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Expression of the glucose-6-phosphate dehydrogenase (G6PD) gene is inhibited by the addition of polyunsaturated fatty acids to the medium of primary hepatocytes in culture. To define the regulated step, we measured the abundance of G6PD mRNA both in the nucleus and in total RNA and measured the transcriptional activity of the G6PD gene. Insulin and glucose stimulated a 5- to 7-fold increase in G6PD mRNA in rat hepatocytes. This increase was attenuated by 60% due to the addition of arachidonic acid. These changes in mRNA accumulation occurred in the absence of changes in the rate of transcription. Amounts of precursor mRNA (pre-mRNA) for G6PD in the nucleus changed in parallel with the amount of mature mRNA. The decrease in G6PD pre-mRNA accumulation caused by arachidonic acid was also observed with other long chain polyunsaturated fatty acids but not with monounsaturated fatty acids. In addition, this decrease was not due to a generalized toxicity of the cells due to fatty acid oxidation. These changes in G6PD expression in the primary hepatocytes are qualitatively and quantitatively similar to the changes observed in the intact animal due to dietary carbohydrate and polyunsaturated fat. Regulation of G6PD expression by a nuclear posttranscriptional mechanism represents a novel form of regulation by fatty acids.

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Glucose-6-phosphate dehydrogenase (G6PD) activity differs among tissues and, in liver, with the dietary state of the mouse. Tissue-specific differences in G6PD activity in adipose tissue, liver, kidney, and heart were associated with similar differences in the amount of G6PD mRNA. Regulation of mRNA amount by dietary fat was only observed in liver. In mice fed a low-fat diet, the relative amounts of G6PD mRNA were 3:1:1:0.38, respectively, in the four tissues. Further, the amount of precursor mRNA for G6PD in liver, kidney, and heart reflected the amount of mature mRNA in these tissues, suggesting differing transcriptional activity. Our S1 nuclease and primer-extension analyses indicated that the same transcriptional start site is used in liver, kidney, and adipose tissue, resulting in a common 5' end of the mRNA in these tissues. Thus, differential regulation is not attributable to alternate promoter usage. A DNase hypersensitivity analysis of the 5' end of the G6PD gene identified three hypersensitive sites (HS): HS 1 and HS 2 were present in all tissues, whereas HS 3 was liver specific. Thus, regulation of G6PD expression involves both dietary and tissue-specific signals that appear to act via different mechanisms.

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Glucagon, acting via cAMP, inhibits transcription of the malic enzyme gene in chick embryo hepatocytes. In transiently transfected hepatocytes, fragments from the 5'-flanking DNA of the malic enzyme gene confer cAMP responsiveness to linked reporter genes. The major inhibitory cAMP response element at -3180/-3174 base pairs (bp) is similar to the consensus binding site for AP1. DNA fragments from -3134/-3115, -1713/-944, and -413/-147 bp also contain inhibitory cAMP response elements. The negative action of cAMP is mimicked by overexpression of the catalytic subunit of protein kinase A, inhibited by overexpression of a specific inhibitor of protein kinase A, and inhibited by overexpression of the T3 receptor; these results indicate involvement of the classical eukaryotic pathway for cAMP action and suggest interaction between the T3 and cAMP pathways. Sequence-specific complexes form between nuclear proteins and a DNA fragment containing -3192/-3158 bp of 5'-flanking DNA. In nuclear extracts prepared from cells treated with chlorophenylthio-cyclic AMP and T3, the complexes have different masses than those formed with extracts from cells treated with T3 alone. Antibodies to c-Fos or ATF-2 inhibit formation of the complex formed by proteins from cells treated with chlorophenylthio-cyclic AMP and T3 but not by those from cells treated with T3 alone. These results suggest an important role for c-Fos and ATF-2 in glucagon-mediated inhibition of transcription of the malic enzyme gene.

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In vivo, feeding stimulates and starvation inhibits transcription of the malic enzyme gene. In chick-embryo hepatocytes in culture, triiodothyronine (T3) stimulates and glucagon inhibits transcription of this gene. As a first step in the characterization of the involved regulatory mechanisms, fragments of genomic DNA spanning the structural and 5'-flanking regions of the chicken malic enzyme gene were cloned. The coding region of the gene is organized into 14 exons and 13 introns and is greater than 106 kb in length. The size of the gene, the number and lengths of the exons, and positions at which introns are inserted into the coding regions are virtually identical in the chicken and rat genes. When transiently transfected into chick-embryo hepatocytes, 5800 bp of 5'-flanking DNA conferred T3 responsiveness to a linked chloramphenicol acetyltransferase (CAT) reporter gene. Using deletion and site-specific mutations of 5'-flanking DNA, we identified a complex T3 response unit that contains one major T3 response element (T3RE) and several minor ones. The major element contains two degenerate copies of the hexamer, RGGWMA, separated by 4 bp and was a strong repressor in the absence of ligand. Endogenous levels of T3 receptor are sufficient to allow the T3 response elements in the upstream region of the malic enzyme gene to confer responsiveness to T3, suggesting that they are physiologically relevant.

