Evaluation of the isolated perfused rat hindquarter for the study of muscle metabolism

1. The metabolic integrity of a new isolated rat hindquarter preparation was studied. The hindquarter was perfused with a semi-synthetic medium containing aged human erythrocytes. More than 95% of the oxidative metabolism of the preparation was due to muscle, the remainder being due to bone, adipose tissue and, where present, skin. 2. Consumption of O(2), glucose utilization, glycerol release and lactate production were similar in the presence and in the absence of the skin, indicating that the latter contributed little to the overall metabolism of the preparation. 3. After 40min of perfusion, tissue concentrations of creatine phosphate, ATP and ADP were similar to those found in muscle taken directly from intact animals. The muscle also appeared normal under the electron microscope. 4. The hindquarter did not lose K(+) to the medium during a 30min perfusion. In the presence of insulin it had a net K(+) uptake. 5. Insulin caused a sixfold increase in glucose uptake, stimulated O(2) consumption by nearly 40% and depressed glycerol release to less than half the control value. 6. Bilateral sciatic-nerve stimulation caused severalfold increases in O(2) consumption and lactate production. In the absence of insulin nerve stimulation also enhanced glucose uptake; in the presence of insulin it did not further increase the already high rate of glucose uptake. 7. Rates of lactate production and O(2) consumption of the rat hindquarter in vivo and the isolated perfused hindquarter were very similar. 8. Ketone bodies were a major oxidative fuel in vivo of the hindquarter of a rat starved for 2 days. If the acetoacetate and 3-hydroxybutyrate removed by the tissue were completely oxidized, they would have accounted for 77% of the O(2) consumption. 9. Acetoacetate accounted for 84% of the ketone bodies removed by the hindquarter in vivo even though its arterial concentration was half that of 3-hydroxybutyrate. 10. Similar rates of acetoacetate and 3-hydroxybutyrate utilization were observed in the perfused hindquarter. 11. Acetoacetate utilization by the perfused hindquarter was not diminished by the addition of either oleate or insulin to the perfusate. 12. Oxidation of glucose to CO(2) accounted for less than 4% of the O(2) consumed by the perfused hindquarter in both the presence and the absence of insulin. 13. The results indicate that the isolated perfused hindquarter is a useful tool for studying muscle metabolism. They also suggest that ketone bodies, if present in sufficient concentration, are the preferred oxidative fuel of resting muscle.     

The effect of octanoate and palmitate on the metabolism of valine in perfused hindquarter of rat.

The effect of octanoate and palmitate on the oxidation of 14C-labelled valine has been studied in perfused hindquarter of rat. 1. The oxidation rate of valine increases 30 times when the concentration of valine is increased from 0.1 mM to 5 mM. 2. Octanoate at a 5 mM concentration effected a 10-fold increase in the flux through the alpha-ketoisovalerate dehydrogenase step and a 5-fold increase at 0.5 mM concentration. 3. Palmitate (1 mM) effects only a moderate increase in the valine oxidation. 4. With no octanoate there was a great accumulation of alpha-ketoisovalerate in both the muscle and the perfusion medium. 5. With octanoate little alpha-ketoisovalerate accumulated whereas 3-hydroxyisobutyrate was found in high concentration both in the muscle and in the medium. 6. Octanoate stimulated the production of citric-acid-cycle intermediates and lactate. 7. The results are discussed in relation to valine metabolism in the body.     

Amino acid catabolism by perfused rat hindquarter. The metabolic fates of valine.

