Methionine dependency of cultured human lymphocytes

Human peripheral blood lymphocytes stimulated with phytohemagglutinin and a lymphocyte model consisting of the RPMI 6410 cell, a human virus-transformed B cell, required added methionine (Met) for growth of the cultures. This failure to meet all needs for Met via endogenous synthesis, which is characteristic of oncogenic transformation, occurred even in the presence of adequate homocysteine, methylfolate (5-CH3-H4PteGlu) and cobalamin (Cbl)-dependent methionine synthetase activity. Folinic acid (5-CHO-H4PteGlu), which provides available folate independently of Cbl, improved growth only slightly in the absence of Met. Free Cbl at 222 nM, an amount great enough to alter other intracellular events, failed to increase growth in the absence of Met, but 0.22 nM Cbl bound to transcobalamin II did, however, enhance growth.     

The regulation of one-carbon oxidation in the rat by nitrous oxide and methionine

Formate is oxidized to CO₂ in the rat by folate-dependent reactions. Nitrous oxide treatment inhibited hepatic methionine synthetase activity, reduced hepatic S-adenosyl-l-methionine (Ado-Met) and tetrahydrofolate (H₄ folate) concentrations and decreased the rate of formate oxidation in the rat. The administration of methionine to nitrous oxide-treated rats increased hepatic Ado-Met concentrations and restored hepatic H₄folate levels and formate oxidation to control values but did not reverse the inhibition of methionine synthetase. Positive correlations were observed between hepatic Ado-Met levels and H₄folate concentrations and between hepatic H₄folate concentrations and formate oxidation. These results suggest that alterations in hepatic H₄folate concentrations may profoundly influence the oxidation of one-carbon compounds. They confirm the importance of the methionine synthetase reaction as a major source of regeneration of H₄folate. These findings also indicate that methionine acts at a site other than the methionine synthetase reaction to restore hepatic H₄folate concentrations and formate oxidation to control values in nitrous oxide-treated rats.     

Increased methionine synthetase activity in zinc-deficient rat liver

To study the effect of zinc deficiency on folate metabolism, three groups of male Sprague-Dawley rats (zinc deficient (ZD), restricted-fed (RF + Zn), and ad libitum-fed control (control] were given a semipurified 25% egg white protein diet. The ZD group received less than 10.3 nmol zinc/g of diet, while the RF + Zn and control groups were given 1620 nmol zinc/g of diet. After 6-7 weeks of feeding, severe zinc deficiency developed in ZD rats. Hepatic methionine synthetase activity was increased in the ZD group compared to both the RF + Zn and control groups, but hepatic 5,10-CH2-H4folate reductase activity was similar in all groups. This increased methionine synthetase activity found in zinc-deficient rats might induce secondary alterations in folate metabolism. These changes include significantly lowered plasma folate levels, decreased 5-CH3-H4folate in liver, and increased rates of histidine and formate oxidation. The latter two findings suggest that the available non-5-CH3-H4folate is increased in zinc deficiency.     

The relationships between vitamin B12 and folic acid and the effect of methionine on folate metabolism

The relationship between vitamin B12 and folate and the effect of methionine on folate metabolism during B12 deficiency in rats is best explained by the prevention of the accumulation of 5-methyl-H4PteGlu by vitamin B12 and/or methionine. Although several points remain to be clarified, the 'methyl trap' hypothesis provides the most satisfactory explanation for the relation between vitamin B12, methionine and folic acid. This concept is extended by the hypothesis that H4PteGlu is the most active substrate for pteroylpolyglutamate synthetase, and thus accounts for the effect of methionine or vitamin B12 increasing liver folate levels.     

