Effect of age, stress and protein supply on plasma amino acids during continuous enteral nutrition; a pragmatic study in rats.

BACKGROUND & AIMS: As life expectancy increases, an increasing older population may require surgery with perioperative nutritional management. While little is known about the combined effect of age and stress on amino acid metabolism during enteral nutrition, we hypothesized that blood amino acid bioavailability may be influenced not only by the characteristics of the ingested protein but also by intestinal ageing and splanchnic sequestration of amino acids. Plasma amino acid kinetics were thus evaluated in aged and adult rats receiving continuous enteral nutrition before and after standardized surgical stress. METHODS: Sixteen 5-month-old and sixteen 21-month-old male rats were used. After a gastrostomy, the insertion of a jugular vein catheter and a one-week recovery, the animals were enterally fed with commercially available formulas containing whole milk proteins or a whey hydrolysate for 24 h before (healthy state) and 18 h after a standardized laparotomy (surgical stress). Data were analyzed by 3-factor ANOVA. RESULTS: In all rats, enteral nutrition was associated with a marked increase in plasma alanine, threonine, lysine and proline (+50 to +150 µmol/L; p < 0.001), and a decrease in glycine (≈-80 µmol/L; p < 0.01). For most amino acids, their availability depended first on the amino acid composition of each protein and second on surgical stress. Aging was only associated with higher tyrosine and threonine availability (p < 0.001). There was only limited statistical interaction between age and surgical stress. CONCLUSION: In rats, plasma amino acid availability during continuous enteral nutrition is determined by the nature of the protein source and the occurrence of stress. The effects of aging on plasma amino acid availability seem very limited. Commonly used formulas therefore appear to be as suitable for elderly patients as for adult patients.

Effect of aging on the availability of amino acids from an immune-enhancing diet (IED) after a surgical stress in rats.

BACKGROUND & AIMS: Dietary amino acid (AA) requirements increase after a surgical stress while the systemic AA availability from the diet decreases with age, due to splanchnic sequestration. While immune-enhancing diets (IEDs) have been recommended for the nutritional management of surgical patients, the systemic bioavailability of their AA supply has not been evaluated in elderly surgical patients. This was determined in surgically-stressed IED-fed aged rats. METHODS: Thirty-four 5-month- or 21-month-old male Sprague-Dawley rats were used. After a gastrostomy and placement of a jugular vein catheter and a one-week recovery period, the animals underwent two 24 h-enteral feedings with an arginine-enriched IED (Impact®, Nestlé Health Science) before (healthy state) and 18 h after a standardized laparotomy, used as a model of surgical stress. During enteral nutrition, blood samples were repeatedly collected to measure plasma AA bioavailability (incremental areas under the curve) at 2, 5 and 24 h. Surgical stress was evaluated from urinary catecholamines and plasma protein profile. RESULTS: Whatever the age or stress situation, IED feeding was associated with decreased plasma glycine and increased alanine, proline and arginine. Aging was mainly associated with a delayed plasma AA accumulation in the first hours after the initiation of enteral nutrition. Stress was associated with higher plasma arginine increase and lower histidine, methionine, phenylalanine and tyrosine accumulation. Age and stress interactions seem limited. CONCLUSIONS: AA bioavailability from an arginine-enriched IED seems to be maintained whatever age and stress situation. Aging appears to be mainly associated with a delay in plasma AA accumulation probably related to age-associated splanchnic sequestration of AAs. Additional effects of surgical stress per se seem limited.

Citrulline and muscle protein homeostasis in three different models of hypercatabolism.

