Perturbation of methionine metabolism in sheep with nitrous-oxide-induced inactivation of cobalamin

Exposure of sheep to 36% nitrous oxide for 8 days (2-hr per day) led to 90%, 82% and 74% inhibition of 5-methyltetrahydrofolate-homocysteine methyltransferase in the liver, heart and brain, respectively, while there was no significant decrease in the activity of methylmalonyl-CoA mutase. There was also no change of betaine-homocysteine methyltransferase activity. The level of plasma methionine in nitrous-oxide-exposed sheep fell to 30% of its initial value. S-Adenosylmethionine level was reduced to 50% of the control value in the liver, and was also significantly decreased in the heart, but not in the brain. Excretion of formiminoglutamic acid and homocystine was also observed in the urine of sheep exposed to nitrous oxide. These results demonstrate that inhibition of 5-methyltetrahydrofolate-homocysteine methyltransferase causes a pronounced perturbation of methionine metabolism in sheep, suggesting that dietary methionine plus methionine synthesized from the methyl groups of betaine are not sufficient to meet the methyl needs for biological methylation reactions in this species and, in turn, emphasizing the role of 5-methyltetrahydrofolate-homocysteine methyltransferase in methionine synthesis in the sheep.     

Sulfur and methionine metabolism in sheep. II. Quantitative estimates of sulfur metabolism in the sheep's stomach.

The metabolism of dietary and supplemental DL-methionine sulfur in the stomach of sheep was studied in two experiments. In both experiments sheep were fed a 50 : 50 oaten chaff: lucerne chaff ration at two levels of intake, and some animals received intraruminal infusions of DL-methionine. In experiment 2 increasing dry matter intake (DMI) increased first approximations of total, neutral, protein and reducible sulfur flows and also sulfide sulfur flow from the reticulo-rumen. Increased DMI (from 500 to 1000 g/day) also resulted in greater true flows of total (2207 v. 1104 mg/day), neutral (1867 v. 1043 mg/day) and protein (893 v. 482 mg/day) sulfur at the duodenum. Two flow diagrams of sulfur metabolism in the compartments of the ruminant stomach were developed from the data of experiment 2. Fluid flows of sulfur in experiment 1 were used to supplement the data of experiment 2 in developing the balance models. The two models represent the extremes of dietary and supplemental sulfur metabolism in the sheep's stomach under the conditions of experiment 2, and they are discussed in relation to previous research on sulfur metabolism in the stomach.     

Folic acid metabolism in vitamin B12-deficient sheep. Effects of injected methionine on liver constituents associated with folate metabolism

1. The effects of injected l-methionine (2g every second day for 28 days) on liver folates and other constituents of liver associated with folate metabolism were studied in vitamin B(12)-deficient ewes and their pair-fed controls receiving vitamin B(12). The dose rate of methionine used was sufficient to restore almost to normal the elevated excretion in the urine of formiminoglutamate in the deficient animals. 2. Liver folates active for Lactobacillus casei, Streptococcus faecalis R and Pediococcus cerevisiae were severely depressed in deficient livers and were partly restored by methionine. Analysis of the folates after ion-exchange chromatography showed that the major effect of methionine was to increase the concentrations of tetrahydrofolates and formyltetrahydrofolates. Methyltetrahydrofolates were also increased, but there was no effect of methionine on the small amounts of incompletely reduced folates present in deficient livers. The folates present were predominantly penta-, hexa- and hepta-glutamates whether or not animals received vitamin B(12) or methionine. 3. Concentrations of ATP, NAD(+), NADH and NADPH were lower in freeze-clamped liver from vitamin B(12)-deficient sheep than in liver from pair-fed, vitamin B(12)-treated sheep. These changes were not affected by methionine which was also without effect on the elevated K(+)/Na(+) ratios found in deficient livers. 4. The livers of vitamin B(12)-deficient animals contained lower concentrations of choline and higher concentrations of lipid than their pair-fed controls. These effects were reversed by methionine.     

Folic acid metabolism in vitamin B12-deficient sheep. Effects of injected methionine on liver constituents associated with folate metabolism

