Precursor of a mitochondrial enzyme accumulates in the cytoplasm of preen glands for a specialized function

Malonyl-CoA decarboxylase in the mitochondria of the liver of goose is immunologically identical with the decarboxylase in the cytoplasm of the uropygial gland (Buckner et al. (1978) $\text{Arch. Biochem. Biophys.}$ 186, 152–163). Messenger RNA was isolated from the liver and the uropygial gland and translated in a rabbit reticulocyte system. Specific immunoprecipitation of the translation products with anti malonyl-CoA decarboxylase showed that in both cases the primary translation product was a 50 K dalton peptide identical in size to the cytoplasmic enzyme in the gland. Specific immunoprecipitation of malonyl-CoA decarboxylase from liver slices which had been incubated with [³⁵S]methionine showed that the mature mitochondrial enzyme was a 47 K dalton peptide, 3 K daltons smaller than the primary translation product and the isolated cytoplasmic enzyme. These results suggest that the decarboxylase is proteolytically processed during transport into the mitochondria and that the large amount of the cytoplasmic decarboxylase found in the gland represents accumulation of the unprocessed precursor form of the normally mitochondrial enzyme.     

Molecular cloning, nucleotide sequence, and tissue distribution of malonyl-CoA decarboxylase

Malonyl-CoA decarboxylase was purified from goose uropygial gland, reduced, carboxymethylated, and digested with trypsin. Several peptides were purified by high performance liquid chromatography and their amino acid sequences determined. Oligonucleotide probes were prepared based on their amino acid sequences. Size-selected RNA from the goose uropygial gland was used to construct cDNA libraries in lambda gt11 and pUC9 vectors. Immunological screening of the lambda gt11 cDNA library yielded one clone, lambda DC1, which contained a 2.2-kilobase pair insert; hybridization with the synthetic oligonucleotide probes confirmed its identity as malonyl decarboxylase. Screening of the pUC9 cDNA library with the insert of lambda DC1 as a probe detected one clone, pDC2, with an insert of 2.9 kilobase pairs. The nucleotide sequences of the two cDNAs revealed an open reading frame encoding a polypeptide of 462 amino acids. The deduced amino acid sequence was confirmed as malonyl-CoA decarboxylase by matching it to the amino acid sequences of three tryptic peptides derived from mature enzyme. Northern blot analysis of mRNA from goose brain, kidney, liver, lung, and gland revealed malonyl-decarboxylase mRNA of 3000 nucleotides. Since clone pDC2 contains a 2928-nucleotide insert, it represents nearly the full length of mRNA. Brain, kidney, lung, and liver contained less than 1% of the malonyl-CoA decarboxylase mRNA in the gland. Southern blot analysis of genomic DNA showed a single band in both liver and gland, suggesting that malonyl-CoA decarboxylase is a single copy gene.     

Malonyl-CoA decarboxylase from the uropygial gland of waterfowl: purification, properties, immunological comparison, and role in regulating the synthesis of multimethyl-branched fatty acids.

Analysis of the acyl portion of the wax from the uropygial gland of muscovy duck, wood duck, (Cairininae subfamily) and Canadian goose (Anserinae) by combined gas-liquid chromatography and mass spectrometry showed that 2,4,6-trimethyloctanoic acid and 2,4,6-trimethylnonanoic acid were the major (~100%) components. Similar analyses of the wax from the glands of mallard and Peking duck (Anatinae) showed that 2- and 4-mono-methylhexanoic acids predominated (>75%) with no multimethyl-branched acids. The uropygial glands of the former group contained 20 to 100 times as much malonyl-CoA decarboxylase activity as those of the latter group. These results strongly support the hypothesis that this decarboxylase, by causing specific decarboxylation of malonyl-CoA, makes available only methylmalonyl-CoA for fatty acid synthesis, and thus causes the production of multimethyl-branched acids. Malonyl-CoA decarboxylase was purified to apparent homogeniety in 30% yield from the uropygial glands of muscovy and wood ducks. Properties of the enzyme from the ducks, such as S_20.w (7.8 S), molecular weight (190,000) subunit composition (4 × 47,000), amino acid composition, strict substrate specificity, pH optimum (~9.0), K_m (~33 μm), V (~80 μmol/min/mg), and inhibition by SH-directed reagents were similar to those observed with the decarboxylase from the domestic goose. Antiserum prepared against the goose enzyme cross-reacted with and inhibited the decarboxylase from the four genera of ducks and Canadian goose. Ouchterlony double-diffusion analyses showed fusion of precipitant lines with the enzyme from muscovy, wood duck, and Canadian goose, whereas spurs were observed with the enzymes from mallard and Peking ducks. Immunoelectrophoresis showed that the decarboxylases from muscovy and wood ducks were similar and that they were different from the enzyme from the domestic goose. It appears that during evolution, the subfamilies (Anserinae and Cairininae) which synthesize multimethyl-branched acids acquired the ability to produce a high level of malonyl-CoA decarboxylase, an enzyme which is also present in low levels in other organisms.     

