An isotope dilution model for partitioning of phenylalanine and tyrosine uptake by the liver of lactating dairy cows.

An isotope dilution model to describe the partitioning of phenylalanine and tyrosine in the bovine liver was developed. The model comprises four intracellular and six extracellular pools and various flows connecting these pools and external blood. Conservation of mass principles were applied to generate the fundamental equations describing the behaviour of the system in the steady state. The model was applied to datasets from multi-catheterised dairy cattle during a constant infusion of [1-13C]phenylalanine and [2,3,5,6-2H]tyrosine tracers. Model solutions described the extraction of phenylalanine and tyrosine from the liver via the portal vein and hepatic artery. In addition, the exchange of free phenylalanine and tyrosine between extracellular and intracellular pools was explained and the hydroxylation of phenylalanine to tyrosine was estimated. The model was effective in providing information about the fates of phenylalanine and tyrosine in the liver and could be used as part of a more complex system describing amino acid metabolism in the whole animal.

Gluconeogenesis, non-essential amino acid synthesis and substrate partitioning in chicken embryos during later development.

We aimed to quantify the rate of gluconeogenesis (GNG), non-essential amino-acid (NEAA) synthesis, and substrate partitioning to the Krebs cycle in embryonic (e) day e14 and e19 chicken embryos. An in ovo continuous tracer infusion approach was employed to test the hypotheses that GNG and NEAA synthesis in developing chicken embryo increases from e14 to e19. [13C6]Glucose or [13C3]glycerol was continuously infused (8 h) into the chorio-allantoic compartment of eggs on e14 and e19. Glucose entry rate, Cori cycling, and GNG were higher (P < 0.05) in e19 compared to e14 embryos, presumably to support higher glycogen deposition in liver and muscle. Whereas de novo synthesis of alanine, aspartate, and glutamate via glycolysis and the Krebs cycle was higher (P < 0.01) in e14 embryos, synthesis of these NEAA from glycerol was higher (P < 0.05) in e19 compared to e14 embryos. These patterns of glucose and glycerol utilization suggest a metabolic shift to conserve glucose for glycogen synthesis and an increased utilization of yolk glycerol (from triacylglyceride) after e14. Although the contribution of glycerol to GNG in e19 embryos was higher (P < 0.05) than that in e14 embryos, the contribution of glycerol to GNG (1.3 to 6.0%) was minor. Based on [13C6]glucose tracer kinetics, the activities of both pyruvate carboxylase (PC) and pyruvate dehydrogenase (PDH) in the liver were higher (P < 0.05) in e19 embryos; whereas the higher (P < 0.01) relative activity of liver PC compared to PDH in e14 embryos suggests a greater anaplerotic flux into the Krebs cycle. In summary, the in ovo continuous tracer infusion approach allowed for a measurement of chicken embryo whole body and liver metabolism over a shorter window of development. This study provided quantitative estimates of the developmental shifts in substrate utilization, GNG, and NEAA synthesis by chicken embryos, as well as qualitative estimates of the activities of enzymes central to the Krebs cycle, glucose, and fatty acid metabolism.

Short communication: Amino acid supplementation and stage of lactation alter apparent utilization of nutrients by blood neutrophils from lactating dairy cows in vitro.

Glutamine is the preferred AA used by polymorphonuclear leukocytes (PMN) during the inflammatory response. However, the effect of other AA on bovine PMN response during inflammation and how this is altered by stage of lactation has not been fully elucidated. The objective of this study was to determine the effect of additional AA supplementation (pool of AA excluding Gln) on AA profiles, gene expression, and inflammatory function of PMN from dairy cows in early and mid lactation in vitro. We used 18 Holstein cows for this study. Polymorphonuclear leukocytes were isolated. Working solutions of AA (0 or 4 mM) and LPS (0 or 50µg/mL) were added to cell populations suspended in RPMI and incubated for 2h at 37°C. We used a subset of samples for gene and protein expression. Concentrations of AA in medium were determined using gas chromatography-mass spectrometry with norleucine as an internal standard. Apparent AA and glucose utilization were calculated by subtracting the concentration after from that of before incubation. Data were analyzed as a randomized block design. Challenge with LPS increased the expression of proinflammatory genes and AA supplementation decreased both the expression of some proinflammatory genes and the media concentrations of tumor necrosis factor-α. Neither stage of lactation, LPS challenge, nor AA supplementation altered the chemotactic or phagocytic abilities of PMN in vitro. Polymorphonuclear leukocytes supplemented with AA had greater concentrations and apparent utilization of most of the supplemented AA, whereas the unsupplemented group had greater apparent utilization of glucose. Alanine was not provided in the media but was present in spent media, and Ile, Gly, and Pro were greater in spent media than in media before incubation indicating synthesis of these AA. Regarding expression of genes involved in nutrient metabolism, the expression of G6PD, coding for the enzyme glucose 6-phosphate dehydrogenase, was increased and that of PDHA1, coding for the enzyme pyruvate dehydrogenase α 1, tended to increase with AA supplementation. Due to the lower concentration of tumor necrosis factor-α in media coupled with a downregulation of several proinflammatory genes, we concluded that AA, rather than Gln, alter the inflammatory response of bovine blood PMN. Independent from Gln, blood PMN from cows in early lactation may use certain AA as their primary carbon source for energy than cows in later lactation. Evaluating cows during the early postpartum period will provide additional information on the effect of stage of lactation and nutrient supplementation on PMN function.

