Identification of Sequences Encoding the Detoxification Metalloisomerase Glyoxalase I in Microbial Genomes from Several Pathogenic Organisms

The ubiquitous glyoxalase system, which is composed of two enzymes, removes cellular cytotoxic methylglyoxal (MG). In an effort to identify critical residues conserved in the evolution of the first enzyme in this system, glyoxalase I (GlxI), as well as the structural implications of sequence alterations in this enzyme, a search of the National Center for Biotechnology Information (NCBI) database of unfinished genomes was undertaken. Eleven putative GlxI sequences from pathogenic organisms were identified and analyses of these sequences in relation to the known and previously identified GlxI enzymes were performed. Several of these sequences show a very high similarity to the Escherichia coli GlxI sequence, most notably the 79% identity of the sequence identified from Yersinia pestis, the causative agent of bubonic plague. In addition to the conservation of residues critical to binding the catalytic metal in all of the proposed GlxI enzymes, four regions in the Homo sapiens GlxI enzyme are absent in all of the bacterial GlxI sequences, with the exception of Pseudomonas putida. Removal of these regions may alter the active-site conformation of the bacterial enzymes in relation to that of the H. sapiens. These differences may be targeted for the development of inhibitors selective to the bacterial enzymes. Received: 13 October 1999 / Accepted: 17 January 2000     

Identification of Glyoxalase I Sequences in Brassica oleracea and Sporobolus stapfianus: Evidence for Gene Duplication Events

Glyoxalase I (GlxI) is the first of two enzymes involved in the cellular detoxification of methylglyoxal. A recent search of the National Center for Biotechnology Information (NCBI) databases with the protein sequence of Salmonella typhimurium GlxI identified two new hypothetical proteins with unassigned function. These two sequences, from Brassica oleracea and Sporobolus stapfianus, have significant sequence similarity to known GlxI sequences, suggesting that these two open reading frames encode for GlxI in these plants. Interestingly, analysis of these two new sequences indicates that they code for a protein composed of two fused monomers, a situation previously found solely in the yeast GlxI enzymes. Received: 10 May 1997 / Accepted: 15 October 1997     

Novel approach for structural identification of protein family: glyoxalase I

Glyoxalase is one of two enzymes of the glyoxalase detoxification system against methylglyoxal and other aldehydes, the metabolites derived from glycolysis. The glyoxalase system is found almost in all living organisms: bacteria, protozoa, plants, and animals, including humans, and is related to the class of ‘life essential proteins’. The enzyme belongs to the expanded Glyoxalase/Bleomycin resistance protein/Dioxygenase superfamily. At present the GenBank contains about 700 of amino acid sequences of this enzyme type, and the Protein Data Bank includes dozens of spatial structures. We have offered a novel approach for structural identification of glyoxalase I protein family, which is based on the selecting of basic representative proteins with known structures. On this basis, six new subfamilies of these enzymes have been derived. Most populated subfamilies A1 and A2 were based on representative human Homo sapiens and bacterial Escherichia coli enzymes. We have found that the principle feature, which defines the subfamilies’ structural differences, is conditioned by arrangement of N- and C-domains inside the protein monomer. Finely, we have deduced the structural classification for the glyoxalase I and assigned about 460 protein sequences distributed among six new subfamilies. Structural similarities and specific differences of all the subfamilies have been presented. This approach can be used for structural identification of thousands of the so-called hypothetical proteins with the known PDB structures allowing to identify many of already existing atomic coordinate entrees.     

Escherichia coli glyoxalase II is a binuclear zinc-dependent metalloenzyme

Cytotoxic methylglyoxal is detoxified by the two-enzyme glyoxalase system. Glyoxalase I (GlxI) catalyzes conversion of non-enzymatically produced methylglyoxal-glutathione hemithioacetal into its corresponding thioester. Glyoxalase II (Glx II) hydrolyzes the thioester into d-lactate and free glutathione. Glyoxalase I and II are metalloenzymes, which possess mononuclear and binuclear active sites, respectively. There are two distinct classes of GlxI; the first class is Zn2+-dependent and is composed of GlxI from mainly eukaryotic organisms and the second class is composed of non-Zn2+-dependent (but Ni2+ or Co2+-dependent) GlxI enzymes (mainly prokaryotic and leishmanial species). GlxII is typically Zn2+-activated, containing Zn2+ and either Fe3+/Fe2+ or Mn2+ at the active site depending upon the biological source. To address whether two classes of GlxII might exist, glyoxalase II from Escherichia coli was cloned and overexpressed and characterized. Unlike E. coli GlxI, which is non-Zn2+-dependent, Zn2+ activates the E. coli GlxII enzyme, with no evidence for Ni2+ metal utilization.     