Synthesis of multimethyl-branched fatty acids by avian and mammalian fatty acid synthetase and its regulation by malonyl-CoA decarboxylase in the uropygial gland

Fatty acid synthetase, partially purified by gel filtration with Sepharose 4B from goose liver, showed the same relative rate of incorporation of methylmalonyl-CoA (compared to malonyl-CoA) as that observed with the purified fatty acid synthetase from the uropygial gland. In the presence of acetyl-CoA, methylmalonyl-CoA was incorporated mainly into 2,4,6,8-tetramethyldecanoic acid and 2,4,6,8,10-pentamethyl-dodecanoic acid by the enzyme from both sources. Methylmalonyl-CoA was a competitive inhibitor with respect to malonyl-CoA for the enzyme from the gland just as previously observed for fatty acid synthetase from other animals. Furthermore, rabbit antiserum prepared against the gland enzyme cross-reacted with the liver enzyme, and Ouchterlony double-diffusion analyses showed complete fusion of the immunoprecipitant lines. The antiserum inhibited both the synthesis of n-fatty acids and branched fatty acids catalyzed by the synthetase from both liver and the uropygial gland. These results suggest that the synthetases from the two tissues are identical and that branched and n-fatty acids are synthesized by the same enzyme. Immunological examination of the 105,000g supernatant prepared from a variety of organs from the goose showed that only the uropygial gland contained a protein which cross-reacted with the antiserum prepared against malonyl-CoA decarboxylase purified from the gland. Thus, it is concluded that the reason for the synthesis of multimethyl-branched fatty acids by the fatty acid synthetase in the gland is that in this organ the tissue-specific and substrate-specific decarboxylase makes only methylmalonyl-CoA available to the synthetase. Fatty acid synthetase, partially purified from the mammary gland and the liver of rats, also catalyzed incorporation of [methyl-¹⁴C]methylmalonyl-CoA into 2,4,6,8-tetramethyldecanoic acid and 2,4,6,8-tetramethylundecanoic acid with acetyl-CoA and propionyl-CoA, respectively, as the primers. Evidence is also presented that fatty acids containing straight and branched regions can be generated by the fatty acid synthetase from the rat and goose, from methylmalonyl-CoA in the presence of malonyl-CoA or other precursors of n-fatty acids. These results provide support for the hypothesis that, under the pathological conditions which result in accumulation of methylmalonyl-CoA, abnormal branched acids can be generated by the fatty acid synthetase.     

Purification and properties of malonyl-CoA decarboxylase from rat liver mitochondria and its immunological comparison with the enzymes from rat brain, heart, and mammary gland.

