Identification of EcoRV fragments spanning the N alpha-tubulin gene of Physarum.

The N alpha-tubulin gene of Physarum polycephalum has an EcoRV site at codons 252/253. EcoRV digestion of physarum DNA generated two EcoRV fragments per gene copy comprising both coding and flanking sequences. Hybridisation probes which included coding sequences upstream from the central EcoRV site cross-hybridised with another alpha-tubulin gene. Probes derived from either 5'- or 3'-flanking regions were gene-specific. These probes identified two EcoRV fragments in the haploid strain CLdAXE viz 5.4 kb (5'-fragment) and 6.2 kb (3'-fragment). The same two fragments were identified in EcoRV digests of DNA of the diploid strain M3CVIII, and a second form of the gene was also identified comprising two fragments viz 5.0 kb (5'-end) and 5.5 kb (3'-end). Both forms gave rise to an identical 4.65 kb HindIII fragment as judged by restriction mapping.

Differential gene expression during the amoebal-plasmodial transition in Physarum.

We have prepared cDNA libraries for amoebae and plasmodia of the acellular slime mould, Physarum polycephalum. Differential screening was used to isolate cell-type-specific cDNA clones (in bacteriophage M13) and both libraries yielded approximately 5% of such sequences. The amoebal- and plasmodial-specific clones were used to assay changes in transcription during the amoebal-plasmodial transition. The results obtained substantiate the view that the switch from amoebal to plasmodial characteristics occurs over several nuclear division cycles. With one exception, the specific cDNAs came from single-gene families. Southern blotting experiments also showed that they hybridised to identical restriction fragments from amoebal and plasmodial DNAs indicating that genomic rearrangements are unlikely to be involved in the regulation of these genes.

Proline and hepatic lipogenesis.

The effects of proline on lipogenesis in isolated rat hepatocytes were determined and compared with those of lactate, an established lipogenic precursor. Proline or lactate plus pyruvate increased lipogenesis (measured with 3H2O) in hepatocytes from fed rats depleted of glycogen in vitro and in hepatocytes from starved rats. Lactate plus pyruvate but not proline increased lipogenesis in hepatocytes from starved rats. ( - )-Hydroxycitrate, an inhibitor of ATP-citrate lyase, partially inhibited incorporation into saponifiable fatty acid of 3H from 3H2O and 14C from [U-14C]lactate with hepatocytes from fed rats. Incorporation of 14C from [U-14C]proline was completely inhibited. Similar complete inhibition of incorporation of 14C from [U-14C]proline by ( - )-hydroxycitrate was observed with glycogen-depleted hepatocytes or hepatocytes from starved rats. Inhibition of phosphoenolpyruvate carboxykinase by 3-mercaptopicolinate did not inhibit the incorporation into saponifiable fatty acid of 3H from 3H2O or 14C from [U-14C]proline or [U-14C]lactate. Both 3-mercaptopicolinate and ( - )-hydroxycitrate increased lipogenesis (measured with 3H2O) in the absence or presence of lactate or proline with hepatocytes from starved rats. The results are discussed with reference to the roles of phosphoenolpyruvate carboxykinase, mitochondrial citrate efflux, ATP-citrate lyase and acetyl-CoA carboxylase in proline- or lactate-stimulated lipogenesis.

Inhibition of lipogenesis by vasopressin and angiotensin II in glycogen-depleted hepatocytes.

