A stress-responsive glyoxalase I from the parasitic nematode Onchocerca volvulus (original) (raw)
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The glyoxalase pathway: the first hundred years… and beyond
Biochemical Journal, 2013
The discovery of the enzymatic formation of lactic acid from methylglyoxal dates back to 1913 and was believed to be associated with one enzyme termed ketonaldehydemutase or glyoxalase, the latter designation prevailed. However, in 1951 it was shown that two enzymes were needed and that glutathione was the required catalytic co-factor. The concept of a metabolic pathway defined by two enzymes emerged at this time. Its association to detoxification and anti-glycation defence are its presently accepted roles, since methylglyoxal exerts irreversible effects on protein structure and function, associated with misfolding. This functional defence role has been the rationale behind the possible use of the glyoxalase pathway as a therapeutic target, since its inhibition might lead to an increased methylglyoxal concentration and cellular damage. However, metabolic pathway analysis showed that glyoxalase effects on methylglyoxal concentration are likely to be negligible and several organisms, ...
The glyoxalase pathway in protozoan parasites
International Journal of Medical Microbiology, 2012
The glyoxalase system is the main catabolic route for methylglyoxal, a non-enzymatic glycolytic byproduct with toxic and mutagenic effects. This pathway includes two enzymes, glyoxalase I and glyoxalase II, which convert methylglyoxal to d-lactate by using glutathione as a catalytic cofactor. In protozoan parasites the glyoxalase system shows marked deviations from this model. For example, the functional replacement of glutathione by trypanothione (a spermidine-glutathione conjugate) is a characteristic of trypanosomatids. Also interesting are the lack of glyoxalase I and the presence of two glyoxalase II enzymes in Trypanosoma brucei. In Plasmodium falciparum the glyoxalase pathway is glutathionedependent, and glyoxalase I is an atypical monomeric enzyme with two active sites. Although it is tempting to exploit these differences for their potential therapeutic value, they provide invaluable clues regarding methylglyoxal metabolism and the evolution of protozoan parasites. Glyoxalase enzymes have been characterized in only a few protozoan parasites, namely Plasmodium falciparum and the trypanosomatids Leishmania and Trypanosoma. In this review, we will focus on the key features of the glyoxalase pathway in major human protozoan parasites, with particular emphasis on the characterized systems in Plasmodium falciparum, Trypanosoma brucei, Trypanosoma cruzi, and Leishmania spp. We will also search for genes encoding glyoxalase I and II in Toxoplasma gondii, Entamoeba histolytica, and Giardia lamblia.
A NovelTypeofGlutathione S-Transferase inOnchocerca volvulus
1994
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Glyoxalase 2: Towards a Broader View of the Second Player of the Glyoxalase System
Antioxidants
Glyoxalase 2 is a mitochondrial and cytoplasmic protein belonging to the metallo-β-lactamase family encoded by the hydroxyacylglutathione hydrolase (HAGH) gene. This enzyme is the second enzyme of the glyoxalase system that is responsible for detoxification of the α-ketothaldehyde methylglyoxal in cells. The two enzymes glyoxalase 1 (Glo1) and glyoxalase 2 (Glo2) form the complete glyoxalase pathway, which utilizes glutathione as cofactor in eukaryotic cells. The importance of Glo2 is highlighted by its ubiquitous distribution in prokaryotic and eukaryotic organisms. Its function in the system has been well defined, but in recent years, additional roles are emerging, especially those related to oxidative stress. This review focuses on Glo2 by considering its genetics, molecular and structural properties, its involvement in post-translational modifications and its interaction with specific metabolic pathways. The purpose of this review is to focus attention on an enzyme that, from th...
Molecular and Biochemical Parasitology, 1994
Glutathione S-transferases (GSTs) constitute a major detoxification mechanism in helminth organisms and are regarded vaccine candidates against helminth infections. Onchocerca volvulus glutathione-binding proteins were purified from the aqueous soluble fraction of homogenised adult females by affinity chromatography on glutathione-agarose. The eluted proteins had a specific GST activity of 1.6/xmol min-1 rag-x, lmmunohistochemical studies localised these antigens in the hypodermis, the wall of the seminal receptacle and spermatozoa of adult worms. A hgtll clone was isolated from an expression library of O. volvulus by immunoscreening. Sequence analysis revealed that it encoded a ~'-class GST with 60% identity with Caenorhabditis elegans and up to 45% identity with mammalian 7r-class GSTs. Antibodies affinity selected with recombinant GST demonstrated cross-reactivity between Litomosoides sigmodontis and O. volvulus GSTs.
