Cloning, sequencing and functional expression of a cDNA encoding a NADP-dependent malic enzyme from human liver

This work reports the structure of a cDNA (ME) encoding a human malic enzyme (ME) (malate NADP oxidoreductase, EC 1.1.1.40) elucidated by joining several overlapping fragments amplified by PCR from human hepatic cDNA or from cDNA libraries. The full-length cDNA has an open reading frame (ORF) of 1719 bp that encodes a 572-amino-acid protein of 64 113 Da, similar to the native monomeric, cytosolic, NADP-dependent ME isolated from human liver. The comparison of the structure of this cDNA with that of the human mitochondrial NAD(P)-dependent ME (EC 1.1.1.39) shows a homology of 63%, suggesting that these two forms originated from the same gene. The expression of the cDNA in Escherichia coli as a translational fusion (glutathione S-transferase::ME) protein yielded a product of the predicted mass. The recombinant protein shows NADP-dependent malate oxidoreductase activity and is virtually inactive with NAD. It also shows other distinct features of the native cytosolic NADP-dependent ME, like Mn2+ dependence, similar substrate (Km = 117 microM) and cofactor affinity (Km = 2 microM) constants, and a lack of allosteric regulation. In human proliferative cells, the NADP-dependent ME activity is poorly expressed and barely inducible by thyroid hormones.

Molecular cloning, sequencing and expression of a cDNA encoding a human liver NAD-dependent alpha-glycerol-3-phosphate dehydrogenase

This work reports the primary nucleotide structure and in vitro translation of a cDNA, expressed by a gene mapping on chromosome 12, that encodes a human hepatic alpha-glycerol-3-phosphate dehydrogenase (L-glycerol-3-phosphate:NAD oxidoreductase, E.C. 1.1.1.8). The 1413 bp cDNA comprises an ORF of 1050 bp that encodes a 349 amino acid protein of 37.5 kDa. Northern blot analysis of poly(A)+ mRNA from human liver showed three transcripts, while from human placenta only two transcripts were detected.

Role of amino acid-induced changes in ion fluxes in the regulation of hepatic protein synthesis

Alanine is a powerful stimulator of hepatic protein synthesis whose mechanism of action has not yet been ascertained. The present work aimed to elucidate whether rate changes in ion fluxes accompanying the transport of this amino acid could play a role in the stimulation of protein synthesis. In perfused livers, the utilization of alanine produced a net uptake of K+ of 1.5 mumol/min/liver, a progressively increasing efflux of Ca2+ to reach a maximum of 0.9 mumol/min/liver, and alkalization of the extracellular medium. Inhibition of Na+/K+ exchange by ouabain reversed only the uptake of K+, indicating that this is the main way for the efflux of Na+ cotransported with alanine. In isolated hepatocytes, the uptake of alanine increased the intracellular content of K+ and the cell volume. The following observations suggest that these changes, and not an increased intracellular concentration of Na+, are associated with the stimulation of protein synthesis: 1) Ouabain inhibited the alanine stimulation of L-[3H]-valine incorporation into protein without altering the basal rate of protein labeling; 2) ouabain had no effects on alanine uptake indicating that Na+ influx is not involved in the alanine stimulation of protein synthesis; 3) disruption of Na+ gradient across the plasma membrane by specific ionophores, monensin and gramicidin D, inhibited both basal and alanine-stimulated protein synthesis, but substitution of extracellular Na+ by K+ did not prevent the stimulatory action of alanine. The observation that hypotonic buffer enhanced protein synthesis to the same degree than alanine in liver cells indicates that alanine-induced cell swelling could be sufficient to stimulate protein synthesis.