Vasopressin and angiotensin II inhibited lipogenesis (measured with 3H2O) in hepatocytes from fed rats. Inhibition was also observed with hepatocytes from fed rats which had been depleted of glycogen in vitro and incubated with lactate + pyruvate (5 mM + 0.5 mM) as substrates. The inhibitory actions of the hormones are therefore independent of hormone-mediated changes in glycogenolytic or glycolytic flux from glycogen, and thus the site(s) of hormone action must be subsequent to the formation of lactate. (-)Hydroxycitrate, a specific inhibitor of ATP-citrate lyase, decreased lipogenesis in hepatocytes from fed rats incubated with lactate + pyruvate by approx. 51% but had little effect on lipogenesis in glycogen-depleted hepatocytes similarly incubated. There was parallel inhibition of incorporation of 14C from [U-14C]lactate into fatty acid and lipogenesis as measured with 3H2O in each case. Thus depletion of glycogen, or conceivably the process of glycogen-depletion (incubation with dibutyryl cyclic AMP) causes a change in the rate-determining step(s) for lipogenesis from lactate. Vasopressin and angiotensin II also decreased lipogenesis and incorporation of 14C into fatty acids in glycogen-depleted hepatocytes provided with [U-14C]proline as opposed to [U-14C]-lactate. However, proline-stimulated lipogenesis was inhibited by (-)hydroxycitrate, and proline-stimulated lipogenesis and incorporation of 14C from [U-14C]-proline were not decreased in parallel by this inhibitor (inhibition of 52% and 85% respectively). It is inferred that lactate and proline stimulate lipogenesis by different mechanisms and incorporation of 14C from [U-14C]proline and [U-14C]lactate into fatty acid occurs via different routes.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of dichloroacetate on fatty acid synthesis in interscapular brown adipose tissue of the rat in vivo and in vitro.

The effects of dichloroacetate (DCA) on fatty acid synthesis in interscapular brown adipose tissue of the rat were investigated. Administration of DCA to rats inhibited fatty acid synthesis in brown adipose tissue, measured in vivo using 3H2O, regardless of the nutritional state of the animals. Glucose administration increased lipogenesis in brown adipose tissue of fed and starved rats and DCA did not suppress this stimulation. DCA (1 mM or 10 mM) inhibited [1-14C]glucose incorporation into fatty acid by brown adipose tissue slices in vitro but was without effect on 14CO2 production from [1-14C]glucose. This demonstrates that DCA inhibits fatty acid synthesis directly, and the effects of DCA in vivo need not be attributed to decreased supply or utilization of lipogenic precursors.

Is the direct effect of naloxone on liver cell metabolism an artifact?

Proprietary naloxone hydrochloride (Narcan) acts on isolated hepatocytes from 24-h starved rats to increase 14CO2 production from [1-14C]oleate and to reverse in part the inhibitory effect of ethanol on the oxidation of [1-14C]oleate to 14CO2. The effects are attributable not to naloxone itself, but to the methyl p-hydroxybenzoate present in Narcan as a preservative. The question is posed as to whether methyl p-hydroxybenzoate and p-hydroxybenzoate contribute to the reported antagonism by proprietary naloxone of acute ethanol intoxication in vivo.

Direction of carbon flux in starvation and after refeeding: in vitro and in vivo effects of 3-mercaptopicolinate.

3-Mercaptopicolinate (3-MPA) is a specific inhibitor of phosphoenolpyruvate carboxykinase (PEP CK). In vivo the hypoglycaemic action of 3-MPA in 24 h-starved rats was abolished on intragastric glucose refeeding. Nonetheless, 3-MPA decreased hepatic glycogen content and rate of synthesis in starved animals re-fed glucose. The inference is that on re-feeding after starvation hepatic glycogen is synthesised mainly de novo via glyconeogenesis involving PEP CK. 3-MPA increased hepatic lipogenesis in water- and glucose-fed normal and diabetic rats. This increase is presumed to result from inhibition of PEP CK and consequent diversion of pyruvate from gluconeogenesis to lipogenesis. In contrast, 3-MPA inhibited brown-fat lipogenesis in water- and glucose-fed rats.

Can isolated spans of the tricarboxylic acid cycle operate independently? L-proline, oleate and butyrate metabolism in rat hepatocytes.

