Synthesis Of Malic Enzyme Research Articles

Triiodothyronine and insulin effects on malic enzyme in hypothyroid and diabetic rats

We examined the effects of T3 and insulin on the activity of hepatic mitochondrial alpha-glycerophosphate dehydrogenase and cytosolic malic enzyme in control, thyroidectomized, thyroidectomized food-restricted, and thyroidectomized diabetic rats. In the three untreated thyroidectomized groups, the decrease in hepatic nuclear T3 content was accompanied by a marked reduction in the levels of alpha-glycerophosphate dehydrogenase and malic enzyme activity. Although the levels of both enzymes were increased by a receptor-saturating dose of T3, the alpha-glycerophosphate dehydrogenase response in the thyroidectomized groups was almost identical to that in controls, whereas that of malic enzyme was reduced to 45-62% of control values. Insulin failed to stimulate the alpha-glycerophosphate dehydrogenase levels in untreated and T3-treated thyroidectomized groups, but caused an increase in malic enzyme activity by 79-130% in untreated thyroidectomized groups, and enhanced the activity of this enzyme to about twice that seen with T3 alone. These effects were independent of changes in nuclear T3 binding parameters. The data suggest that insulin may act on malic enzyme synthesis through its general stimulatory effect on protein synthesis, or by antagonizing factors that inhibit the induction of this enzyme.

Thyroid Function in Embryonic and Early Posthatch Chickens and Quail

Technological advances, especially radioimmunoassays, have led to good descriptive information about the timing and pattern of development of the thyroid gland (TG) and circulating thyroid hormone (TH). Immunocytochemical studies in combination with more traditional techniques such as gland ablation and hormone replacement have revealed the time of appearance of each hormone in the axis, the relative amounts of hormone present in each gland at different developmental stages, and a general picture of the pattern of maturation of the hypothalamic-pituitary-thyroid axis. Studies of the pituitary control of the TG remain limited by the lack of adequately specific techniques for measuring avian thyroid-stimulating hormone. Our understanding of peripheral TH dynamics is progressing as a result of iodothyronine deiodinase assays but full understanding will require more elaborate studies that adequately characterize the enzyme system(s) in each case. Molecular techniques have made powerful strides in identifying the gene responsible for producing a protein that appears to be the triiodothyronine receptor. Receptor assays have revealed the pattern of changes in receptor-binding capacities during development but have not yet revealed how binding of hormone to the receptor triggers cellular activity. Molecular genetic techniques are being used to reveal the mechanisms whereby some examples of developmental events (e.g., malic enzyme synthesis) are induced by TH. Although it is not yet possible to assess the value of molecular studies in this area for developing practical applications, these techniques are revealing the fundamental biological roles of TH in growth and development.

Effects of insulin and fructose on transcriptional and post-transcriptional regulation of malic enzyme synthesis in diabetic rat liver

Insulin action on regulation of hepatic malic enzyme has been investigated in comparison with fructose, using streptozotocin-induced diabetic rats. Insulin-treatment caused a 2.8-fold increase in the transcriptional rate of malic enzyme (EC 1.1.1.40) after 8 h, and a 5-fold increase in the mRNA concentration of the liver. In Northern blot analysis, we demonstrated that after insulin treatment, the nuclear mRNA of malic enzyme tended to increase more rapidly than the total cellular mRNA. Therefore, it is suggested that the nuclear mRNA was primarily increased by insulin. The insulin-dependent increase of malic enzyme mRNA was blocked by cycloheximide, suggesting that synthesis of a peptide is required. On the other hand, by feeding a high-fractose diet to diabetic rats, the malic enzyme mRNA concentration was considerably increased, though with a delayed peaking in comparison with the insulin-treated animals, whereas the transcriptional rate was not significantly increased. Dietary fructose may stabilize the transcripts. Fructose increased the enzyme level far less than mRNA level. These results suggest that insulin is required in both the translational and transcriptional regulation of malic enzyme.

