The gene encoding the biotin carboxylase subunit of Escherichia coli acetyl-CoA carboxylase.

We report the molecular cloning and DNA sequence of the gene encoding the biotin carboxylase subunit of Escherichia coli acetyl-CoA carboxylase. The biotin carboxylase gene encodes a protein of 449 residues that is strikingly similar to amino-terminal segments of two biotin-dependent carboxylase proteins, yeast pyruvate carboxylase and the alpha-subunit of rat propionyl-CoA carboxylase. The deduced biotin carboxylase sequence contains a consensus ATP binding site and a cysteine-containing sequence preserved in all sequenced bicarbonate-dependent biotin carboxylases that may play a key catalytic role. The gene encoding the biotin carboxyl carrier protein (BCCP) subunit of acetyl-CoA carboxylase is located upstream of the biotin carboxylase gene and the two genes are cotranscribed. As previously reported by others, the BCCP sequence encoded a protein of 16,688 molecular mass. However, this value is much smaller than that (22,500 daltons) obtained by analysis of the protein. Amino-terminal amino acid sequencing of the purified BCCP protein confirmed the deduced amino acid sequence indicating that BCCP is a protein of atypical physical properties. Northern and primer extension analyses demonstrate that BCCP and biotin carboxylase are transcribed as a single mRNA species that contains an unusually long untranslated leader preceding the BCCP gene. We have also determined the mutational alteration in a previously isolated acetyl-CoA carboxylase (fabE) mutant and show the lesion maps within the BCCP gene and results in a BCCP species defective in acceptance of biotin. Translational fusions of the carboxyl-terminal 110 or 84 (but not 76) amino acids of BCCP to beta-galactosidase resulted in biotinated beta-galactosidase molecules and production of one such fusion was shown to result in derepression of the biotin biosynthetic operon.     

Localization of the gene for acetyl-CoA carboxylase to human chromosome 17

In situ hybridization was used to localize a cDNA probe of the acetyl-CoA carboxylase gene to human metaphase chromosomes. A significant proportion of the grains were situated over chromosome band 17q21. In situ hybridization to a t(6;17)(p25;q21.33) confirmed the location of the gene proximal to 17q21.33.     

Regulation of acetyl-CoA carboxylase gene expression. Insulin induction of acetyl-CoA carboxylase and differentiation of 30A5 preadipocytes require prior cAMP action on the gene.

30A5 preadipocytes, derived from 10T1/2 mouse fibroblasts, can be induced to differentiate into adipocytes by hormone treatment. In this paper, we introduce a modified procedure to induce differentiation of 30A5 cells by pretreatment with cAMP for a brief period or by a "nutrition deprivation" pretreatment, followed by incubation in medium containing insulin. These procedures accelerate the differentiation of the preadipocytes, so that the cells are fully differentiated within 4 days instead of the 7-8 days normally required. This differentiation is accompanied by the early induction of acetyl-CoA carboxylase (ACC). ACC catalyzes the rate-limiting step in the biogenesis of long chain fatty acids. To analyze the relationship between cAMP and insulin action in the induction of ACC and cell differentiation, we identified the DNA sequences in promoter II of the ACC gene necessary for the action of insulin and cAMP. Chimeric genes between different fragments of the ACC promoter and the promoterless chloramphenicol transacetylase (CAT) gene were constructed, and stable clones containing these chimeric genes were obtained. By analyzing the CAT activities in these stable clones, we established that insulin action in inducing ACC and cell differentiation requires prior treatment of cells with cAMP and the presence of specific DNA regions in the ACC promoter for cAMP action. Stable clones containing a chimeric gene which consists of DNA sequences in promoter II that are required for insulin action, thymidine kinase promoter, and the CAT gene did not respond to insulin. However, when the DNA sequences required for cAMP action were placed in this chimeric gene, it responded to insulin upon prior treatment of 30A5 cells with cAMP. Thus, cAMP and insulin, whose physiological actions generally appear to be antagonistic, are synergistically interacting in the induction of ACC and the differentiation of 30A5 cells.     

Hepatic zonation of acetyl-CoA carboxylase activity.