Effect of folate deficiency on placental DNA methylation in hyperhomocysteinemic rats

We report that the maternal folate status can influence folate-mediated one-carbon metabolism and DNA methylation in the placenta. Thirty-six female Sprague-Dawley rats were divided into the following three dietary groups: folate-supplemented (FS; 8 mg/kg folic acid, n=12), homocystine- and folate-supplemented (HFS; 0.3% homocystine and 8 mg/kg folic acid, n=12) and homocystine-supplemented and folate-deficient (HFD; 0.3% homocystine and no folic acid, n=12). The animals were fed their experimental diets from 4 weeks prior to mating until Day 20 of pregnancy (n=7-9 per group). The HFS diet increased the plasma homocysteine and placental DNA methylation but did not affect plasma folate, vitamin B-12, S-adenosyl methionine (SAM) or S-adenosyl homocysteine (SAH) levels, or the SAM/SAH ratio in the liver and placenta compared with the FS diet. The HFD diet induced severely low plasma folate concentrations, with plasma homocysteine levels increasing up to 100 micromol/L, and increased hepatic SAH and decreased placental SAM levels and SAM/SAH ratio in both tissues, with a concomitant decrease in placental DNA methylation. Placental DNA methylation was significantly correlated with placental (gamma=0.819), hepatic (gamma=0.7) and plasma (gamma=0.752) folate levels; plasma homocysteine level (gamma=-0.688); hepatic SAH level (gamma=-0.662) and hepatic SAM/SAH ratio (gamma=0.494). These results suggest that the maternal folate status in hyperhomocysteinemic rats influences the homeostasis of folate-mediated one-carbon metabolism and the methyl pool, which would, in turn, affect placental DNA methylation by altering the methylation potential of the liver.     

The role of transcobalamin II in the methionine dependency of human lymphocytes

Neither normal human B lymphoblasts (RPMI 6410) transformed by the EB virus nor human peripheral blood lymphocytes (PBL) stimulated by a mitogen replicated well when the methionine (Met) of the medium was replaced with homocysteine (Hcy). Cbl bound to human transcobalamin II (TC II) substantially increased cell division over that observed when the Cbl of the medium was in the free form. Although, as expected, the TC II enhanced the cell entry of Cbl 1000-fold, this was not the basis of the TC II effect. Through adjustment of the respective concentrations of free Cbl and TC II-Cbl in the medium, equal amounts of Cbl entered the cell, yet the TC II effect persisted. TC II-Cbl did not restore cell division in the absence of Met by virus-transformed lymphoblasts from a child with defective Met synthesis from Hcy. The TC II did not act by enhanced induction of the Cbl-dependent methionine synthase activity of cell extracts but the ability of intact cells to produce Met from Hcy by the Cbl-dependent process appeared to have a role in the TC II effect.     

Chronic ethanol perturbs testicular folate metabolism and dietary folate deficiency reduces sex hormone levels in the Yucatan micropig

Although alcoholism causes changes in hepatic folate metabolism that are aggravated by folate deficiency, male reproductive effects have never been studied. We evaluated changes in folate metabolism in the male reproductive system following chronic ethanol consumption and folate deficiency. Twenty-four juvenile micropigs received folate-sufficient (FS) or folate-depleted (FD) diets or the same diets containing 40% of energy as ethanol (FSE or FDE) for 14 wk, and the differences between the groups were determined by ANOVA. Chronic ethanol consumption (FSE and FDE compared with FS and FD groups) reduced testis and epididymis weights, testis sperm concentrations, and total sperm counts and circulating FSH levels. Folate deficiency (FD and FDE compared with FS and FSE groups) reduced circulating testosterone, estradiol and LH levels, and also testicular 17,20-lyase and aromatase activities. There was histological evidence of testicular lesions and incomplete progression of spermatogenesis in all treated groups relative to the FS control, with the FDE group being the most affected. Chronic ethanol consumption increased testis folate concentrations and decreased testis methionine synthase activity, whereas folate deficiency reduced total testis folate levels and increased methionine synthase activity. In all pigs combined, testicular methionine synthase activity was negatively associated with circulating estradiol, LH and FSH, and 17,20-lyase activity after controlling for ethanol, folate deficiency, and their interaction. Thus, while chronic ethanol consumption primarily impairs spermatogenesis, folate deficiency reduces sex hormones, and the two treatments have opposite effects on testicular folate metabolism. Furthermore, methionine synthase may influence the hormonal regulation of spermatogenesis.     

