Purification and characterization of glyoxalase I from Pseudomonas putida

Profiling of Methylglyoxal Blood Metabolism and Advanced Glycation End-Product Proteome Using a Chemical Probe

Methylglyoxal (MG) is quantitatively the most important precursor to advanced glycation end-products (AGEs), and evidence is accumulating that it is also a causally linked to diabetes and aging related diseases. Living systems primarily reside on the glyoxalase system to detoxify MG into benign d-lactate. The flux to either glycation or detoxification, accordingly, is a key parameter for how well a system handles the ubiquitous glyoxal burden. Furthermore, insight into proteins and in particular their individual modification sites are central to understanding the involvement of MG and AGE in diabetes and aging related diseases. Here, we present a simple method to simultaneously monitor the flux of MG both to d-lactate and to protein AGE formation in a biological sample by employing an alkyne-labeled methylglyoxal probe. We apply the method to blood and plasma to demonstrate the impact of blood cell glyoxalase activity on plasma protein AGE formation. We move on to isolate proteins modified by the MG probe and accordingly can present the first general inventory of more than 100 proteins and 300 binding sites of the methylglyoxal probe on plasma as well as erythrocytic proteins. Some of the data could be validated against a number of in vivo and in vitro targets for advanced glycation previously known from the literature; the majority of proteins and specific sites however were previously unknown and may guide future research into MG and AGE to elucidate how these are functionally linked to diabetic disease and aging.

Modulating glyoxalase I metal selectivity by deletional mutagenesis: underlying structural factors contributing to nickel activation profiles

Metabolically produced methylglyoxal is a cytotoxic compound that can lead to covalent modification of cellular DNA, RNA and protein. One pathway to detoxify this compound is via the glyoxalase enzyme system. The first enzyme of this detoxification system, glyoxalase I (GlxI), can be divided into two classes according to its metal activation profile, a Zn(2+)-activated class and a Ni(2+)-activated class. In order to elucidate some of the key structural features required for selective metal activation by these two classes of GlxI, deletional mutagenesis was utilized to remove, in a step-wise fashion, a key α-helix (residues 73-87) and two small loop regions (residues 99-103 and 111-114) from the Zn(2+)-activated Pseudomonas aeruginosa GlxI (GloA3) in order to mimic the smaller Ni(2+)-activated GlxI (GloA2) from the same organism. This approach was observed to clearly shift the metal activation profile of a Zn(2+)-activated class GlxI into a Ni(2+)-activated class GlxI enzyme. The α-helix structural component was found to contribute significantly toward GlxI metal specificity, while the two small loop regions were observed to play a more crucial role in the magnitude of the enzymatic activity. The current study should provide additional information on the fundamental relationship of protein structure to metal selectivity in these metalloenzymes.

Arabidopsis thaliana glyoxalase 2-1 is required during abiotic stress but is not essential under normal plant growth

The glyoxalase pathway, which consists of the two enzymes, GLYOXALASE 1 (GLX 1) (E.C.: 4.4.1.5) and 2 (E.C.3.1.2.6), has a vital role in chemical detoxification. In Arabidopsis thaliana there are at least four different isoforms of glyoxalase 2, two of which, GLX2-1 and GLX2-4 have not been characterized in detail. Here, the functional role of Arabidopsis thaliana GLX2-1 is investigated. Glx2-1 loss-of-function mutants and plants that constitutively over-express GLX2-1 resemble wild-type plants under normal growth conditions. Insilico analysis of publicly available microarray datasets with ATTEDII, Mapman and Genevestigator indicate potential role(s) in stress response and acclimation. Results presented here demonstrate that GLX2-1 gene expression is up-regulated in wild type Arabidopsis thaliana by salt and anoxia stress, and by excess L-Threonine. Additionally, a mutation in GLX2-1 inhibits growth and survival during abiotic stresses. Metabolic profiling studies show alterations in the levels of sugars and amino acids during threonine stress in the plants. Elevated levels of polyamines, which are known stress markers, are also observed. Overall our results suggest that Arabidopsis thaliana GLX2-1 is not essential during normal plant life, but is required during specific stress conditions.

