Pulmonary artery smooth muscle cells from chronically hypoxic neonatal calves retain fetal-like and acquire new growth properties.

Growth properties retained and acquired by immature pulmonary artery (PA) smooth muscle cells (SMC) in vivo after chronic exposure to hypoxia and the mechanisms that regulate hypoxia-induced change in proliferative phenotype are not known. We tested the hypothesis that PA SMC from neonatal calves exposed to hypoxia after birth would both retain fetal-like and acquire new growth characteristics and that these changes would be at least partially dependent on protein kinase C (PKC), a key proproliferative signal transduction pathway. Like fetal cells, PA SMC from hypoxic calves grew faster in the presence and absence of serum and were more responsive to insulin-like growth factor I and platelet-derived growth factor-BB than control neonatal and adult cells. PA SMC from hypoxic calves also acquired other growth properties (i.e., including increased hypoxic growth after PKC activation) that were new compared with those observed for fetal cells. The proliferative response to hypoxia was first detectable in the neonatal period and was further increased in cells from hypoxic calves. SMC from fetuses and hypoxic calves were more susceptible to the growth-inhibiting effects of PKC antagonists (dihydrosphingosine and calphostin C) than control neonatal and adult cells. To test if the Ca(2+)-dependent isozymes of PKC were uniquely important in the developmental and acquired growth changes observed, the antagonistic effect of the specific, but isozyme nonselective, PKC inhibitor Ro-81-8220 was then compared with GF-109203X, a structural analog with relative specificity for the Ca(2+)-dependent isozymes of PKC (alpha and beta in PA SMC). The faster growing PA SMC from bovine fetuses and hypoxia-exposed calves again demonstrated greater growth inhibition in response to both inhibitors. GF-109203X was equipotent to Ro-31-8220, and its antiproliferative effects were shown to not be due to an increase in apoptosis. Phorbol ester-induced PKC downregulation, another inhibitor strategy that selectively depletes bovine PA SMC of PKC-alpha, but not -beta, mimicked the antiproliferative effects of GF-109203X. Whole cellular PKC catalytic activity paralleled the pattern of peptide-induced growth and susceptibility to PKC inhibition. These results suggest that PA SMC from hypoxia-exposed neonatal calves retain enhanced fetal-like proliferative capacity and acquire new growth properties that are at least partially dependent on the Ca(2+)-regulated isozymes of PKC and in particular PKC-alpha.

Selected isozymes of PKC contribute to augmented growth of fetal and neonatal bovine PA adventitial fibroblasts.

We sought to determine which isozymes of protein kinase C (PKC) contribute to the increased proliferation of immature bovine pulmonary artery (PA) adventitial fibroblasts. Seven were identified in lysates of neonatal PA fibroblasts by Western blot: three Ca2+ dependent (alpha, beta I, and beta II) and four Ca2+ independent (delta, epsilon, zeta, and mu). Four isozymes (gamma, eta, theta, and iota) were not detected in fibroblasts isolated at any developmental stage. Of the seven detected isozymes, only PKC-alpha and -beta II protein levels were higher in fetal and neonatal cells compared with adult fibroblasts. Their role in the enhanced growth of immature fibroblasts was then evaluated. The isozyme nonselective PKC inhibitor Ro-31-8220 was first compared with GF-109203X, a structural analog of Ro-31-8220 with relative specificity for the Ca(2+)-dependent isozymes of PKC. GF-109203X selectively inhibited the growth of immature cells and was nearly as potent as Ro-31-8220. Go-6976, a more specific inhibitor of the Ca(2+)-dependent isozymes, mimicked the antiproliferative effect of GF-109203X. PKC downregulation with 1 microM phorbol 12-myristate 13-acetate had the same selective antiproliferative effect on immature fibroblasts as GF-109203X and Go-6976. The protein levels of PKC-alpha and -beta II, but not of PKC-beta I, were completely degraded in response to phorbol 12-myristate 13-acetate pretreatment. These results suggest that PKC-alpha and -beta II are important in the augmented growth of immature bovine PA adventitial fibroblasts.

Overexpression of endothelin-1 and enhanced growth of pulmonary artery smooth muscle cells from fawn-hooded rats.

