Hepatic cystathionine beta-synthase activity does not increase in response to methionine supplementation in rats fed a low casein diet: association with plasma homocysteine concentrations.

To elucidate the mechanism by which moderate and high protein diets fail to increase plasma homocysteine concentration despite dietary methionine levels being higher, rats were fed diets with graded levels (10, 30, and 50%) of casein or low casein diets supplemented with methionine at levels of 0.5 and 1.0% together with or without glycine+serine, which corresponded to moderate and high casein diets with respect to these amino acids, for 14 d. The plasma homocysteine concentration significantly decreased with an increase in dietary casein level, whereas it significantly increased with an increase in dietary methionine level when the low casein diet was supplemented with methionine. Supplementation with glycine+serine significantly suppressed the elevation of plasma homocysteine concentration due to methionine supplementation, but it could not decrease plasma homocysteine concentration to the levels in rats fed corresponding casein diets. Increased concentrations of hepatic S-adenosylhomocysteine and homocysteine due to methionine supplementation were also significantly suppressed by glycine+serine. The activity of hepatic cystathionine beta-synthase (CBS) did not increase in response to methionine supplementation, while it significantly increased with an increase in dietary casein level. In contrast, the activity of hepatic betaine-homocysteine S-methyltransferase (BHMT) significantly increased with increase in both dietary casein level and dietary methionine level. Hepatic levels of mRNA for CBS and BHMT were parallel to the enzyme activities. The results suggest that, in contrast to methionine-supplemented low casein diets, moderate and high casein diets avoid increasing plasma homocysteine concentration through dual mechanisms, greater supply of glycine+serine and an increase in CBS activity.

High casein diet decreases plasma homocysteine concentration in rats.

Experiments were conducted to clarify the relationship between dietary protein level and plasma homocysteine concentration in rats. Male Wistar rats were fed diets differing in casein level from 5 to 50% for 14 d (Expt. 1). Plasma total homocysteine concentration was positively correlated with dietary casein level in the range of 5 to 10% but inversely correlated with dietary casein level in the range of 10 to 50%. Hepatic cystathionine beta-synthase (CBS) and betaine-homocysteine S-methyltransferase (BHMT) activities and renal CBS activity increased in response to dietary casein level in the range of 10 to 50%, whereas hepatic serine and betaine concentrations decreased with increasing dietary casein levels. When rats were fed the 10% casein diet or 10% casein+17.2% amino acid mixture diet for 14 d, plasma homocysteine concentration was significantly lower in rats fed the amino acid mixture-added diet than in rats fed the 10% casein diet (Expt. 2), indicating that the hypohomocysteinemic effect of high casein diets was elicited by amino acids, not by casein contaminants. The degree of increase in plasma homocysteine concentration caused by dietary supplementation with 0.75% L-methionine was significantly lower in rats fed the 40% casein diet than in rats fed the 10% casein diet (Expt. 3). These results indicate that high casein diets do not increase but rather decrease plasma homocysteine concentration and cause resistance to hyperhomocysteinemic treatment, and suggest that such effects of high casein diets are mediated at least by increased activities of CBS and BHMT.

Hypohomocysteinemic effect of cysteine is associated with increased plasma cysteine concentration in rats fed diets low in protein and methionine levels.

Rats were fed diets with and without 0.5% L-cysteine supplement for 14 d or shorter periods to clarify the mechanism by which dietary cysteine elicits its hypohomocysteinemic effect. Cysteine supplementation significantly decreased plasma homocysteine concentration with an increase in plasma cysteine concentration in rats fed 10% casein diet (10C) or 15% soybean protein diet (15S) but not in rats fed 25% casein diet (25C) or 25% soybean protein diet. Cysteine supplementation also significantly suppressed hyperhomocysteinemia induced by choline-deprived 10C with an increase in plasma cysteine concentration but not that induced by 25C+0.65% methionine or 25C+0.4% guanidinoacetic acid. Hepatic S-adenosylmethionine (SAM) and homocysteine concentrations were significantly decreased by cysteine supplementation of 15S. These decreases in plasma homocysteine concentration and hepatic SAM and homocysteine concentrations due to cysteine supplementation disappeared when 15S was fortified with 0.3% methionine. The plasma homocysteine concentration significantly decreased with an increase in plasma cysteine concentration only 1 d after diet change from 15S to cysteine-supplemented 15S, while hepatic cystathionine beta-synthase and betaine-homocysteine S-methyltransferase activities were not altered. Unlike cysteine, cysteic acid and 2-mercaptoethylamine did not decrease plasma homocysteine concentration. These results indicate that cysteine markedly decreases plasma homocysteine concentration only when added to diets low in both protein and methionine levels and suggest that increased plasma cysteine concentration and decreased flow of methionine toward homocysteine formation, but not alteration of homocysteine-metabolizing enzyme activities, are associated with the hypohomocysteinemic effect of cysteine.

High-casein diet suppresses guanidinoacetic acid-induced hyperhomocysteinemia and potentiates the hypohomocysteinemic effect of serine in rats.

To determine the effect of dietary protein level on experimental hyperhomocysteinemia, rats were fed 10% casein (10C) and 40% casein (40C) diets with or without 0.5% guanidinoacetic acid (GAA) for 14 d. In addition, rats were fed 10C + 0.75% methionine (10CM) and 40C + 0.75% methionine (40CM) diets with or without 2.5% serine for 14 d to determine the relationship between the dietary protein level and intensity of the hypohomocysteinemic effect of serine. GAA supplementation markedly increased the plasma homocysteine concentration in rats fed with the 10C diet, whereas it did not increase the plasma homocysteine concentration in rats fed with the 40C diet. Although serine supplementation significantly suppressed the methionine-induced enhancement of plasma homocysteine concentration, the decreased plasma homocysteine concentration was significantly lower in rats fed with the 40CM diet than in rats fed with the 10CM diet. The hepatic cystathionine beta-synthase and betaine-homocysteine S-methyltransferase activities were significantly higher in rats fed with the 40C or 40CM diet than in rats fed with the 10C or 10CM diet, irrespective of supplementation with GAA and serine. These results indicate that the high-casein diet was effective for both suppressing GAA-induced hyperhomocysteinemia and potentiating the hypohomocysteinemic effect of serine, probably through the enhanced activity of homocysteine-metabolizing enzymes.

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.