1,720,971 research outputs found
In vivo effect of xenobiotic compounds on the Proteus mirabilis glutathione transferase B1-1.
No full textRegulation of IP6K1 gene expression: role of the proximal promoter GC-rich Sp1 binding region
No full textRedox regulation of the tumor suppressor Phosphatase and Tensin homolog deleted on chromosome ten (PTEN) by methionine sulfoxide reductase A.
No full textMu-class glutathione transferase from Xenopus laevis: molecular cloning, expression and site-directed mutagenesis
No full textExpression of glutathione S-transferase and methionine sulphoxide reductase in Ochrobactrum anthropi is correlated to the production of reactive oxygen species caused by aromatic substrates.
No full textPeptide methionine sulphoxide reductase (MsrA) and glutathione S-transferases (GSTs) are considered as detoxification enzymes. In the xenobiotics-degrading bacterium Ochrobactrum anthropi the two enzymes are co-induced by toxic concentrations of aromatic substrates such as phenol and 4-chlorophenol. In aerobic organisms, degradation of aromatic substrates by mono- and dioxygenases leads to a generation of oxidative stress that causes the occurrence of reactive oxygen species (ROS). A capillary electrophoretic method, using the intracellular conversion of dihydrorhodamine-123 into rhodamine-123, was developed to measure the content of ROS in the bacteria. The presence of toxic concentrations of the aromatic substrate 4-chlorophenol, an inducer of GST and MsrA, leads to a significant increase in the production of ROS. These results strongly suggest that GST and MsrA enzymes are part of the bacterial defence mechanism against particular oxidative stress conditions. As oxidative stress is known to be present predominantly close to the cytoplasmic membrane, we investigated the subcellular distribution of both MsrA and GST enzymes in this bacterium grown in the presence of 4-chlorophenol. By Western blotting, MsrA and GST was assayed in the cytoplasm as well as in the periplasm. Moreover, immunolocalisation by colloidal gold immunoelectron microscopy identified the two proteins associated with the cell envelope
Contribution of two conserved trypthophan residues to the catalytic and structural properties of Proteus mirabilis glutathione S-transferase B1-1
No full textPmGSTB1-1 (Proteus mirabilis glutathione S-transferase B1-1) has two tryptophan residues at positions 97 and 164 in each monomer. Structural data for this bacterial enzyme indicated that Trp97 is positioned in the helix α4, whereas Trp164 is located at the bottom of the helix α6 in the xenobiotic-binding site. To elucidate the role of the two tryptophan residues they were replaced by site-directed mutagenesis. Trp97 and Trp164 were mutated to either phenylalanine or alanine. A double mutant was also constructed. The effects of the replacement on the activity, structural properties and antibiotic-binding capacity of the enzymes were examined. On the basis of the results obtained, Trp97 does not seem to be involved in the enzyme active site and structural stabilization. In contrast, different results were achieved for Trp164 mutants. Conservative substitution of the Trp164 with phenylalanine enhanced enzyme activity 10-fold, whereas replacement with alanine enhanced enzyme activity 17-fold. Moreover, the catalytic efficiency for both GSH and 1-chloro-2,4-dinitrobenzene substrates improved. In particular, the catalytic efficiency for 1-chloro-2,4-dinitrobenzene improved for both W164F (Trp164 → Phe) and W164A by factors of 7- and 22-fold respectively. These results are supported by molecular graphic analysis. In fact, W164A presented a more extensive substrate-binding pocket that could allow the substrates to be better accommodated. Furthermore, both Trp164 mutants were significantly more thermolabile than wild-type, suggesting that the substitution of this residue affects the overall stability of the enzyme. Taken together, these results indicate that Trp164 is an important residue of PmGSTB1-1 in the catalytic process as well as for protein stability
Identification and functional analysis of the glutathione transferase promoter region in Ochrobactrum anthropi.
No full textProteus mirabilis glutathione S-transferase B1-1 is involved in the protective mechanisms against oxidative and chemical stresses.