Increased production of endothelin-1 (ET-1) has been detected in lungs of fawn-hooded rats (FHR) with idiopathic pulmonary hypertension. Accelerated pulmonary artery (PA) smooth muscle cell (SMC) proliferation contributes to vascular remodeling in these rats. We hypothesized that PA SMC would be an important site of enhanced ET-1 expression in FHR lung, that these SMC would have increased growth compared with cells from a normotensive strain, and that this locally produced ET-1 would contribute to the increased growth of these cells. We found that isolated FHR PASMC overexpressed preproET-1 mRNA and produced more ET-1 peptide compared with cells from normotensive Sprague-Dawley control rats (SDR). PA SMC from FHR had increased growth compared with control cells under conditions of serum withdrawal (0.1%), submaximal serum stimulation (0.3%; a condition previously found to be required for detection of growth in response to the comitogen, ET-1), and maximal serum stimulation (10%). Enhanced growth of FHR PA SMC in the presence of 0.3% serum, but not under the other test conditions, was inhibited by the ETA receptor antagonist, BQ-123. In summary, PA SMC from rats with idiopathic pulmonary hypertension overproduce ET-1. This overproduction contributes to the enhanced growth of FHR PA SMC in the presence of 0.3% serum. These cells also possess other unique growth characteristics that are independent of ET-1. Together, these ET-1-dependent and -independent growth properties likely contribute to the hyperplasia of FHR PA SMC found in vivo.

Carnitine delays rat skeletal muscle fatigue in vitro.

Carnitine has been used to enhance human exercise performance. To test the hypothesis that carnitine can directly modify skeletal muscle function, fatigue of isolated rat skeletal muscle strips was studied in vitro. Carnitine (10 mM) did not modify the initial force of soleus contraction. The time over which force declined by 50% during repetitive electrical stimulation of the soleus muscle (fiber type I) was prolonged 25% in the presence of 10 mM carnitine. In contrast, carnitine had no effect on the fatigue of extensor digitorum longus muscle strips (fiber type II). The beneficial effect of carnitine on soleus muscle strips was not observed if the routine 30-min preincubation in the presence of carnitine was decreased to 5 min; it was associated with a five- to sixfold increase in muscle total carnitine content and a 50-150% increase in muscle long-chain acylcarnitine content. Carnitine did not consistently modify lactate accumulation or glycogen depletion during the fatigue protocol. Incubation with propionyl-L-carnitine resulted in a decreased initial force of contraction and a delay in reaching maximal contractile force. Thus, carnitine can directly improve the fatigue characteristics of muscles enriched in type I fibers.

Rat hepatic coenzyme A is redistributed in response to mitochondrial acyl-coenzyme A accumulation.

Coenzyme A without an acyl-thioester (CoASH) is required for numerous cellular reactions, and sequestration of CoASH as acyl-CoAs may impair metabolic function. Increased total CoA protects the cell from acyl-CoA accumulation, and enhanced CoA biosynthesis may represent a compensatory response in metabolic disease. To test the hypothesis that cellular CoA is redistributed from the cytosol to the mitochondria in response to mitochondrial acyl-CoA accretion, the subcellular distribution of hepatic CoA was determined by differential centrifugation and measurement of the mitochondrial marker enzyme citrate synthase. Liver from control, clofibrate-treated and hydroxycobalamin[c-lactam] (HCCL)-treated rats were used. Clofibrate increased total hepatic CoA concentration 2.2-fold, whereas HCCL (which causes inhibition of L-methylmalonyl-CoA mutase and consequent propionyl- and methylmalonyl-CoA accumulation) increased it threefold. However, clofibrate did not affect the percentage of total CoA in the mitochondria (control: 44 +/- 3%, clofibrate: 49 +/- 5%), and HCCL-treatment induced a marked redistribution of CoA into the mitochondria (HCCL: 78 +/- 8%). Redistribution of total CoA was also induced acutely by incubation of hepatocytes from control rats with 10 mmol/L propionate. Thus, redistribution of the cellular CoA pool can help maintain CoASH availability as mitochondrial acyl-CoA accumulation occurs and may be an important compensatory response to metabolic injury.

Metabolic effects of pivalate in isolated rat hepatocytes.