The activities of several hepatic enzymes are preferentially zonated to the periportal or perivenous cells of the liver acinus. Employing dual-digitonin-pulse perfusion of rat liver in the study of acetyl-CoA carboxylase (ACC), we have identified a heretofore unrecognized feature of hepatic zonation, namely an intrahepatic gradient in enzyme specific activity. ACC activity shows a relative periportal localization in normally feeding rats, even when corrected for ACC protein mass. In contrast with results previously reported by us [Evans, Quistorff & Witters (1989) Biochem. J. 259, 821-829], the total mass of both hepatic ACC isoenzymes was not found to differ between the two hepatic zones in the present study. In perfusion eluates from fed animals, periportal ACC displays enhanced citrate reactivity and two kinetic components of acetyl-CoA reactivity; the largest periportal/perivenous gradient (5-fold) is accounted for by a species with a lower Km for acetyl-CoA. The zonal gradient in ACC maximal velocity, measured in eluates from fed rats, does not persist after ACC purification, although the isolated periportal enzyme, like dephosphorylated ACC, has a lower activation constant for citrate. Total ACC protein phosphatase activity is higher in periportal eluates, but no differences in the activities of either a 5'-AMP-activated ACC kinase or the cyclic-AMP-dependent protein kinase are noted between the hepatic zones. The induction of total hepatic ACC mass and specific activity, on fasting/refeeding with a high-carbohydrate diet, abolishes the periportal/perivenous activity gradient, largely owing to a selective activation of perivenous enzyme. Nutritional induction is also accompanied by a marked alteration in ACC acetyl-CoA kinetics and abolition of the gradient in total ACC phosphatase. These studies indicate that hepatic enzyme zonation, which is often attributed to differential expression of enzyme protein, may result from zonal variations in enzyme specific activity, owing to differences in allosteric regulation and/or covalent modification.     

Physiological regulation of acetyl-CoA carboxylase gene expression: effects of diet, diabetes, and lactation on acetyl-CoA carboxylase mRNA

We measured acetyl-CoA carboxylase mRNA levels in various tissues of the rat under different nutritional and hormonal states using a cDNA probe. We surveyed physiological conditions which are known to alter carboxylase activity, and thus fatty acid synthesis, to determine whether changes in the levels of carboxylase mRNA are involved. The present studies include the effects of fasting and refeeding, diabetes and insulin, and lactation on carboxylase mRNA levels. Northern blot analysis of liver RNA revealed that fasting followed by refeeding animals a fat-free (high carbohydrate) diet dramatically increased the amount of carboxylase mRNA compared to the fasted condition. These changes in the level of mRNA correspond to changes in the activity and amount of acetyl-CoA carboxylase. Acetyl-CoA carboxylase mRNA levels in epididymal fat tissue decreased upon fasting and increased to virtually normal levels after 72 h of refeeding, closely resembling the liver response. The amount of acetyl-CoA carboxylase mRNA decreased markedly in epididymal fat tissue of diabetic rats as compared to nondiabetic animals. However, 6 h after injection of insulin the mRNA level returned to that of the nondiabetic animals. Gestation and lactation also affected the levels of carboxylase mRNA in both liver and mammary gland. Maximum induction in both tissues occurred 5 days postpartum. These studies suggest that these diverse physiological conditions affect fatty acid synthesis in part by altering acetyl-CoA carboxylase gene expression.     

Knockdown of the plastid-encoded acetyl-CoA carboxylase gene uncovers functions in metabolism and development

De novo fatty acid biosynthesis in plants relies on a prokaryotic-type acetyl-CoA carboxylase (ACCase) that resides in the plastid compartment. The enzyme is composed of four subunits, one of which is encoded in the plastid genome, whereas the other three subunits are encoded by nuclear genes. The plastid gene (accD) encodes the β-carboxyltransferase subunit of ACCase and is essential for cell viability. To facilitate the functional analysis of accD, we pursued a transplastomic knockdown strategy in tobacco (Nicotiana tabacum). By introducing point mutations into the translational start codon of accD, we obtained stable transplastomic lines with altered ACCase activity. Replacement of the standard initiator codon AUG with UUG strongly reduced AccD expression, whereas replacement with GUG had no detectable effects. AccD knockdown mutants displayed reduced ACCase activity, which resulted in changes in the levels of many but not all species of cellular lipids. Limiting fatty acid availability caused a wide range of macroscopic, microscopic, and biochemical phenotypes, including impaired chloroplast division, reduced seed set, and altered storage metabolism. Finally, while the mutants displayed reduced growth under photoautotrophic conditions, they showed exaggerated growth under heterotrophic conditions, thus uncovering an unexpected antagonistic role of AccD activity in autotrophic and heterotrophic growth.