Structural variation in bacterial glyoxalase I enzymes: investigation of the metalloenzyme glyoxalase I from Clostridium acetobutylicum

The glyoxalase system catalyzes the conversion of toxic, metabolically produced α-ketoaldehydes, such as methylglyoxal, into their corresponding nontoxic 2-hydroxycarboxylic acids, leading to detoxification of these cellular metabolites. Previous studies on the first enzyme in the glyoxalase system, glyoxalase I (GlxI), from yeast, protozoa, animals, humans, plants, and Gram-negative bacteria, have suggested two metal activation classes, Zn(2+) and non-Zn(2+) activation. Here, we report a biochemical and structural investigation of the GlxI from Clostridium acetobutylicum, which is the first GlxI enzyme from Gram-positive bacteria that has been fully characterized as to its three-dimensional structure and its detailed metal specificity. It is a Ni(2+)/Co(2+)-activated enzyme, in which the active site geometry forms an octahedral coordination with one metal atom, two water molecules, and four metal-binding ligands, although its inactive Zn(2+)-bound form possesses a trigonal bipyramidal geometry with only one water molecule liganded to the metal center. This enzyme also possesses a unique dimeric molecular structure. Unlike other small homodimeric GlxI where two active sites are located at the dimeric interface, the C. acetobutylicum dimeric GlxI enzyme also forms two active sites but each within single subunits. Interestingly, even though this enzyme possesses a different dimeric structure from previously studied GlxI, its metal activation characteristics are consistent with properties of other GlxI. These findings indicate that metal activation profiles in this class of enzyme hold true across diverse quaternary structure arrangements.     

Pseudomonas aeruginosa contains multiple glyoxalase I-encoding genes from both metal activation classes

The glyoxalase (Glx) system is a critical detoxification enzyme system that is widely distributed in prokaryotic and eukaryotic organisms. Glyoxalase I (GlxI), the first enzyme in the system, is a divalent metal-ion dependent lyase (isomerizing), and its homologs have recently been categorized into two metal activation classes which are either Zn2+-dependent or non-Zn2+ dependent (Ni2+-/Co2+-activated). The latter class encompasses enzymes of predominantly bacterial origin. We have identified two genes in Pseudomonas aeruginosa PAO1 encoding glyoxalase I enzymes in addition to the gloA1 sequence recently reported and characterized. The gloA1 and gloA2 genes encode non-Zn2+ dependent glyoxalase I enzymes and the gloA3 gene remarkably encodes a Zn2+-dependent homolog. To our knowledge this is the first report of a eubacterial species with several GlxI encoding genes, and also of an organism possessing GlxI enzymes from both metal activation classes.     

Sugar beet M14 glyoxalase I gene can enhance plant tolerance to abiotic stresses

Glyoxalase I is the first enzyme of the glyoxalase system that can detoxify methylglyoxal, a cytotoxic compound increased rapidly under stress conditions. Here we report cloning and characterization of a glyoxalase I from sugar beet M14 line (an interspecific hybrid between a wild species Beta corolliflora Zoss and a cultivated species B. vulgaris L). The full-length gene BvM14-glyoxalase I has 1,449 bp in length with an open reading frame of 1,065 bp encoding 354 amino acids. Sequence analysis shows the conserved glyoxalase I domains, metal and glutathione binding sites and secondary structure (α-helixes and β-sheets). The BvM14-glyoxalase I gene was ubiquitously expressed in different tissues of sugar beet M14 line and up-regulated in response to salt, mannitol and oxidative stresses. Heterologous expression of BvM14-glyoxalase I could increase E. coli tolerance to methylglyoxal. Transgenic tobacco plants constitutively expressing BvM14-glyoxalase I were generated. Both leaf discs and seedlings showed significant tolerance to methylglyoxal, salt, mannitol and H₂O₂. These results suggest an important role of BvM14-glyoxalase I in cellular detoxification and tolerance to abiotic stresses.     

Purification and characterization of glyoxalase I from Hansenula mrakii

Glyoxalase I was purified from Hansenula mrakii IFO 0895 which was resistant to 25 mM methylglyoxal. The molecular weight of the purified enzyme was calculated to be 38,000 by both gel-filtration of Sephadex G-150 and SDS-PAGE. The enzyme was almost specific to methylglyoxal (K_m = 0.91 mM). The activity of the enzyme was not inhibited by metal ion chelators such as EDTA, which is a potent inhibitor for glyoxalase Is from other sources.     