No full textWe investigated the effects of several xenobiotics, including antimicrobial agents and general stress factors such as starvation, heat and osmotic shock, on the modulation of expression of Proteus mirabilis glutathione S-transferase B1-1 (PmGST B1-1). The level of expression of PmGST B1-1 was established by both Western- and Northern-blot experiments. Our results show that several compounds can modulate expression of PmGST B1-1. The level of PmGST B1-1 increased when bacterial cells were exposed to a variety of stresses such as 1-chloro-2,4-dinitrobenzene, H2O2, fosfomycin or tetracycline. A knock-out gstB gene was also constructed using the suicide vector pKNOCKlox-Ap. Successful inactivation of the wild-type gene was confirmed by PCR, DNA sequence analysis and Western blotting. Under normal culture conditions, this mutant was viable and displayed no significant phenotypic differences compared with the wild- type. However, viability tests revealed that the null mutant was more sensitive to oxidative stress in the form of H2O2 and to several antimicrobial drugs when compared with the wild-type. These results suggest that PmGST B1-1 has an active role in the protection against oxidative stress generated by H2O2 and it ap- pears to be involved in the detoxification of antimicrobial agents
Bacterial peptide methionine sulphoxide reductase: co-induction with glutathione S-transferase during chemical stress conditions.
No full textPeptide methionine sulphoxide reductase (MsrA; EC 1.8.4.6) is a ubiquitous enzyme catalysing the reduction of methionine sulphoxide to methionine in proteins, while the glutathione S- transferases (GSTs) are a major family of detoxification enzymes. A gene homologous to MsrA was identified in a chromosomal fragment from the bacterium Ochrobactrum anthropi, and this gene is located just downstream of a GST gene identified previously (OaGST) [Favaloro, Tamburro, Angelucci, De Luca, Melino, Di Ilio and Rotilio (1998) Biochem. J. 335, 573–579]. This raises the question of whether the products of these two genes may be involved in a common cellular protection function. To test this hypothesis, the hypothetical MsrA protein has been overexpressed in Escherichia coli as a functional 51 kDa GST fusion protein. Following cleavage with thrombin and purifi- cation, the soluble 24 kDa protein showed MsrA activity with N- acetylmethionine sulphoxide as substrate, as well as with other sulphoxide compounds. Therefore polyclonal antibodies were raised against the recombinant protein, and the modulation of MsrA in this bacterium, grown in the presence of different stimulants simulating several stress conditions, was investigated. The level of expression of MsrA was detected both by measuring the mRNA level and by immunoblotting experiments, in addition to measuring its catalytic activity. MsrA is a constitutive enzyme which is also inducible by chemical stress involving phenolic compounds such as phenol and 4-chlorophenol. Recently we reported that the GST of this bacterium, like MsrA, is only modulated by toxic chemical compounds [Favaloro, Tamburro, Trofino, Bologna, Rotilio and Heipieper (2000) Biochem. J. 346, 553–559] ; therefore this is the first indication of a co-induction of the MsrA and GST enzymes during chemical stress
Glutamic acid 65 is an essential residue for catalysis in Proteus mirabilis glutathione transferase B1-1
No full textThe functional role of three conserved amino acid residues in Proteus mirabilis glutathione S-transferase B1-1 (PmGST B1-1) has been investigated by site-directed mutagenesis. Crystallographic analyses indicated that Glu65, Ser103 and Glu104 are in hydrogen-bonding distance of the N-terminal amino group of the γ-glutamyl moiety of the co-substrate, GSH. Glu65 was mutated to either aspartic acid or leucine, and Ser103 and Glu104 were both mutated to alanine. Glu65 mutants (Glu65Asp and Glu65Leu) lost all enzyme activity, and a drastic decrease in catalytic efficiency was observed for Ser103Ala and Glu104 Ala mutants toward both 1-chloro-2,4-dinitrobenzene and GSH. On the other hand, all mutants displayed similar intrinsic fluorescence, CD spectra and thermal stability, indicating that the mutations did not affect the structural integrity of the enzyme. Taken together, these results indicate that Ser103 and Glu104 are significantly involved in the interaction with GSH at the active site of PmGST B1-1, whereas Glu65 is crucial for catalysis
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