Propionate supplementation improves nitrogen use by reducing urea flux in sheep.

Feeding and postruminal infusion of propionate is known to increase N retention in ruminants. Our aim was to determine the role of rumen propionate on urea N recycling and gluconeogenesis in growing sheep. In Exp. 1, wether sheep ( = 6; 32.5 ± 3.57 kg BW) fitted with a rumen cannula were fed to 1.8 × ME requirement a concentrate-type ration (172 g CP/kg DM and 10.4 MJ ME/kg DM) and continuously infused into the rumen with isoenergetic (10% of dietary ME intake) solutions of either sodium acetate (control) or sodium propionate for 9-d periods in a crossover design. In Exp. 2, a different group of wether sheep ( = 5; 33.6 ± 3.70 kg BW) fitted with a rumen cannula were fed, on an isonitrogenous basis, either a control (151 g CP/kg DM and 8.4 MJ ME/kg DM) or sodium propionate-supplemented (139 g CP/kg DM and 8.9 MJ ME/kg DM) diet at 2-h intervals. [N] urea was continuously infused intravenously for the last 5 d of each period, and total urine was collected by vacuum and feces were collected by a harness bag. Over the last 12 h, [C]glucose was continuously infused intravenously and hourly blood samples were collected during the last 5 h. Propionate treatments increased ( < 0.001) the proportion of rumen propionate in both experiments. In Exp. 1, N retention was not affected by propionate infusion as compared with isoenergetic acetate. There was no effect on urea entry (synthesis) rate (UER) in Exp. 1; however, sodium propionate infusion tended ( < 0.1) to increase urinary urea elimination (UUE). In Exp. 2, feeding propionate increased ( < 0.01) N retention by 0.8 g N/d. In addition, UER was reduced by approximately 2 g urea N/d, leading to a reduction ( < 0.05) in UUE (7.0 vs. 6.2 g urea N/d). Between the 2 experiments, the proportion of UER recycled to the gut was greater with the forage-type diet in Exp. 2 (approximately 60%) compared with the concentrate-type diet in Exp. 1 (approximately 40%), although urea N fluxes across the gut remained unchanged in both experiments. In Exp. 1, glucose entry and gluconeogenesis were greater ( < 0.05) and plasma glucose tended ( < 0.1) to be greater with sodium propionate infusion than with sodium acetate infusion, but there was no difference in Cori cycling. In Exp. 2, glucose entry, gluconeogenesis, Cori cycling, and plasma glucose increased ( < 0.05) with dietary propionate. Our studies indicate that propionate inclusion in feed, but not continuous infusion in to the rumen, improves N utilization in growing sheep. The propionate effect is likely mediated by providing additional precursors for gluconeogenesis.

Hepatic metabolic response of Holstein cows in early and mid lactation is altered by nutrient supply and lipopolysaccharide in vitro.

The metabolic response of the liver during periods of inflammation is poorly understood. The objective of this study was to characterize the effects of nutrient supply and lipopolysaccharide (LPS) challenge on hepatic intermediate metabolism of early- and mid-lactation cows by employing gas chromatography-mass spectrometry with stable isotope tracer. Twelve multiparous Holstein-Friesian cows in early (n = 6; 12 ± 4.2 d in milk) and mid (n = 6; 115 ± 13.5 d in milk) lactation were used for this study. Liver biopsies were performed on all cows. Liver slices (40-60 mg) were incubated in a 37°C water bath for 2 h with either control (phosphate buffered saline), pyruvate (PYR; 1mM unlabeled pyruvate and 1mM [(13)C3]pyruvate), pyruvate + propionate (PYR+PRO; 1mM unlabeled pyruvate, 1mM [(13)C3]pyruvate, and 2mM sodium propionate), or pyruvate + AA (PYR+AA; 1mM unlabeled pyruvate, 1mM [(13)C3]pyruvate, and 2mM AA solution), and LPS (0.0 or 0.2 µg/mL) was added to flasks per treatment. Enrichment of isotopomers in metabolic equilibrium with Krebs cycle intermediates was assessed. Pyruvate fluxes and the enzymatic activity of pyruvate carboxylase (PC) versus pyruvate dehydrogenase (PDH) and phosphoenol pyruvate carboxykinase (PEPCK) were calculated. Media were analyzed for concentrations of tumor necrosis factor-α (TNF-α), glucose, and haptoglobin. Data were analyzed as randomized block (stage of lactation) design in a factorial arrangement of nutrient treatments by LPS dose. Challenge with LPS increased the mRNA abundance of TNF-α, haptoglobin, and serum amyloid A 2, and the concentration of TNF-α in media. Challenge with LPS increased mRNA abundance of PC but reduced the enrichment of (13)C1[M1] and (13)C2[M2]alanine and tended to reduce the enzymatic activity of PEPCK. Incubation with PYR+PRO and PYR+AA increased the flux of pyruvate to acetyl CoA. However, only PYR+PRO increased the enzymatic activity of PEPCK and PDH versus PC and decreased the mRNA abundance of PC. Cows in early lactation tended to receive a greater contribution of pyruvate to the oxaloacetate flux via the lower PDH versus PC activity and a higher mRNA abundance of PC than cows in mid lactation. Our results suggest that regardless of stage of lactation and nutrient supplement, hepatic gluconeogenesis was impaired during inflammation. Further research examining how various nutrients support liver function and improve the immunometabolic response of liver during inflammation is warranted.

