of glutathione transferase from the marsupial Antechinus stuartii has been purified and characterized as an Alpha class enzyme (Ast GST A1-1) with distant sequence relationships to other class Alpha sublines, compatible with the early origin of marsupials. Amino acid replacements toward the closest enzyme characterized (chicken, form A3) involve no less than 79 positions (36%). At the active site, as deduced from comparisons with the known tertiary structure of the corresponding human enzyme, over half of the residues (8 of 15) ascribed to substrate binding interactions are exchanged although the general character of that site is conserved, while only 1 of 11 positions ascribed to interactions with GSH is exchanged. Class variability and species variability appear to coincide, with divergent segments centering around positions 33-49, 103-130 and 205-222. The pattern is reminiscent of that in similarly multiple MDR alcohol dehydrogenases. Both these enzyme families involved in cellular defense reactions have diverged considerably.