Nutritional and Hormonal Regulation of the Gene for Avian Malic Enzyme

This paper reviews work from our laboratory on the molecular mechanisms involved in the nutritional and hormonal regulation of avian malic enzyme. The activity of hepatic malic enzyme, one of the set of "lipogenic" enzymes, is high in well-fed chickens and low in starved chickens. In chick embryo hepatocytes in culture, insulin and triiodothyronine (T3) are positive effectors and glucagon, acting via cyclic AMP, is a negative effector. Hormone concentrations in blood are consistent with insulin and T3 playing the major positive roles, and glucagon a major negative role, in regulating hepatic malic enzyme activity during the transitions between the fed and the starved states. New results indicate that insulin-like growth factor 1 also stimulates accumulation of malic enzyme. Our strategy has been to trace the intracellular signalling pathway from its distal end, altered enzyme activity, towards its proximal end, interaction of humoral factors with their appropriate cellular receptors. Nutrition- and hormone-induced changes in malic enzyme activity are due to altered concentrations of malic enzyme protein which, in turn, are due to altered rates of synthesis of malic enzyme. Synthesis of malic enzyme is controlled by regulating the level of malic enzyme mRNA which, in turn is regulated at initiation of transcription. The next step in this analysis will be to identify cis-acting sequence elements in the malic enzyme gene which bestow upon it a selective response to nutritional state and hormones. We are using transient expression systems and avian retroviral vectors to test the function of cis-acting elements involved in the regulation of transcription.

Transcriptional and posttranscriptional regulation of malic enzyme synthesis by insulin and triiodothyronine

To investigate the transcriptional and posttranscriptional regulation of malate dehydrogenase (EC 1.1.1.40) induction by insulin, the transcriptional rate, mRNA concentration and enzyme induction of malic enzyme were compared in livers of normal and diabetic rats fed a high-carbohydrate diet. When rats were fed the diet for 4 days, the enzyme induction and mRNA concentration in livers of diabetic rats were only about 10% and 39%, respectively, of the values of normal rats, and the transcriptional rate was about 64%. Insulin treatment restored the transcriptional rate and mRNA concentration in 8 h and the enzyme induction in 4 days. Thus, it is suggested that insulin is involved in malic enzyme transcription of the gene and also possibly in the translation of the cytoplasm. On the other hand, by giving triiodothyronine treatment, the transcriptional rate and mRNA concentration were increased about twice and the enzyme induction, about 10-times in the diabetic animals. Triiodothyronine appears to stimulate malic enzyme transcription and possibly post-transcriptional steps even at a very low insulin level.

The effect of thyroid hormone on the chromatin structure and expression of the malic enzyme gene in hepatocytes.

Malic enzyme catalyzes the NADP-dependent oxidative decarboxylation of malate to pyruvate and carbon dioxide and is involved in lipogenesis. We have investigated the effect of thyroid hormone on the chromatin structure of the malic enzyme gene in rat liver. Hypersensitivity to DNase I in the immediate 5'-flanking region was altered by T3. T3 stimulation induced hypersensitive sites at -310 base pairs (bp) and -50 bp whereas a hypersensitive site at -170 bp was thyroid hormone independent. Hypersensitive sites identified in the 3'-flanking region showed no change with T3 stimulation. We further characterized expression of the malic enzyme gene as a function of thyroidal state by localizing malic enzyme mRNA in hepatocytes using in situ hybridization histochemistry. In hypothyroid and euthyroid states, two populations of hepatocytes were seen, some with malic enzyme message and others with no detectable message. These differences in malic enzyme gene expression were most evident between groups or regions of hepatocytes. After 10 days of thyroid hormone treatment all hepatocytes demonstrated malic enzyme message. The hypersensitivity results confirm that thyroid hormone stimulation of malic enzyme synthesis occurs in part at the level of transcription, and localization of malic enzyme gene expression suggests this stimulation is accompanied by recruitment of hepatocytes. Hepatocytes may be heterogeneous in their ability to respond to thyroid hormone.

Hormonal regulation of lipogenic enzymes in chick embryo hepatocytes in culture. Expression of the fatty acid synthase gene is regulated at both translational and pretranslational steps.