Malonyl-CoA decarboxylase (EC 4.1.1.9) was found to be localized in the mitochondria in rat liver. Low ionic strength (10 mm Na phosphate) buffer extracted the bulk (>85%) of the enzyme from the mitochondria. From this extract the enzyme was purified over 2,000-fold using a combination of (NH₄)₂SO₄ precipitation, gel filtration with Sepharose 4B and Sephadex G-150, ion exchange chromatography with QAE-Sephadex and CM-Sephadex, and finally chromatography on NADP-agarose. The purified enzyme, which had a specific activity of about 16 μmol/min/mg, appeared to be electrophoretically homogeneous and had a molecular weight of 160,000. The decarboxylase had a broad pH optimum between 8.5 and 10.0 and showed a typical Michaelis-Menten substrate saturation pattern from which K_m and V were calculated to be 54 μm and 18.8 μmol/min/mg, respectively. This enzyme decarboxylated neither malonic acid nor methylmalonyl-CoA and was severely inhibited by thiol-directed reagents such as p-hydroxymercuribenzoate and N-ethylmaleimide but not by iodoacetamide. Acetyl-CoA, propionyl-CoA, and methylmalonyl-CoA also inhibited the enzyme. The purified decarboxylase was immunogenic in rabbits and Ouchterlony double diffusion analysis revealed a single precipitant line with the purified enzyme. The IgG fraction isolated from the antiserum inhibited the enzyme from not only liver mitochondria but also the mammary gland, heart, and kidney of the rat. However, malonyl-CoA decarboxylase from rat brain mitochondria was not inhibited by the antibody. Malonyl-CoA decarboxylase purified from the uropygial gland of a domestic goose neither cross reacted nor was it inhibited by the antiserum prepared against the rat liver mitochondrial enzyme and the antibody against the goose enzyme neither cross-reacted nor inhibited the enzyme from the rat. It is proposed that a role for mitochondrial malonyl-CoA decarboxylase is to decarboxylate malonyl-CoA generated by propionyl-CoA carboxylase and thus protect mitochondrial enzymes susceptible to inhibition by malonyl-CoA.     

Lipid biosynthesis in sebaceous glands: regulation of the synthesis of n- and branched fatty acids by malonyl-coenzyme A decarboxylase.

Crude cell-free extracts isolated from the uropygial glands of goose catalyzed the carboxylation of propionyl-CoA but not acetyl-CoA. However, a partially purified preparation catalyzed the carboxylation of both substrates and the characteristics of this carboxylase were similar to those reported for chicken liver carboxylase. The Km and Vmax for the carboxylation of either acetyl-CoA or propionyl-CoA were 1.5 times 10- minus-5 M and 0.8 mumol per min per mg, respectively. In the crude extracts an inhibitor of the acetyl-CoA carboxylase activity was detected. The inhibitor was partially purified and identified as a protein that catalyzed the rapid decarboxylation of malonyl-CoA. This enzyme was avidin-insenitive and highly specific for malonyl-CoA with very low rates of decarboxylation for methylmalonyl-CoA and malonic acid. Vmax and Km for malonyl-CoA decarboxylation, at the pH optimum of 9.5, were 12.5 mumol per min per mg and 8 times 10- minus-4 M, respectively. The relative activities of the acetyl-CoA carboxylase and malonyl-CoA decarboxylase were about 4 mumol per min per gland and 70 mumoles per min per gland, respectively. Therefore acetyl-CoA and methylmalonyl-CoA should be the major primer and elongating agent, respectively, present in the gland. The major fatty acid formed from these precursors by the fatty acid synthetase of the gland would be 2,4,6,8-tetramethyl-decanoic acid which is known to be the major fatty acid of the gland (Buckner, J. S. and Kolattukudy, P. E. (1975), Biochemistry, following paper). Therefore it is concluded that the malonyl-CoA decarboxylase controls fatty acid synthesis in this gland.     

Uropygial gland size,feather holes and moult performance in the House Sparrow Passer domesticus

Feather holes represent damage to the plumage of birds and are correlated with delayed moult. Uropygial gland size is negatively correlated with feather holes. Consequently, it was predicted that birds with smaller uropygial glands would have more feather holes, and that this would affect moult performance. I examined this prediction in the House Sparrow Passer domesticus. Individuals with smaller uropygial glands had more feather holes, and those with more feather holes moulted later and faster. Therefore, uropygial gland size seemed to affect moult performance via its effect on feather holes. Uropygial gland size may have a positive effect on plumage quality, through a negative effect on feather holes, and therefore on moult timing and speed.     