Role of rumen butyrate in regulation of nitrogen utilization and urea nitrogen kinetics in growing sheep.

Butyrate, a major rumen VFA, has been indirectly linked to enhancement of urea recycling on the basis of increased expression of urea transporter in the rumen epithelia of steers fed a rumen butyrate-enhancing diet. Two studies were conducted to quantify the effect of elevated rumen butyrate concentrations on N balance, urea kinetics and rumen epithelial proliferation. Wether sheep (n= 4), fitted with a rumen cannula, were fed a pelleted ration (∼165 g CP/kg DM, 10.3 MJ ME/kg DM) at 1.8 × ME requirement. In Exp. 1, sheep were infused intraruminally with either an electrolyte buffer solution (Con-Buf) or butyrate dissolved in the buffer solution (But-Buf) during 8-d periods in a balanced crossover design. In Exp. 2, sheep were infused intraruminally with either sodium acetate (Na-Ac) or sodium butyrate (Na-But) for 9 d. All solutions were adjusted to pH 6.8 and 8.0 in Exp. 1 and 2, respectively, and VFA were infused at 10% of ME intake. [15N2] urea was continuously infused intravenously for the last 5 d of each period, and total urine and feces were collected. In Exp. 1, 2H5-phenylalanine was continuously infused intravenously over the last 12 h, after which a biopsy from the rumen papillae was taken for measurement of fractional protein synthesis rate (FSR). Butyrate infusion treatments increased (P = 0.1 in Exp. 1; P < 0.05 in Exp. 2) the proportion of rumen butyrate, and acetate infusion increased (P < 0.05) rumen acetate. All animals were in positive N balance (4.2 g N/d in Exp. 1; 7.0 g N/d in Exp. 2), but no difference in N retention was observed between treatments. In Exp. 2, urea entry (synthesis) rate was reduced ( < 0.05) by Na-But compared with the Na-Ac control. In Exp. 1, although But-Buf infusion increased the FSR of rumen papillae (35.3% ± 1.08%/d vs. 28.7% ± 1.08%/d; P < 0.05), urea kinetics were not altered by But-Buf compared with Con-Buf. These studies are the first to directly assess the role of butyrate in urea recycling and its effects on rumen papillae protein turnover in growing lambs. Under the feeding conditions used and the rate of continuous butyrate infusion into the rumen in the present studies, butyrate does not affect overall N retention in growing sheep. However, butyrate may play a role in the redistribution of urea N fluxes in the overall scheme of N metabolism.

Assessing the ruminal action of the isopropyl ester of 2-hydroxy-4-(methylthio) butanoic acid in continuous and batch cultures of mixed ruminal microbes.

In dairy rations, Met is often a limiting amino acid that is provided by rumen-undegradable protein and rumen-protected sources of Met. A Met precursor, 2-hydroxy-4-(methylthio) butanoic acid (HMB) has undergone considerable study for ruminal and postruminal metabolism, whereas its isopropyl ester (HMBi) has been evaluated primarily with respect to its supply of metabolizable Met rather than as a preformed source of Met for microbial metabolism. A control and 3 isomolar Met treatments-0.097% dl-Met, 0.048% dl-Met plus 0.055% HMBi (Met + HMBi treatment), and 0.11% HMBi-were pulse-dosed every 8h into continuous cultures simultaneously with feeding. Treatment had no effect on digestibilities of acid-detergent fiber or true organic matter. Digestibilities of neutral detergent fiber and hemicellulose were linearly decreased with increasing HMBi inclusion. Concentration of NH3-N tended to decrease linearly and quadratically, and NH3-N flow tended to decrease linearly, with increasing HMBi inclusion; in contrast, the proportion of bacterial N derived from NH3-N increased linearly. Peptide N increased linearly and tended to be affected quadratically (highest for the HMBi treatment). Acetate and propionate production both decreased with increasing HMBi, but acetate declined more such that acetate:propionate increased linearly. Isobutyrate production decreased, but isovalerate and valerate increased with increasing HMBi inclusion. Relative changes in population abundance were not detected by denaturing gradient gel electrophoresis. In the second study, which was done in batch culture, Met treatments consisted of control, 0.097% l-Met, 0.097% l-Met, 0.125% dl-HMBi, 0.098% dl-HMB, 0.250% dl-HMBi (2× HMBi), 0.049% dl-Met + 0.063% dl-HMBi (Met + HMBi), and 0.098% dl-HMB + 0.039% isopropanol. All of these Met treatments were unlabeled (i.e., at natural abundance of (13)C) but simultaneously dosed with equivalent dosages of [1-(13)C]-l-Met. All 8 treatments were inoculated with faunated or partially defaunated inocula. Protozoal abundance had minor effect on measurements. The unlabeled l-Met treatment had the lowest (13)C enrichment of Met in the microbial pellet followed by Met + HMBi and then d-Met or dl-HMB, which were lower than remaining treatments. The percentage of the [1-(13)C]-l-Met dose recovered in microbial Met was lowest for the l-Met treatment; intermediate for d-Met, dl-HMB (with or without isopropanol), and Met + HMBi treatments; and highest for HMBi, 2× HMBi, and control. Results suggest that racemization of d-Met lags behind l-Met. The similar conversions of the HMBi and 2× HMBi treatments compared with the control suggests a low degradation of HMBi to provide unlabeled Met to dilute the [1-(13)C]-l-Met dose for protein synthesis. The lack of treatment by time interaction suggests that these initial responses carried through during the 24h of incubation. The proportion of HMBi available to ruminal microbes can influence microbial metabolism, potentially through formation of l-Met.