Supplementation of enteral nutrition (EN) by specific amino acids (AAs) has been proposed to prevent muscle protein loss in intensive care unit (ICU) patients. Citrulline (Cit), which has been shown to stimulate muscle protein synthesis in other situations, may be of interest in this setting. Our aim was to assess the effect of Cit in three catabolic models relevant to critical illness: endotoxemia (LPS), traumatic brain injury (TBI), and TBI with infectious complications (TBI-Ec), which are characterized by different alterations in protein homeostasis. Fifty-eight male Sprague-Dawley rats (200-220 g) were randomized to receive a standard diet ad libitum (CON, n = 9) or to undergo catabolic injuries on day 0 (D0, n = 49), and EN (Sondalis HP energy® 290 kcal/kg/d) from day 1 (D1) combined with Cit (2 g/kg/d) or isonitrogenous non-essential AAs (NEAAs) until day 3 (D3). Endotoxemia was induced by IP injection of LPS from E. coli (3 mg/kg), TBI by hydraulic percussion, and infectious complications (TBI-Ec) by administration of luminescent E. coli on D1. Nitrogen balance (ΔN) and 3-methylhistidine (3-MHis) were measured daily. Muscle protein synthesis (MPS, measured by the SUnSET method) and mTORC1 activation (S6K-1 and 4E-BP1 phosphorylation) were measured on D3 2 h after the arrest of enteral nutrition in soleus, extensor digitorum longus (EDL), gastrocnemius and tibialis muscles. ΔN was lower (p < 0.001) in all three models of injury compared with basal and CON from D1 to D3, and more negative in the LPS-CIT (p < 0.05) than in the LPS group. The 3-MHis/creatinine ratio was significantly increased on D1 in all groups compared with CON, and on D2 only in the LPS and TBI groups (p < 0.0001, LPS and TBI vs. CON). MPS was similar in all groups in soleus and tibialis but significantly higher in EDL in LPS-CIT [LPS-CIT: 4.5 ± 1.7 (mean ± SD) vs. CON: 2.3 ± 1.2; and vs. LPS-NEAA: 3.1 ± 2.3] and in gastrocnemius (LPS-CIT vs. CON; p = 0.05). S6K-1 phosphorylation in the EDL was also higher in LPS-CIT vs. CON (LPS-CIT: 0.94 ± 0.51 CON: 0.42 ± 0.28), but not in gastrocnemius. IL-6 plasma level was significantly higher in all the catabolic groups vs. CON (p < 0.005) with no difference between treatments (Cit or NEAAs). In conclusion, the TBI model showed only a rise in muscle proteolysis, whereas the LPS model displayed a rise in both protein synthesis and proteolysis. Secondly, our results show that the Cit effect varies according to the type of injury and to the muscle under study. The stimulation of MPS rate and the mTOR pathway in LPS-treated rats contrasts with degraded ΔN, suggesting that the Cit effect on protein metabolism in critically ill rats is limited at the whole-body level.

[Understanding the pathophysiology of malnutrition for better treatment]. / Comprendre la physiopathologie de la dénutrition pour mieux la traiter.

Malnutrition results from an imbalance between intake and protein-energy requirements resulting in tissue losses with adverse functional consequences. However, it would be better to speak of "states of malnutrition" rather than "malnutrition". Indeed, the mechanisms involved associate, with varying degrees, intake deficiency and increased needs with different clinical consequences. Adaptation to nutrient deficiency aims at establishing lasting saving conditions by promoting optimization of energy reserve utilization while preserving protein pool. This is achieved by reducing basal metabolism (low T3), by decreasing the secretion of anabolic factors and moderately increasing catabolic hormones. Unlike the previous process, the metabolic response to injury or stress, which will sometime induce major increase in requirements, will have as immediate purpose the defense of the organism. The body will draw sometime substantially in its protein pool to produce the glucose required for example by the immune cells. Stress response stems from both an endocrine response, and an immuno-inflammatory one with the important role of pro-inflammatory cytokines released in response to pathogens and more recently alarmins in response to endogenous stress in the inflammatory phenomena of the stress response and in the resulting malnutrition state. Treatment of these malnutrition conditions will thus differ: promoting anabolism in one case and fighting resistance to anabolism and hypercatabolism in the other.

Aliphatic polyamines in physiology and diseases.