1. A study was made of the effects of injected l-methionine on the activity of several enzymes of folate metabolism, and on the transport of methotrexate in liver preparations from vitamin B(12)-deficient ewes and their pair-fed controls receiving vitamin B(12). 2. The activities of dihydrofolate reductase (EC 1.5.1.3) and 5-methyltetrahydrofolate-homocysteine transmethylase were significantly decreased in the liver of vitamin B(12)-deficient animals, but were unaffected by l-methionine. 3. The concentration of S-adenosyl-l-methionine in the liver of deficient animals was about one-half of that in normal animals, and was restored to normal by either vitamin B(12) or l-methionine. 4. Methylenetetrahydrofolate reductase (EC 1.1.1.68) from sheep liver was inhibited by S-adenosyl-l-methionine in vitro, but not by concentrations of S-adenosyl-l-methionine found in the liver of vitamin B(12)-deficient animals after injection of physiological amounts of l-methionine. 5. Pteroylpolyglutamate synthetase activity was significantly increased in the liver of vitamin B(12)-deficient animals, and was decreased by intravenous injections of l-methionine. 6. l-Methionine injections increased the initial rate of uptake of methotrexate in liver slices from deficient animals and acted synergistically with vitamin B(12) to increase the quantity taken up in 40min. The failure of folate metabolism in vitamin B(12) deficiency can be satisfactorily explained if l-methionine similarly affects the membrane transport of naturally occurring folates. 7. Further details of the results have been deposited as Supplementary Publication SUP 50028 (4 pages) at the British Library (Lending Division), (formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7BQ, U.K., from whom copies may be obtained on the terms given in Biochem. J. (1973) 131, 5.     

Tissue perfusion in anaesthetised sheep

1. Tissue perfusion was measured in seven sheep by the radioactive microsphere method. 2. The sheep were anaesthetised and ventilated to a near normal arterial carbon dioxide tension. 3. Cardiac output was measured utilizing the Fick principle as applied to thermodilution and at the end of the investigation the sheep were killed by an overdose of anaesthetic. 4. The results were compared with previously published values for conscious sheep and anaesthetised horses and found to be similar when known variations in body composition and physiology were considered.     

Androgen metabolism in sheep

³H-Testosterone (³H-T) plus ¹⁴C-androst-4-ene-3.17-dione (A-dione) and ³H-epi-testosterone (17α-hydroxy-4-androsten-3-one) (epiT) plus ¹⁴C-T were injected intravenously into two male sheep with bile fistulae, respectively. Urine and bile samples were collected at intervals for 4–8 hours and analyzed by the use of DEAE-Sephadex A-25 and Lipidex 5000 columns, TLC, and paper chromatography; the aglycones were identified by co-crystallization with authentic standards.Five fractions were obtained from urine and bile: unconjugated, glucosiduronates, sulfates, sulfo-glucosiduronates and disulfates. In urine, the major conjugates were glucosiduronates, while sulfates predominated in bile. About 80–90% of recovered radioactivity was found to be either glucosiduronates or sulfates. Among the metabolites identified, epi-T was the principal one, accounting for 10–15% of the administered doses. Conversion to 17α-hydroxysteroids thus appears to be a major route of metabolism of the androgens administered in sheep. Other metabolites in the glucosiduronate and sulfate fractions were androsterone, etiocholanolone (3α-hydroxy-5β-androstan-17-one), 5β-androstane-3α, 17β-diol, two unknown diols and polar metabolites. The results indicated that androgen metabolism is somewhat unusual in sheep, as compared with other animals and the human.     

Tissue distribution of bupivacaine enantiomers in sheep

rac-Bupivacaine HCl was infused intravenously to constant arterial blood drug concentrations in sheep using a regimen of 4 mg/min for 15 min followed by 1 mg/min to 24 h. At 24 h, arterial blood was sampled, the animal was killed with a bolus of KCl solution, then rapidly dissected and samples were obtained from heart, brain, lung, kidney, liver, muscle, fat, gut, and rumen. Tissue:blood distribution coefficients for (+)-(R)-bupivacaine exceeded those of (?)-(S)-bupivacaine (P < 0.05) for heart, brain, lung, fat, gut, and rumen by an overall mean of 43%. Blood:plasma distribution coefficients of (?)-(S)-bupivacaine exceeded those of (+)-(R)-bupivacaine by a mean of 29% and this offset the tissue:blood distribution coefficients so that the previously significant enantioselective differences disappeared. It is concluded that although enantioselectivity of bupivacame distribution is shown by the measured tissue:blood distribution coefficients, it is not shown when tissue:plasma water distribution coefficients are calculated, suggesting that there is no intrinsic difference between the bupivacaine enantiomers in tissue affinity. Sheep given fatal intravenous bolus doses of rac-bupivacaine had significantly greater concentrations of (+)-(R)-bupivacaine than (?)-(S)-bupivacaine in brain (P = 0.028) and ventricle (P = 0.036); these could augment the greater myocardial toxicity of this enantiomer found in vitro. © 1993 Wiley-Liss, Inc.     