Mechanisms involved in the multihormonal regulation of fatty acid synthase have been investigated by comparing levels of its mRNA with rates of enzyme synthesis in chick embryo hepatocytes in culture. Triiodothyronine or insulin caused about a 2.5-fold increase in the relative rate of synthesis of fatty acid synthase. Together, these hormones were synergistic, stimulating enzyme synthesis by nearly 40-fold (Fischer, P.W.F., and Goodridge, A.G. (1978) Arch. Biochem. Biophys. 190, 332-344). Addition of triiodothyronine stimulated increases in mRNA levels comparable to increases in enzyme synthesis whether insulin was present or not. Thus, triiodothyronine regulates fatty acid synthase primarily by controlling the amount of its mRNA. Addition of insulin, in the presence of triiodothyronine, stimulated enzyme synthesis by 14-fold and mRNA levels by only 2-fold. In the absence of triiodothyronine, insulin had no effect on mRNA levels. Thus, insulin has a major effect on the translation of fatty acid synthase mRNA. After the addition of triiodothyronine, fatty acid synthase mRNA accumulated with sigmoidal kinetics, approaching a new steady state about 48 h after the addition of hormone. Puromycin, an inhibitor of protein synthesis, blocked the effect of triiodothyronine. We suggest that the abundances of both fatty acid synthase and malic enzyme mRNAs are regulated by a common triiodothyronine-induced peptide intermediate which has a relatively long half-life. Glucagon caused an 80% decrease in the synthesis of fatty acid synthase (Fischer, P.W.F., and Goodridge, A.G. (1978) Arch. Biochem. Biophys. 190, 332-344) and a 60% decrease in the level of fatty acid synthase mRNA. Thus, glucagon regulates fatty acid synthase by controlling the concentration of its mRNA. The synthesis of malic enzyme also was inhibited by glucagon at a pretranslational step, but the inhibition was almost complete. Thus, despite coordinated regulation of the concentrations of these enzymes during starvation and refeeding, individual hormones sometimes regulate synthesis of the two enzymes at the same step and to about the same degree and sometimes at different steps or to very different degrees.

Hormonal regulation of lipogenic enzymes in chick embryo hepatocytes in culture. Thyroid hormone and glucagon regulate malic enzyme mRNA level at post-transcriptional steps.

Mechanisms involved in stimulation of the synthesis of malic enzyme by insulin and triiodothyronine and in inhibition of synthesis by glucagon have been investigated by assessing levels and rates of synthesis of malic enzyme mRNA in chick embryo hepatocytes in culture. Insulin alone had no effect on the level of malic enzyme mRNA, whereas triiodothyronine by itself caused a 7-fold increase. Insulin plus triiodothyronine caused an 11-fold increase. Glucagon caused a 93% decrease in the accumulation of malic enzyme mRNA caused by insulin plus triiodothyronine. Although the relative changes in mRNA level are smaller in magnitude, they are qualitatively similar to the effects of these hormones on synthesis of malic enzyme, suggesting that control is exerted primarily at pretranslational steps. After addition of triiodothyronine, malic enzyme mRNA accumulated with sigmoidal kinetics, approaching a new steady state at 36-48 h after adding hormone. Puromycin, an inhibitor of protein synthesis, blocked the effect of triiodothyronine if added 30 min prior to the hormone and inhibited further accumulation of malic enzyme mRNA if added 24 h after triiodothyronine. However, puromycin had no effect on the level of beta-tubulin mRNA (t1/2 = 3-5 h), suggesting that the effect of triiodothyronine on malic enzyme mRNA required synthesis of a peptide. Triiodothyronine increased transcription of the malic enzyme gene by 2-fold and level of its mRNA by 11-14-fold, indicating regulation is primarily at a post-transcriptional step. Glucagon caused malic enzyme mRNA to decay with a half-life of 1.5 h, whereas alpha-amanitin or actinomycin D, inhibitors of transcription, caused the mRNA to decay with a half-life of 8-11 h. The effect of glucagon was entirely post-transcriptional because the hormone had no effect on transcription. Taken together, these results suggest a model in which triiodothyronine regulates production of a peptide that stabilizes malic enzyme transcripts in the cytoplasm and/or nucleus. Glucagon may inhibit activity of the peptide induced by triiodothyronine.

Thyroid hormone regulation of malic enzyme synthesis. Dual tissue-specific control.