Aliphatic polyamines are a family of polycationic molecules derived from decarboxylation of the amino acid ornithine that classically comprise three molecules: putrescine, spermidine and spermine. In-cell polyamine homeostasis is tightly controlled at key steps of cell metabolism. Polyamines are involved in an array of cellular functions from DNA stabilization, and regulation of gene expression to ion channel function and, particularly, cell proliferation. As such, aliphatic polyamines play an essential role in rapidly dividing cells such as in the immune system and digestive tract. Because of their role in cell proliferation, polyamines are also involved in carcinogenesis, prompting intensive research into polyamine metabolism as a target in cancer therapy. More recently, another aliphatic polyamine, agmatine, the decarboxylated derivative of arginine, has been identified as a neurotransmitter in mammals, and investigations have focused on its effects in the CNS, notably as a neuroprotector in brain injury.

An in silico model of enterocytic glutamine to citrulline conversion pathway.

Enterocyte is one of the main sites of amino acids metabolism and particularly of the citrulline biosynthesis. Working at the cellular scale and applying ordinary differential equations (ODEs) formalism, we have built a mathematical model of the enterocytic glutamine to citrulline conversion in the fasting state. This model enables us to test different physiopathological scenarios of enzyme activity loss. Results from two different approaches were compared: a standard approach (KA) based on the Michaelis-Menten assumptions and an association-dissociation approach (VH) based on the kinetic mass action law. For both approaches, ODEs system was numerically solved using Mathematica™. In both cases, the model correctly predicts the physiological plasma citrulline steady-state, but the two approaches present clear differences for metabolites of enzymes having a complex mechanism, challenging the validity of the KA approach in such cases. When physiopathological scenarios of enzyme activity loss are simulated, both approaches predict a very sharp transition from the physiological citrulline plasma level to the lack of its production: the concentration profiles of these simulations show a clear threshold of which characteristics vary with the involved enzyme. Moreover, amongst all enzymes included in the model, the ornithine aminotransferase (OAT) shows the highest sensitivity in the system whatever the approach used. This model points out the limits of the Michaelis-Menten approach to model complex enzyme mechanisms. It highlights the key role of OAT in the studied citrulline synthesis pathway and also suggests an order of magnitude about the optimal ratio of enzyme concentrations in this pathway.

N-Carbamoylputrescine, a citrulline-derived polyamine, is not a significant citrulline metabolite in rats.

Citrulline, a key amino acid of the urea cycle, has been shown to play a regulatory role in protein and energy metabolism in mammals. We questioned whether N-carbamoyl-putrescine (NCP), the decarboxylated derivative of citrulline, could play a role in the biological properties of this amino acid. To evidence the presence of NCP in mammalian tissues, we developed a sensitive reverse-phase high-performance liquid chromatography (HPLC) with fluorimetric detection method with precolumn dansyl derivatization and solid-phase extraction for the determination of NCP together with polyamines in biological samples. Dansyl NCP was identified with a 5.85-min retention time. Linearity was obtained in a concentration range of 0.125 to 12.5 µM. Intraday and day-to-day relative coefficients of variation ranged from 8.9% to 12.3% and from 14% to 14.3%, respectively. Recovery rates in serum ranged from 75% to 83%. Thereafter, we used this method to search for the presence of NCP in serum, muscle, liver, jejunum, and ileum in rats after both short-term intraperitoneal injection and long-term oral citrulline supplementation. We failed to detect NCP in these animals. These data suggest that NCP is not a significant citrulline metabolite in rats.

Evidence for a role of the ileum in the control of nitrogen homeostasis via the regulation of arginine metabolism.