Impaired protein kinase C activation is associated with decreased hepatic alpha 1-adrenoreceptor responsiveness in adrenalectomized rats

The present work aimed to study the influence of corticosteroids on the alpha 1-adrenoreceptor-induced activation of hepatic metabolic functions. The experiments were performed in a nonrecirculating liver perfusion system featuring continuous monitoring of pO2, pCa2+, Ca2+, pH, and portal pressure. The alpha 1-adrenergic-induced stimulation of respiration, H+ and Ca2+ release, glycogen breakdown, and gluconeogenesis, were diminished in livers from adrenalectomized animals. The normal liver responsiveness was restored on administration of exogenous corticosteroids but not mineralocorticoids. The following observations support the conclusion that corticosteroids control a hepatocyte-specific early postreceptor step in the alpha 1-adrenergic signaling pathway: 1) the alpha 1-adrenergic stimulation of vascular smooth muscle contraction was not impaired by corticosteroid deficiency; 2) the alpha 1-adrenoreceptor ligand-binding affinity does not seem to be altered by adrenalectomy; 3) the alpha 1-adrenergic-induced intracellular alkalosis, protein kinase C activation, and Ca2+ mobilization were diminished in hepatocytes from adrenalectomized rats, indicating that both Ca(2+)-dependent and -independent processes were altered; and 4) non-receptor-mediated homeostatic mechanisms of metabolic or intracellular pH control were not impaired by adrenalectomy.

Loss of fatty acid control of gluconeogenesis and PDH complex flux in adrenalectomized rats

This work aimed to determine the role played by the adrenal gland in the fatty acid control of gluconeogenesis in isolated perfused rat livers. The gluconeogenic substrate concentration responses were not altered in adrenalectomized (ADX) rats. This observation indicates that glucocorticoids are not essential to maintain normal basal gluconeogenic rates. In contrast, fatty acid failed to stimulate gluconeogenesis from lactate and elicited attenuated stimulation with pyruvate as substrate in livers from ADX rats. Fatty acid-induced stimulation of respiration and ketone body production were similar in control and ADX rats. Thus the diminished responsiveness of the gluconeogenic pathway to fatty acid cannot be the result of different rates of energy production and/or generation of reducing power. Fatty acids did not inhibit pyruvate decarboxylation in livers from ADX rats. Even though mitochondria isolated from livers of ADX rats showed normal basal rates of pyruvate metabolism, fatty acids failed to inhibit pyruvate decarboxylation and the activity of the pyruvate dehydrogenase complex. This novel observation of the glucocorticoid effect in controlling the pyruvate dehydrogenase complex responsiveness indicates that the mitochondrial partitioning of pyruvate between carboxylation and decarboxylation reactions may be altered in livers from ADX rats. We propose that the diminished effect of fatty acid in stimulating gluconeogenesis in livers from ADX rats is the result of a limited pyruvate availability for the carboxylase reaction due to a lack of inhibition of flux through the pyruvate dehydrogenase complex.

Functional coupling of Na+/H+ and Na+/Ca2+ exchangers in the alpha 1-adrenoreceptor-mediated activation of hepatic metabolism

The purpose of this study was to characterize the role of ions other than Ca2+ in hepatic responses to alpha 1-adrenergic stimulation. We report that the alpha 1-adrenoreceptor activation of hepatic functions is accompanied by extracellular acidification and an increase in intracellular pH. These effects are dependent on extracellular Na+ concentration and are inhibited by the Na+/H+ antiporter blocker 5-(N-ethyl-N-isopropyl) amiloride under conditions that preclude antagonistic effects on agonist binding. Thus, the activation of plasma membrane Na+/H+ exchange is an essential feature of the hepatic alpha-adrenoreceptor-coupled signaling pathway. The following observations indicate that the sustained hepatic alpha 1-adrenergic actions rely on a functional coupling between the plasma membrane Na+/H+ and Na+/Ca2+ exchangers, resulting in the stimulation of Ca2+ influx. 1) Inhibition of the Na+/K(+)-ATPase does not prevent the alpha 1-adrenergic effects. However, alpha 1-adrenoreceptor stimulation fails to induce intracellular alkalinization and to acidify the extracellular medium in the absence of extracellular Ca2+. 2) A non-receptor-induced increase in intracellular Na+ concentration, caused by the ionophore monensin, stimulates Ca2+ influx and increases vascular resistance. 3) Inhibition of Na+/Ca2+ exchange prevents, in a concentration-dependent manner, most of the alpha 1-agonist-induced responses. 4) The actions of Ca(2+)-mobilizing vasoactive peptide receptors or alpha 2-adrenoreceptors, which produce neither sustained extracellular acidification nor release of Ca2+, are insensitive to Na+/H+ exchange blockers.