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The activity of glucose-6-phosphate dehydrogenase (G6PD) is inhibited by the addition of polyunsaturated fat (PUFA) to a high carbohydrate diet. To define the regulated step, we measured enzyme activity, accumulation of G6PD mRNA, and transcriptional activity of the gene. At steady-state, G6PD activity and mRNA abundance were inhibited by 80% in the livers of mice fed a high-fat diet (6% safflower oil) compared to mice fed a low-fat diet (1% safflower oil). Inhibition of mRNA accumulation was 20% by 4 h and was maximal by 9 h after beginning the high-fat diet. Changes in mRNA accumulation preceded changes in enzyme activity, indicating pretranslational regulation. The rapid kinetics of G6PD mRNA accumulation depended on prior dietary history of the mice. In meal-trained mice, abundance of G6PD mRNA increased by twofold within 4 h of the onset of a low-fat meal and was maximal by 12 h. In contrast, an increase in G6PD mRNA was not observed until 12 h after refeeding starved mice and the increase was maximal (12-fold) by 27 h. Transcriptional activity of the gene was measured using the nuclear run-on assay. The G6PD probes were rigorously screened for repetitive elements and for transcription of the noncoding strand of the gene. Throughout the time course of changes in G6PD mRNA accumulation due to PUFA or refeeding, transcriptional activity of the gene did not change. Therefore, regulation of G6PD expression by nutritional status occurs at a posttranscriptional step.

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We have provided a historical and personal description of the analysis of physiological and molecular mechanisms by which diet and hormones regulate the activity of hepatic malic enzyme. For the most part, our analyses have been reductionist in approach, striving for increasingly simpler systems in which we can ask more direct questions about the molecular nature of the signaling pathways that regulate the activity of malic enzyme. The reductionist approaches that were so successful at analyzing molecular mechanisms in cells in culture may now provide the means to analyze more definitively questions about the physiological mechanisms involved in nutritional regulation of gene expression. In addition to physiological questions, however, there are still many aspects of the molecular mechanisms that have not been elucidated. Despite considerable effort from many laboratories, the molecular mechanisms by which T3 regulates transcription are not clear. Similarly, the molecular details for the mechanisms by which glucagon, insulin, glucocorticoids, and fatty acids regulate gene expression remain to be determined. The role of fatty acids is particularly interesting because it may provide a model for mechanisms by which genes are regulated by metabolic intermediates; this is a form of transcriptional regulation widely used by prokaryotic organisms and extensively analyzed in prokaryotic systems, but poorly understood in higher eukaryotes. At any specific time, there is, of course, only one rate of transcription for each copy of the malic-enzyme gene in a cell. Our long-term objective is to understand how signals from all of the relevant regulatory pathways are integrated to bring about that rate.

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Addition of triiodothyronine (T3) to chick-embryo hepatocytes in culture causes increased accumulations of malic enzyme, fatty acid synthase, acetyl-CoA carboxylase and their mRNAs. H-8 and other protein kinase inhibitors inhibited the T3-induced accumulations of these lipogenic enzymes and their mRNAs but had no effect on the activities of 6-phosphogluconate dehydrogenase and isocitrate dehydrogenase, enzymes not induced by T3 in chick-embryo hepatocytes. H-8 also had no effect on the activities of malic enzyme, fatty acid synthase, and acetyl-CoA carboxylase in hepatocytes not treated with T3. Synthesis of soluble protein, levels of mRNAs for beta-actin and glyceraldehyde-3-phosphate dehydrogenase, and induction of metallothionein mRNA by Zn2+ were unaffected by H-8 at concentrations that inhibited the T3-induced accumulation of lipogenic enzymes and their mRNAs. H-8 inhibited T3-induced transcription of the genes for both malic enzyme and fatty acid synthase but had little effect on transcription of the beta-actin or glyceraldehyde-3-phosphate dehydrogenase genes or on total RNA synthesis in isolated nuclei. H-8 also had no effect on binding of T3 to its nuclear receptor. In isolated nuclei, H-8 inhibited phosphorylation of total protein by 15-20%. Phosphorylation of only one major protein was consistently and substantially inhibited, indicating that the effect of H-8 was selective. These results suggest that on-going protein phosphorylation is required specifically for stimulation of transcription of the lipogenic genes by T3.

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Refeeding starved chicks causes a 25- to 50-fold increase in the level of malic enzyme mRNA in liver. To define the regulated steps, we measured transcriptional activity of the malic enzyme gene using the nuclear run-on assay and a variety of DNA probes specific to the malic enzyme gene. Refeeding starved chicks stimulated transcription of the malic enzyme gene in liver by 40- to 50-fold. An increased transcription rate was detectable at 1.5 h, was maximal at 3 h, and remained high at 24 h of refeeding. The level of nuclear precursor RNA for malic enzyme assessed by hybridization with intron-specific probes was high in liver of refed birds, and barely detectable in that of starved birds. These results indicate that nutritional regulation of the level of malic enzyme mRNA is transcriptional. Low levels of malic enzyme mRNA in brain, kidney, and heart correlated well with low rates of transcription of the malic enzyme gene in these tissues. In contrast to liver, neither the rate of transcription nor the steady-state level of malic enzyme mRNA was affected by refeeding starved birds. A series of DNase I-hypersensitive sites were located within 4000 base pairs upstream of the transcription start site of the malic enzyme gene in liver. The DNase I-hypersensitive region extending from the start of transcription to 400 base pairs upstream was much more pronounced in the refed state than in the starved state. This change in DNase I hypersensitivity followed the same time course as increased transcription of the malic enzyme gene. This DNase I-hypersensitive region also was present at low intensity in kidney and heart independently of nutritional state. The three constitutive DNase I-hypersensitive sites further upstream were present in liver but not in kidney or heart.

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