Hindquarters from starved rats were perfused with plasma concentrations of amino acids, but without other added substrates. Release of amino acids was similar to that previously reported, but, if total amino acid changes were recorded, alanine and glutamine were not formed in excess of their occurrence in muscle proteins. In protein balance (excess insulin) there was no net formation of either alanine or glutamine, even though the branched-chain amino acids and methionine were consumed. If [U-14C]valine was present, radiolabelled 3-hydroxyisobutyrate and, to a lesser extent, 2-oxo-3-methylbutyrate accumulated and radiolabel was incorporated into citrate-cycle intermediates and metabolites closely associated with the citrate cycle (glutamine and glutamate, and, to a smaller extent, lactate and alanine). If a 2-chloro-4-methylvalerate was present to stimulate the branched-chain oxo acid dehydrogenase, flux through this step was accelerated, resulting in increased accumulation of 3-hydroxyisobutyrate, decreased accumulation of 2-oxo-3-methylbutyrate, and markedly increased incorporation of radiolabel (specific and total) into all measured metabolites formed after 3-hydroxyisobutyrate. It is concluded that: amino acid catabolism by skeletal muscle is confined to degradation of the branched-chain amino acids, methionine and those that are interconvertible with the citrate cycle; amino acid catabolism is relatively minor in supplying carbon for net synthesis of alanine and glutamine; and partial degradation products of the branched-chain amino acids are quantitatively significant substrates released from muscle for hepatic gluconeogenesis. For valine, 3-hydroxyisobutyrate appears to be quantitatively the most important intermediate released from muscle. A side path for inter-organ disposition of the branched-chain amino acids is proposed.     

Participation of mast cell 5-hydroxytryptamine in the vasoconstrictor effect of neurotensin in the rat perfused hindquarter

Neurotensin (NT) (1 X 10(-8) - 1.5 X 10(-6) g ml-1) caused a transient, dose-dependent increase in perfusion pressure in the rat perfused hindquarter. The vasoconstrictor effect of NT was associated with a short-lived, dose-dependent release of histamine and 5-hydroxytryptamine (5-HT) in the hindquarter effluent. Compound 48/80, a classical mast cell secretagogue, also elicited a vasoconstrictor effect in, and release of histamine from, the rat hindquarter. The vasoconstrictor effect and the release of histamine and 5-HT evoked by NT were much smaller in hindquarters derived from rats pretreated with compound 48/80 for 4 days to cause mast cell depletion than in hindquarters derived from control rats. The mast cell inhibitor cromoglycate (4 mg ml-1) inhibited by about 50% the histamine releasing effect and vasoconstriction produced by the lowest concentrations of NT utilized. The histamine releasing effect of compound 48/80 was more sensitive to blockade by cromoglycate than that of NT. The steroidal antiinflammatory and antiallergic drug dexamethasone did not affect the histamine and 5-HT releasing effect of NT. The vasoconstrictor effects of NT, compound 48/80 and 5-HT were markedly reduced by the 5-HT receptor antagonist methysergide (1 X 10(-7) g ml-1). Histamine (1 X 10(-6) - 10(-4) g ml-1) evoked a decrease in perfusion pressure in hindquarters pre-exposed to noradrenaline. The results suggest the participation of mast cell 5-HT in the vasoconstrictor effect of NT in the rat perfused hindquarter.     

Conversion of p-tyrosine to p-tyramine in the isolated perfused rat kidney: modulation by perfusate concentrations of p-tyrosine

We used the isolated perfused rat kidney to evaluate the role of renal decarboxylation of p-tyrosine as the source of urinary p-tyramine. Kidneys were perfused with concentrations of p-tyrosine ranging from 0.02 mM to 2.0 mM. p-Tyramine was measured by a sensitive and specific radioenzymatic assay. An increase in the perfusate concentration of p-tyrosine resulted in a significant increase in p-tyramine production that was blocked by the addition of NSD-1015, an inhibitor of aromatic-1-amino decarboxylase (AADC). We conclude p-tyrosine is the precursor for the renal production of p-tyramine, renal AADC catalyzes the formation of urinary p-tyramine, synthesized p-tyramine is predominantly excreted in the urine, and p-tyramine synthesis is modulated by the arterial delivery of p-tyrosine to the kidney.     