Characterization of the alpha 1-adrenoceptor-mediated responses in perfused rat liver

The present work aimed to further characterise the hepatic alpha 1-adrenergic actions by studying the influence of nutritional status and/or extracellular medium composition in the alpha 1-adrenoceptor-induced responses. The experiments were performed in a non-recirculating liver-perfusion system featuring continuous monitoring of vascular resistance, as well as the effluent perfusate changes in pO2, pCa2+, pK+ and pH. The alpha 1-adrenoceptor activation produced biphasic responses to most parameters studied. The acute phase lasted for about 3 min and it was followed by a phase of sustained stimulation that lasted as long as the receptor activation was maintained. Our data indicate that there is not a single pattern of alpha 1-adrenergic responses but variable patterns depending on the nutritional status and the experimental conditions. Gluconeogenic substrates alone produced reciprocal changes in the outflow perfusate pH and Ca2+ activity. The magnitude of these changes indicates that the diversity of alpha 1-adrenoceptor responses are the result of the superposed effects of different rates of substrates and/or metabolites transport. The sustained alpha 1-adrenoceptor stimulation produced extracellular acidification and increases in respiration, vascular resistance and Ca2+ release. These responses required physiological extracellular [Ca2+]. At low extracellular [Ca2+], the alpha 1-adrenoceptor activation failed to acidify the extracellular medium, suggesting that receptor-induced H+ efflux demands normal rates of Ca2+ influx. The correlation between alpha 1-adrenergic-induced increase in O2 uptake and Ca2+ release indicates that the increased energy production can be accounted for by the energy cost of Ca2+ release. The alpha 1-agonist concentration-response studies have shown significant differences in the [alpha 1-agonist]0.5 for each type of response, suggesting the existence of multiple alpha 1-adrenoceptor-coupled signal-transduction pathways.

Reciprocal changes in gluconeogenesis and ureagenesis induced by fatty acid oxidation

Fatty acids produced a stimulation of gluconeogenesis and either inhibition or no effect on ureagenesis in livers perfused with gluconeogenic substrates and having NH4Cl plus ornithine as the nitrogen source. This finding indicates that stimulation of flux through pyruvate carboxylase is not sufficient to enhance urea production from ammonia. The metabolic action of fatty acids showed the following characteristics: (1) it was concentration-dependent, showing saturation-type kinetics similar to those described for fatty acid oxidation; (2) the stimulatory action on gluconeogenesis was constant and independent of NH4Cl concentration, whereas the inhibition of ureagenesis was variable and dependent on NH4Cl concentration and the degree of reduction of the gluconeogenic substrate; and (3) fatty acids produced apparent reciprocal changes in the state of reduction of the cytosolic and mitochondrial NAD systems. Fatty acid oxidation exerted its effect mainly, if not exclusively, by preventing the gluconeogenic substrate-induced stimulation of ureagenesis. Fatty acids also inhibited ureagenesis without stimulating gluconeogenesis (lactate < 1 mmol/L), ruling out a limiting energy availability as the cause of the inhibition. One or both of the following two mechanisms seem to account for the fatty acid-induced inhibition of ureagenesis from NH4Cl. First, a decreased uptake of ornithine, and second, decreased flux through pyruvate dehydrogenase and probably other NAD(P)-linked mitochondrial dehydrogenases. The correlation found between the ability of fatty acids to inhibit ureagenesis and the state of activation of pyruvate dehydrogenase supports the latter point.