Kinetics of microbial methionine metabolism in continuous cultures administered different methionine sources.

The Met precursor 2-hydroxy-4-(methylthio) butanoic acid (HMB) is expected to be more extensively degraded in the rumen than its isopropyl ester (HMBi). A control and 3 isomolar treatments-0.097% dl-methionine, 0.11% HMBi (HMBi), and 0.055% HMBi plus 0.048% Met (Met + HMBi)-were dosed every 8h simultaneously with 3-times-daily feeding into continuous cultures. Starting on d 9, for 6 consecutive doses, both [1-(13)C]-l-Met and [methyl-(2)H3]-l-Met replaced part of the unlabeled dl-Met, [(13)C5]-dl-HMBi replaced a portion of the unlabeled dl-HMBi, and [1-(13)C]-l-Met plus [(13)C5]-dl-HMBi replaced a portion of the respective unlabeled doses for the Met + HMBi treatment. After the sixth dose (d 11), unlabeled Met or HMBi provided 100% of the doses to follow elimination kinetics of the labels in HMBi, free Met, and bacterial Met compartments. The free [1-(13)C]-l-Met recycled more and was recovered in bacterial Met to a lesser extent than was the free [methyl-(2)H3]-l-Met recycling and that was recovered in bacterial Met. Increasing HMBi inclusion (0, 50, and 100% substitution of the exogenously dosed Met on a molar equivalent basis) tended to increase HMBi escape from 54.7 to 71.3% for the 50 and 100% HMBi treatments, respectively. Despite HMBi substituting for and decreasing the dosage of Met, increasing HMBi increased accumulation of free Met in fermenter fluid. The HMBi (after de-esterification of the isopropyl group) presumably produces Met through the intermediate α-ketomethylthyiobutyrate with an aminotransferase that also has high affinity for branched-chain AA. We provide evidence that the HMBi-derived Met is likely released from bacterial cells and accumulates rather than being degraded, potentially as a result of lagging d-stereoisomer metabolism. More research is needed to evaluate racemization and metabolism of stereoisomers of HMBi, Met, and other AA in ruminal microbes.

An isotope dilution model for partitioning phenylalanine and tyrosine uptake by the mammary gland of lactating dairy cows.

An isotope dilution model for partitioning phenylalanine and tyrosine uptake by the mammary gland of the lactating dairy cow is constructed and solved in the steady state. The model contains four intracellular and four extracellular pools and conservation of mass principles are applied to generate the fundamental equations describing the behaviour of the system. The experimental measurements required for model solution are milk secretion and plasma flow rate across the gland in combination with phenylalanine and tyrosine concentrations and plateau isotopic enrichments in arterial and venous plasma and free and protein bound milk during a constant infusion of [1-(13)C]phenylalanine and [2,3,5,6-(2)H]tyrosine tracer. If assumptions are made, model solution enables determination of steady state flows for phenylalanine and tyrosine inflow to the gland, outflow from it and bypass, and flows representing the synthesis and degradation of constitutive protein and phenylalanine hydroxylation. The model is effective in providing information about the fates of phenylalanine and tyrosine in the mammary gland and could be used as part of a more complex system describing amino acid metabolism in the whole ruminant.

Energy sensing in developing chicken embryos and posthatch chicks from different size eggs.