Determination of the structure of Escherichia coli glyoxalase I suggests a structural basis for differential metal activation

The metalloenzyme glyoxalase I (GlxI) converts the nonenzymatically produced hemimercaptal of cytotoxic methylglyoxal and glutathione to nontoxic S-D-lactoylglutathione. Human GlxI, for which the structure is known, is active in the presence of Zn(2+). Unexpectedly, the Escherichia coli enzyme is inactive in the presence of Zn(2+) and is maximally active with Ni(2+). To understand this difference in metal activation and also to obtain a representative of the bacterial enzymes, the structure of E. coli Ni(2+)-GlxI has been determined. Structures have also been determined for the apo enzyme as well as complexes with Co(2+), Cd(2+), and Zn(2+). It is found that each of the protein-metal complexes that is catalytically active has octahedral geometry. This includes the complexes of the E. coli enzyme with Ni(2+), Co(2+), and Cd(2+), as well as the structures reported for the human Zn(2+) enzyme. Conversely, the complex of the E. coli enzyme with Zn(2+) has trigonal bipyramidal coordination and is inactive. This mode of coordination includes four protein ligands plus a single water molecule. In contrast, the coordination in the active forms of the enzyme includes two water molecules bound to the metal ion, suggesting that this may be a key feature of the catalytic mechanism. A comparison of the human and E. coli enzymes suggests that there are differences between the active sites that might be exploited for therapeutic use.     

Trypanothione-dependent glyoxalase I in Trypanosoma cruzi

The glyoxalase system, comprizing glyoxalase I and glyoxalase II, is a ubiquitous pathway that detoxifies highly reactive aldehydes, such as methylglyoxal, using glutathione as a cofactor. Recent studies of Leishmania major glyoxalase I and Trypanosoma brucei glyoxalase II have revealed a unique dependence upon the trypanosomatid thiol trypanothione as a cofactor. This difference suggests that the trypanothione-dependent glyoxalase system may be an attractive target for rational drug design against the trypanosomatid parasites. Here we describe the cloning, expression and kinetic characterization of glyoxalase I from Trypanosoma cruzi. Like L. major glyoxalase I, recombinant T. cruzi glyoxalase I showed a preference for nickel as its metal cofactor. In contrast with the L. major enzyme, T. cruzi glyoxalase I was far less fast-idious in its choice of metal cofactor efficiently utilizing cobalt, manganese and zinc. T. cruzi glyoxalase I isomerized hemithio-acetal adducts of trypanothione more than 2400 times more efficiently than glutathione adducts, with the methylglyoxal adducts 2-3-fold better substrates than the equivalent phenylglyoxal adducts. However, glutathionylspermidine hemithioacetal adducts were most efficiently isomerized and the glutathionylspermidine-based inhibitor S-4-bromobenzylglutathionylspermidine was found to be a potent linear competitive inhibitor of the T. cruzi enzyme with a K(i) of 5.4+/-0.6 microM. Prediction algorithms, combined with subcellular fractionation, suggest that T. cruzi glyoxalase I localizes not only to the cytosol but also the mitochondria of T. cruzi epimastigotes. The contrasting substrate specificities of human and trypanosomatid glyoxalase enzymes, confirmed in the present study, suggest that the glyoxalase system may be an attractive target for anti-trypanosomal chemotherapy.     

Paclobutrazol mitigates salt stress in <Emphasis Type="Italic">indica</Emphasis> rice seedlings by enhancing glutathione metabolism and glyoxalase system

Stress-induced methylglyoxal (MG) functions as a toxic molecule, inhibiting plant physiological processes such as photosynthesis and antioxidant defense systems. In the present study, an attempt was made to investigate the MG detoxification through glutathione metabolism in indica rice [Oryza sativa L. ssp. indica cv. Pathumthani 1] under salt stress by exogenous foliar application of paclobutrazol (PBZ). Fourteen-day-old rice seedlings were pretreated with 15 mg L^?1 PBZ foliar spray. After 7 days, rice seedlings were subsequently exposed to 0 (control) or 150 mM NaCl (salt stress) for 12 days. Prolonged salt stress enhanced the production of MG molecules and the oxidation of proteins, leading to decreased activity of glyoxalase enzymes, glyoxalase I (Gly I) and glyoxalase II (Gly II). Consequently, the decreased glyoxalase activities were also associated with a decline in reduced glutathione (GSH) content and glutathione reductase (GR) activity. PBZ pretreatment of rice seedlings under salt stress significantly lowered MG production and protein oxidation, and increased the activities of both Gly I and Gly II. PBZ also increased GSH content and GR activity along with the up-regulation of glyoxalase enzymes, under salt stress. In summary, salinity induced a high level of MG and the associated oxidative damage, while PBZ application reduced the MG toxicity by up-regulating glyoxalase and glutathione defense system in rice seedlings.     

