Isabel Pérez-Mato scite author profile

S-Adenosylmethionine serves as the methyl donor for many biological methylation reactions and provides the propylamine group for the synthesis of polyamines. SAdenosylmethionine is synthesized from methionine and ATP by the enzyme methionine adenosyltransferase. The cellular factors regulating S-adenosylmethionine synthesis have not been well defined. Here we show that in rat hepatocytes S-nitrosoglutathione monoethyl ester, a cell-permeable nitric oxide donor, markedly reduces cellular S-adenosylmethionine content via inactivation of methionine adenosyltransferase by S-nitrosylation. Removal of the nitric oxide donor from the incubation medium leads to the denitrosylation and reactivation of methionine adenosyltransferase and to the rapid recovery of cellular S-adenosylmethionine levels. Nitric oxide inactivates methionine adenosyltransferase via S-nitrosylation of cysteine 121. Replacement of the acidic (aspartate 355) or basic (arginine 357 and arginine 363) amino acids located in the vicinity of cysteine 121 by serine leads to a marked reduction in the ability of nitric oxide to S-nitrosylate and inactivate hepatic methionine adenosyltransferase. These results indicate that protein S-nitrosylation is regulated by the basic and acidic amino acids surrounding the target cysteine.In the liver S-adenosylmethionine (AdoMet) 1 serves as the methyl donor for many biological methylation reactions (such as DNA, proteins, phospholipids, and adrenergic, dopaminergic, and serotoninergic molecules) and provides the propylamine group for the synthesis of polyamines (1-3). AdoMet is synthesized from methionine and ATP by the enzyme methionine adenosyltransferase (MAT). There are two MAT genes; one is expressed only in the liver, and the other is expressed in extrahepatic tissues and fetal liver (2-4). Up to 85% of all methylation reactions and as much as 50% of methionine metabolism occur in the liver (5), which agrees with this tissue having the highest specific activity of MAT (6). Moreover, in the liver the half-life of AdoMet is of only about 5 min (6).Reduced levels of AdoMet and/or MAT activity, resulting in the abnormal metabolism of methionine, have been found in human cirrhosis and in a variety of experimental models including liver injury induced by ethanol, CCl 4 , and galactosamine (3, 7). The importance of this alteration in AdoMet synthesis in the pathogenesis of a variety of liver disorders is suggested by the finding that exogenous AdoMet administration protects from the hepatotoxic effect induced by a variety of agents, such as ethanol, CCl 4 , paracetamol, tumor necrosis factor, and galactosamine (3, 7). The cellular factors regulating hepatic AdoMet levels are beginning to be defined. One such factor is nitric oxide (NO). In previous studies we demonstrated that conditions that induce NO synthesis, such as septic shock and hypoxia, induce the inactivation of hepatic MAT without affecting the expression of the liver-specific MAT gene (8, 9). Further, we have reported previously that incubation of rat hepa...

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Importance of a deficiency in S-adenosyl-l-methionine synthesis in the pathogenesis of liver injury,,,

Martínez‐Chantar

Garcı́a-Trevijano

Latasa

et al. 2002

The American Journal of Clinical Nutrition

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One of the features of liver cirrhosis is an abnormal metabolism of methionine--a characteristic that was described more than a half a century ago. Thus, after an oral load of methionine, the rate of clearance of this amino acid from the blood is markedly impaired in cirrhotic patients compared with that in control subjects. Almost 15 y ago we observed that the failure to metabolize methionine in cirrhosis was due to an abnormally low activity of the enzyme methionine adenosyltransferase (EC 2.5.1.6). This enzyme converts methionine, in the presence of ATP, to S-adenosyl-L-methionine (SAMe), the main biological methyl donor. Since then, it has been suspected that a deficiency in hepatic SAMe may contribute to the pathogenesis of the liver in cirrhosis. The studies reviewed here are consistent with this hypothesis.

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Regulation of Mammalian Liver Methionine Adenosyltransferase

Corrales

Pérez-Mato

Pino

et al. 2002

The Journal of Nutrition

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S-adenosylmethionine (SAM) is an essential metabolite in all cells. SAM is the most important biological methyl group donor and is a precursor in the synthesis of polyamines. Methionine adenosyltransferase (MAT; EC 2.5.1.6) catalyzes the only known SAM biosynthetic reaction from methionine and ATP. In mammalian tissues, three different forms of MAT (MAT I, MAT III and MAT II) have been identified that are the product of two different genes (MAT1A and MAT2A). Although MAT2A is expressed in all mammalian tissues, the expression of MAT1A is primarily restricted to adult liver. In mammals, up to 85% of all methylation reactions and as much as 48% of methionine metabolism occurs in the liver, which indicates the important role of this organ in the regulation of blood methionine. Recent evidence indicates that not only is SAM the main biological methyl group donor and an intermediate metabolite in methionine catabolism, but it is also an intracellular control switch that regulates essential hepatic functions such as liver regeneration and differentiation as well as the sensitivity of this organ to injury. Therefore, knowledge of factors that regulate the activity of MAT I/III, the specific liver enzyme, is essential to understand how cellular SAM levels are controlled.

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Folding of Dimeric Methionine Adenosyltransferase III

Pino¹,

Pérez-Mato²,

Sanz³

et al. 2002

Journal of Biological Chemistry

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Methionine adenosyl transferase (MAT) is an essential enzyme that synthesizes AdoMet. The liver-specific MAT isoform, MAT III, is a homodimer of a 43.7-kDa subunit that organizes in three nonsequential ␣-␤ domains. Although MAT III structure has been recently resolved, little is known about its folding mechanism. Equilibrium unfolding and refolding of MAT III, and the monomeric mutant R265H, have been monitored using different physical parameters. Tryptophanyl fluorescence showed a three-state folding mechanism. The first unfolding step was a folding/association process as indicated by its dependence on protein concentration. The monomeric folding intermediate produced was the predominant species between 1.5 and 3 M urea. It had a relatively compact conformation with tryptophan residues and hydrophobic surfaces occluded from the solvent, although its N-terminal region may be very unstructured. The second unfolding step monitored the denaturation of the intermediate. Refolding of the intermediate showed first order kinetics, indicating the presence of a kinetic intermediate within the folding/association transition. Its presence was confirmed by measuring the 1,8-anilinonaphtalene-8-sulfonic acid binding in the presence of tripolyphosphate. We propose that the folding rate-limiting step is the formation of an intermediate, probably a structured monomer with exposed hydrophobic surfaces, that rapidly associates to form dimeric MAT III.

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Creation of a functional S‐nitrosylation site in vitro by single point mutation

et al. 1999

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Here we show that in extrahepatic methionine adenosyltransferase replacement of a single amino acid (glycine 120) by cysteine is sufficient to create a functional nitric oxide binding site without affecting the kinetic properties of the enzyme. When wild-type and mutant methionine adenosyltransferase were incubated with S-nitrosoglutathione the activity of the wild-type remained unchanged whereas the activity of the mutant enzyme decreased markedly. The mutant enzyme was found to be S-nitrosylated upon incubation with the nitric oxide donor. Treatment of the S-nitrosylated mutant enzyme with glutathione removed most of the S-nitrosothiol groups and restored the activity to control values. In conclusion, our results suggest that functional S-nitrosylation sites can develop from existing structures without drastic or large-scale amino acid replacements.z 1999 Federation of European Biochemical Societies.

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