Stereospecificity of malonyl-CoA decarboxylase, acetyl-CoA carboxylase, and fatty acid synthetase from the uropygial gland of goose

Malonyl-CoA decarboxylase from the uropygial gland of goose decarboxylated (R,S)-methylmalonyl-CoA at a slow rate and introduced 3H from [3H]2O into the resulting propionyl-CoA. Carboxylation of this labeled propionyl-CoA by propionyl-CoA carboxylase from pig heart and acetyl-CoA carboxylase from the uropygial gland completely removed 3H. Repeated treatment of (R,S)-[methyl-14C]methylmalonyl-CoA with the decarboxylase converted 50% of the substrate into propionyl-CoA, whereas (S)-methylmalonyl-CoA, generated by both carboxylases, was completely decarboxylated. Radioactive (R)- (S), and (R,S)-methylmalonyl-CoA were equally incorporated into fatty acids by fatty acid synthetase from the uropygial gland. The residual methylmalonyl-CoA remaining after fatty acid synthetase reaction on (R,S)-methylmalonyl-CoA was also racemic. These results show that: (a) the decarboxylase is stereospecific, (b) replacement of the carboxyl group by hydrogen occurs with retention of configuration, (c) acetyl-CoA carboxylase of the uropygial gland generates (S)-methylmalonyl-CoA from propionyl-CoA, and (d) fatty acid synthetase is not stereospecific for methylmalonyl-CoA.     

Malonyl-CoA decarboxylase from Mycobacterium tuberculosis and Pseudomonas fluorescens.

Malonyl-CoA decarboxylase was partially purified (nearly 1000-fold) from Mycobacterium tuberculosis H37Ra by ammonium sulfate precipitation, gel filtration with Sepharose 6B, and chromatography on DEAE Sephacel, carboxymethyl-Sephadex, and NADP-agarose. Polyacrylamide gel electrophoresis showed a major band (60–70%), which contained the enzymatic activity, and a minor band which had no decarboxylase activity. The molecular weight of the enzyme was 44,000, and the PI and pH optimum were 6.7 and 5.5, respectively. The enzyme showed a typical Michaelis-Menten substrate saturation, with an apparent K_m and V of 0.2 mm and 3.85 μmol/min/mg, respectively. It catalyzed decarboxylation of methylmalonyl-CoA only at 5% of the rate observed with malonyl-CoA, whereas malonic acid and succinyl-CoA were not decarboxylated. Antibodies prepared against malonyl-CoA decarboxylase from the uropygial glands of goose and rat liver mitochondria did not inhibit the bacterial enzyme. Avidin did not inhibit the enzyme suggesting that biotin was not involved in the reaction. Thiol-directed reagents inhibited the enzyme as did CoA, acetyl-CoA, propionyl-CoA, methylmalonyl-CoA, and succinyl-CoA. Malonyl-CoA decarboxylase was also partially purified from malonate-grown Pseudomonas fluorescens. The molecular weight of this enzyme was 56,000 and the pH optimum and apparent K_m were 5.5 and 1 mm, respectively. Unlike the mycobacterial enzyme, this enzyme was insensitive to p-hydroxymercuribenzoate, acetyl-CoA, and propionyl-CoA, and it was less sensitive to inhibition by succinyl-CoA and CoA than the mycobacterial enzyme. The size and properties of the two bacterial enzymes suggest that these are quite unlike the mammalian and avian enzymes and that they constitute a different class of malonyl-CoA decarboxylases.     

Evidence for an "active serine" in each fatty acid synthetase peptide.

Ultracentrifugally homogeneous fatty acid synthetase was isolated from the uropygial gland of goose by a one-step purification procedure. Formation of fatty acids from malonyl-CoA and hydrolysis of palmitoyl-CoA catalyzed by the synthetase were inhibited to an equal extent by diisopropylfluorophosphate. With labeled inhibitor, it was shown that one mole of the inhibitor was covalently attached per mole of the subunit of the enzyme. Sodium dodecyl sulphate electrophoresis showed that all of the label was contained in a 270,000 M.Wt peptide. That the active serine was not at the loading site was suggested by the observations that neither acetylation nor malonylation of the enzyme affected the reaction of the enzyme with the inhibitor and acetylation or malonylation of the enzyme was not affected by this inhibitor. Thus, each fatty acid synthetase peptide is shown to have one active serine which most probably is at the chain terminating active site of the peptide.     