The regulatory mechanism(s) involved in the tissue-specific induction of cytosolic malic enzyme (EC 1.1.1.40) by triiodothyronine (T3) have been investigated in rat liver and heart. In these two tissues, cellular malic enzyme mRNA accumulates to different extents in response to hormonal stimulation (11-16- and 3-4-fold above the respective basal levels) (Dozin, B., Magnuson, M. A., and Nikodem, V. M. (1985) Biochemistry 24, 5581-5586). To gain further insight into this pretranslational control, nuclear in vitro run-off transcription assays were performed and correlated with the levels of malic enzyme RNA sequences in cytoplasm. The data demonstrate that the rate of transcription of the malic enzyme gene is stimulated by T3 to similar extents in liver and heart (3-4-fold above the basal activity). In liver, T3 also promotes an additional increase in cellular malic enzyme mRNA. This additional effect could be due to a tissue-specific change in the rate of degradation of cytoplasmic mRNA or to an effect on malic enzyme mRNA in the nucleus.

Tissue-specific control of rat malic enzyme activity and messenger RNA levels by a high carbohydrate diet.

In euthyroid rats fed a high carbohydrate fat-free diet for 10 days, the mass of cellular malic enzyme mRNA in liver is increased 7- to 8-fold above the basal level. Malic enzyme activity is stimulated to the same extent. This effect does not result from an increase either in the transcriptional activity of the malic enzyme gene, as determined by nuclear run-off transcription assay, or in the content of intranuclear malic enzyme RNA sequences. Mathematical modeling shows that this increase in cytoplasmic mRNA is compatible with retarded degradation of cytoplasmic mRNA. Regulation of malic enzyme by carbohydrates is liver-specific, since no response is observed in the following nonhepatic tissues: brain, heart, spleen, kidney, testis, and lung. Furthermore, the amplitude of the response in liver depends on the thyroid state of the animals, being lower (by a factor of approximately 4) in hypothyroidism and higher (12- to 15-fold) when normal animals are injected simultaneously with a daily dose of 15 micrograms of triiodothyronine per 100 g of body weight for 10 days. Since thyroid hormones regulate liver malic enzyme synthesis predominantly at the nuclear level and carbohydrates at the cytoplasmic level, the additive effect of triiodothyronine and a high carbohydrate diet on the activity of malic enzyme is readily explicable.

Malic enzyme levels are increased by the activation of NADPH-consuming pathways: detoxification processes

The administration to rats of either t-butyl hydroperoxide or phénobarbital, compounds that are metabolized through detoxification processes, produces an increase in specific activity of the NADPH-consuming enzymes, glutathione reductase and NADPH-cytochrome c reductase. These compounds also produce a very significant increase in the specific activity of malic enzyme. Immunoprecipitation with a specific antibody for malic enzyme indicates that specific activity changes are the result of corresponding changes in the amounts of enzyme protein present. The administration of 1,3-bis(chloroethyl(-1-nitrosourea (a glutathione reductase inhibitor) together with t-butyl hydroperoxide abolishes any stimulation of malic enzyme activity. These results indicate that an increase in NADPH consumption induces the synthesis of malic enzyme. Alternatively, a protection of enzyme degradation cannot be rigorously excluded.

Nutritional and hormonal regulation of malic enzyme synthesis in rat mammary gland.

Cytosolic malic enzyme was purified from rat mammary gland by L-malate affinity chromatography. The pure enzyme obtained was used to produce a specific antiserum in a rabbit. Relative synthesis of malic enzyme in the mammary gland of mid-lactating rats was 0.097%, measured by labelling the enzyme in isolated acini. When food was removed, malic enzyme synthesis decreased to 35% and 20% of the control value at 4 and 6 h respectively. Incorporation of [3H]leucine into soluble proteins was constant during the first 6 h of starvation. When lactating rats (maintained with their pups) were starved for 24 h and then re-fed, the relative rate of enzyme synthesis increased 2.5-, 4-, and 4.5-fold at 3 h, 6 h and 18 h respectively after initiation of re-feeding. The relative rate of malic enzyme synthesis was about 50% of normal at 15 h after weaning, whereas the rate of synthesis of soluble proteins did not change. Administration of bromocriptine or adrenalectomy of lactating rats decreased the relative rate of synthesis of malic enzyme by 40% or 30% respectively; these effects were counteracted by hormone supplementation. Hormone therapy also caused an increase in the rate of incorporation of [3H]leucine into soluble proteins and in malic enzyme activity.