Role of protein kinase-C in the alpha 1-adrenoceptor-mediated responses of perfused rat liver

The present work aimed to determine the role played by protein kinase-C (PKC) in the alpha 1-adrenoceptor-induced activation of hepatic metabolism. The following observations indicate that activation of PKC is a condition necessary for alpha 1-adrenoceptor activation of hepatic functions, but not sufficient to mimic the receptor-mediated effects in the absence of external physiological stimuli. 1) alpha 1-Adrenoceptor activation promoted the translocation of PKC from the cytosol to its active form in the plasma membrane. 2) Activation of PKC by the phorbol ester 12-myristate 13-acetate or exogenous diacylglycerols or by elevation of endogenous levels of diacylglycerols by inhibiting diacylglycerol kinase mimicked the alpha 1-adrenoceptor-mediated actions. However, the time course and magnitude of the nonreceptor responses differ from those mediated by alpha 1-adrenoceptor activation. In addition, nonreceptor-mediated activation of PKC decreased the alpha 1-adrenoceptor responsiveness. 3) Inhibition of PKC by either H-7 [1-(5-isoquinolinilsulfonyl)2-methylpiperazine] or staurosporine inhibited all of the alpha 1-adrenoceptor-induced responses, except gluconeogenesis. The vasopressin effects were not inhibited by H-7, indicating that PKC activation is a distinct feature of the hepatic alpha 1-adrenoceptor activation that is not shared by all the Ca(2+)-mobilizing agonists. The diacylglycerol-PKC branch of the alpha 1-adrenoceptor signaling pathway seems to control the sustained phase of stimulation of hepatic functions. In these studies we have also observed that phorbol 12-myristate 13-acetate produces a concentration-dependent inhibition of hepatic respiration. However, decreased energy availability does not seem to be the cause of its action to decrease alpha 1-adrenoceptor responsiveness.

Interrelationships between ureogenesis and gluconeogenesis in perfused rat liver

Stimulation of ureogenesis by ornithine and/or NH4Cl inhibited gluconeogenesis from lactate but not from equimolar concentrations of pyruvate in perfused rat liver. Neither a shortage of energy nor a decrease in alpha-ketoglutarate availability seems to be responsible for this inhibition. With lactate as substrate the extracellular concentration of pyruvate attained was approximately equal to 0.15 mM that assuming reflects its cytosolic concentration it would be limiting for its mitochondrial transport. Stimulation of ureogenesis from NH4Cl enhances flux through pyruvate dehydrogenase. Furthermore, activation of pyruvate dehydrogenase by dichloroacetate led to stimulation of ureogenesis and inhibition of glucose production. Conversely, inhibition of pyruvate dehydrogenase flux by fatty acid enhanced glucose production and inhibited ureogenesis. Thus, ornithine and/or NH4Cl seem to inhibit lactate to glucose flux by shifting the mitochondrial partitioning of pyruvate from carboxylation towards decarboxylation with the result of a decreased oxaloacetate formation. Gluconeogenic substrates enhanced the hepatic uptake of ornithine. However, no correlation seems to exist between the uptake of ornithine, ornithine-induced stimulation of ureogenesis and total rates of urea production. Ornithine produced a concentration-dependent acidification of the hepatic outflow perfusate, suggesting that it may be transported in exchange for H+.

Pertussis toxin inhibition of alpha 1-adrenergic or vasopressin-induced Ca2+ fluxes in rat liver. Selective inhibition of the alpha 1-adrenergic receptor-coupled metabolic activation

