Splanchnic metabolism of nitrogenous compounds and urinary nitrogen excretion in steers fed alfalfa under conditions of increased absorption of ammonia and L-arginine supply across the portal-drained viscera.

Effects of increased ammonia and/or arginine absorption across the portal-drained viscera (PDV) on net splanchnic (PDV and liver) metabolism of nitrogenous compounds and urinary N excretion were investigated in six catheterized Hereford x Angus steers (501 +/- 1 kg BW) fed a 75% alfalfa:25% (as-fed basis) corn-soybean meal diet (0.523 MJ of ME/[kg BW(0.75).d]) every 2 h without (27.0 g of N/kg of dietary DM) and with 20 g of urea/kg of dietary DM (35.7 g of N/kg of dietary DM) in a split-plot design. Net splanchnic flux measurements were obtained immediately before beginning and ending a 72-h mesenteric vein infusion of L-arginine (15 mmol/h). For 3 d before and during arginine infusion, daily urine voided was measured and analyzed for N composition. Feeding urea increased PDV absorption (P < 0.01) and hepatic removal (P < 0.01) of ammonia N, accounting for 80% of increased hepatic urea N output (P < 0.01). Numerical increases in net hepatic removal of AA N could account for the remaining portion of increased hepatic urea N output. Arginine infusion increased hepatic arginine removal (P < 0.01) and hepatic urea N output (P < 0.03) and switched hepatic ornithine flux from net uptake to net output (P < 0.01), but numerical changes in net hepatic removal of ammonia and AA N could not account fully for the increase in hepatic urea N output. Increases in urine N excretion equaled quantities of N fed as urea or infused as arginine. Estimated salivary urea N excretion was not changed by either treatment. Urea cycle regulation occurs via a complex interaction of mechanisms and requires N sources other than ammonia, but the effect of increased ammonia absorption on hepatic catabolism of individual AA in the present study was not significant.

Splanchnic metabolism of nutrients and hormones in steers fed alfalfa under conditions of increased absorption of ammonia and L-arginine supply across the portal-drained viscera.

Effects of increased ammonia and/or arginine absorption on net splanchnic (portal-drained viscera [PDV] plus liver) metabolism of nonnitrogenous nutrients and hormones in cattle were examined. Six Hereford x Angus steers (501 +/- 1 kg BW) prepared with vascular catheters for measurements of net flux across the splanchnic bed were fed a 75% alfalfa:25% (as-fed basis) corn and soybean meal diet (0.523 MJ of ME/[kg BW(0.75).d]) every 2 h without (27.0 g of N/kg of DM) and with 20 g of urea/kg of DM (35.7 g of N/kg of DM) in a split-plot design. Net flux measurements were made immediately before and after a 72-h mesenteric vein infusion of L-arginine (15 mmol/h). There were no treatment effects on PDV or hepatic O2 consumption. Dietary urea had no effect on splanchnic metabolism of glucose or L-lactate, but arginine infusion decreased net hepatic removal of L-lactate when urea was fed (P < 0.01). Net PDV appearance of n-butyrate was increased by arginine infusion (P < 0.07), and both dietary urea (P < 0.09) and arginine infusion (P < 0.05) increased net hepatic removal of n-butyrate. Dietary urea also increased total splanchnic acetate output (P < 0.06), tended to increase arterial glucagon concentration (P < 0.11), and decreased arterial ST concentration (P < 0.03). Arginine infusion increased arterial concentration (P < 0.07) and net PDV release (P < 0.10) and tended to increase hepatic removal (P < 0.11) of insulin, as well as arterial concentration (P < 0.01) and total splanchnic output (P < 0.01) of glucagon. Despite changes in splanchnic N metabolism, increased ammonia and arginine absorption had little measurable effect on splanchnic metabolism of glucose and other nonnitrogenous components of splanchnic energy metabolism.

The effect of amino acids on the metabolic fate of 15NH4Cl in isolated sheep hepatocytes.

Ruminants characteristically absorb a large proportion of dietary nitrogen across the portal-drained viscera as ammonia nitrogen which is detoxified by conversion to urea in the liver. In theory, ammonia can supply both nitrogen atoms of the urea molecule via mitochondrial (carbamoyl phosphate) and cytoplasmic (aspartate) precursor pathways of the ornithine cycle but the effect of amino acids on the flux of nitrogen from ammonia to each of the two urea nitrogen atoms has not been determined. We report a study designed to determine the distribution of [15N] ammonia between [15N1]urea and [15N2]urea in sheep hepatocytes in response to ammonia concentrations (0.33, 0.67 and 1.00 mM) in the presence or absence of amino acids. In the absence of amino acids, the enrichment of [15N2]urea rose more rapidly during incubations than [15N1]urea and attained enrichments of 66-88% within 5 min of incubation. At the end of 2.5 h of incubation, [15N2]urea represented 60% and 90% of the total urea molecules at low and high ammonia concentrations, respectively. The enrichments of glutamate and aspartate were similar to [15N1]urea in the cells at the end of the incubations, even in the presence of unlabelled amino acids, supporting the concept of mitochondrial ammonia being in equilibrium with cytosolic aspartate formation. In the presence of amino acids basal urea synthesis increased but ammonia uptake and 15NH4Cl conversion to urea was less than in the absence of amino acids. The rate of formation of [15N1]urea was greater in incubations containing amino acids but when ammonia concentration in the media was raised only [15N2]urea flux increased with no change in either [15N1]urea or the unlabelled species. Measurement of media amino acid concentrations after 2.5 h of incubation in the presence of amino acids revealed that arginine, glutamine, glycine and alanine were removed while there was net formation of aspartate, threonine, serine, glutamate, and the branched chain amino acids. However, less than 12% of the 15N transfer appeared in free amino acids. The increases in basal and unlabelled urea synthesis in the presence of amino acids could be numerically accounted as the sum of arginine and glutamine removal from incubations. It is concluded that in sheep hepatocytes 15NH4Cl removal leads to quantitative formation of [15N2]urea, even in the presence of a physiological mixture of amino acids. The increase in the formation of the [15N1]urea in the presence of amino acids can be explained by the preferential utilisation of the amide nitrogen of glutamine for urea synthesis.

Regulation of nutrient partitioning by visceral tissues in ruminants.

Together, tissues of the portal-drained viscera and liver account for 35 to 53% of body oxygen uptake in ruminants, and therefore have a substantial impact on the partition of metabolizable energy between heat loss and production. As proposed more than a century ago, these tissues are principal determinants of heat increment of feeding and increases in heat resulting from increased fiber digestion. The metabolism of these tissues also has a profound impact on the structure and quantity of absorbed nutrients ultimately available for utilization by peripheral tissues. Substantial amounts of absorbed volatile fatty acids and amino acids are oxidized or transformed during their absorption and never reach the portal vein in the form in which they were absorbed. In addition, the liver utilizes large quantities of these nutrients to support glucose, urea and protein synthesis. Ruminants absorb large amounts of ammonia which must be converted to urea by the liver and portal-drained viscera absorption of ammonia and liver urea production are highly correlated with nitrogen intake, but portal-drained viscera absorption of alpha-amino and urea nitrogen is poorly correlated with nitrogen intake. The portal-drained viscera and liver also effect nutrient partitioning by regulating amounts of insulin and glucagon released to peripheral tissues.