Modulation of aldose reductase activity through S-thiolation by physiological thiols.

The glutathionyl-modified aldose reductase (GS-ALR2) is unique, among different S-thiolated enzyme forms, in that it displays a lower specific activity than the native enzyme (ALR2). Specific interactions of the bound glutathionyl moiety (GS) with the ALR2 active site, were predicted by a low perturbative molecular modelling approach. The outcoming GS allocation, involving interactions with residues relevant for catalysis and substrate allocation, explains the rationale behind the observed differences in the activity between GS-ALR2 and other thiol-modified enzyme forms. The reversible S-glutathionylation of ALR2 observed in cultured intact bovine lens undergoing an oxidative/non oxidative treatment cycle is discussed in terms of the potential of ALR2/GS-ALR2 inter-conversion as a response to oxidative stress conditions.

Thiol disulfide exchange modulates the activity of aldose reductase in intact bovine lens as a response to oxidative stress.

The reversibility of S-thiolation of aldose reductase was shown in intact bovine lens subjected to oxidative stress. The glutathione modified aldose reductase generated in the lens as a consequence of hyperbaric oxygen treatment was recovered in its reduced form following culturing in normobaric air conditions. Nucleus and cortex were differently affected by both oxidative treatment and normobaric air recovery. The extent of S-thiolation of aldose reductase appeared to be higher in the nucleus than in the cortex. Moreover, the nucleus, but not the cortex, was unable to completely recover from the protein S-thiolation process. The ratios of GSH/GSSG and NADPH/NADP(+)as well as the Energy Charge values were determined in the cortex and nucleus both after oxidative stress and recovery. The results are consistent with the existence of a quite well-defined boundary between the two lens regions. Moreover, they are supportive of the hypothesis that thiol/disulfide exchange has the potential to be a regulatory mechanism for certain enzymes which can modulate the flux of NADPH inside the cell.

Site-specific inactivation of aldose reductase by 4-hydroxynonenal.

Bovine lens aldose reductase (ALR2), which catalyzes the NADPH-dependent reduction of 4-hydroxy-2-nonenal (HNE), is readily inactivated by its own substrate in a time- and concentration-dependent manner. Both DTT and NADP+ can prevent enzyme inactivation but neither extensive dialysis nor thiol-reducing treatment were able to restore enzyme activity once inactivation had occurred. Unlike the native enzyme, S-glutathionyl-modified ALR2 is unaffected by HNE, and can be easily reverted to the native form under thiol-reducing conditions. Evidence is presented of the involvement of Cys298 in the inactivation process. Zofenoprilat, an antioxidant thiol compound, mimics the effect of GSH. The possibility is raised that enzyme thiolation may function as a protection mechanism against the irreversible modification of ALR2.

Deoxyadenosine metabolism in a human colon-carcinoma cell line (LoVo) in relation to its cytotoxic effect in combination with deoxycoformycin.

We have assessed the intracellular metabolism of 2'-deoxyadenosine in a human colon-carcinoma cell line (LoVo), both in the absence and in the presence of deoxycoformycin, the powerful inhibitor of adenosine deaminase. The combination of 2'-deoxyadenosine and deoxycoformycin has been reported to inhibit the growth of LoVo cells in culture. In this paper we demonstrate that the observed toxic effect is strictly dependent on cell density. In the absence of deoxycoformycin, 2'-deoxyadenosine is primarily deaminated to 2'-deoxyinosine and then converted into hypoxanthine. In the presence of the inhibitor, the deoxynucleoside, in addition to a phosphorylation process, undergoes phosphorolytic cleavage giving rise to adenine. The conversion of 2'-deoxyadenosine to adenine might represent a protective device, emerging when the activity of adenosine deaminase is reduced or inhibited. There is much evidence to indicate that the enzyme catalyzing this process may be distinct from methylthioadenosine phosphorylase and S-adenosyl homocysteine hydrolase, which are the enzymes reported to be responsible for the formation of adenine from 2'-deoxyadenosine in mammals.

The phosphotransferase activity of cytosolic 5'-nucleotidase; a purine analog phosphorylating enzyme.

Cytosolic 5'-nucleotidase is involved in the phosphorylation of several purine nucleoside analogs,used as antiviral and chemotherapeutic agents. In order to assess its role in the mechanisms of activation and inactivation of purine prodrugs, it is essential to study the regulation of both hydrolase and phosphotransferase activities of the enzyme. Using a zone capillary electrophoresis apparatus, we were able to separate substrates and products of the reactions catalyzed by cytosolic 5'-nucleotidase. The method overcomes the frequent unavailability of radiolabeled substrates, and allows the influence of possible effectors and/or experimental conditions on both enzyme activities to be evaluated simultaneously. Results showed that the enzyme was able to phosphorylate several nucleosides and nucleoside analogs with the following efficiency: inosine and 2'-deoxyinosine > 2',3'-dideoxyinosine > 6-chloropurineriboside > 6-hydroxylaminepurine riboside> 2,6-diaminopurine riboside > adenosine > cytidine > deoxycoformycin > 2'deoxyadenosine. This is the first report of deoxycoformycin phosphorylation catalyzed by a 5'-nucleotidase purified from eukaryotic cells. The optimum pH for nucleoside monophosphate hydrolysis was 6.5, slightly more acidic than the optimum pH for the transfer of the phosphate, which was 7.2. Finally, the presence of a suitable substrate for the phosphotransferase activity of cytosolic 5'-nucleotidase caused a stimulation of the rate of formation of the nucleoside. The results suggest the requirements for phosphorylation of nucleoside analogs are a purine ring and the presence of an electronegative group in the 6 position. The stimulation of the rate of nucleoside monophosphate disappearance exerted by the phosphate acceptor suggests that the hydrolysis of the phosphoenzyme intermediate is the rate-limiting step of the process.