Effect of glucocorticoides on the release of amino acids in the perfused rat hindquarter (author's transl)]

The release of amino acids by skeletal muscle was studied in the isolated perfused rat hindquarter. Adrenalectomy depressed the formation of glutamine and alanine as well as the efflux of all other amino acids measured. Betamethasone--a synthetic glucocorticoid--caused a significant increase in the efflux of nearly all amino acids up to the level of normal controls. The release of amino acids was also increased in perfused hindquarters of diabetic rats. On the other hand, insulin exhibited a depressing effect on the release of amino acids by hindquarters of normal rats. The metabolic integrity of the muscle tissue was proved by measuring creatine phosphate, ATP, ADP and water content as well as by the significant insulin effect on glucose uptake and on [14C]leucine incorporation into muscle proteins.     

Lipoproteins in a nonrecirculating perfusate of rat liver

Rat livers were perfused in a nonrecirculating system for 30-40 min with Krebs-Ringer bicarbonate-0.1% glucose solution gassed with 95% O(2)-5% CO(2) at 37 degrees C at a flow rate of 3 ml/g/min. The livers appeared normal as judged by O(2) uptake, bile flow, transaminase release, and net protein output (2.5 mg/g/hr). The perfusate was concentrated by ultrafiltration using Amicon PM-10 or PM-30 membranes. The concentrated perfusate was subjected to sequential ultracentrifugation at solution densities of 1.006, 1.04, 1.06, and 1.21, and the top fractions were analyzed for protein and lipid. The net release of protein in the four density classes, suitably corrected, averaged 39, 10, 5, and 20 micro g/g/hr. The lipid composition of the perfusate lipoprotein fractions differed from that of serum mainly in the high percentage of free cholesterol, reflecting the lack of exposure to lecithin:cholesterol acyltransferase. When rat serum was fractionated in the same way, most of the lipoprotein in the d 1.006-1.06 range had a density greater than 1.04. It was concluded from these experiments that the liver secretes very low density lipoprotein (VLDL), high density lipoprotein (HDL), and a modified form of VLDL containing less lipid. Comparison of secretion rates and serum lipoprotein levels leads to the conclusion that the latter are largely determined by catabolic rates. When labeled amino acids were present, the perfusate HDL had a higher specific activity than VLDL. Addition of carrier whole serum did not alter recovery of labeled lipoproteins, but when these were isolated from Golgi membranes after a 40-min perfusion, more than twice as much label was recovered in HDL, suggesting the presence of precursors within the Golgi. The main advantages of the nonrecirculation perfusion technique are the avoidance of catabolic reactions, simplicity, and complete control over the composition of the perfusing medium.     

Quantitative effects of thermal injury and insulin on the metabolism of the skeletal muscle using the perfused rat hindquarter preparation

Injury from a severe burn or trauma can propel the body into a hypermetabolic state that can lead to the significant erosion of lean muscle mass. Investigations describing this process have been somewhat limited due to the lack of adequate experimental models. Here we report the use of a perfused rat hindquarter preparation to study the consequences of a moderate burn injury (approximately 20% total body surface area), with or without the addition of exogenous insulin (12.5 mU/mL), on the fluxes of major metabolites across the isolated skeletal muscle. The metabolic flux data was further analyzed using metabolic flux analysis (MFA), which allows for the estimation of the impact of these conditions on the intracellular muscle metabolism. Results indicate that this model is able to capture the increased rate of proteolysis, glutamine formation, and the negative nitrogen balance associated with the burn-induced hypermetabolic state. The inclusion of exogenous insulin resulted in significant changes in several fluxes, including an increase in the metabolism of glucose and the flux through the pentose phosphate pathway, as well as a reduction in the metabolism of glutamine, alanine, and leucine. However, insulin administration did not affect the nitrogen balance or the rate of proteolysis in the muscle, as has been suggested using other techniques. The use of the perfused hindquarter model coupled with MFA is a physiologically relevant and experimentally flexible platform for the exploration of skeletal muscle metabolism under catabolic conditions, and it will be useful in quantifying the specific metabolic consequences of other therapeutic advances.     