We hypothesized that 5'-adenosine monophosphate-activated protein kinase (AMPK), a ubiquitous energy sensor, plays a key role in coordinating nutrient use in developing broiler breeder embryos. To test this hypothesis, we measured AMPK activity in the liver of embryos developing in small versus large (typical) eggs. Small (53.2 ± 1.0 g) eggs from 26-wk-old and large (69.0 ± 1.9 g) eggs from 42-wk-old broiler breeder hens were acquired and measurements were made on embryonic day (e) 11, 14, 17, and 20, and on posthatch d 1. The initial weight of dry yolk to albumen was higher (2.3 vs. 1.7) in large versus small eggs, and embryo weight differed from e17 onward. The AMPK activity was higher in livers of embryos from large versus small eggs across all sampling days, and activity was highest on e14 for both sizes of eggs. We speculate that higher AMPK activity in livers of embryos from large eggs may facilitate increased metabolism of their larger nutrient supplies to support faster growth rate in ovo. Taken together, our results are the first to investigate the relationship between liver AMPK activity and egg size and nutrient composition in developing chicken embryos.

Protein and energy intakes affected amino acid concentrations in plasma, muscle, and liver, and cell signaling in the liver of growing dairy calves.

The nutrient content of and feeding recommendations for milk replacers (MR) vary widely in North America, and acceleration of growth through manipulation of protein and energy intakes can reduce rearing costs of dairy operations. The effects of varying the protein and energy intake of MR on metabolite concentrations in plasma, liver, and muscle and the phosphorylation activity of protein kinase B (AKT) and ribosomal protein S6 (rpS6) cell signals in liver and muscle were assessed. Twenty-four newborn Holstein calves were fed 1 of 4 MR for 9 wk (n=6/treatment): (1) a 20% crude protein (CP), 20% fat MR fed at 441 g of dry matter (DM)/d (CON); (2) a high-protein, medium-fat MR (HPMF; 28% CP, 20% fat) fed at 951 g of DM/d; (3) a high-protein, high-fat MR (HPHF; 27% CP, 28% fat) fed at 951 g of DM/d; and (4) HPHF fed at 1,431 g of DM/d (HPHF+). Water and starter (20% CP, 1.43% fat) were offered ad libitum and calves were fed MR twice daily. Plasma samples were obtained at 1, 5, and 9 wk of age. Calves were not weaned and were slaughtered after the last blood sampling. Liver and muscle tissues were collected and analyzed for metabolite concentrations and cell signaling activity. Calves fed all treatments had lower plasma concentrations of Phe and Tyr, and a trend for lower Leu, but greater concentrations of Thr relative to calves fed CON. Calves fed all treatments had increased muscle concentrations of Met and muscle to plasma ratios of Phe, Tyr, and branched-chain amino acids compared with CON. All treatments increased liver to plasma ratios of Phe and Tyr but diminished the ratios of Met compared with CON. Phosphorylation of protein kinase B was not affected by treatment; however, relative to calves fed HPHF, HPMF and HPHF+ diets increased phosphorylation ratios of ribosomal protein S6 in the liver. Therefore, the changes in plasma and tissue concentrations and plasma to tissue ratios of amino acids were associated with enhanced growth rates. However, cell signaling activity was not consistent with accelerated growth in calves fed treatments with increased contents of energy and protein possibly due to confounding effects of diet (MR + starter) or fasting before tissue harvesting. Muscle concentrations of Met might have a regulatory role in protein synthesis in rapidly growing calves fed high levels of CP and energy.

Glycerol is a major substrate for glucose, glycogen, and nonessential amino acid synthesis in late-term chicken embryos.

The objective was to determine the contributions of glucose to glycogen synthesis and glycerol to glycogen, glucose, and nonessential AA (NEAA) synthesis on embryonic day (e) 14/15 and e19/20. Chicken embryos from small (56.6 ± 0.88 g) and large eggs (71.7 ± 1.09 g) were repeatedly dosed with either [(13)C(3)]glycerol (14 mg/d for 4 d) or [(13)C(6)]glucose (15 mg/d for 3 d) into the chorio-allantoic fluid before blood and tissue collection. (13)C-Mass isotopomer enrichments in blood glucose, liver, and muscle glycogen, and blood and tissue NEAA were analyzed by mass spectrometry. Glucose metabolism did not differ between small- and large-egg embryos. Although glucose entry was 60% less for e20 compared with e15 embryos, e20 embryos conserved glucose more efficiently as a result of 2- to 3-fold greater (P < 0.001) rates of glucose carbon recycling. Importantly, the direct contribution of glucose to liver glycogen synthesis was minimal on e15, and on e20 direct incorporation of glucose into liver glycogen was only 17%. By comparison, [(13)C(3)]glycerol dosing led to the appearance of [M + 1], [M + 2], and [M + 3] isotopomers in blood glucose and in liver and muscle glycogen on e14 and e19. Here, the (13)C-isotopomer enrichments in blood glucose were ~2-fold greater (P < 0.05) in small- than in large-egg embryos on e14 and e19. Furthermore, [(13)C(3)]glycerol dosing led to substantial labeling of [M + 1], [M + 2], and [M + 3] isotopomers of alanine, aspartate, and glutamate in blood and in tissues where (13)C enrichments were greater (P < 0.05) in liver of small-egg embryos. In summary, this study provides unequivocal evidence that glycerol is a precursor for glucose and NEAA synthesis. Furthermore, glycerol, but not egg-derived glucose, is a major substrate for synthesis of liver and muscle glycogen and is an important anaplerotic substrate for the tricarboxylic acid cycle of embryos during later development.