Pivalate (trimethylacetic acid) administration in humans or rat has been reported to cause metabolic changes and increased urinary carnitine excretion secondary to pivaloylcarnitine generation. As pivaloylcarnitine formation is dependent on intracellular activation of pivalate, the effects of pivalate on cellular coenzyme A and acyl-CoA contents and oxidative metabolism were defined using isolated rat hepatocytes. During incubations with pivalate (1.0 mM), hepatocyte coenzyme A content fell to less than 0.05 nmol/10(6) cells (vs 0.97 nmol/10(6) cells in the absence of pivalate) as pivaloyl-CoA accumulated. Pivalate (5 mM) inhibited 14CO2 generation from 10 mM [1-14C]pyruvate by 34%, but had no effect on 0.8 mM [1-14C]palmitate oxidation. Pivaloyl-CoA was a substrate for hepatocyte carnitine acyltransferase activity, but supported acylcarnitine formation at rates only 10-20% of those observed with equimolar acetyl-CoA or isovaleryl-CoA as substrates. Thus, hepatocytes activate pivalate to pivaloyl-CoA, which can then be used as a substrate for pivaloylcarnitine formation. The sequestration of hepatocyte coenzyme A as pivaloyl-CoA is associated with inhibition of pyruvate oxidation. As with other organic carboxylic acids, activation of pivalate to the coenzyme A thioester is an important aspect in the biochemical toxicology of the compound.

Effect of clofibrate treatment on hepatic prostaglandin catabolism and action.

Prostaglandins (PG) modulate hepatocyte glucose and lipid metabolism. Hepatocytes rapidly metabolize PG via beta-oxidation, terminating PG action. Clofibrate induces hepatic peroxisomal beta-oxidative activity, for which PG are substrates. To determine the effect of clofibrate-treatment on liver PG metabolism and action, hepatocytes were isolated from rats maintained on a control or clofibrate-supplemented (0.5%) diet for 7 to 9 days. Rates of PG catabolism were determined by high performance liquid chromatography resolution of [3H]PG from [3H]metabolites. Clofibrate treatment enhanced the rates of PGE2, PGF2, and PGD2 degradation by 85%, 278% and 137%, respectively. Rates of PG degradation were correlated with hepatocyte carnitine acetyltransferase activity, a marker of peroxisomal proliferation. Further evidence of enhanced hepatocyte peroxisomal beta-oxidation of PG after clofibrate-treatment was obtained by confirming loss of the 1-position carbon from [1-14C]PGE2 during PGE2 metabolism and failure of the carnitine acyltransferase inhibitor acetyl-DL-aminocarnitine to inhibit PGE2 metabolism. Associated with the faster degradation of PGE2 by hepatocytes from clofibrate-treated rats was loss of inhibition of hepatocyte glucagon-stimulated glycogenolysis by exogenous PGE2. Thus, clofibrate's induction of peroxisomal beta-oxidation is associated with accelerated catabolism of PG and decreased PG action. Alterations in PG breakdown provide a mechanism for modulating hepatic PG effects.

Effect of exogenous carnitine on carnitine homeostasis in the rat.

The interaction of exogenous carnitine with whole body carnitine homeostasis was characterized in the rat. Carnitine was administered in pharmacologic doses (0-33.3 mumols/100 g body weight) by bolus, intravenous injection, and plasma, urine, liver, skeletal muscle and heart content of carnitine and acylcarnitines quantitated over a 48 h period. Pre-injection urinary carnitine excretion was circadian as excretion rates were increased 2-fold during the lights-off cycle as compared with the lights-on cycle. Following carnitine administration, there was an increase in urinary total carnitine excretion which accounted for approx. 60% of the administered carnitine at doses above 8.3 mumols/100 g body weight. Urinary acylcarnitine excretion was increased following carnitine administration in a dose-dependent fashion. During the 24 h following administration of 16.7 mumols [14C]carnitine/100 g body weight, urinary carnitine specific activity averaged only 72 +/- 4% of the injection solution specific activity. This dilution of the [14C]carnitine specific activity suggests that endogenous carnitine contributed to the increased net urinary carnitine excretion following carnitine administration. 5 min after administration of 16.7 mumol carnitine/100 g body weight approx. 80% of the injected carnitine was in the extracellular fluid compartment and 5% in the liver. Plasma, liver and soleus total carnitine contents were increased 6 h after administration of 16.7 mumols carnitine/100 g body weight. 6 h post-administration, 37% of the dose was recovered in the urine, 12% remained in the extracellular compartment, 9% was in the liver and 22% was distributed in the skeletal muscle. In liver and plasma, short chain acylcarnitine content was increased 5 min and 6 h post injection as compared with controls. Plasma, liver, skeletal muscle and heart carnitine contents were not different from control levels 48 h after carnitine administration. The results demonstrate that single, bolus administration of carnitine is effective in increasing urinary acylcarnitine elimination. While liver carnitine content is doubled for at least 6 h following carnitine administration, skeletal muscle and heart carnitine pools are only modestly perturbed following a single intravenous carnitine dose. The dilution of [14C]carnitine specific activity in the urine of treated animals suggests that tissue-blood carnitine or acylcarnitine exchange systems contribute to overall carnitine homeostasis following carnitine administration.