14CO2 production from [l-14C]oleate, [l-14C]butyrate and [U-14C]proline by isolated rat hepatocytes was studied. In hepatocytes from fed rats, fatty acid and proline oxidation are stimulated in parallel by adrenaline, noradrenaline, vasopressin and angiotensin II. In contrast in hepatocytes from 24 h-starved rats these hormones stimulate proline oxidation whereas oleate and butyrate oxidation is hormone-insensitive. This suggests that 14CO2 production from [U-14C]proline and [l-14C]oleate is subject to independent endocrine control. In support of this in hepatocytes from fed rats, glucagon and dibutyryl cyclic AMP stimulate 14CO2 production from proline but inhibit 14CO2 production from [l-14C]oleate. The pathway of hepatic proline oxidation is discussed and it is suggested that 2-oxoglutarate dehydrogenase is one site of endocrine control of proline oxidation.

Stimulation of [1-14C]oleate oxidation to 14CO2 in isolated rat hepatocytes by the catecholamines, vasopressin and angiotensin. A possible mechanism of action.

Adrenaline, noradrenaline, vasopressin and angiotensin increased 14CO2 production from [1-14C]oleate by hepatocytes from fed rats but not by hepatocytes from starved rats. The hormones did not increase 14CO2 production when hepatocytes from fed rats were depleted of glycogen in vitro. Increased 14CO2 production from ]1-14C]oleate in response to the hormones was observed when hepatocytes from starved rats were incubated with 3-mercaptopicolinate, an inhibitor of phosphoenolpyruvate carboxykinase. 3-Mercaptopicolinate inhibited uptake and esterification of [1-14C]oleate, slightly increased 14CO2 production from [1-14C]oleate and greatly increased the [3-hydroxybutyrate]/[acetoacetate] ratio. In the presence of 3-mercaptopicolinate 14CO2 production in response to the catecholamines was blocked by the alpha-antagonist phentolamine and required extracellular Ca2+. The effects of vasopressin and angiotensin were also Ca2+-dependent. The actions of the hormones of 14CO2 production from [I-14C]oleate by hepatocytes from starved rats in the presence of 3-mercaptopicolinate thus have the characteristics of the response to the hormones found with hepatocytes from fed rats incubated without 3-mercaptopicolinate. The stimulatory effects of the hormones on 14CO2 production from [1-14C]oleate were not the result of decreased esterification (as the hormones increased esterification) or increased beta-oxidation. It is suggested that the effect of the hormones to increase 14CO2 production from [1-14C]oleate are mediated by CA2+-activation of NAD+-linked isocitrate dehydrogenase, the 2-oxoglutarate dehydrogenase complex, and/or electron transport. The results also demonstrate that when the supply of oxaloacetate is limited it is utilized for gluconeogenesis rather than to maintain tricarboxylic acid-cycle flux.

Interactions between insulin and thyroid hormone in the control of lipogenesis.

1. The effects of intragastric glucose feeding and L-tri-iodothyronine (T3) administration on rates of hepatic and brown-fat lipogenesis in vivo were examined in fed and 48 h-starved rats. 2. T3 treatment increased hepatic lipogenesis in the fed but not the starved animals. Brown-fat lipogenesis was unaffected or slightly decreased by T3 treatment of fed or starved rats. 3. Intragastric glucose feeding increased hepatic lipogenesis in control or T3-treated fed rats, but did not increase hepatic lipogenesis in starved control rats. Glucose feeding increased hepatic lipogenesis if the starved rats were treated with T3. Glucose feeding increased rates of brown-fat lipogenesis in all experimental groups. The effects of glucose feeding on liver and brown-fat lipogenesis were mimicked by insulin injection. 4. The increase in hepatic lipogenesis in T3-treated 48 h-starved rats after intragastric glucose feeding was prevented by short-term insulin deficiency, but not by (-)-hydroxycitrate, an inhibitor of ATP citrate lyase. The increase in lipogenesis in brown adipose tissue in response to glucose feeding was inhibited by both short-term insulin deficiency and (-)-hydroxycitrate. 5. The results tend to preclude pyruvate kinase and acetyl-CoA carboxylase as the sites of interaction of insulin and T3 in the regulation of hepatic lipogenesis in 48 h-starved rats. Other potential sites of interaction are discussed.