Regulation of protein synthesis in mammary glands of lactating dairy cows by starch and amino acids.

The objective of this study was to evaluate local molecular adaptations proposed to regulate protein synthesis in the mammary glands. It was hypothesized that AA and energy-yielding substrates independently regulate AA metabolism and protein synthesis in mammary glands by a combination of systemic and local mechanisms. Six primiparous mid-lactation Holstein cows with ruminal cannulas were randomly assigned to 4 treatment sequences in a replicated incomplete 4 x 4 Latin square design experiment. Treatments were abomasal infusions of casein and starch in a 2 x 2 factorial arrangement. All animals received the same basal diet (17.6% crude protein and 6.61 MJ of net energy for lactation/kg of DM) throughout the study. Cows were restricted to 70% of ad libitum intake and abomasally infused for 36 h with water, casein (0.86 kg/d), starch (2 kg/d), or a combination (2 kg/d starch+0.86 kg/d casein) using peristaltic pumps. Milk yields and composition were assessed throughout the study. Arterial and venous plasma samples were collected every 20 min during the last 8h of infusion to assess mammary uptake. Mammary biopsy samples were collected at the end of each infusion and assessed for the phosphorylation state of selected intracellular signaling molecules that regulate protein synthesis. Animals infused with casein had increased arterial concentrations of AA, increased mammary extraction of AA from plasma, either no change or a trend for reduced mammary AA clearance rates, and no change in milk protein yield. Animals infused with starch had increased milk and milk protein yields, increased mammary plasma flow, reduced arterial concentrations of AA, and increased mammary clearance rates and net uptake of some AA. Infusions of starch increased plasma concentrations of glucose, insulin, and insulin-like growth factor-I. Starch infusions increased phosphorylation of ribosomal protein S6 and endothelial nitric oxide synthase, consistent with changes in milk protein yields and plasma flow, respectively. Phosphorylation of the mammalian target of rapamycin was increased in response to starch only when casein was also infused. Thus, cell signaling molecules involved in the regulation of protein synthesis differentially responded to these nutritional stimuli. The hypothesized independent effects of casein and starch on animal metabolism and cell signaling were not observed, presumably because of the lack of a milk protein response to infused casein.

Dietary nitrogen-to-energy ratio alters amino acid partition in the whole body and among the splanchnic tissues of growing rams.

The aim of this study was to determine whether subtle changes in the energy-to-N ratio of medium-concentrate diets alters hepatic export protein synthesis and the partition of protein metabolism in the whole body of growing rams. Rams (n = 6; 41.5 +/- 2.6 kg of BW) were fitted with catheters for measurement of Leu and Phe tracer kinetics across the portal drained-viscera (PDV) and liver. Rams were assigned to receive 3 dietary treatments according to a duplicated Latin square design. Animals received forage-concentrate-based diets that were balanced for ME and available N (CON), 20% imbalanced (reduced) in available N (LN), or 20% imbalanced in ME (LE). After 15 d on each experimental diet, [ring-(2)H(5)]Phe (4.3 micromolxkg(-1)xh(-1)) and [1-(13)C]Leu (8.6 micromolxkg(-1)xh(-1)) were continuously infused into the vena cava for 10 h and, over the last 7 h of infusion, matched sets of blood samples were taken. Daily BW gain was less (P < 0.05) for the LE (0.191 kgxd(-1)) diet compared with CON (0.265 kg/d) and LN (258 kgxd(-1)) diets. Compared with CON, whole body irreversible loss rate (ILR) of Leu and Phe was less (10 to 16%, P < 0.02) for LN and LE diets, which for Leu reflected its decreased (20 to 24%, P < 0.05) net PDV absorption. The decreased whole body ILR is due to a decreased PDV ILR in both diets with a relative contribution of the PDV to the whole body ILR decreased (P < 0.05) in the LN (27%) diet compared with the CON (36%) and LE (33%) diets. This decreased PDV ILR was associated with a decreased net Leu PDV uptake in LN and LE diets (-25 and -20%, respectively; P < 0.05). Conversely, the decreased whole body Phe ILR is explained by a decreased hepatic ILR (and contribution to the whole body ILR) and was associated with a decreased net hepatic uptake of Phe in LN (-25%) and LE (-20%) diets compared with CON (P = 0.03). The fractional and absolute synthesis rates of total proteins and albumin were decreased by 10% in LE animals (P < 0.05), whereas they were not affected by the LN diet. These results suggest a specific decreased utilization of Leu at the PDV due to a specific sparing mechanism in the LN diet. Conversely, a decreased Phe utilization occurred in the liver in both diets (due to a decreased export protein synthesis and a probable decreased oxidation in LE diet, whereas only oxidation is reduced in LN diet).