As arginine plays a key role in the regulation of liver ureagenesis, we hypothesised that a modulation of enzymes involved in arginine metabolism within the intestine contributes to the regulation of N homeostasis according to protein supply. Our aim was to study the influence of variations in protein or amino acid (AA) supply on intestinal arginase, glutaminase, ornithine aminotransferase (OAT), argininosuccinate lyase and argininosuccinate synthetase. We evaluated in vivo in rats the responses of these enzymes to short-term (ST, 16 h) and long-term (LT, 15 d) variations in dietary protein (10, 17 or 25 % protein diet). In addition, in order to test whether these responses could involve a direct action of AA on the gene expression and activity of these enzymes, Caco-2/TC7 cells were cultured for 3 d with increasing AA concentrations. In vivo, in the ST, both high- and low-protein diets increased arginase activity in the intestinal mucosa (ST25 %: 46 (sem 2) µmol/g per min and ST10 %: 46 (sem 2) µmol/g per min v. ST17 %: 36 (sem 3) µmol/g per min, P < 0.05). In the LT, OAT expression was increased in the LT10 % group (+277 %, P < 0.05) compared with the LT17 % group. Caco-2/TC7 cells showed inverse relationships between AA supply and arginase (P = 0.058) and OAT (P = 0.035) expressions. The present study demonstrates the regulation of intestinal arginase and OAT expressions in response to protein supply. Our in vitro experiments further indicate a direct AA-induced regulation of the mRNA abundance of these enzymes. In situations of limited protein supply, this regulation would increase intestinal arginine catabolism and, possibly via a decrease in arginine portal release, decrease hepatic AA oxidation, thus promoting N sparing.

Adaptative response of nitrogen metabolism in early endotoxemia: role of ornithine aminotransferase.

Arginine (Arg) and glutamine (Gln) utilization is greatly increased during catabolic stress. While the supply of both amino acids has been advocated in this situation, arginine administration is possibly associated with deleterious effects. From a metabolic point of view, these two amino acids are reciprocal precursors via ornithine aminotransferase (OAT). We hypothesized that OAT plays a key role in the interconversion between Arg and Gln. To test this hypothesis, we evaluated the influence of OAT activity in a model of septic shock induced by intraperitoneal injection of lipopolysaccharide (LPS) in wild-type (WT) and transgenic mice overexpressing OAT (OAT) in the liver, kidney and intestine, i.e. the three main organs of OAT expression. Plasma and tissue amino acid concentrations and tissue OAT expression and activity were measured. Five hours after LPS injection, WT and OAT mice showed a similar response to LPS in terms of inflammatory cytokine production and protein catabolism, suggesting that the interconversion between Arg and Gln through this pathway remains limited. Endotoxemia led to a significant decrease in plasma Orn levels and an increase in liver Orn levels. Of note, Orn levels were always lower in OAT mice. While only plasma Arg and Gln remained unaffected by LPS treatment, hepatic Gln was significantly increased without any difference between the two genotypes. In this model of early endotoxemia, arginine and glutamine maintained their metabolic homeostasis. Our results show an inhibition of OAT activity and expression in the liver following LPS treatment. These data highlight the importance of OAT in ornithine metabolism, especially in the liver, and suggest a post-transcriptional regulation of OAT by LPS in the liver.

Simultaneous determination of retinol and alpha-tocopherol in polymeric diets for enteral nutrition.

Existing methods for simultaneous measurements of retinol and alpha-tocopherol in enteral formulas require large sample and solvent volumes and are time-consuming and costly. We have developed a simple, sensitive, cost-effective method for the determination of these vitamins in polymeric diets that can easily be applied to standard quality control of large numbers of samples. Our analytical procedure comprises deproteinization with pure ethanol, saponification with a 3.6M KOH solution in a sonicator for 30 min at 65 degrees C under a nitrogen atmosphere, solubilization of samples in phosphate buffer and extraction with hexane. Vitamins are separated by reversed-phase HPLC and quantified by dual-wavelength spectrophotometry. The method gives satisfactory results, with recovery rates of 106.3+/-1.5% for retinol and 102.3+/-1.5% for alpha-tocopherol and RSDs ranging between 1.2 and 4.8% for precision. This method is suitable for the quality control of enteral formulas.

Splanchnic sequestration of amino acids in aged rats: in vivo and ex vivo experiments using a model of isolated perfused liver.