Tissue-specific regulation of two functional malic enzyme mRNAs by triiodothyronine

Rat liver malic enzyme (ME) synthesis is known to be regulated by 3,5,3'-triiodo-L-thyronine (T3). Hybridization of 32P-labeled ME cDNA with RNA extracted from normal and T3-induced livers (15 or 50 micrograms/100 g body weight for 10 days) showed an increase in the ME mRNA concentration by approximately 11-fold in T3-treated rats. ME activity and ME mass were stimulated to the same degree as ME mRNA. Northern blot analysis of either total or poly(A+) RNA revealed two distinct ME mRNAs (21 and 27 S) which were equally induced by T3 treatment. Both mRNAs were shown by in vitro translation assay to program the synthesis of the same immunoprecipitable protein corresponding to full-sized ME. From all the above, we concluded that both messages code for active enzyme. ME activity and ME mRNA were also detected in nonhepatic tissues for which different responses to T3 induction were observed without direct correlation with their respective content of T3 nuclear receptor. Increases in ME activity and level of hybridizable ME mRNA were seen 48 h after a single administration of T3 (200 micrograms/100 g body weight) in liver, kidney, and heart (10.3- and 15.5-, 1.7- and 2.6-, and 1.72- and 3.4-fold above basal values, respectively). Lower levels of induction could already be detected after 24 h, liver being the most stimulated tissue. ME was not affected in brain, lung, testis, and spleen. Northern blot analysis showed that both ME mRNAs are present in all tissues tested, although in different relative proportions.(ABSTRACT TRUNCATED AT 250 WORDS)

Coordinate regulation of the biosynthesis of ATP-citrate lyase and malic enzyme during adipocyte differentiation. Studies on 3T3-L1 cells.

The biosynthesis and degradation of two lipogenic enzymes were studied during the differentiation of 3T3-L1 preadipocytes into adipocytes. The activity and mass of malic enzyme, rose by an order of magnitude during adipocyte development and the enzyme accounted for 0.3% of the cytosol protein in mature fat cells. Similarly, the activity and amount of ATP-citrate lyase increased approximately 7-fold during the adipose conversion. The relative rates of synthesis of the two enzymes were less than or equal to 0.02% in preadipocytes, but increased sharply as the cells began to differentiate. Maximal steady state rates of malic enzyme and ATP-citrate lyase synthesis in 3T3-L1 adipocytes were 13- and 8-fold higher, respectively, than the basal rates in preadipocytes. In contrast, the half-lives of malic enzyme (67 h) and ATP-citrate lyase (47 h) were not altered during adipocyte development. Thus, accelerated rates of enzyme synthesis account for the differentiation-dependent accumulation of the two lipogenic enzymes. Increased rates of malic enzyme, ATP-citrate lyase, and fatty acid synthetase biosynthesis are expressed in a highly coordinated manner during adipocyte differentiation and are associated with parallel elevations in the levels of translatable mRNAs for these enzymes.

Regulation of the activity and synthesis of malic enzyme in 3T3-L1 cells

Malic enzyme activity in differentiated 3T3-L1 cells was about 20-fold greater than activity in undifferentiated cells. A new steady-state level was achieved about 8 days after initiating differentiation of confluent cultures with a 2-day exposure to dexamethasone, isobutylmethylxanthine, and insulin. This increase in enzyme activity resulted from an increase in the mass of malic enzyme as detected by immunotitration of enzyme activity with goat antiserum directed against purified rat liver malic enzyme. Malic enzyme synthesis was undetectable in undifferentiated cells and increased to about 0.2% of soluble protein in differentiated cells, suggesting that the increase in enzyme mass was due primarily to an increase in enzyme synthesis. Thyroid hormone, a potent stimulator of malic enzyme activity in hepatocytes in culture and in liver and adipose tissue in intact animals, decreased or increased malic enzyme activity in differentiating 3T3-L1 cells by about 40% when it was removed or added to the medium, respectively. Insulin, another physiologically important regulator of malic enzyme activity in vivo, had no effect on the initial rate of accumulation of malic enzyme activity in the differentiating cells and caused a 30 to 40% decrease in the final level of enzyme activity in the fully differentiated cells. Cyclic AMP, a potent inhibitor of malic enzyme synthesis in hepatocytes in culture, inhibited this process in 3T3-L1 cells by 30%. Malic enzyme is like several other enzymes in that the large increase in its concentration which accompanies differentiation of 3T3-L1 cells is due to increased synthesis of enzyme protein. However, the hormonal modulation of malic enzyme characteristic of liver and adipose tissue in intact animals does not appear to occur in differentiated 3T3-L1 cells, suggesting that differentiated 3T3-L1 cells may not be an appropriate model system in which to study the hormonal modulation of malic enzyme that occurs in liver and adipose tissue of intact animals.