Synthesis of methyl-branched fatty acids from methylmalonyl-CoA by fatty acid synthase from both the liver and the harderian gland of the guinea pig

Partially purified fatty acid synthase preparations from both the liver and the harderian gland of guinea pig showed the same relative rates of utilization of methylmalonyl-CoA when compared to malonyl-CoA. Radio gas-liquid chromatographic analysis of the products generated from [methyl-14C]methylmalonyl-CoA and from [2-14C]malonyl-CoA in the presence of unlabeled methylmalonyl-CoA showed that the enzyme from both tissues generated identical mixtures of branched fatty acids. Therefore, it is concluded that the production of methyl-branched acids only by the harderian gland is not due to any unique specificity of the fatty acid synthase of this gland, in contrast to the conclusion reached from results obtained from mass spectrometry of the products generated by crude extracts (Y. Seyama, H. Otsuka, A. Kawaguchi, and T. Yamakawa J. Biochem. 90, 789-797, 1981).     

Differentiation in culture of cells from an avian holocrine secretory gland: preparation of isolated cells and conditions which induce accumulation of malic enzyme

Mammalian sebaceous glands contain cells which are constantly going through a process of cell division, differentiation, and destruction. Birds have an analogous holocrine secretory gland, the uropygial gland, which is an excellent model for mammalian sebaceous glands and for analysis of the regulation of differentiation. Isolated uropygial cells were purified in good yield, and with high viability, after enzymatic digestion of the duck uropygial gland. Almost exclusively progenitor (basal) cells are recovered after separation of isolated cells on a Percoll density gradient; mature uropygial cells are destroyed during preparation of isolated cells. In primary culture, uropygial gland cells grow to confluence and partially duplicate the in vivo differentiation pathway. Malic enzyme activity increases 30-fold during 4 wks in culture, but there is little, if any, accumulation of fatty acid synthase and only a modest deposition of fat droplets. Medium conditioned by chick embryo fibroblasts inhibits the accumulation of malic enzyme without affecting cell growth. The basement membrane components, collagen, laminin, and Matrigel, which stimulate differentiation in other cell systems, were without effect on uropygial gland cultures. Triiodothyronine, cyclic AMP, and dexamethasone together with isobutylmethylxanthine had no effect on cell growth or malic enzyme activity. Epidermal growth factor, which stimulates cell division, increased cell number with no increase in malic enzyme accumulation. Factors which would stimulate further differentiation are missing from our culture system, but may include components of the basal lamina and/or factors secreted by mesenchymal cells.     

Lipid biosynthesis in the sebaceous glands: synthesis of multibranched fatty acids from methylmalonyl-coenzyme A in cell-free preparations from the uropygial gland of goose.

Cell-free extracts from the uropygial gland of goose catalyzed the incorporation of malonyl-CoA and methylmalonyl-CoA into n- and multi-branched fatty acids, respectively, with NADPH as the preferred reductant. Methylmalonyl-CoA was shown to be incorporated almost exclusively into the acyl portion of wax esters by the cell-free extract while malonyl-CoA was incorporated into polar lipids and both the acyl and alcohol portions of the wax. The optimal pH for the synthesis of both n- and multibranched acids was 6.0. Apparent Km and Vmax for malonyl-CoA were 2 times 10- minus-4 M and 250 nmol per min per mg, respectively, while the Km and Vmax for methylmalonyl-CoA were 7.7 times 10- minus-4 M and 0.8 nmol per min per mg, respectively with 105,000g supernatant; but partial purification resulted in a tenfold decrease in Km values. The partially purified synthetase preparation catalyzed the formation of n-C16 acid (80%) and n-C18 acid (20%) from acetyl-CoA and malonyl-CoA. With the same synthetase preparation and the appropriate primer methylmalonyl-CoA was converted into 2,4,6,8-tetramethyldecanoic acid and 2,4,6,8-tetramethylundecanoic acid which were identified by radio gas-liquid chromatography and combined gas chromatography-mass spectrometry. Experiments with an equimolecular mixture of acetyl-CoA and propionyl-CoA showed that the synthetase preferred acetyl-CoA as a primer. Since malonyl-CoA is known to be rapidly decarboxylated in the gland, acetyl-CoA and methylmalonyl-CoA are expected to be the major primer and elongating agent, respectively, available in the gland and therefore 2,4,6,8-tetramethyldecanoic acid should be the major product. Combined gas-liquid chromatography and mass spectrometry demonstrated that this acid was in fact the major acid of the gland.     