Effect of Cobalamin Deficiency on the Biosynthesis of Phosphatidylcholine in Euglena gracilis

Euglena gracilis requires cobalamin (Cbl) as an essential growth factor. Phosphatidylcholine (PC) synthesis was greatly reduced by Cbl deficiency. Rapid cell division occurred after Cbl was replenished, and PC was actively synthesized during the cell divisions. When the deficient cells were given methionine (a precursor for the choline moiety), active synthesis of PC occurred even without the Cbl supplement, although cell division was not induced. As methionine synthase in Euglena requires methylcobalamin as a coenzyme, decrease in methionine synthesis may account for reduced PC synthesis under Cbl-deficient conditions. Phosphatidyleth-anolamine and phosphatidylserine synthesis were also suppressed, commensurate with decrease of PC synthesis, under Cbl deficiency, even though Cbl is not thought to participate in their synthesis. In contrast, a lot of triglyceride and wax ester accumulated in Cbl-deficient cells. Moreover, Cbl depletion altered fatty acid composition, notably due to increased proportion of odd-numbered fatty acids     

Palm tocotrienol-rich fraction reduced plasma homocysteine and heart oxidative stress in rats fed with a high-methionine diet

Oxidative stress contributes to cardiovascular diseases. We aimed to study the effects of palm tocotrienol-rich fraction (TRF) on plasma homocysteine and cardiac oxidative stress in rats fed with a high-methionine diet. Forty-two male Wistar rats were divided into six groups. The first group was the control. Groups 2–6 were fed 1 % methionine diet for 10 weeks. From week 6 onward, folate (8 mg/kg diet) or palm TRF (30, 60 and 150 mg/kg diet) was added into the diet of groups 3, 4, 5 and 6. The rats were then killed. Palm TRF at 150 mg/kg and folate supplementation prevented the increase in plasma total homocysteine (4.14?±?0.33 and 4.30?±?0.26 vs 5.49?±?0.25 mmol/L, p?<?0.05) induced by a high-methionine diet. The increased heart thiobarbituric acid reactive substance in rats fed with high-methionine diet was also prevented by the supplementations of palm TRF (60 and 150 mg/kg) and folate. The high-methionine group had a lower glutathione peroxidase activity (49?±?3 vs 69?±?4 pmol/mg protein/min) than the control group. This reduction was reversed by palm TRF at 60 and 150 mg/kg diet (p?<?0.05), but not by folate. Catalase and superoxide dismutase activities were unaffected by both methionine and vitamin supplementations. In conclusion, palm TRF was comparable to folate in reducing high-methionine diet-induced hyperhomocysteinemia and oxidative stress in the rats’ hearts. However, palm TRF was more effective than folate in preserving the heart glutathione peroxidase enzyme activity.     

The effect of methionine on the metabolism of serine and glycine in vitamin B-12-deficient rats.

The effect of methionine supplementation on glycine and serine metabolism was studied in vitamin B-12-deficient rats which received only 0.2% methionine in the diet. In the perfused liver, incorporation of the C-2 of glycine to the C-3 of serine was increased by addition of methionine to the perfusate. The oxidation of [1-14C]glycine to 14CO2 was however depressed. Unlike methionine, glycine did not have any significant effect on the liver folate coenzyme distribution. Oxidation of [3-14C]serine to 14CO2 both in vivo and in perfused liver was increased by methionine. A major portion of the C-3 radioactivity however was recovered in glucose. Data presented indicate that the rate of oxidation of [2-14C]histidine to 14CO2 is a more sensitive indicator of folate deficiency than the rate of oxidation of [3-14C]serine to 14CO2 although both are presumably tetrahydrofolate dependent.     

Folate and homocysteine metabolism in copper-deficient rats.