Analysis of the only plastid genome-encoded fatty acid biosynthesis gene reveals functions in plastid division and seed development, and antagonistic roles in autotrophic and heterotrophic growth.     

A two-component nodule-specific enhancer in the soybean N23 gene promoter.

The two positive cis elements in the soybean nodulin N23 gene promoter were investigated in transgenic Lotus corniculatus plants and shown to constitute a two-component nodule-specific enhancer. Equal quantitative contributions from the two components were suggested by the similar expression level of chimeric N23-chloramphenicol acetyltransferase genes after deletion of either the distal positive element (PE-A, -320 to -298) or the proximal positive element (PE-B, -257 to -165). A combined effect of the two elements was indicated by orientation-dependent effects in the N23 promoter, and by the observation that neither PE-A nor PE-B separately was able to confer any activity to the cauliflower mosaic virus 35S minimal promoter. Reactivation of the minimal N23 and the minimal cauliflower mosaic virus 35S promoters by the inverted complete element (PE-AB) further suggested that PE-AB is a nodule-specific enhancer containing two equally strong enhancer components. Two 12-bp sequence motifs, InvA and InvB, constituting an inverted repeat, were identified as the core of the enhancer components PE-A and PE-B, respectively. Point mutations in InvA or InvB resulted in lower expression levels and mutations in both abolished enhancer activity. Point mutations in two nodulin consensus sequences, 5'-CTCTT and 5'-AAAGAT located downstream of PE-AB, resulted in a decreased level of expression, confirming the involvement of these two motifs in nodulin gene expression. The binding site for the nodule-specific trans-acting factor, NAT2, present in the PE-A segment, was removed without affecting expression significantly. This interaction is, therefore, dispensable for enhancer activity.     

Changes in the activity of acetyl-CoA carboxylase during rape-seed formation.

During the formation of rape-seeds, lipid accumulated in the cotyledons from 16 days after pollination, rising to a plateau after 28 days. The accumulation of lipid was preceded by a marked rise in acetyl-CoA carboxylase activity, which declined rapidly, correlating with the decline in rate of lipid formation. Incubation of rape-seed extracts with avidin-agarose resulted in a decrease in acetyl-CoA carboxylase activity in the extract. Polyacrylamide-gel electrophoresis of polypeptides bound to avidin-agarose showed the presence of a polypeptide of Mr 225 000. The intensity of this band increased during the period of increase of acetyl-CoA carboxylase activity in the seeds.     

Hormonal regulation of acetyl-CoA carboxylase activity in the liver cell.

Chick liver cell monolayers synthesize fatty acids at in vivo rates and are responsive to insulin and glucagon. High rates of fatty acid synthesis are maintained with insulin present and lost slowly without insulin. Glucagon or 3',5'-cyclic AMP cause immediate cessation of fatty acid synthesis. The site of inhibition appears to be cytoplasmic acetyl-CoA carboxylase which catalyzes the first committed step of fatty acid synthesis. Liver carboxylase exists either as catalytically inactive protomers or active filamentous polymers. Citrate, an allosteric activator of the enzyme, is required for both catalysis and polymerization. Glucagon and cAMP cause an immediate decrease in the cytoplasmic citrate concentration of chick liver cells apparently by inhibiting the conversion of glucose to citrate at the phosphofructokinase reaction. Since fatty acid synthesis and citrate level are closely correlated, citrate appears to be a feed-forward activator of the carboxylase in vivo. Compelling evidence indicates that carboxylase filaments are present in the intact cell when citrate levels are high and depolymerize when citrate levels fall. Hence, carboxylase activity and fatty acid synthetic rate appear to be determined by cytoplasmic citrate level.