Effect of hydroxycobalamin[c-lactam] on propionate and carnitine metabolism in the rat.

The administration in vivo of the cobalamin analogue hydroxycobalamin[c-lactam] inhibits hepatic L-methylmalonyl-CoA mutase activity. The current studies characterize in vivo and in vitro the hydroxycobalamin[c-lactam]-treated rat as a model of disordered propionate and methylmalonic acid metabolism. Treatment of rats with hydroxycobalamin[c-lactam] (2 micrograms/h by osmotic minipump) increased urinary methylmalonic acid excretion from 0.55 mumol/day to 390 mumol/day after 2 weeks. Hydroxycobalamin[c-lactam] treatment was associated with increased urinary propionylcarnitine excretion and increased short-chain acylcarnitine concentrations in plasma and liver. Hepatocytes isolated from cobalamin-analogue-treated rats metabolized propionate (1.0 mM) to CO2 and glucose at rates which were only 18% and 1% respectively of those observed in hepatocytes from control (saline-treated) rats. In contrast, rates of pyruvate and palmitate oxidation were higher than control in hepatocytes from the hydroxycobalamin[c-lactam]-treated rats. In hepatocytes from hydroxycobalamin[c-lactam]-treated rats, propionylcarnitine was the dominant product generated from propionate when carnitine (10 mM) was present. The addition of carnitine thus resulted in a 4-fold increase in total propionate utilization under these conditions. Hepatocytes from hydroxycobalamin[c-lactam]-treated rats were more sensitive than control hepatocytes to inhibition of palmitate oxidation by propionate. This inhibition of palmitate oxidation was partially reversed by addition of carnitine. Thus hydroxycobalamin[c-lactam] treatment in vivo rapidly causes a severe defect in propionate metabolism. The consequences of this metabolic defect in vivo and in vitro are those predicted on the basis of propionyl-CoA and methylmalonyl-CoA accumulation. The cobalamin-analogue-treated rat provides a useful model for studying metabolism under conditions of a metabolic defect causing acyl-CoA accretion.

Effect of carnitine on propionate metabolism in the vitamin B-12--deficient rat.

Acyl-CoA thioesters are generated during the oxidation of organic acids in mammalian systems. Vitamin B-12 deficiency is associated with decreased L-methylmalonyl-CoA mutase activity, and consequent accumulation of propionyl-CoA and methylmalonyl-CoA. The formation of propionylcarnitine from propionyl-CoA and carnitine provides an alternative pathway to remove propionyl-CoA from cells. Hepatocytes isolated from vitamin B-12--deficient rats metabolized propionate (1 mM) to CO2 and glucose at only 23% and 12%, respectively, of the rates observed in hepatocytes from control animals. In contrast, no difference was seen in rates of pyruvate metabolism by hepatocytes from control and vitamin B-12--deficient rats. Addition of carnitine (10 mM) to hepatocyte incubations increased the rate of propionylcarnitine formation 10- to 20-fold without altering conversion of propionate to CO2 or glucose. The rate of propionylcarnitine formation was not affected by vitamin B-12 deficiency. When carnitine (10 mM) was added, propionylcarnitine generation represented 65-71% of total propionate utilization in hepatocytes isolated from vitamin B-12--deficient rats. Gluconeogenesis from [1-14C]pyruvate was inhibited by 1 mM propionate in hepatocytes from vitamin B-12--deficient rats. No effect of 1 mM propionate on glucose formation from pyruvate was seen using hepatocytes from control rats. Intraperitoneal administration of L-carnitine resulted in a significant increase in urinary propionylcarnitine excretion from vitamin B-12--deficient rats, but not from control animals. The results demonstrate that exogenous carnitine can significantly enhance propionyl-group utilization via the formation of acylcarnitines under the conditions of impaired acyl-CoA metabolism associated with vitamin B-12 deficiency.