Pretreatment with pertussis toxin produced a impairment of the response to the alpha-adrenergic agonist phenylephrine in perfused isolated rat livers. The sustained phases of phenylephrine-induced increases in respiration, glucose mobilization, gluconeogenesis, vascular resistance, and efflux of H+ and Ca2+ were inhibited to variable degrees in livers from pertussis toxin-treated animals. The susceptibility of such a diversity of receptor-mediated effects suggests that a common, most likely early step(s) of the alpha 1-receptor-coupled signaling pathway may be regulated by a pertussis toxin-sensitive Gi protein(s) that appears to be involved in the control of the rate of these processes. The most significant effect of pertussis toxin has been to almost entirely prevent the phenylephrine-induced sustained release of Ca2+. Pertussis toxin also inhibited the vasopressin-mediated influx of Ca2+. These findings indicate that G proteins associated with receptor-operated calcium channels are a site of interaction of pertussis toxin. The following observations support the conclusion that pertussis toxin per se does not perturb the hepatic metabolism. Its effects are specifically linked to functional responses mediated by alpha 1-type adrenergic receptors: 1) polypeptide receptor-mediated metabolic effects, as those induced by vasopressin, were not affected by pertussis toxin; 2) non-receptor-mediated effects, such as fatty acid-induced stimulation of respiration and gluconeogenesis, were not impaired by pertussis toxin; and 3) neither the hepatic responses to alpha 2-(clonidine) nor to beta-(isoproterenol) adrenergic receptor agonists were altered in livers from pertussis toxin-treated rats. The differential effects of pertussis toxin in the metabolic actions of phenylephrine and vasopressin, in spite of apparently similar effects in perturbing their actions on Ca2+ fluxes, suggest that pertussis toxin-sensitive alpha 1-receptor-associated G protein(s) other than those controlling Ca2+ channels, were also specifically affected in the alpha 1-agonist-signaling pathway. The finding that increasing concentrations of phenylephrine were capable of overcoming these pertussis toxin actions indicates that alpha 1-adrenoreceptors' ligand affinity is controlled by Gi proteins.

Correlations of language abnormalities with localization of mutations in the beta-thyroid hormone receptor in 13 kindreds with generalized resistance to thyroid hormone: identification of four new mutations

Generalized resistance to thyroid hormone is an inherited disease characterized by unresponsiveness of pituitary and peripheral tissues to thyroid hormone. Genetic analysis of several kindreds linked this syndrome to the gene for the beta-form of the thyroid hormone receptor, and this led to the subsequent identification of various mutations in the ligand-binding domain of this receptor. In this region we now have found 4 new point mutations with reduced T3-binding affinities from separate kindreds by direct sequencing of polymerase chain reaction products. Similar to previously studied kindreds, the reduction in T3 binding of these four kindreds ranged from 2.5- to 5-fold, indicating that these are not neutral polymorphisms. Furthermore, the pattern of inheritance of these 4 kindreds is familial in 2, sporadic in 1, and unknown in 1. To date, 20 distinct mutations have been identified, of which 18 are clustered in 2 distinct topographical regions: 11 are within the tau i/dimerization subdomains of exon 9, and 7 are within the L2 subdomain of exon 10. The 4 newly identified mutations coupled to the 9 mutations our laboratory has previously identified provide new insights into the clinical aspects of generalized resistance to thyroid hormone. Kindreds with mutations in exon 9 compared with those in exon 10 have significantly more problems in language development, as manifested by articulation problems and/or wide discrepancies in verbal and performance IQs. Interestingly, marked variability in language deficiency as well as other clinical patterns were seen not only between kindreds but also within a kindred. Further identification and clinical correlations of new mutations will continue to enhance our understanding of the structure/function relationships and physiological role of the human thyroid hormone receptor.

On the mechanism of stimulation of ureagenesis by gluconeogenic substrates: role of pyruvate carboxylase

Gluconeogenic substrates, lactate or pyruvate, or ornithine produced 100% increase of urea synthesis from NH4Cl. The combined administration of ornithine and lactate (or pyruvate) produced more than additive effects, indicating that they acted at different steps in a potentiating manner. The uptake of ornithine was enhanced by gluconeogenic substrates. This finding may explain, at least in part, the stimulating effect of these substrates on ureagenesis from NH4Cl and ornithine. The gluconeogenic substrate-induced stimulation of ureagenesis from NH4Cl was still observed under conditions of reduced flux through pyruvate carboxylase, ruling out that their action was exclusively mediated by the anaplerotic effect of this enzyme. Pyruvate was a more potent stimulator of ureagenesis than lactate and its effect less sensitive to pyruvate carboxylase inhibition. These observations indicate that a correlation exists between stimulation of ureagenesis by gluconeogenic substrates and flux through pyruvate dehydrogenase. It is concluded that gluconeogenic substrates may stimulate ureagenesis from NH4Cl by 1) increasing intracellular ornithine availability and/or 2) enhancing flux through pyruvate dehydrogenase and consequently the tricarboxylic acid cycle activity.