Histamine release by neurotensin in the rat hindquarter: structure-activity studies

Histamine releasing effects of neurotensin (NT) and several NT fragments and structural analogues were measured in the rat perfused hindquarter. The results show that the chemical groups responsible for histamine release are located in the C-terminal sequence Arg9-Pro10-Tyr11-Ile12-Leu13-OH. Both the spatial configuration and positive charge of Arg8 and Arg9 appear to contribute to the histamine releasing effect of NT. Optimization of the histamine releasing effect of NT requires both a free C-terminal carboxyl group and the presence in position 11 of NT of an aromatic residue, with the L-configuration, bearing an heteroatom capable of hydrogen bonding with the receptor. The results indicate that the structural requirements of NT to induce histamine release from the rat perfused hindquarter are similar to those involved in other peripheral biological actions of NT.     

Pyridoxal 5'-phosphate disappearance from perfused rat jejunal segments: correlation with perfusate alkaline phosphatase and water absorption

The relative effects of perfusate alkaline phosphatase activity and net water absorption on 2 microM pyridoxal 5'-phosphate (PLP) luminal disappearance from rat jejunum were studied in a single-pass, in vivo perfused intestinal segment model. Perfusate consisted of unlabeled PLP in buffer (pH = 7.4). Net water flux was monitored by inclusion of [3H]polyethylene glycol. PLP was measured by the [14C]tyrosine apodecarboxylase assay. Single and multiple regression analysis of results during perfusion of 2 microM PLP in Krebs bicarbonate buffer demonstrated no correlation between perfusate alkaline phosphatase activity and net water absorption and significant correlations between PLP luminal disappearance and both perfusate alkaline phosphatase activity and net water absorption. Correlation for the latter was improved when disappearance results were corrected for variations in perfusate alkaline phosphatase activity. When perfusate buffers were selected to yield divergent rates of net water absorption, the one associated with greater net water absorption was also associated with greater PLP disappearance. That this could not be explained by changes in perfusate alkaline phosphatase activity was demonstrated both by assessment of the rate of decay of PLP added in vitro to exited perfusate incubated at 37 degrees C and by measurement of alkaline phosphatase activity under conditions defined by the buffers using a modified spectrophotometric assay. Conclusions were: (1) In vivo PLP luminal disappearance correlates significantly with both perfusate alkaline phosphatase activity and net water absorption; (2) these two factors appear to act as independent variables; and (3) future studies on PLP intestinal absorption will need to take both of these variables into account in the interpretation of results.     

In vitro effects of glycosylated insulin in perfused liver and hindquarter in rats.

Using the perfused liver and hindquarter of the rat, the uptake of glycosylated insulin and its effect on glucose output were investigated. Insulin was glycosylated in ambient high glucose concentration, and glycosylated insulin GI80 (insulin incubated with 0.08% glucose), GI350 (incubated with 0.35% glucose), and GI1000 (incubated with 1% glucose) were prepared. The liver and hindquarter were perfused with nonglycosylated insulin (N-GI) or glycosylated insulin at a concentration of 100 or 1000 microU/ml. There were no significant differences in the fractional uptake of insulin by perfused liver and hindquarter despite glycosylation. Insulin-induced decrement in glucose output was significantly lower in the liver perfused with GI1000 than that in the liver perfused with N-GI, GI80, and GI350 at an insulin concentration of 100 microU/ml. There were no significant differences in insulin-induced decrement in glucose output between the hindquarter perfused with N-GI, GI80, GI350, and GI1000. These results suggest that when insulin (100 microU/ml) is incubated with a markedly elevated concentration of glucose (1000 mg/dl) its biological activity is reduced in the liver, but not in the hindquarter.     

Apoproteins of the lipoproteins in a nonrecirculating perfusate of rat liver.

The apoproteins of serum lipoproteins and of lipoproteins present in a nonrecirculating perfusate of rat liver were compared by immunochemical, gel electrophoretic, and solubility techniques. Serum and perfusate very low density lipoprotein apoprotein composition were not different. No evidence for the presence of a lipoprotein resembling serum low density lipoprotein was obtained. However, the apoprotein composition of circulatory high density lipoprotein was quantitatively different from the secretory product in the density 1.06-1.21 range. As measured by stained sodium dodecyl sulfate gel electrophoretic patterns, the arginine-rich protein was the major secretory apoprotein while the A-I protein was the major apoprotein in circulating high density lipoprotein. A very similar pattern was seen in perfusates of orotic acid-fatty livers. It was concluded that although the liver secrets lipoproteins in the high density class, circulatory high density lipoprotein is largely a product of catabolic processes.     