To investigate the effect of copper deficiency on folate and homocysteine metabolism, we measured plasma, red-cell and hepatic folate, plasma homocysteine and vitamin B-12 concentrations, and hepatic methionine synthase activities in rats. Two groups of male Sprague-Dawley rats were fed semi-purified diets containing either 0. 1 mg (copper-deficient group) or 9.2 mg (control group) of copper per kg. After 6 weeks of dietary treatment, copper deficiency was established as evidenced by markedly decreased plasma and hepatic copper concentrations in rats fed the low-copper diet. Plasma, red-cell, hepatic folate, and plasma vitamin B-12 concentrations were similar in both groups, whereas plasma homocysteine concentrations in the copper-deficient group were significantly higher than in the control group (P<0.05). Copper deficiency resulted in a 21% reduction in hepatic methionine synthase activity as compared to the control group (P<0.01). This change most likely caused the increased hepatic 5-methyltetrahydrofolate and plasma homocysteine concentrations in the copper-deficient group. Our results indicate that hepatic methionine synthase may be a cuproenzyme, and plasma homocysteine concentrations are influenced by copper nutriture in rats. These data support the concept that copper deficiency can be a risk factor for cardiovascular disease.     

Cobalamin deficiency results in severe metabolic disorder of serine and threonine in rats.

Dietary cobalamin (vitamin B12; Cbl) deficiency caused significant increases in plasma serine, threonine, glycine, alanine, tyrosine, lysine and histidine levels in rats. In particular, the serine and threonine levels were over five and eight times, respectively, higher in the Cbl-deficient rats than those in the sufficient controls. In addition, some amino acids, including serine and threonine, were excreted into urine at significantly higher levels in the deficient rats. When Cbl was supplemented into the deficient rats for 2 weeks, in coincidence with the disappearance of the urinary excretion of methylmalonic acid (an index of Cbl deficiency), the plasma serine and threonine levels were normalized. These results indicate that Cbl deficiency results in metabolic disorder of certain amino acids, including serine and threonine. The expression level of hepatic serine dehydratase (SDH), which catalyzes the conversion of serine and threonine to pyruvate and 2-oxobutyrate, respectively, was significantly lowered by Cbl deficiency, even though Cbl does not participate directly in the enzyme reaction. The SDH activity in the deficient rats was less than 20% of that in the sufficient controls, and was normalized 2 weeks after the Cbl supplementation. It is thus suggested that the decrease of the SDH expression relates closely with the abnormalities in the plasma and urinary levels of serine and threonine in the Cbl-deficient rats.     

Cobalamin deficiency results in severe metabolic disorder of serine and threonine in rats

Dietary cobalamin (vitamin B12; Cbl) deficiency caused significant increases in plasma serine, threonine, glycine, alanine, tyrosine, lysine and histidine levels in rats. In particular, the serine and threonine levels were over five and eight times, respectively, higher in the Cbl-deficient rats than those in the sufficient controls. In addition, some amino acids, including serine and threonine, were excreted into urine at significantly higher levels in the deficient rats. When Cbl was supplemented into the deficient rats for 2 weeks, in coincidence with the disappearance of the urinary excretion of methylmalonic acid (an index of Cbl deficiency), the plasma serine and threonine levels were normalized. These results indicate that Cbl deficiency results in metabolic disorder of certain amino acids, including serine and threonine. The expression level of hepatic serine dehydratase (SDH), which catalyzes the conversion of serine and threonine to pyruvate and 2-oxobutyrate, respectively, was significantly lowered by Cbl deficiency, even though Cbl does not participate directly in the enzyme reaction. The SDH activity in the deficient rats was less than 20% of that in the sufficient controls, and was normalized 2 weeks after the Cbl supplementation. It is thus suggested that the decrease of the SDH expression relates closely with the abnormalities in the plasma and urinary levels of serine and threonine in the Cbl-deficient rats.     

Mechanism of conversion of human apo- to holomethionine synthase by various forms of cobalamin.