Uropygial gland size correlates with feather holes,body condition and wingbar size in the house sparrow Passer domesticus

The uropygial gland is an organ exclusive of birds that secretes an oily substance, the uropygial secretion, the functions of which are still debated. One of the proposed hypothesis is its possible action against chewing lice (order Phthiraptera), a group of avian ectoparasites that feed on feathers, causing different types of harm. However, this hypothesis lacks support. The present study analyses the relationship between uropygial gland size and the number of feather holes (which is correlated with the load of chewing lice) in the house sparrow Passer domesticus. Moreover, the relationship between the uropygial gland size and different aspects of sparrow health (body condition, immunocompetence and haematocrit), as well as sexually selected traits in males (badge and wingbar size), is tested. The results show a negative correlation between uropygial gland size and number of feather holes, a result found both years of the study. This result supports the hypothesis that uropygial secretion is used against chewing lice. Uropygial gland size also correlated positively with body condition (residuals of body mass relative to tarsus length) and immunocompetence, being therefore related to bird health. After a year in captivity, with resources provided ad libitum, no correlation was found between individual uropygial gland size and body condition or haematocrit, perhaps because the negative effect that chewing lice exert on bird health was offset by captivity conditions. Uropygial gland size was not correlated with badge size, but it was correlated with wingbar size, which furthermore supports the contention that this sexually selected signal acts as an indicator of lice resistance in the house sparrow. In summary, this study supports the idea of a positive relationship between uropygial gland and bird health in the house sparrow, the gland secretion affording resistance against chewing lice.     

Overexpression of a modified human malonyl-CoA decarboxylase blocks the glucose-induced increase in malonyl-CoA level but has no impact on insulin secretion in INS-1-derived (832/13) beta-cells

The long-chain acyl-CoA (LC-CoA) model of glucose-stimulated insulin secretion (GSIS) holds that secretion is linked to a glucose-induced increase in malonyl-CoA level and accumulation of LC-CoA in the cytosol. We have previously tested the validity of this proposal by overexpressing goose malonyl-CoA decarboxylase (MCD) in INS-1 cells, but these studies have been criticized due to: 1) the small insulin secretion response (2-4-fold) of the INS-1 cells used; 2) unknown contribution of the ATP-sensitive K(+) (K(ATP)) channel-independent pathway of GSIS in INS-1 cells, which has been implicated as the site at which lipids regulate insulin granule exocytosis; and 3) deletion of the N-terminal mitochondrial targeting sequence, but not the C-terminal peroxisomal targeting sequence in the goose MCD construct, raising the possibility that a significant fraction of the overexpressed enzyme was localized to peroxisomes. To address these outstanding concerns, INS-1-derived 832/13 cells, which exhibit robust K(ATP) channel-dependent and -independent pathways of GSIS, were treated with a new adenovirus encoding human MCD lacking both its mitochondrial and peroxisomal targeting sequences (AdCMV-MCD Delta 5), resulting in large increases in cytosolic MCD activity. Treatment of 832/13 cells with AdCMV-MCD Delta 5 completely blocked the glucose-induced rise in malonyl-CoA and attenuated the inhibitory effect of glucose on fatty acid oxidation. However, MCD overexpression had no effect on K(ATP) channel-dependent or -independent GSIS in 832/13 cells. Furthermore, combined treatment of 832/13 cells with AdCMV-MCD Delta 5 and triacsin C, an inhibitor of long chain acyl-CoA synthetase that reduces LC-CoA levels, did not impair GSIS. These findings extend our previous observations and are not consistent with the LC-CoA hypothesis as originally set forth.     