Splanchnic sequestration of amino acids (SSAA) is a process observed during aging that leads to decreased peripheral amino acid (AA) availability. The mechanisms underlying SSAA remain unknown. The aim of the present study was to determine whether a high-protein diet could increase nitrogen retention in aged rats by saturating SSAA and whether SSAA could be explained by dysregulation of hepatic nitrogen metabolism. Adult and aged male Sprague-Dawley rats were housed in individual metabolic cages and fed a normal-protein (17% protein) or high-protein diet (27%) for 2 wk. Nitrogen balance (NB) was calculated daily. On day 14, livers were isolated and perfused for 90 min to study AA and urea fluxes. NB was lower in aged rats fed a normal-protein diet than in adults, but a high-protein diet restored NB to adult levels. Isolated perfused livers from aged rats showed decreased urea production and arginine uptake, together with a release of alanine (vs. uptake in adult rats) and a hepatic accumulation of alanine. The in vivo data suggest that SSAA is a saturable process that responds to an increase in dietary protein content. The hepatic metabolism of AA in aged rats is greatly modified, and urea production decreases. This result refutes the hypothesis that SSAA is associated with an increase in AA disposal via urea production.

Effect of apoE/ATP-containing liposomes on hepatic energy state.

BACKGROUND/AIMS: ATP-containing liposomes partially prevent ATP depletion in the cold-stored liver. As hepatocytes can specifically bind apoE, we investigated whether the addition of apoE to large (200 nm) ATP-containing liposomes increases their uptake by the liver and further improves hepatic energy stores. METHODS: Livers from fasted male Hartley guinea-pigs (231 +/- 3 g) were perfused for 90 min under our standard conditions (Control, n = 6) or after a single bolus addition of plain liposomes (Lip, n = 6), ATP (5 micromol)-containing liposomes (ATP-Lip, n = 6) or apoE/ATP-containing liposomes (0.8 or 8mg apoE/g phospholipids; apoE1-Lip and apoE10-Lip, respectively, n = 6 in each group). Liposome uptake and its impact on energy and nitrogen metabolism were studied. RESULTS: At its highest concentration, apoE significantly increased liposome uptake (apoE10-Lip: - 9.17 +/- 0.69 vs apoE1-Lip: - 6.18 +/- 0.44 vs ATP-Lip: - 6.40 +/- 0.88 nmol min(-1) g(-1) P < 0.05). This was associated with a significant increase in intrahepatic ATP (apoE10-Lip: 1033 +/- 137 vs apoE1-Lip: 811 +/- 98 and ATP-Lip: 648 +/- 36 nmol g(-1); P < 0.05), which was restored to its level in non-perfused livers. Hepatic viability and nitrogen metabolism were not affected. CONCLUSIONS: Hepatic ATP content being a key factor in the maintenance of liver graft function, apoE/ATP-containing liposomes should be useful in liver preservation for transplantation.

Hepatic preservation, liposomally entrapped adenosine triphosphate and nitric oxide production: a study of energy state and protein metabolism in the cold-stored rat liver.

BACKGROUND: Liposomally entrapped adenosine triphosphate (ATP) has been demonstrated to improve energy state and function of the cold-stored liver. The increased nitrite release associated with liposome administration led us to investigate the interactions between liposome supply and nitric oxide (NO) production through the use of L-NAME, a non-selective inhibitor of NO synthesis. METHODS: Twenty-four livers from fasted rats were stored for 18 h at +4 degrees C in University of Wisconsin solution directly (control group) or after infusion with ATP-containing liposomes (Lip-ATP), L-NAME (L-NAME) or both (Lip-ATP-L-NAME). Metabolic fluxes, cell volume and energy state were studied during reperfusion. RESULTS: After storage, nitrite release was increased by 61% in the Lip-ATP group, markedly decreased in the Lip-ATP-L-NAME group and almost abolished in the L-NAME group. The ATP content was increased by 20% in the Lip-ATP group (P < 0.05 versus control) and on reperfusion this was associated with an increase in cell volume (17%; P < 0.05) and a decrease in branched-chain amino acid release (21%; P < 0.01). The simultaneous addition of L-NAME did not affect these results, but induced a large (6-fold) increase in glucose production, possibly related to the metabolism of glycerol supplied by the liposomes. In the L-NAME group, global amino acid release was 50% lower and was associated with a dramatic decrease in urea production while the energy state deteriorated rapidly. CONCLUSIONS: The improvement in energy state and anabolic cell swelling induced by ATP-containing liposomes seems to be independent of NO synthesis. On the other hand, inhibition of NO synthesis appears to exert a detrimental effect on the liver, presumably through the decrease in hepatic energy content.