Role of endogenous fatty acids in the control of hepatic gluconeogenesis

Inhibition of endogenous long chain fatty acids oxidation by tetradecylglycidate (TDGA) impeded gluconeogenesis from lactate or from low concentrations of pyruvate (less than 0.5 mM). The inhibitory effect of TDGA was overcome by medium and short chain fatty acid or by concentrations of pyruvate about 0.5 mM, but not by 10-fold higher concentrations of lactate. Despite decreased energy demand when gluconeogenesis was inhibited by TDGA, the pyruvate-induced increase in hepatic oxygen consumption was similar to the control, indicating that pyruvate transport across the mitochondrial membrane and/or its decarboxylation was not altered, and therefore can not be responsible for the inhibition of gluconeogenesis. Neither does a deficiency of acetyl-CoA explain the decrease in the gluconeogenic flux since high pyruvate loads (greater than 0.5 mM), beta-hydroxybutyrate or even ethanol was capable of overcoming the inhibitory effect of TDGA in the absence of significant changes in the hepatic content of acetyl-CoA. At low (less than 0.3 mM), presumably physiological, pyruvate concentrations, its rate of mitochondrial utilization is limited by the activity of the monocarboxylate transporter. Agents that reduced the mitochondrial NAD system, and therefore reduced flux through pyruvate dehydrogenase, like beta-hydroxybutyrate or ethanol, stimulated gluconeogenesis when fatty acid oxidation was inhibited. The latter observations indicate that the primary role of endogenous fatty acid, when substrate availability is limiting, is to spare mitochondrial pyruvate by decreasing its oxidation, and therefore shifting the partitioning between the carboxylation and decarboxylation reactions toward the former.

Effect of alanine supply on hepatic protein synthesis in animals maintained on a protein free diet

In contrast to what it is observed during starvation, animals maintained on a protein-free isocaloric diet showed an increase in the rate of hepatic peptide chain elongation as determined by measuring the ribosomal transit time in vivo. The loss of body nitrogen per se is insufficient to generate the signal(s) which arrests hepatic peptide chain elongation. This observation suggests that it is an increase in gluconeogenic demand, and not the negative nitrogen balance, which is implicated in determining reciprocal changes in the rate of protein synthesis. The rate of protein synthesis, as expressed per mg of DNA, does not change in protein deprived animals, while the RNA to DNA ratio decreased. These data also agree with a higher ribosomal efficiency at the elongation step. The animals maintained on a protein-free diet have a decreased hepatic content of protein and an increased concentration of valine, indicating an increased proteolysis. The enhanced rate of polypeptide elongation observed in animals kept on a protein-free diet was accompanied by decreases in the state of aggregation of polyribosomes and in the ability of liver extracts to form eIF-2 catalyzed ternary complexes. These observations suggest that the activity of the hepatic initiation factor in vivo may not be rate limiting. The administration of alanine in vivo to animals maintained on a protein-free diet showed a preferential effect in reaggregating polyribosomes. This action was neither accompanied by detectable effects on the rate of eIF-2 catalyzed ternary complexes formation nor by significant changes in the rate of elongation.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of seven novel mutations of the c-erbA beta gene in unrelated kindreds with generalized thyroid hormone resistance. Evidence for two "hot spot" regions of the ligand binding domain