Passive cigarette smoke and renal glyoxalase system

Cigarette smoking is associated with a number of fatal diseases, including cancer of different organs. A number of oxoaldehydes are found in cigarette smoke, among which methylglyoxal (MG) is known to cause toxicity to cells upon accumulation. In biological systems, MG is converted to s-d-lactoylglutathione by glyoxalase I with reduced glutathine (GSH) as a cofactor, and s-d-lactoylglutathione is converted to D-lactic acid with simultaneous regeneration of GSH, by glyoxalase II. In the present study, we have investigated the status of the glyoxalase enzymes in kidney tissues from rats exposed to passive cigarette smoke. No significant change has been noted in glyoxalase I activity. Glyoxalase II was decreased during 1 and 2 weeks of exposure, and after that the activity was increased. The initial decrease in the activity of gly II may be due to the excess amount of methylglyoxal generated due to smoke exposure or the adduct formed by MG and GSH which known to inhibit gly II activity. Both enzymes help in the detoxification of cigarette smoke induced chemicals and biochemicals.     

Crystal structure of Staphylococcus aureus Zn-glyoxalase I: new subfamily of glyoxalase I family

The crystal structures of protein SA0856 from Staphylococcus aureus in its apo-form and in complex with a Zn²⁺-ion have been presented. The 152 amino acid protein consists of two similar domains with α + β topology. In both crystalline state and in solution, the protein forms a dimer with monomers related by a twofold pseudo-symmetry rotation axis. A sequence homology search identified the protein as a member of the structural family Glyoxalase I. We have shown that the enzyme possesses glyoxalase I activity in the presence of Zn²⁺, Mg²⁺, Ni²⁺, and Co²⁺, in this order of preference. Sequence and structure comparisons revealed that human glyoxalase I should be assigned to a subfamily A, while S. aureus glyoxalase I represents a new subfamily B, which includes also proteins from other bacteria. Both subfamilies have a similar protein chain fold but rather diverse sequences. The active sites of human and staphylococcus glyoxalases I are also different: the former contains one Zn-ion per chain; the latter incorporates two of these ions. In the active site of SA0856, the first Zn-ion is well coordinated by His58, Glu60 from basic molecule and Glu40*, His44* from adjacent symmetry-related molecule. The second Zn3-ion is coordinated only by residue His143 from protein molecule and one acetate ion. We suggest that only single Zn1-ion plays the role of catalytic center. The newly found differences between the two subfamilies could guide the design of new drugs against S. aureus, an important pathogenic micro-organism.     

Molecular cloning of the Pseudomonas putida glyoxalase I gene in Escherichia coli

The glyoxalase I gene of Pseudomonas putida was cloned onto a vector plasmid pBR 322 as a 7.5 kilobase Sau 3AI fragment of chromosomal DNA and the hybrid plasmid was designated pGI 318. The gene responsible for the glyoxalase I activity in pGI 318 was recloned in pBR 322 as a 2.2 kilobase Hin dIII fragment and was designated pGI 423. The P. putida glyoxalase I gene on pGI 318 and pGI 423 was highly expressed in E. coli cells and the glyoxalase I activity level was increased more than 150 fold in the pGI 423 bearing strain compared with that of E. coli cells without pGI 423. The E. coli transformants harboring pGI 318 or pGI 423 could grow normally in the presence of methylglyoxal, although the E. coli cells without plasmid were inhibited to grow and showed the extremely elongated cell shape.     

A reinvestigation of inhibitors of glyoxalase I

It has been reported earlier that nucleotides, nucleosides and a series of structurally related compounds as well as compounds based on transition state analogy inhibit yeast glyoxalase I. In our study on the metabolic regulation of glyoxalase I, we have found that nucleotides such as ATP, GTP and different classes of other reagents based on transition state analogy (D-isoascorbate, dihydroxyfumaric acid, rhodizonic acid) do not inhibit yeast or goat liver glyoxalase I. The reported inhibition of glyoxalase I by these compounds has been found to be due to the interference of these compounds with the absorbancy at 240 nm of S-D-lactoylglutathione formed by the glyoxalase I reaction. Glyoxalase I from goat liver has been found to be strongly and competitively inhibited by lactaldehyde. But, lactaldehyde has very little inhibitory effect on yeast glyoxalase I. Lactaldehyde is formed from methylglyoxal, the substrate for glyoxalase I by the enzyme methylglyoxal reductase. D-Lactaldehyde inhibits the liver enzyme more strongly than L-lactaldehyde.     