The frequency of unilateral milking alters leucine metabolism and amino acid removal by the mammary gland of lactating goats.

The objective of this study was to test whether mammary AA metabolism and blood flow (BF) fluctuate in relation to changes in milk protein yield brought about by unilateral milking frequency. To investigate these relationships, the vascular systems of the mammary glands of 4 lactating goats were separated by ligation and flow probes were fitted around the external pudic artery of each gland. Goats were subjected to 3 consecutive periods (5 d each) during which 1) both glands were milked twice daily (2x; period 1); 2) glands were unilaterally milked, with gland A milked 8 times daily and gland B milked incompletely (30% of period 1 milk yield retained in the gland) once daily (8x vs. 1x; period 2); and 3) both glands milked twice daily (2x; period 3). On d 5 of periods 1 (2x) and 2 (8x vs. 1x), arteriovenous [1-(13)C]Leu kinetics were monitored for each gland. Milk protein yield was greater for gland A compared with gland B. After 2x milking resumed in period 3, yields for both glands returned to period 1 levels. Similarly, BF increased (19%) for gland A (8x), whereas BF was decreased (21%) for gland B (1x). For both glands, BF returned to previous levels when 2x milking resumed in period 3. Mammary net uptakes and oxidation of Leu were greater for the gland milked 8x compared with that milked 1x. Net uptakes from blood of Ile, Leu, Val, Lys, Pro, and Arg were greater (39-79%) for the 8x compared with the 1x gland. In conclusion, the excess removal and oxidation by the mammary gland of some amino acids appears an obligatory requirement to support increases or decreases in milk protein yield when milking frequency is altered.

Gluconeogenesis differs in developing chick embryos derived from small compared with typical size broiler breeder eggs.

We hypothesized that, as the supply of preformed glucose diminishes during development, the embryo would transition to a greater rate of gluconeogenesis (GNG) and that GNG would be greater in embryos from small vs. typical size eggs. Gluconeogenesis by embryos from small (51.1 +/- 3.46 g) and typical size (65 +/- 4.35 g) broiler breeder eggs was measured by dosing [(13)C(6)]glucose (15 mgxegg(-1)) into the chorio-allantoic fluid for 3 consecutive days to achieve isotopic steady-state before blood collection on embryonic day (e) 12, e14, e16, and e18 (4 to 5 eggsxsize(-1)xd(-1)). The (13)C-Mass isotopomer enrichment of blood glucose was determined by gas chromatography-mass spectrometry. On e14, e16, and e18, but not on e12, embryos from small eggs weighed less (P < 0.05) than typical size eggs. For both sizes of eggs, blood glucose concentration, glucose entry rate (g.d(-1)), and Cori cycling and glucose (13)C-recycling (% of entry rate) increased (P < 0.05) with development. On e12 and e14, rates of glucose entry and Cori cycle flux were greater (P < 0.05) for embryos from small eggs. When standardized to BW (g.100 g of BW(-1)xd(-1)), glucose entry and Cori and non-Cori cycle fluxes were greater for embryos from small eggs. From e12 through e18, blood concentrations of gluconeogenic AA (threonine, glutamine, arginine, proline, isoleucine, and valine) were 25 to 48% less (P < 0.01) in embryos from small eggs. In conclusion, embryos from small eggs exhibit greater rates of GNG earlier in development compared with typical size eggs and, perhaps as a consequence, their reduced embryonic growth may result from diverting greater supplies of AA toward GNG.

Determination of milk and blood concentrations of lipopolysaccharide-binding protein in cows with naturally acquired subclinical and clinical mastitis.

Blood and milk concentrations of the acute phase protein lipopolysaccharide-binding protein (LBP) were evaluated in cows with naturally occurring mastitis. Blood and milk samples were collected from 101 clinically healthy dairy cows and 17 dairy cows diagnosed with clinical mastitis, and the LBP concentrations of the samples were measured by an ELISA. Concentrations of LBP were greater in the blood and milk of cows with clinical mastitis than in those with healthy quarters. Concentrations of LBP also differed between uninfected and subclinically infected quarters with low somatic cell count. Blood concentrations of LBP in cows with subclinical intramammary infections could not be differentiated from those of cows with all healthy quarters. Together, these data demonstrate that increased blood and milk concentrations of LBP can be detected in dairy cows with naturally acquired intramammary infections that cause clinical mastitis.

Lactation performance of mid-lactation dairy cows fed ruminally degradable protein at concentrations lower than national research council recommendations.