Genetic analysis in our laboratory of families with generalized thyroid hormone resistance (GTHR) has demonstrated tight linkage with a locus, c-erbA beta, encoding a nuclear T3 receptor. Three point mutations and two deletions in this locus have previously been reported in affected individuals in unrelated families as potential molecular bases for this disorder. In the present study, we have used direct sequencing of polymerase chain reaction-amplified exons of the c-erbA beta gene to rapidly identify novel point mutations from seven previously uncharacterized kindreds with GTHR. Six single base substitutions and one single base insertion were identified and found to be clustered in two regions of exons 9 and 10 in the ligand binding domain of the receptor: in the distal ligand-binding subdomain L2 and across the juncture of the taui and dimerization subdomains. Reduction of T3-binding affinity in each of four mutations tested as well as segregation of all mutations to clinically affected individuals strongly supports the hypothesis that these changes are the cause of GTHR in these kindreds. In view of the diversity of clinical phenotypes manifested, the distinct topographic clustering of the mutations provides an invaluable genetic tool for the molecular dissection of thyroid receptor function.

On the mechanism of sodium 2-5-4 chlorophenylpentyloxirane-2-carboxylate (POCA) inhibition of hepatic gluconeogenesis

Inhibition of hepatic long chain fatty acid oxidation by 2-5-4 chlorophenylpentyloxirane-2-carboxylate (POCA) leads to decreased gluconeogenic rates from lactate or from low concentrations of pyruvate. The inhibitory effect is fully overcome by concentrations of pyruvate above 0.8 mM or by the simultaneous administration of a medium chain fatty acid. At low pyruvate availability the energy cost of gluconeogenesis is mainly supported by fatty acid oxidation and POCA-induced inhibition of glucose production is secondary to a decreased energy availability. This is supported by the following observations: (i) POCA decreases hepatic respiration and phosphorylation potential: (ii) the rate of pyruvate-induced respiration was the same regardless of whether gluconeogenesis was inhibited or not by POCA: and (iii) concentrations of pyruvate above 0.8 mM, at which gluconeogenesis is not inhibited, prevented the POCA-induced decrease in the phosphorylation potential. It is concluded that inhibition of long chain fatty acid oxidation by POCA leads to a switch of energy fuel, and results in the oxidation of more pyruvate to meet the cellular energy demands. When pyruvate availability is low and thus, presumably, its mitochondrial transport restricted, pyruvate carboxylation most probably becomes limiting as a result of the increased flux through pyruvate dehydrogenase, in the presence of POCA.

Role of fatty acid in the control of protein synthesis in liver cells

Concentrations of oleate (0.2-1 mM) within the physiological range of plasma free fatty acids induced a dose dependent statistically significant inhibition of protein labelling in isolated liver cells. The inhibitory effect was as high as 50% and it was not impeded when long chain fatty acid oxidation was prevented. Experiments carried out with hepatocytes from 48 h fasted rats, incubated in the absence of any exogenous energy source, show that the inhibition of endogenous long chain fatty acid oxidation induced a decreased rate of protein synthesis apparently related to changes in the cellular energy state. It is concluded that fatty acids play a dual role in the regulation of protein synthesis in liver cells: 1. endogenous fatty acids appear to be the main energy fuel for protein synthesis when no other exogenous substrate is present and the carbohydrate stores are low; 2. exogenous fatty acids seem to control protein synthesis by interacting with some key regulatory step.

Ca2(+)-fatty acid interaction in the control of hepatic gluconeogenesis

Calcium depletion induced by perfusing livers with calcium-free buffer did not alter the rates of basal glucose production from pyruvate or from increasing concentrations of lactate. However, calcium deficiency selectively prevented the fatty acid-induced stimulation of gluconeogenesis from lactate. This effect is not related to the higher NAD redox potential consistently observed in Ca2(+)-deficient livers. On the other hand, octanoate was capable of inducing dose-dependent changes in the [pyruvate]0.5 in calcium-depleted livers perfused with lactate, ruling out that low cellular calcium content could perturb the mitochondrial transport of pyruvate. The observation that the effect of calcium deficiency can be overcome by supraphysiological concentrations of pyruvate supports the proposal that stimulation of the maximal capacity of the gluconeogenic pathway by fatty acid relies largely on the tricarboxylic acid cycle activity, restricted in calcium deficiency conditions.