Cold preservation injury in rat liver: effect of liposomally-entrapped adenosine triphosphate.

BACKGROUND/AIMS: Energy charge and capacity for adenosine triphosphate (ATP) synthesis have been demonstrated to play a major role in the maintenance of organ function after liver preservation for transplantation. The aim of this study was to evaluate whether a supply of liposomally-entrapped ATP during preservation could improve the energy state and metabolism of cold-stored rat liver. METHODS: In the first set of experiments, the uptake of ATP-containing liposomes and their effects on hepatic viability were determined in isolated perfused unstored rat liver. In the second set of experiments, rat livers were preserved for 18 h at 4 degrees C in UW solution in the presence of these liposomes, and effects on energy state, cell volume and metabolism were evaluated. In each part, data were compared with adequate control, unloaded liposome-treated, and free ATP-treated groups (n=6 in each group). RESULTS: In non-stored livers, ATP-containing liposomes were taken up by the liver; they did not alter hepatic viability and induced a decrease in energy substrate consumption (glucose and amino acids), and an improvement in intrahepatic ATP content (+23% vs. Control). Addition of liposomally-entrapped ATP during cold storage produced a significant attenuation of the decrease in hepatic ATP content (Lip ATP 2: 524+/-45 vs. Control 2: 364+/-106 nmol/g; p<0.05), and induced, during reperfusion, a decrease in proteolysis associated with an increase in cell volume compared with the other groups (Lip ATP 2: 633+/-63 vs. Control 2: 532+/-38, Unloaded Lip 2: 483+/-55 and Free ATP 2: 500+/-29 microl/g; p<0.01). CONCLUSIONS: These data indicate that liposomally-entrapped ATP represents an effective means to improve liver graft energy state and function. The decrease in protein degradation may be related to the modification of cell volume.

Ornithine alpha-ketoglutarate improves wound healing in severe burn patients: a prospective randomized double-blind trial versus isonitrogenous controls.

OBJECTIVE: To compare the effectiveness on wound healing time in severe burn patients of ornithine alpha-ketoglutarate supplementation of enteral feeding vs. an isonitrogenous control. Previous clinical and experimental studies suggest a beneficial effect of enterally administered ornithine alpha-ketoglutarate supplementation on protein metabolism in burn patients, but few data deal with clinical outcome. DESIGN: Prospective double-blind randomized trial. SETTING: Burn treatment center of an army hospital. PATIENTS: Forty-seven severe burn patients with total burned body surface areas of 25% to 95% and presence of full thickness burn who were prescribed early exclusive enteral nutrition. Either ornithine alpha-ketoglutarate or isonitrogenous control (soy protein mixture, Protil-1) were administered twice a day as a bolus (2 x 10 g) at 9 am and 9 pm for 3 wks. The patients were evaluated for wound healing time (primary end point), antibiotic use, tolerance, duration of enteral nutrition, and nutritional status. INTERVENTIONS: Serial blood samples were collected in each patient for determination of serum transthyretin and plasma phenylalanine, and urine sampling was performed for determination of 3-methylhistidine excretion at day 4 and day 21 after burn injury. MEASUREMENTS AND MAIN RESULTS: Wound healing times in patients receiving ornithine alpha-ketoglutarate or Protil-1 were 60 +/- 7 and 90 +/- 12 days, respectively (p < .05) for similar grafted surfaces. Based on increased serum transthyretin concentrations, both groups showed an improvement of nutritional status at day 21 after burn. Taking a cut-off value of 110 unit burn standard for severity of injury, plasma phenylalanine concentrations, and urinary 3-methylhistidine/creatinine ratio were significantly reduced (p < .05) in the less severe burn patients (<110 unit burn standard) supplemented with ornithine alpha-ketoglutarate. CONCLUSIONS: Ornithine alpha-ketoglutarate supplementation of enteral feeding significantly shortens wound healing time in severe burn patients. In addition, ornithine alpha-ketoglutarate administration was safe and well tolerated and decreased protein hypercatabolism in the less severe burn patients.