Unique regulation of glyoxalase I activity during osmotic stress response in the fission yeast <Emphasis Type="Italic">Schizosaccharomyces pombe</Emphasis>: neither the mRNA nor the protein level of glyoxalase I increase under conditions that enhance its activity

Glyoxalase I is a ubiquitous enzyme that catalyzes the conversion of methylglyoxal, a toxic 2-oxoaldehyde derived from glycolysis, to S-D-lactoylglutathione. The activity of glyoxalase I in the fission yeast Schizosaccharomyces pombe was increased by osmotic stress induced by sorbitol. However, neither the mRNA levels of its structural gene nor its protein levels increased under the same conditions. Cycloheximide blocked the induction of glyoxalase I activity in cells exposed to osmotic stress. In addition, glyoxalase I activity was increased in stress-activated protein kinase-deficient mutants (wis1 and spc1). We present evidence for the post-translational regulation of glyoxalase I by osmotic stress in the fission yeast.     

A convenient quantitative synthesis of methylglyoxal for glyoxalase I assays

A simple, convenient, and quantitative method for the preparation of methylglyoxal (pyruvaldehyde) solutions is described. The method involved acid hydrolysis (5% H₂SO₄) of pyruvaldehyde dimethyl acetal at 100°C for 25 min. The hydrolysis method is quite reproducible and does not require standardization of the methylglyoxal solutions. The preparations of methylglyoxal by the procedure described have been used in the study of glyoxalase I activity.     

Cloning and characterization of glyoxalase I from soybean

Glyoxalase I and glutathione transferase (GST) are two glutathione-dependent enzymes which are enhanced in plants during cell division and in response to diverse stress treatments. In soybean, a further connection between these two enzymes has been suggested by a clone (Accession No. X68819) resembling a GST being described as a glyoxalase I. To characterize glyoxalase I in soybean, GmGlyox I resembling the dimeric enzyme from animals has been cloned from a cDNA library prepared from soybean suspension cultures. When expressed in Escherichia coli, GmGlyox I was found to be a 38-kDa dimer composed of 21-kDa subunits and unlike the enzyme from mammals showed activity in the absence of metal ions. GmGlyox I was active toward the hemithioacetal adducts formed by reacting methylglyoxal, or phenylglyoxal, with glutathione, homoglutathione, or gamma-glutamylcysteine, showing no preference for homoglutathione adducts over glutathione adducts, even though homoglutathione is the dominant thiol in soybean. When the clone X68819 was expressed in E. coli, the respective recombinant enzyme was active as a GST rather than a glyoxalase and was termed GmGST 3. GmGST 3 was active as a homodimer (45 kDa) composed of 26-kDa subunits and showed a preference for glutathione over homoglutathione when conjugating 1-chloro-2,4-dinitrobenzene. Both enzymes are associated with cell division in soybean cultures, but GmGST 3 (0.4% total protein) was 40 times more abundant than GmGlyox I (0.01%).     

Mussel glyoxalase I as a possible marker for ecotoxicological studies: Purification and preliminary characterization

Alpha-ketoaldehydes may be formed in cells during oxidative processes and glyoxalase I is the main enzyme involved in the detoxification pathway for these highly toxic compounds. Increased glyoxalase I activity has been observed in mussels exposed to high environmental levels of pollutants and a role for this enzyme as a protection mechanism against peroxidation damage has been hypothesized. In this paper, glyoxalase I from mussel tissue has been purified and a preliminary investigation of its molecular properties carried out. A two step purification procedure for glyoxalase I from digestive gland of Mytilus galloprovincialis is described. The pure enzyme is a 48 kDa protein with an heterodimeric quaternary structure composed of 24 and 25 kDa subunits. The isoelectric point of the native enzyme is at pH 5.0 and there is a divalent cation (probably Zn⁺⁺) requirement for activity. The series of alkyl-S-glutathiones, from methyl- to decyl-, are competitive inhibitors of glyoxalase I. Ki values exponentially decrease from 1.15 mM to 2.65 μM with increasing chain length. Mussel glyoxalase I exhibits molecular properties similar to those of the mammalian enzyme. The possible role of glyoxalase I in the detoxification of α-ketoaldehydes formed during oxidative stress is discussed.