Hyperhomocysteinemia induced by guanidinoacetic acid is effectively suppressed by choline and betaine in rats.

Rats were fed 25% casein (25C) diets differing in choline levels (0-0.5%) with and without 0.5% guanidinoacetic acid (GAA) or 0.75% L-methionine for 7 d to determine the effects of dietary choline level on experimental hyperhomocysteinemia. The effects of dietary choline (0.30%) and betaine (0.34%) on GAA- and methionine-induced hyperhomocysteinemia were also compared. Dietary choline suppressed hyperhomocysteinemia induced by GAA, but not by methionine, in a dose-dependent manner. GAA-induced enhancement of the plasma homocysteine concentration was suppressed by choline and betaine to the same degree, but the effects of these compounds were relatively small on methionine-induced hyperhomocysteinemia. Dietary supplementation with choline and betaine significantly increased the hepatic betaine concentration in rats fed a GAA diet, but not in rats fed a methionine diet. These results indicate that choline and betaine are effective at relatively low levels in reducing plasma homocysteine, especially under the condition of betaine deficiency without a loading of homocysteine precursor.

Choline deprivation induces hyperhomocysteinemia in rats fed low methionine diets.

To clarify the relationship between dietary choline level and plasma homocysteine concentration, the effects of choline deprivation on plasma homocysteine concentration and related variables were investigated in rats fed a standard (25%) casein (25C) diet or standard soybean protein (25S) diet. Using the 25S diet, the time-dependent effect of choline deprivation and the comparative effects of three kinds of lipotropes were also investigated. Feeding rats with the choline-deprived 25S diet for 10 d significantly increased plasma total homocysteine concentration to a level 2.68-times higher than that of the control group, whereas choline deprivation had no effect in rats fed the 25C diet. Increases in hepatic S-adenosylhomocysteine and homocysteine concentrations, decreases in hepatic betaine concentration and the activity of cystathionine beta-synthase, but not betaine-homocysteine S-methyltransferase, and fatty liver also occurred in rats fed the choline-deprived 25S diet. Plasma homocysteine concentration increased when rats were fed the choline-deprived 25S diet for only 3 d, and the increase persisted up to 20 d. The hyperhomocysteinemia induced by choline deprivation was effectively suppressed by betaine or methionine supplementation. Choline deprivation caused hyperhomocysteinemia also in rats fed a choline-deprived low (10%) casein diet. The results indicate that choline deprivation can easily induce prominent hyperhomocysteinemia when rats are fed relatively low methionine diets such as a standard soybean protein diet and low casein diet, possibly through the suppression of homocysteine removal by both remethylation and cystathionine formation. This hyperhomocysteinemia might be a useful model for investigating the role of betaine in the regulation of plasma homocysteine concentration.

Dietary eritadenine suppresses guanidinoacetic Acid-induced hyperhomocysteinemia in rats.

We assessed the effect of eritadenine, a hypocholesterolemic factor isolated from the edible mushroom Lentinus edodes, on plasma homocysteine concentration using methyl-group acceptor-induced hyperhomocysteinemic rats. Male Wistar rats were fed a control diet or diets supplemented with a methyl-group acceptor or a precursor of methyl-group acceptor. Diets were supplemented with guanidinoacetic acid (GAA) at 2.5, 5, 7.5, and 10 g/kg, nicotinic acid (NiA) or ethanolamine (EA) at 5 and 10 g/kg, or glycine at 25 and 50 g/kg, and the rats were fed for 10 d (Expt. 1). Plasma total homocysteine concentration was increased 255 and 421% by 5 and 10 g/kg GAA, respectively, and 39 and 58% by 5 and 10 g/kg NiA, respectively, but not by EA or glycine. GAA supplementation dose-dependently decreased the hepatic S-adenosylmethionine (SAM) concentration and the activity of cystathionine beta-synthase (CBS) and increased the hepatic S-adenosylhomocysteine (SAH) and homocysteine concentrations. In another study in which rats were fed 5 g/kg GAA-supplemented diet for 1-10 d, plasma homocysteine and the other variables affected in Expt. 1 were affected in rats fed the GAA-supplemented diet (Expt. 2). We investigated the effect of supplementation of 5 g/kg GAA-supplemented diet with eritadenine (50 mg/kg) on plasma homocysteine concentration (Expt. 3). Eritadenine supplementation significantly suppressed the GAA-induced increase in plasma homocysteine concentration. Eritadenine also restored the decreased SAM concentration and CBS activity in the liver, whereas it further increased hepatic SAH concentration, suggesting that eritadenine might elicit its effect by both slowing homocysteine production and increasing cystathionine formation. The results confirm that GAA is a useful compound to induce experimental hyperhomocysteinemia and indicate that eritadenine can effectively counteract the hyperhomocysteinemic effect of GAA.