Molecular cloning of a cDNA sequence for rat malic enzyme. Direct evidence for induction in vivo of rat liver malic enzyme mRNA by thyroid hormone.

Malic enzyme (EC 1.1.1.40) mRNA was partially purified to 12% of total mRNA activity (greater than 150-fold enrichment) from 3-5-3'-triiodo-L-thyronine-carbohydrate-stimulated rat liver by polysome immunopurification followed by oligo(dT)-cellulose chromatography. This preparation was used as the template for synthesis of cDNA on a pBR322-SV40 hybrid plasmid DNA primer which was then circularized with linker DNA and used to transform Escherichia coli. The resulting transformants were screened by in situ differential hybridization using 32P-labeled poly(A+)RNA prepared from uninduced and 3-5-3'-triiodo-L-thyronine-carbohydrate-induced rat livers. Of 750 transformants screened, 6 were found to hybridize differentially; 1 of these, prME, contained an insert of about 1250 base pairs and hybrid-selected an mRNA which directed synthesis of malic enzyme in a cell-free translation system. Using this cDNA as a probe, we demonstrated that the level of malic enzyme mRNA after thyroid hormone treatment was markedly increased and the size of the major malic enzyme mRNA was shown by Northern analysis to be about 2700 nucleotides in length.

Light-stimulated synthesis of NADP malic enzyme in leaves of maize.

Illumination of etiolated maize plants for 80 h brings about a 15-20-fold increase in activity of NADP malic enzyme (EC 1.1.1.40). Increases in NADP malic enzyme protein and in the level of translatable mRNA for this protein occur simultaneously with the activity increase. Radiolabeled amino acids are also incorporated into NADP malic enzyme during this time. These results are consistent with the conclusion that an increase in NADP malic enzyme activity during greening results from de novo synthesis of NADP malic enzyme protein. Polyadenylated RNA extracted from greening maize leaves directs the synthesis in vitro of a protein 12,000 daltons larger than NADP malic enzyme purified from corn leaves. This protein is a precursor of NADP malic enzyme because 1) both the precursor and mature NADP malic enzyme are immunoprecipitated by antibody made against NADP malic enzyme purified from corn leaves, 2) both NADP malic enzyme protein and the level of mRNA for the precursor increase during greening, and 3) peptide maps of the precursor and of mature NADP malic enzyme are very similar. Mature NADP malic enzyme and its precursor (synthesized in vitro) both migrate on sodium dodecyl sulfate-polyacrylamide gradient gels as doublet bands. Peptide analyses show all bands to be structurally related.

The effect of dietary fat on the activity, content, rates of synthesis, and degradation and translation of messenger RNA coding for malic enzyme in mouse liver