Methionine synthase catalyzes the conversion of N5-methyltetrahydrofolate and homocysteine to tetrahydrofolate and methionine. Methylcobalamin (Me-Cbl) is tightly bound to methionine synthase and is required for enzymatic activity. When added to crude tissue homogenates, Me-Cbl stimulates methionine synthase but similar stimulation is observed with hydroxocobalamin, cyanocobalamin (CN-Cbl), and adenosyl-Cbl, although the mechanisms involved are unknown. We prepared human apomethionine synthase and studied its activation in the presence of [14C]CN-Cbl and [14CH3]Me-Cbl with concentrations of 2-mercaptoethanol ranging from 0.15 to 100 mM. We observed that the removal of the labeled upper axial ligands from CN-Cbl and Me-Cbl both paralleled the activation of human apomethionine synthase. Spectral studies employing CN-Cbl and Me-Cbl showed that both forms of Cbl must be converted to Cob(II)alamin before they can bind to human apomethionine synthase and convert it to its activated holoenzyme form. Studies with 14 different Cbl analogues with alterations in various portions of the corrin ring and the nucleotide showed that all of the analogues were able to fully activate human methionine synthase when they were reduced with 2-mercaptoethanol. Full activation occurred at lower concentrations of many of the Cbl analogues than occurred with Cbl itself. We conclude that Me-Cbl and other forms of Cob(III)alamin do not bind to human apomethionine synthase and that all must first be reduced to Cob(II)alamin before such binding can occur. The fact that human methionine synthase shows little absolute specificity for alterations in various portions of the Cbl molecule suggests that the potent inhibition of mammalian methionine synthase activity observed in vivo with various Cbl analogues is due to inhibition of intracellular Cbl transport or to inhibition of the enzymatic formation of Cob(II)alamin rather than to direct inhibition of mammalian methionine synthase itself.     

Effects of dietary zinc deficiency on homocysteine and folate metabolism in rats

In rats, zinc deficiency has been reported to result in elevated hepatic methionine synthase activity and alterations in folate metabolism. We investigated the effect of zinc deficiency on plasma homocysteine concentrations and the distribution of hepatic folates. Weanling male rats were fed ad libitum a zinc-sufficient control diet (382.0 nmol zinc/g diet), a low-zinc diet (7.5 nmol zinc/g diet), or a control diet pair-fed to the intake of the zinc-deficient rats. After 6 weeks, the body weights of the zinc-deficient and pair-fed control groups were lower than those of controls, and plasma zinc concentrations were lowest in the zinc-deficient group. Plasma homocysteine concentrations in the zinc-deficient group (2.3 +/- 0.2 micromol/L) were significantly lower than those in the ad libitum-fed and pair-fed control groups (6.7 +/- 0.5 and 3.2 +/- 0.4 micromol/L, respectively). Hepatic methionine synthase activity in the zinc-deficient group was higher than in the other two groups. Low mean percentage of 5-methyltetrahydrofolate in total hepatic folates and low plasma folate concentration were observed in the zinc-deficient group compared with the ad libitum-fed and pair-fed control groups. The reduced plasma homocysteine and folate concentrations and reduced percentage of hepatic 5-methyltetrahydrofolate are probably secondary to the increased activity of hepatic methionine synthase in zinc deficiency.     

Dietary methionine effects on plasma homocysteine and HDL metabolism in mice

The effects of dietary manipulation of folate and methionine on plasma homocysteine (Hcy) and high-density lipoprotein cholesterol (HDL-C) levels in wild-type and apolipoprotein-E-deficient mice were determined. A low-folate diet with or without folate and/or methionine supplementation in drinking water was administered for 7 weeks. Fasted Hcy rose to 23 microM on a low-folate/high-methionine diet, but high folate ameliorated the effect of high methionine on fasted plasma Hcy to approximately 10 microM. Determination of nonfasted plasma Hcy levels at 6-h intervals revealed a large diurnal variation in Hcy consistent with a nocturnal lifestyle. The daily average of nonfasted Hcy levels was higher than fasted values for high-methionine diets but lower than fasted values for low-methionine diets. An acute methionine load by gavage of fasted mice increased plasma Hcy 2.5 h later, but mice that had been on high-methionine diets had a lower fold induction. Mice fed high-methionine diets weighed less than mice fed low-methionine diets. Based on these results, two solid-food diets were developed: one containing 2% added methionine and the other containing 2% added glycine. The methionine diet led to fasted plasma Hcy levels of >60 microM, higher than those with methionine supplementation in drinking water. Mice on methionine diets had >20% decreased body weights and decreased HDL-C levels. An HDL turnover study demonstrated that the HDL-C production rate was significantly reduced in mice fed the methionine diet.     