Branched-chain keto-acids and pyruvate in blood: measurement by HPLC with fluorimetric detection and changes in older subjects.

BACKGROUND: Measurement of keto-acids is important in various clinical situations. The aim of the present work was to develop a rapid HPLC method for the determination of keto-acids in human serum and to assess the concentrations of these acids in young adults and institutionalized elderly adults. This method was applied to the determination of blood keto-acid concentrations of young adults and institutionalized elderly people, divided into age groups METHODS: Four keto-acids (alpha-ketoisocaproate, alpha-ketoisovalerate, alpha-keto-beta-methylvalerate, and pyruvate) were derivatized with o-phenylenediamine to give fluorescent derivatives. After the sample preparation step (75 min to prepare 20 samples), the derivatives were separated chromatographically on a reversed-phase column using a binary gradient. RESULTS: The fluorometric detection of the four keto-acids was rapid, <12 min. The method is repeatable and reproducible: the CVs were <6% and <11%, respectively, for each of the keto-acids. We found no significant difference between males and females. Concentrations of the branched-chain keto-acids decreased after age 60 years, especially alpha-ketoisocaproate, which decreased approximately 40%. CONCLUSIONS: The proposed method allows rapid and reliable measurement of keto-acids. The data demonstrate that changes in branched-chain keto-acids concentrations in serum occur with age.

A Na(+)-dependent system A and ASC-independent amino acid transport system stimulated by glucagon in rat hepatocytes.

The effects of glucagon on amino acid transport in rat hepatocytes are not fully understood. We examined the effect of this hormone on alanine, serine and cysteine preferring system (system ASC)-mediated amino acid transport in rat hepatocyte monolayers using 2-aminoisobutyric acid (AIB) and l -cysteine. Glucagon induced a time and protein synthesis-dependent stimulation of Na(+)-dependent alanine preferring system (system A)-independent AIB transport. The glucagon-induced increase in transport activity was not modified by substrate starvation and not related to changes in the intracellular pool of amino acids. Glucagon did not modify system ASC activity measured by l -cysteine. Therefore the transport activity of AIB independent of system A stimulated by glucagon cannot be attributed to system ASC. This suggests a Na(+)-dependent transport system in rat hepatocytes not identified until now.

Effects of amino acids on bile acid-dependent and independent bile flow in the isolated perfused rat liver.

BACKGROUND/AIMS: Conflicting data on the effects of amino acids on biliary function led us to investigate their interaction with taurocholate in the perfused rat liver model. METHODS: To investigate the influence of amino acids on the bile acid-independent component of bile flow, 12 livers were perfused with (n = 6) and without (n = 6) amino acid addition from t30 min. For the study of bile acid-dependent bile flow, 24 livers were perfused under 8 experimental conditions according to the perfusate taurocholate concentration (12.5, 25, 37.5 or 50 microM) and whether amino acids were or were not added from t30 min. RESULTS: In the absence of taurocholate, amino acids induced a 40% (p<0.01) decrease in bile flow together with an increase in hepatic water content (17.8%, p< 0.05). Thus, amino acids exert an inhibitory effect on bile acid-independent bile flow despite the postulated cell swelling-dependent increase in bile flow. When livers were perfused at various taurocholate concentrations, amino acids induced, in addition to their inhibitory effect on bile acid-independent bile flow, a significant increase in taurocholate apparent choleretic activity (13.2 microl/micromol vs. 10.6 microl/micromol; p = 0.05), while taurocholate intrinsic clearance was significantly decreased (4.5+/-1.2 ml x min(-1) x g(-1) vs. 6.1+/-1.3 ml x min(-1) x g(-1); p<0.01). CONCLUSIONS: These data suggest that at physiological bile acid concentrations amino acids exert an inhibitory effect on both bile acid-dependent and- independent bile flow, whereas at higher taurocholate concentrations this inhibitory effect disappears, probably because of cell swelling-dependent mechanisms.