Effect of cellular Ca2+ loading on alpha 1-agonist or protein kinase C activators-mediated stimulation of phosphorylase "a" in liver cells

Long chain unsaturated fatty acids stimulate phosphorylase "a" activity in liver cells. Similar degree of activation was achieved by increasing cellular Ca2+ content or by treatment with agents other than oleate, like 1,2-diolein or phorbol esters, sharing in common their ability to activate protein kinase C. In Ca2+-loaded liver cells only phenylephrine was capable of inducing a further stimulation of phosphorylase "a" activity. It is concluded that: 1) The state of activation of protein kinase C may play a role in the hormonal control of liver glycogen metabolism; 2) alpha 1-agonist-mediated activation of phosphorylase "a" can occur by a mechanism which is not related to a Ca2+-dependent activation of protein kinase C.

Control of hepatic gluconeogenesis: role of fatty acid oxidation

Octanoate has been found to activate the gluconeogenic pathway in perfused isolated rat liver. Whether a net increase in the production of glucose is observed is a function of the relative concentrations of the glucose precursor and the fatty acid. The kinetics of octanoate interaction with the gluconeogenic pathway are influenced by the rate changes induced by decreases in pyruvate concentration as a result of the increased NAD redox potential produced by the oxidation of fatty acid. Taking this into account, two distinct effects of octanoate were identified. The first is an increase in the Vmax even at the lowest (25 microM) concentration of the fatty acid tested. The second is a progressive decrease in [pyruvate]0.5 as a function of octanoate concentration. The latter occurs at low (less than 0.1 mM), presumably physiological, pyruvate concentrations, when its mitochondrial transport is limiting, indicating that this process must have been activated. The former is observable even at high (greater than 0.5 mM), supraphysiological, concentrations of pyruvate, when its mitochondrial transport is not limiting, indicating that a distal step, presumably pyruvate carboxylation, is activated. The action of octanoate in increasing gluconeogenesis has been found not to be related to a decreased flux through pyruvate dehydrogenase, neither to changes in the NAD redox potential nor to its ability to increase energy production. Actually, the oxygen uptake induced by octanoate was largely accounted for by the production of ketone body and the latter process was found to be independent of variations in energy demand.

Role of calcium in the phenylephrine-induced activation of phosphorylase "A" in isolated liver cells

The ability of phenylephrine to activate phosphorylase in liver cells with variable degrees of Ca2+ loading was studied. Phenylephrine has been found to be capable of stimulating phosphorylase at saturating Ca2+ concentrations that precluded any further action of this ion. Furthermore the degree of activation was proportional to the cellular calcium content. These results allow to conclude that alpha-adrenergic agonists activate phosphorylase by a mechanism apparently unrelated to their ability to mobilize and subsequently increase the cytosolic concentration of free Ca2+.

The interaction of cycloserine with pyruvate and other biologically relevant alpha-ketoacids

The ability of cycloserine solutions to deplete alpha-oxoacids has been found to be correlated with the spontaneous transformation of cycloserine into a derivative dimer (2,5-bis-(aminoxymethyl)-3,6-diketopiperazine). Synthetic dimer was found to react rapidly with pyruvate to form the expected oxime. Two lines of evidence indicate that it is the cycloserine dimer and not cycloserine itself that reacts with alpha-ketoacid. First, the 1H NMR spectrum of the purified oxime is superimposable with that arising when the dimer and pyruvate are mixed and the spectrum taken immediately thereafter. Second, the mass spectrum of the reaction product of cycloserine dimer and methylpyruvate is totally consistent with the formation of a stable oxime derivative. Furthermore, when cycloserine is incubated with pyruvate the oxime derived from the dimer is found. These observations clearly indicate that cycloserine in solution can have chemical activities in addition to its ability to interfere with pyridoxal dependent reactions. On these grounds it is concluded that any biological action of cycloserine should be interpreted cautiously.