Cobalamin metabolism in cultured human chorionic villus cells

Cobalamin (Cbl, vitamin B₁₂) metabolism was analyzed in cultures of human chorionic villus (CV) cells obtained at 9–10 weeks of gestation. CV cells were shown to synthesize transcobalamin II (TCII) and to possess a high affinity receptor for that molecule. The cells bound and internalized radioactive cyanocobalamin (CN[⁵⁷Co]Cbl) complexed to TCII. This internalized CN[⁵⁷Co]Cbl was found to be converted to both methylCbl and adenosylCbl, the two intracellular coenzyme forms of Cbl, and bound to the two known intracellular Cbl requiring enzymes, methionine synthase (MS) and methylmalonyl-CoA mutase. Both enzyme systems were found to be functional in the intact cell by demonstrating the incorporation of the radioactive label from both [¹⁴C]CH₃-tetrahydrofolate and [¹⁴C]propionate into acid insoluble products. MS activity was also detected in lysed cell material. CV cells were shown not to be auxotrophic for methionine since they were able to utilize homocysteine in place of methionine for cell division. Since CV cells are capable of performing many of the complex events associated with Cbl metabolism, it may be possible to use these cells to diagnose genetic defects of Cbl metabolism. © 1993 Wiley-Liss, Inc.     

Heterogeneity in cblG: differential retention of cobalamin on methionine synthase.

Cultured fibroblasts from patients with functional methionine synthase deficiency have been shown to belong to two complementation classes, cblE and cblG. Both are associated with decreased intracellular levels of methylcobalamin (MeCbl) and decreased incorporation of label from 5-methyltetrahydrofolate into macromolecules. Methionine synthase specific activity is normal or near normal in cell extracts from cblE patients under standard reducing conditions, whereas specific activity is low in cblG extracts. Seven of 10 cblG cell lines accumulated [57Co]CN-Cbl equivalent to control cells and showed similar proportions of label associated with the two intracellular cobalamin binders, methionine synthase and methylmalonyl-CoA mutase. The remaining three cblG lines showed reduced accumulation of labeled Cbl and virtually none associated with methionine synthase. The specific activity of methionine synthase was decreased in cell extracts from both cblG subgroups, being almost undetectable in extracts from the latter three lines. Incorporation of label from [14C]MeTHF into either macromolecules or into methionine was decreased in both cblG groups, but was paradoxically higher in the three lines with very low in vitro methionine synthase activity. These results demonstrate further heterogeneity within cblG and suggest that the defect in the three variant lines affects the ability of methionine synthase to retain Cbl.     

Relationships between cobalamin,epidermal growth factor,and normal prions in the myelin maintenance of central nervous system

Cobalamin (Cbl), epidermal growth factor (EGF), and prions (PrPs) are key molecules for myelin maintenance in the central and peripheral nervous systems. Cbl and EGF increase normal prion (PrP^C) synthesis and PrP^C levels in rat spinal cord (SC) and elsewhere. Cbl deficiency increases PrP^C levels in rat SC and cerebrospinal fluid (CSF), and decreases PrP^C-mRNA levels in rat SC. The administration of anti-octapeptide repeat PrP^C region antibodies (Abs) to Cbl-deficient (Cbl-D) rats prevents SC myelin lesions and a local increase in tumor necrosis factor (TNF)-α levels, whereas anti-TNF-α Abs prevent SC myelin lesions and the increase in SC and CSF PrP^C levels. As it is known that both Cbl and EGF regulate SC PrP^C synthesis independently, and that Cbl regulates SC EGF synthesis, EGF may play both Cbl-independent and Cbl-dependent roles. When Cbl-D rats undergo Cbl replacement therapy, SC PrP^C levels are similar to those observed in Cbl-D rats. In rat frontal cortex (which is marginally affected by Cbl deficiency in histological terms), Cbl deficiency decreases PrP^C levels and the increase induced by Cbl replacement leads to their normalization. Increased nerve PrP^C levels are detected in the myelin lesions of the peripheral neuropathy of Cbl-D rats, and CSF PrP^C levels are also increased in Cbl-D patients (but not in patients with Cbl-unrelated neurological diseases). Various common steps in the downstream signaling pathway of Cbl, EGF, and PrP^C underlines the close relationship between the three molecules in keeping myelin normal.