MCD encodes peroxisomal and cytoplasmic forms of malonyl-CoA decarboxylase and is mutated in malonyl-CoA decarboxylase deficiency.

Malonyl-CoA decarboxylase (MCD) catalyzes the proton-consuming conversion of malonyl-CoA to acetyl-CoA and CO(2). Although defects in MCD activity are associated with malonyl-CoA decarboxylase deficiency, a lethal disorder characterized by cardiomyopathy and developmental delay, the metabolic role of this enzyme in mammals is unknown. A computer-based search for novel peroxisomal proteins led to the identification of a candidate gene for human MCD, which encodes a protein with a canonical type-1 peroxisomal targeting signal of serine-lysine-leucine(COOH). We observed that recombinant MCD protein has high intrinsic malonyl-CoA decarboxylase activity and that a malonyl-CoA decarboxylase-deficient patient has a severe mutation in the MCD gene (c.947-948delTT), confirming that this gene encodes human MCD. Subcellular fractionation experiments revealed that MCD resides in both the cytoplasm and peroxisomes. Cytoplasmic MCD is positioned to play a role in the regulation of cytoplasmic malonyl-CoA abundance and, thus, of mitochondrial fatty acid uptake and oxidation. This hypothesis is supported by the fact that malonyl-CoA decarboxylase-deficient patients display a number of phenotypes that are reminiscent of mitochondrial fatty acid oxidation disorders. Additional support for this hypothesis comes from our observation that MCD mRNA is most abundant in cardiac and skeletal muscles, tissues in which cytoplasmic malonyl-CoA is a potent inhibitor of mitochondrial fatty acid oxidation and which derive significant amounts of energy from fatty acid oxidation. As for the role of peroxisomal MCD, we propose that this enzyme may be involved in degrading intraperoxisomal malonyl-CoA, which is generated by the peroxisomal beta-oxidation of odd chain-length dicarboxylic fatty acids.     

Isolation and characterization of a tryptic fragment containing the thioesterase segment of fatty acid synthetase from the uropygial gland of goose.

Trypsin treatment of purified fatty acid synthetase from the uropygial gland of goose released a 33,000 molecular weight peptide from the 270,000 molecular weight synthease. A combination of ammonium sulfate precipitation, Sephadex G-100 gel filtration, anion-exchange chromatography with QAE-Sephadex, and cation-exchange chromatography with cellulose phosphate gave rise to the first homogeneous preparation of the 33,000 molecular weight fragment containing fatty acyl-CoA thioesterase activity. Amino acid composition of this peptide was quite similar to that of the intact fatty acid synthetase except for a lower valine content; a partial specific volume of 0.734 was calculated for the thioesterase fragment. The pH optimum for the thioesterase was near 7.5 and the enzyme showed a high degree of preference for CoA esters of fatty acids with 16 or more carbon atoms. Palmitoyl-CoA inhibited the enzyme and therefore the rate of hydrolysis was not proportional to the amount of protein at low concentrations. Inclusion of bovine serum albumin in the reaction mixture prevented this inhibition. Disregarding the substrate inhibition, an apparent K_m of 5 × 10^?5m and a V of 340 nmol/min/mg were calculated. The thioesterase was inhibited by active serine-directed reagents such as phenylmethanesulfonyl fluoride and diisopropyl fluorophosphate as well as by SH-directed reagents as p-chloromercuribenzoate and N-ethylmaleimide. The isolated thioesterase fragment generated antibodies in rabbits and the antithioesterase inhibited the enzymatic activity of fatty acid synthetase. The antithioesterase showed immunoprecipitant lines with fatty acid synthetase from the uropygial gland and the synthetase from the liver of goose. Anti-fatty acid synthetase prepared against the enzyme from the gland cross-reacted with the thioesterase segment. Even though the synthetase from the uropygial gland synthesizes multimethyl-branched fatty acids in vivo, the thioesterase segment of this synthetase appears to be quite similar to that isolated from the rat.