Methyl group metabolism in sheep

1. Sheep have a very low intake of methyl nutrients in the post-ruminant state, due to the almost complete degradation of dietary choline by rumen microorganisms, the lack of dietary creatine and the relatively low content of methionine in microbial proteins. 2. Methylneogenesis provides a major source of labile methyl groups in post-ruminant sheep and impairment of the methylneogenesis leads to a marked reduction of the labile methyl pool. 3. S-Adenosylmethionine (AdoMet) metabolism via transmethylation is most active in sheep liver and pancreas and is regulated by the availability of methionine and intracellular ratios of AdoMet to S-adenosylhomocysteine (AdoHcy). 4. Adaptive mechanisms which arise as a consequence of the poor methyl nutrition in post-ruminant sheep are a marked reduction of labile methyl catabolism and an increase in the capacity of methylneogenesis.     

Ethanol-induced changes in methionine metabolism in rat liver

The administration of alcohol to rats fed a protein-restricted diet results in significant changes in the hepatic content of four enzymes of methionine metabolism. The levels of s-adenosylmethionine synthetase, cystathionine synthase, and betaine-homocysteine methyltransferase increase while the level of methyltetrahydrofolate-homocysteine methyltransferase decreases. These changes represent a reversal of the normal adaptive response to protein-restriction. The resultant impairment in methionine conservation could explain the alcohol-induced increase in the dietary lipotrope requirement.     

Adaptation of adenosylmethionine metabolism and methionine recycling to variations in dietary methionine in the rat

Weanling rats were fed a casein-based diet supplemented to give dietary methionine (Met) concentrations of 0.41, 0.61, and 1.50%. After 2 weeks of feeding, the rats received intraperitoneally 800 nCi of 2-14C-labeled and/or methyl-3H-labeled L-Met. The animals were killed 20 min, 1 hr, or 2 hr after the isotope injection and the specific radioactivity of adenosylmethionine (AdoMet) as well as the total acid-soluble radioactivity was analyzed in the liver and skeletal muscle. Met concentrations of the liver and skeletal muscle were increased 20-fold by the diet containing 1.50% of Met. In the liver, but not in skeletal muscle, accumulation of AdoMet closely followed changes in Met concentration. Within 2 hr after intraperitoneal injection, the rate of disappearance of 3H label from the acid-soluble fraction was slow in both tissues; increasing in the liver and decreasing in skeletal muscle with increasing dietary Met concentration. At the same time, disappearance of 14C label was slow in both tissues in the rats fed the toxic Met diet, and also in the liver of the rats fed the Met-deficient diet. Decline of the specific radioactivity of the AdoMet pool with respect to 3H label was similar to that of 14C label in the skeletal muscle at all dietary Met concentrations. In the liver, the rate of disappearance of 14C label from the AdoMet pool was markedly increased and that of the 3H label slightly decreased with increasing dietary Met supply. Met deprivation resulted in rapid disappearance of 3H label from the hepatic AdoMet pool, whereas the disappearance of the 14C label was very slow. The results indicate that hepatic Met recycling is very effective with deficient or adequate dietary Met concentrations. In skeletal muscle, the capacity to catabolize extra Met is very limited and continuous flow of Met to liver takes place. Unlike in the liver, in skeletal muscle the transsulfuration route is not adaptable to changes in Met supply and plays a minor role in Met catabolism. The approach used to determine the efficacy and adaptation of methionine salvage pathways by following simultaneously the decline of the specific radioactivities of the methyl group and the methionyl carbon chain of AdoMet following intraperitoneal injection of double-labeled Met has several advantages over that used in literature reports. It offers a reliable means of observing these metabolic pathways in whole animals without disruption of metabolite fluxes.     

Kinetics of glucose metabolism in sheep

The kinetics of glucose cycling in 24 ewes bearing twins were studied 1 month before term by bolus injections of [6-3H]- and [U-14C]glucose. The function representing glucose carbon recycling was determined by deconvolution of the [3H]glucose from the [14C]glucose decay curves in plasma by using the SAAM and CONSAM programs, and a model for kinetics of glucose cycling was developed. The [3H]glucose data were fitted by four compartments, and an additional three compartments were required to explain recycling. The results show that labelled carbon was still recycling to plasma 2 days after the injection of tracer. By contrast, a similar analysis on a non-pregnant sheep, with data taken from the literature, showed that no more material was recycled after 1 day. It appears that a larger fraction (20 v. 5%) of the carbon 6 of glucose recycles in pregnant than in non-pregnant sheep. This presumably reflects the metabolism by the feto-placental unit and the increased rate of glucose metabolism during pregnancy.     

Tyrosine and methionine metabolism in various states of melaninogenesis

Excretion with urine of tyrosine and methionine metabolites as well as the activities of enzymes involved in their metabolism are correlated with the state and type of melanin synthesized in the skin. The response of tyrosine aminotransferase to melaninogenesis induction was more pronounced in animals with predominant pheomelaninogenesis, especially after tyrosine load, while that to dopachrome oxidoreductase--in animals with predominant eumelaninogenesis and after methionine load. Glutathione reductase and cystathionine-beta-synthase responded more vigorously to methionine injections, which was especially well pronounced in animals with prominent pheomelaninogenesis and in albino animals. The metabolic "block" in melanine synthesis in albino animals seems to be observed after the 5-S-cysteinyl-DOPA synthesis, whereas the initial steps of melaninogenesis in these animals are identical to pheomelanine synthesis reactions.     