Insect Biochemistry and Molecular Biology, 2001
Two β-glycosidases (M r 59k) were purified from midgut contents of larvae of the yellow mealworm, Tenebrio molitor (Coleoptera: Tenebrionidae). The two enzymes (βGly1 and βGly2) have identical kinetic properties, but differ in hydrophobicity. The two glycosidases were cloned and their sequences differ by only four amino acids. The T. molitor glycosidases are family 1 glycoside hydrolases and have the E 379 (nucleophile) and E 169 (proton donor) as catalytic amino acids based on sequence alignments. The enzymes share high homology and similarity with other insect, mammalian and plant β-glycosidases. The two enzymes may hydrolyze several substrates, such as disaccharides, arylglucosides, natural occurring plant glucosides, alkylglucosides, oligocellodextrins and the polymer laminarin. The enzymes have only one catalytic site, as inferred from experiments of competition between substrates and sequence alignments. The observed inhibition by high concentrations of the plant glucoside amygdalin, used as substrate, is an artifact generated by transglucosylation. The active site of each purified β-glycosidase has four subsites, of which subsites +1 and +2 bind glucose with more affinity. Subsite +2 has more affinity for hydrophobic groups, binding with increasing affinities: glucose, mandelonitrile and nitrophenyl moieties. Subsite +3 has more affinity for glucose than butylene moieties. The intrinsic catalytic constant calculated for hydrolysis of the glucose β-1,4-glucosidic bond is 21.2 s Ϫ1 M Ϫ1 . The putative physiological role of these enzymes is the digestion of di-and oligosaccharides derived from hemicelluloses.
Molecular Cloning, Heterologous Expression, and Characterization of Human Glyoxalase II
Journal of Biological Chemistry, 1996
A clone encoding glyoxalase II has been isolated from a human adult liver cDNA library. The sequence of 1011 base pairs consists of a full-length coding region of 780 base pairs, corresponding to a protein with a calculated molecular mass of 28,861 daltons. Identities (50 -60%) were found to partial 5 and 3 cDNA sequences from Arabidopsis thaliana as well as within a limited region of glutathione transferase I cDNA from corn. A vector was constructed for heterologous expression of glyoxalase II in Escherichia coli. For optimal yield of enzyme, silent random mutations were introduced in the 5 coding region of the cDNA. A yield of 25 mg of glyoxalase II per liter of culture medium was obtained after affinity purification with immobilized glutathione. The recombinant enzyme had full catalytic activity and kinetic parameters indistinguishable from those of the native enzyme purified from human erythrocytes.
Insect Biochemistry and Molecular Biology, 2001
Two β-glycosidases (M r 59k) were purified from midgut contents of larvae of the yellow mealworm, Tenebrio molitor (Coleoptera: Tenebrionidae). The two enzymes (βGly1 and βGly2) have identical kinetic properties, but differ in hydrophobicity. The two glycosidases were cloned and their sequences differ by only four amino acids. The T. molitor glycosidases are family 1 glycoside hydrolases and have the E 379 (nucleophile) and E 169 (proton donor) as catalytic amino acids based on sequence alignments. The enzymes share high homology and similarity with other insect, mammalian and plant β-glycosidases. The two enzymes may hydrolyze several substrates, such as disaccharides, arylglucosides, natural occurring plant glucosides, alkylglucosides, oligocellodextrins and the polymer laminarin. The enzymes have only one catalytic site, as inferred from experiments of competition between substrates and sequence alignments. The observed inhibition by high concentrations of the plant glucoside amygdalin, used as substrate, is an artifact generated by transglucosylation. The active site of each purified β-glycosidase has four subsites, of which subsites +1 and +2 bind glucose with more affinity. Subsite +2 has more affinity for hydrophobic groups, binding with increasing affinities: glucose, mandelonitrile and nitrophenyl moieties. Subsite +3 has more affinity for glucose than butylene moieties. The intrinsic catalytic constant calculated for hydrolysis of the glucose β-1,4-glucosidic bond is 21.2 s Ϫ1 M Ϫ1 . The putative physiological role of these enzymes is the digestion of di-and oligosaccharides derived from hemicelluloses.
Onchocerca volvulus:Ultrastructural Localization of Two Glutathione S-Transferases
Experimental Parasitology, 1998
GlutathioneS-transferases (GSTs) are essential detoxification enzymes for virtually all cells and may additionally aid in parasite survival by counteracting host-induced damage. GSTs from parasitic nematodes have been identified as potential targets for both immuno- and chemotherapy. To more closely characterize a 31-kDa (OvGST1) and a 24.5-kDa (OvGST2) GST from the pathogenic human filarial parasiteOnchocerca volvulus,immunolocalization by electron microscopy was performed using two distinct affinity-purified polyclonal antisera raised against the recombinant OvGST1 and OvGST2. The strongest immunogold staining for OvGST1 was identified in the body wall of adult worms, especially in protuberances of the cuticle which lie in pouches of the hypodermis and in the outer zone of the syncytial hypodermis, where the external plasma membrane forms series of lamellae. Gold particles were also observed on the epicuticle of the adults and in the region of the border between the cuticle and hypodermis of microfilariae. The larval stages L1, L2, and infective L3 were also immunopositive for OvGST1. There was no specific labeling in the longitudinal musculature, the intestine, or the uterine wall of the adult worm. In contrast to the results for OvGST1, immunogold labeling for OvGST2 was observed throughout the whole hypodermal cytoplasm. The epithelial cells of the uterine wall showed moderate labeling. These ultrastructural immunolocalization results are consistent with the molecular characterization of both enzymes, indicating that OvGST1 is secreted out of the hypodermis into the cuticle and is acting at the host-parasite interface, while OvGST2 functions as an intracellular cytosolic housekeeping enzyme.