Isolation and sequencing of a gene coding for glyoxalase I activity from Salmonella typhimurium and comparison with other glyoxalase I sequences

The glyoxalase I gene (gloA) from Salmonella typhimurium has been isolated in Escherichia coli on a multi-copy pBR322-derived plasmid, selecting for resistance to 3 mM methylglyoxal on Luria-Bertani agar. The region of the plasmid which confers the methylglyoxal resistance in E. coli was sequenced. The deduced protein sequence was compared to the known sequences of the Homo sapiens and Pseudomonas putida glyoxalase I (GlxI) enzymes, and regions of strong homology were used to probe the National Center for Biotechnology Information protein database. This search identified several previously known glyoxalase I sequences and other open reading frames with unassigned function. The clustal alignments of the sequences are presented, indicating possible Zn2+ ligands and active site regions. In addition, the S. typhimurium sequence aligns with both the N-terminal half and the C-terminal half of the proposed GlxI sequences from Saccharomyces cerevisiae and Schizosaccharomyces pombe, suggesting that the structures of the yeast enzymes are those of fused dimers.

Glyoxalase III from Escherichia coli: a single novel enzyme for the conversion of methylglyoxal into D-lactate without reduced glutathione

A single novel enzyme, glyoxalase III, which catalyses the conversion of methylglyoxal into D-lactate without involvement of GSH, has been detected in and purified from Escherichia coli. Of several carbonyl compounds tested, only the alpha-ketoaldehydes methylglyoxal and phenylglyoxal were found to be substrates for this enzyme. Glyoxalase III is active over a wide range of pH with no sharp pH optimum. In its native form it has an M(r) of 82000 +/- 2000, and it is composed of two subunits of equal M(r). Glutathione analogues, which are inhibitors of glyoxalase I, do not inhibit glyoxalase III. Glyoxalase III is found to be sensitive to thiol-blocking reagents. The p-hydroxymercuribenzoate-inactivated enzyme could be almost completely re-activated by dithiothreitol and other thiol-group-containing compounds, indicating the possible involvement of thiol group(s) at or near the active site of the enzyme.

The gene encoding glyoxalase I from Pseudomonas putida: cloning, overexpression, and sequence comparisons with human glyoxalase I

The gene encoding glyoxalase I (GlxI) from Pseudomonas putida has been cloned into the high-expression plasmid pBTacI. In the presence of IPTG, JM109 cells transformed with this vector give expression levels of GlxI 4000-fold higher than wild-type Escherichia coli. Contrary to a previous report, the nucleotide sequence of the gene encodes a 173-amino-acid polypeptide. Edman analysis indicates that the predicted N-terminal methionine is lost post-translationally to yield a 19407-Da protein. Mass spectrometry of the intact protein, and of the peptides generated from treatment with CNBr, does not indicate any additional post-translational modifications of the enzyme. Contrary to previous conclusions, there are no major regions of dissimilarity between the human and bacterial enzymes.

Chicken eggshell porphyrins and the glyoxalase pathway: its possible physiological role

1. The plasma 4,5-dioxovaleric acid (DOVA) levels of two different breeds of chicken were determined and found to be higher in the group with a higher porphyrin eggshell content. 2. The erythrocyte and uterus glyoxalase II activity, investigated by means of a new spectrophotometric method, was found to be significantly higher in the group with a low porphyrin eggshell content. 3. A comparative genetic study of two chicken populations, one with white and one with dark eggshells, showed different gene frequencies for the glyoxalase I polymorphism. 4. An interpretation of these data suggests that the glyoxalase pathway may be involved in the metabolism of early porphyrin precursors.

Overproduction of glutathione and its derivatives by genetically engineered microbial cells

In order to improve the biotechnological potentials of Escherichia coli cells to produce glutathione, S-D-lactoylglutathione and other gamma-glutamyl compounds, the genes for enzymes [gamma-L-glutamyl-L-cysteine synthetase (GSH A) in E. coli B, glutathione synthetase (GSH B) in E. coli B, glyoxalase I (GLO I) in Pseudomonas putida] were cloned and amplified in E. coli. E. coli B cells transformed with both GSH A and GSH B genes exhibited a high activity in the synthesis of glutathione and other gamma-glutamyl compounds in bioreactor systems containing immobilized cells. E. coli C600 cells transformed with GLO I gene of P. putida showed a high GLO I activity and were used for the preparation of S-D-lactoylglutathione and other glutathione thiol esters.

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.