Chromatographic separation of methionine,methionine sulphoxide,methionine sulphone,and their products of oral microbial metabolism

The metabolic pathways of methionine sulphoxide and methionine sulphone were investigated employing a combination of gas chromatography, thin-layer chromatography, paper chromatography, and radioactive methods of analyses. Gas chromatographic analysis demonstrated that methionine, methionine sulphoxide, and methionine sulphone all yielded qualitatively similar volatile sulphur compounds, namely, methyl mercaptan, dimethyl disulphide, and small amounts of dimethyl sulphide. The study indicated that the principal pathway of methionine sulphoxide and methionine sulphone metabolism is mediated via methionine which gives rise to methyl mercaptan, part of which is oxidized to dimethyl disulphide. Whereas methionine sulphoxide was readily reduced to methionine, the reduction of methionine sulphone proceeded at a considerably slower rate.     

Sulfur and methionine metabolism in sheep. I. First approximations of sulfur pools in and sulfur flows from the reticulo-rumen.

Sulfur pools in the rumen and sulfur flows from the rumen were investigated in two experiments with sheep on a diet containing equal parts of oaten and lucerne chaffs. The diet was fed at two levels, either chopped or pelleted, and with intraruminal DL-methionine supplements. Ruminal fluid volumes and fluid flows to the omasum were measured. None of the treatments influenced ruminal fluid volume. Fluid flow to the omasum, however, was increased by increasing dry matter intake (DMI), and was further enhanced by feeding chaffed hay rather than the same materials ground and pelleted; the DL-methionine supplement had no effect. First approximation of the ruminal sulfur pools and of sulfur flows to the omasum were derived from the concentration of sulfur in true digesta and the ruminal fluid volume or fluid flow. Increasing DMI from 500 to 1000 g/day resulted in larger ruminal pools of total (1096 v. 792 mg), neutral (1016 v. 731 mg) and protein (479 v. 419 mg) sulfur, but the reducible sulfur pools were not affected by the level of DMI. Infusions of DL-methionine increased the ruminal sulfide sulfur pool irrespective of level of DMI. The first approximation of total sulfur flow was increased by 1660 mg/day at the higher level of DMI, due mainly to increases of 710 mg S/day as protein sulfur and 859 mg S/day as non-protein neutral sulfur. Flows of inorganic sulfate and ester sulfate sulfur, although small in comparison with organic sulfur flows, increased with level of DMI. Sulfide sulfur flows were also increased at the higher level of DMI, and were almost doubled by intraruminal infusions of DL-methionine.     

Comparative studies on the methionine synthesis in sheep and rat tissues

The important features of the enzymes involved in methionine synthesis in sheep were found to be the low activity of betaine-homocysteine methyltransferase and the high activity of 5-methyltetrahydrofolate-homocysteine methyltransferase. The rate of the methionine synthesis in sheep liver was significantly lower than that in rats due to the low activity of hepatic betaine-homocysteine methyltransferase. The hepatic methionine recycling was stimulated by the addition of betaine in both species. These results indicate that in sheep 5-methyltetrahydrofolate-homocysteine methyltransferase plays a significant role in hepatic methionine synthesis along with betaine-homocysteine methyltransferase. In contrast, in the rat hepatic system methionine synthesis is virtually dependent on betaine-homocysteine methyltransferase.     

Kinetics of ethanol metabolism in sheep.

Kinetic aspects of ethanol metabolism were studied in sheep after intravenous or intraruminal infusion of ethanol. Vmax and Km in fed animals were respectively 295 +/- 10 mg.h-1.l-1 (l = litre of body water) and 32.1 +/- 2.4 mg.l-1. Elimination half-life was 1.47 +/- 0.26 h. The corresponding values in the fasted animal were not significantly different. During venous infusion an increase in plasma acetate, inversely correlated to plasma ethanol, was observed. No modification in glycemia occurred. Intraruminal infusion of ethanol increased the concentration of all SCFA in the rumen juice, the largest part of this modification being relative to acetate. Repetition of the infusion over a period of 11 consecutive days increased the number of SCFA in the rumen, indicating microflora adaptation to ethanol utilization. Taking into account the range of ethanol concentrations found in silage (10-50 g.kg-1 BW) we can consider that ethanol is readily metabolized simultaneously by the rumen microflora and the enzymatic system of the host. With a corresponding daily intake of ethanol (0.2-1 g.kg-1 BW) both systems are not saturated and plasma ethanol level always remains below 0.25 g.l-1.