Effects of L-alanine on ketogenesis in vitro.

Alanine (5 mM) increased 14CO2 production from [1-14C]oleate by 130% and from [1-14C]butyrate by 101%. Alanine inhibited ketone-body production by 37.5% in the presence of butyrate but did not affect ketogenesis in the presence of oleate. Alanine decreased the [3-hydroxybutyrate]/[acetoacetate] ratio when either butyrate or oleate was present. The results are discussed with reference to the hypoketonaemic action of alanine in vivo.

Effects of adrenaline on ketogenesis from long- and medium-chain fatty acids in starved rats.

1. Injection of adrenaline into 24 h-starved rats caused a 69% decrease in blood [ketone-body] (3-hydroxybutyrate plus acetoacetate), accompanied by a decreased [3-hydroxybutyrate]/[acetoacetate] ratio. Blood [glucose] and [lactate] increased, but [alanine] was unchanged. 2. Adrenaline also decreased [ketone-body] after intragastric feeding of both long- and medium-chain triacylglycerol. The latter decrease was observed after suppression of lipolysis with 5-methylpyrazole-3-carboxylic acid, indicating that the antiketogenic action of adrenaline was not dependent on the chain length of the precursor fatty acid. 3. The actions of adrenaline to decrease blood [ketone-body] and to increase blood [glucose] were not observed after administration of 3-mercaptopicolinate, an inhibitor of gluconeogenesis. This suggests that these effects of the hormone are related. 4. The possible clinical significance of the results is discussed with reference to the restricted ketosis often observed after surgical or orthopaedic injury.

Brown-adipose-tissue lipogenesis in starvation: effects of insulin and (-) hydroxycitrate.

Glucose or insulin increased lipogenesis (measured in vivo using 3H2O) in brown fat of starved rats. Such increases were associated with activation of pyruvate dehydrogenase and increased use of glucose as a lipogenic precursor (monitored as an increase in the 14C/3H ratio in brown-fat fatty acids in rats injected with both 3H20 and [U-14C]glucose). (-) Hydroxycitrate did not inhibit basal rates of brown-fat lipogenesis in starved rats but suppressed the increases in lipogenesis and glucose utilization observed in response to insulin. (-)Hydroxycitrate did not, however, inhabit the increase in 14C/3H observed after insulin treatment. The results indicate that in brown fat, glucose is utilized for fatty-acid synthesis predominantly via citrate, and that insulin acts to increase lipogenesis at site(s) prior to citrate cleavage. As basal rates of lipogenesis were not inhibited by (-)hydroxycitrate, it is suggested that acetate may be a lipogenic substrate for brown fat in starvation, and experiments are described which support this suggestion.

Regulation of hepatic lipogenesis in starved and diabetic animals by thyroid hormone.

The effects of intragastric feeding with glucose and of the administration of L-triiodothyronine (T3) on in vivo rates of hepatic lipogenesis were investigated in control (fed ad libitum on normal diet), diabetic (fed ad libitum on normal diet), fat-fed (fed ad libitum on high-fat diet), and starved (food removed for 48 h) rats. Two days of T3 treatment increased hepatic lipogenesis in control and fat-fed animals but not in the diabetic or starved animals, although increases in lipogenesis in diabetic animals were observed after 4 days of T3 treatment. Intragastric glucose feeding increased hepatic lipogenesis in the livers of control animals and T3-treated control animals. Such increases are mediated by an increase in the circulating insulin concentration, as increases are not observed in diabetic rats or T3-treated diabetic rats. Glucose feeding failed to increase hepatic lipogenesis in fat-fed rats or starved rats. Insulin injection together with glucose feeding increased lipogenesis in the fat-fed group but not the starved group; i.e., impaired insulin secretion following an oral glucose load may in part explain the lack of response in the fat-fed but not the starved animals. Marked increases in hepatic lipogenesis after glucose feeding were, however, observed if either the starved or the fat-fed animals were treated with T3. The physiological implications of these observations are discussed.