Influence of dietary selenium on the mutagenic activity of perfusate and bile from rat liver, perfused with 1,1-dimethylhydrazine

The mutagenic effect of 1,1-dimethylhydrazine (UDMH) was studied in the liver perfusion/cell culture system. Male Wistar rats, fed a selenium-deficient diet with or without selenium supplementation in the drinking water, were used as liver donors. UDMH caused an increased mutation frequency in Chinese hamster V79 cells exposed in the perfusate. The effect was statistically significant with both selenium-deficient and selenium-supplemented livers. With selenium-deficient livers, a significant mutagenic effect was also obtained when V79 cells were treated with bile collected after the administration of UDMH. Bile flow and bile acid excretion were not affected by UDMH treatment of selenium-deficient or selenium-supplemented livers. There was a tendency towards reduced C-oxygenation of N,N-dimethylaniline in microsomes from selenium-deficient livers perfused with UDMH. The lactate/pyruvate ratio in the perfusate was increased by UDMH, the effect being more pronounced with selenium-deficient than selenium-supplemented livers.     

Amino acid metabolism by perfused rat hindquarter. Effects of insulin, leucine and 2-chloro-4-methylvalerate.

Hindquarters from starved rats were perfused without substrates but in the presence of an O2- and CO2-carrying perfluorocarbon emulsion to evaluate principally the metabolism of individual endogenous and protein-derived amino acids by this muscle preparation. This experimental model was shown, by a battery of metabolite measurements, to maintain cellular homoeostasis for at least 2h. The net appearance of most amino acids closely approximated their frequency of occurrence in muscle proteins, showing that they are not significantly metabolized. Exceptions were the branched-chain amino acids, methionine and those amino acids that are interconvertible with intermediates of the citrate cycle and pyruvate through coupled transaminations. The evidence indicates that only valine, isoleucine, aspartate and probably methionine can be catabolized by skeletal muscle to provide carbon precursors for glutamate/glutamine and alanine that are formed de novo by protein-catabolic muscle. The protein-sparing effects of insulin and leucine were confirmed. Although each decreased proteolysis and the net appearance of free amino acids, they were generally without effect on the ratios of amino acids formed. 2-Chloro-4-methylvalerate selectively stimulated the removal rate for the branched-chain amino acids, confirming the idea that the branched-chain oxo acid dehydrogenase normally limits the rate of their oxidation by muscle. It is also concluded that, since alanine was not formed in excess of that found in muscle proteins when no glucose was added as substrate, the excess of alanine (carbon) released from muscles in other studies is derived to a large extent, but not exclusively, from preformed carbohydrate.     

The isolated perfused rat liver: standardization of a time-honoured model

For many years, the isolated perfused rat liver (IPRL) model has been used to investigate the physiology and pathophysiology of the rat liver. This in vitro model provides the opportunity to assess cellular injury and liver function in an isolated setting. This review offers an update of recent developments regarding the IPRL set-up as well as the viability parameters that are used, with regards to liver preservation and ischaemia and reperfusion mechanisms.A review of the literature was performed into studies regarding liver preservation or liver ischaemia and reperfusion. An overview of the literature is given with particular emphasis on perfusate type and volume, reperfusion pressure, flow, temperature, duration of perfusion, oxygenation and on applicable viability parameters (liver damage and function).The choice of IPRL set-up depends on the question examined and on the parameters of interest. A standard technique is cannulation of the portal vein, bile duct and caval vein with pressure-controlled perfusion at 20 cm H2O (15 mmHg) to reach a perfusion flow of approximately 3 mL/min/g liver weight. The preferred perfusion solution is Krebs-Henseleit buffer, without albumin. The usual volume is 150-300 cm3, oxygenated to a pO2 of more than 500 mmHg. The temperature of the perfusate is maintained at 37 degrees C. Standardized markers should be used to allow comparison with other experiments.