The specific activity (units activity/mg cytosolic protein) of malic enzyme was found to be three-fold higher in the livers of mice fed a semipurified diet containing 50% ( w w ) glucose and 15% ( w w ) saturated and monounsaturated but no polyunsaturated fat (hydrogenated cottonseed oil) over an 11-day period than in the livers of mice fed a standard laboratory mouse chow (Purina) diet. In contrast, when other lab chow-fed mice were fed an isocaloric diet containing 15% ( w w ) polyunsaturated fat (corn oil), no change in the specific activity of malic enzyme occurred over a similar period of time. Rocket immunoelectrophoresis performed on cytosols from both dietary groups demonstrated that the livers of mice consuming the hydrogenated cottonseed oil diet contained approximately three times more malic enzyme protein than did the livers from the corn oil-fed animals. In mice pulse-labeled with l-[4,5- 3H]leucine, the rate of hepatic malic enzyme synthesis (relative to that for total protein) was approximately twofold greater in the hydrogenated cottonseed oil-fed mice than in their corn oil-fed counterparts whereas the rate of hepatic malic enzyme degradation was similar for both groups. Immunotitration of liver malic enzyme from hydrogenated cottonseed oil-fed and corn oil-fed mice revealed identical equivalence points, demonstrating that the catalytic efficiency of mouse liver malic enzyme had not been affected by the type of dietary fat administered. When total liver RNA, isolated from the hydrogenated cottonseed oil- and the corn oil-fed animals, was translated in cell-free translation systems (wheat germ extract and reticulocyte lysate) we found that both dietary treatments had resulted in an increase in the activity of malic enzyme messenger RNA. Furthermore, there were no significant differences between the two dietary groups in this regard. These results suggest that hepatic malic enzyme specific activity in high-carbohydrate polyunsaturated fat-fed mice is regulated principally by dietary-induced changes in the rate of enzyme synthesis and not by the activity of messenger RNA coding for the enzyme.

Molecular cloning of cDNA sequences for avian malic enzyme. Nutritional and hormonal regulation of malic enzyme mRNA levels in avian liver cells in vivo and in culture.

A double-stranded cDNA library constructed from the total poly(A+) RNA of goose uropygial gland was screened for recombinants containing sequences complementary to malic enzyme mRNA. Replicate arrays of 1400 colonies were hybridized independently with 32P-labeled cDNAs copied from two populations of hepatic RNA derived from tissues which differed by about 35-fold with respect to the relative synthesis of malic enzyme. Forty-eight of the colonies which gave differential signals were further screened by hybrid-selected translation. DNA from one of these contained an insert of 970 base pairs and selected an mRNA which directed the synthesis of malic enzyme in a cell-free system. The malic enzyme sequences were subcloned into the single-stranded bacteriophage M13mp8. The subclones were used to prepare 32P-labeled single-stranded hybridization probe. Northern analysis indicated that malic enzyme mRNA from both goose and chicken is about 2100 bases in length. Hepatic malic enzyme mRNA concentration is stimulated 30- to 50-fold or more when neonatal chicks or goslings, respectively, are fed for 24 h. When added to chick embryo hepatocytes in culture, triiodothyronine stimulated malic enzyme mRNA accumulation by more than 100-fold. Glucagon inhibited the thyroid hormone-stimulated accumulation of malic enzyme mRNA by 99%. In all instances, malic enzyme mRNA concentration was closely correlated with the relative rate of malic enzyme synthesis. These results suggest that nutritional and hormonal regulation of malic enzyme synthesis occurs at the pretranslational level.

Nutritional and hormonal regulation of the translatable levels of malic enzyme and albumin mRNAs in avian liver cells in vivo and in culture.

Relative synthesis of malic enzyme is stimulated 25-to 100-fold by feeding neonatal ducklings or by incubating embryonic chick hepatocytes in culture with triiodothyronine. Synthesis of the enzyme is almost completely blocked when fed birds are starved or when triiodothyronine-treated hepatocytes in culture are also treated with glucagon. Cytoplasmic poly(A)+ RNA was isolated from livers of intact ducklings or hepatocytes in culture treated as described above and translated in an mRNA-dependent rabbit reticulocyte lysate. The identity of malic enzyme synthesized in the cell-free system was confirmed by virtue of its antigenicity, subunit molecular weight, and proteolytic peptide pattern. Translatable levels of malic enzyme mRNA paralleled changes in relative synthesis of malic enzyme in vivo and in hepatocytes in culture. Translatable levels od albumin mRNA were either unaffected or changed in a direction opposite to that of malic enzyme mRNA. Thus, both nutritional and hormonal regulation of malic enzyme synthesis involves regulation of cytoplasmic translatable malic enzyme mRNA levels. The hepatocyte culture system is ideally suited for future studies on the regulation of malic enzyme mRNA synthesis and/or degradation by thyroid hormone and glucagon.