The aim of this study was to test whether feeding of diets containing lower proportions of ruminally degradable protein (RDP) but with a constant proportion of ruminally undegradable protein (RUP) alters feed intake, milk production and yield, and the apparent efficiency of N utilization by mid-lactation dairy cows. During the covariate period (d 1 to 28), 40 mid-lactation cows (36 Holstein and 4 Jersey x Holstein cross-breds) were fed a common diet formulated to contain 11.3% of diet dry matter (DM) as RDP. During the treatment period (d 29 to 47), cows were randomly assigned to 1 of 4 diets formulated to contain 11.3, 10.1, 8.8, or 7.6% RDP, whereas ruminally undegradable protein remained constant at 7.1% of DM. All diets contained 47.5% forage and 52.5% concentrate on a DM basis. Dry matter intake was significantly reduced for the 7.6% RDP diet. The lowest RDP content was associated with a trend for reduced milk yield. Dietary RDP had no effect on body weight or milk fat, protein, and lactose contents. Milk protein yield was not affected by RDP level; however, milk fat yield decreased linearly as dietary RDP was reduced. Concentrations of plasma essential amino acids were unaffected, whereas milk urea-N concentrations decreased linearly as dietary RDP content was reduced. The apparent efficiency of N utilization for milk N production increased from 27.7% on the 11.3% RDP diet to 38.6% on the 7.6% RDP diet. The dietary RDP requirement of cows in this study was apparently met between 15.9 and 14.7% dietary crude protein. Milk production was not significantly affected by the 8.8% RDP (15.9% crude protein) diet even though the NRC (2001) model predicted that RDP supply was 87% of that required, suggesting the current NRC recommendations for RDP may be overestimated for mid-lactation dairy cows in this study.

Nutrient net absorption across the portal-drained viscera of forage-fed beef steers: Quantitative assessment and application to a nutritional prediction model.

This study aimed to establish the relationship between ME intake and energy and nutrient absorption across the portal-drained viscera (PDV) of forage-fed beef steers. Eight Angus (328 +/- 40 kg of BW) steers were surgically fitted with portal, mesenteric arterial, and mesenteric venous catheters, and were fed alfalfa cubes in a replicated 4 x 4 Latin square design with 4 levels of energy intake between 1 and 2 times maintenance energy requirements. On d 28 of each experimental period, p-aminohippuric acid was infused to measure blood and plasma flow across the PDV, and blood samples (1 every hour, for 6 h) were collected simultaneously from arterial and venous catheters for net absorption measurements. Oxygen utilization, and therefore energy utilization, increased (P < 0.05) linearly in relation to ME intake. Glucose net uptake was unaffected, but lactate net release increased linearly in response to ME intake (P < 0.05). Net absorption of all AA except tryptophan, glutamate, and glutamine increased linearly with ME intake (P < 0.05). The constant net absorption of glutamate and glutamine indicated increased net utilization of these AA when dietary supply was increased. These data provide quantitative measures of the PDV effects on energy and AA availability for productive tissues, and suggest that the greater net utilization of some AA when ME intake is increased could relate to their catabolism for energy production. Prediction estimates of small intestinal AA absorption, based on the Cornell Net Carbohydrate and Protein System (CNCPS), exceeded observed net AA PDV absorption. Mean bias represented the greatest proportion (87 to 96%) of the deviation between individual AA absorption and observed net AA PDV absorption, suggesting that the CNCPS model may be used to predict AA net absorption when factors describing AA utilization by the PDV are applied to model predictions.

Salvage of blood urea nitrogen in sheep is highly dependent on plasma urea concentration and the efficiency of capture within the digestive tract.

The aims of this study were 1) to determine whether transfer of blood urea to the gastrointestinal tract (GIT) or the efficiency of capture of urea N within the GIT is more limiting for urea N salvage, and 2) to establish the relationship between plasma urea concentration and recycling of urea N to the GIT. We used an i.v. urea infusion model in sheep to elevate the urea entry rate and plasma concentrations, thus avoiding direct manipulation of the rumen environment that otherwise occurs when feeding additional N. Four growing sheep (28.1 +/- 0.6 kg of BW) were fed a low-protein (6.8% CP, DM basis) diet and assigned to 4 rates of i.v. urea infusion (0, 3.8, 7.5, or 11.3 g of urea N/d; 10-d periods) in a balanced 4 x 4 Latin square design. Nitrogen retention (d 6 to 9), urea kinetics([(15)N2]urea infusion over 80 h), and plasma AA were determined. Urea infusion increased apparent total tract digestibility of N (29.9 to 41.3%) and DM (47.5 to 58.9%), and N retention (1.45 to 5.46 g/d). The plasma urea N entry rate increased (5.1 to 21.8 g/d) with urea infusion, as did the amount of urea N entering the GIT (4.1 to 13.2 g/d). Urea N transfer to the GIT increased with plasma urea concentration, but the increases were smaller at greater concentrations of plasma urea. Anabolic use of urea N within the GIT also increased with urea infusion (1.43 to 2.98 g/d; P = 0.003), but anabolic use as a proportion of GIT entry was low and decreased (35 to 22%; P = 0.003) with urea infusions. Consequently, much (44 to 67%) of the urea N transferred to the GIT returned to the liver for resynthesis of urea (1.8 to 9.2 g/d; P < 0.05). The present results suggest that transfer of blood urea to the GIT is 1) highly related to blood urea concentration, and 2) less limiting for N retention than is the efficiency of capture of recycled urea N by microbes within the GIT.