The prosthetic group of citrate-lyase acyl-carrier protein.

The acyl carrier protein of citrate lyase contains adenine, phosphate, sugar, cysteamine, beta-alanine and pantoic acid in a molar ratio of 1:2:2:1:1:1. Peptides containing these components in the same stoichiometric relationship were isolated after proteolytic digestion of acyl carrier protein. All components were linked together in a single prosthetic group. This was released from the peptide by mild alkaline hydrolysis. Under these conditions a phosphodiester bond is cleaved which links the prosthetic group to a serine residue of the peptide. Incubation of the prosthetic-group-containing peptide with phosphodiesterase I yielded 4'-phosphopantetheine and adenylic acid. The 5'-AMP was not free but was substituted by presumably an acidic sugar residue, which was released by mild acid hydrolysis yielding free 5'-AMP. It was concluded from these results that the prosthetic group of citrate lyase acyl carrier protein consists of a substituted isomeric dephospho-CoA. This is bound to the protein by the 5'-phosphate group of adenylic acid. The 4'-phosphopantetheine residue is bound by a phosphodiester linkage to the 2' or 3' position of ribose and the remaining hydroxyl group of ribose is substituted with presumably an acidic sugar residue. The structural similarities of this prothetic group and coenzyme A are discussed and related to the catalytic properties of citrate lyase.     

Isolation,purification, and properties of mammalian and avian liver and yeast fatty acid synthetase acyl carrier proteins

Acyl carrier proteins were isolated from rat, human, pigeon, and chicken liver and yeast fatty acid synthetase complexes. These proteins were separated from the other proteins of subunit I of each complex by ultrafiltration after dialysis of subunit I for 3 h against low ionic strength buffer [Qureshi et al. (1974) Biochem. Biophys. Res. Commun.60, 158–165]. Subunit I of each fatty acid synthetase was previously separated from subunit II by affinity chromatography on Sepharose ?-aminocaproyl pantetheine and subsequent sucrose density gradient centrifugation. The separated acyl carrier proteins were then subjected to gel filtration on a Sephadex G-50 column. The proteins obtained from each fatty acid synthetase were homogeneous with respect to size and charge on gel filtration, paper and disc gel electrophoresis, and chromatography on diethylaminoethyl-cellulose. The physical properties and the ability to accept acetyl and malonyl groups from acetyl- and malonyl-CoA in the presence of transacylase were similar to those of Escherichia coli acyl carrier protein. These proteins ranged in molecular weight from 7500 to 10,000. Each of the acyl carrier proteins showed the presence of β-alanine and each yielded acetyl- and malonyl-A₁ and A₂ peptic peptides, thus indicating the presence of a 4′-phosphopantetheine prosthetic group in each. They differed somewhat from each other in amino acid composition, but each had a high number of negatively charged (aspartate and glutamate) amino acid residues.     

The enzyme complex citramalate lyase from Clostridium tetanomorphum.

1. The enzyme citramalate from Clostridium tetanomorphum is not stable in crude extracts. However, the inactive enzyme can be reactivated by incubation with dithioerythritol followed by acetylation with acetic anhydride. Reactivation was also obtained with acetate, ATP, MgCl2 and acetate : SH-enzyme ligases (AMP) from C. tetanomorphum or Klebsiella aerogenes. 2. Incubation of the inactive enzyme with iodoacetate resulted in rapid loss of enzymic activity as determined by reactivation with acetic anhydride whereas the active enzyme was stable in the presence of iodoacetate. Using ido[2-(14)C]acetate the sites of carboxymethylation and acetylation where identified as cysteamine residues of the enzyme. The results demonstrate that the active enzyme contains acetyl thiolester residues which play the central role in the catalytic mechanism. 3. Citramalate lyase was purified by a procedure almost identical to that already described for citrate lyase from K. aerogenes. The molecular weight of citramalate lyase is equal to that of citrate lyase (Mr = 5.2--5.8 X 10(5)) as estimated by gel chromatography and sucrose gradient centrifugation. Polyacrylamide gel elctrophoresis of citramalate lyase in sodium dodecylsulfate yielded three polypeptide chains (Mr: alpha 5.3--5.6 X 10(4); beta 3.3--3.6 X 10(4); gamma 1.0--1.2 X 10(4)) in probably equal molar amounts. These data lead to a hexameric structure (alpha,beta,gamma)6 of the complete enzyme. 4. Pantothenate (5 mol/mol of enzyme) and the essential cysteamine residues were exclusively present in the gamma-chain, the acyl carrier protein of citramalate lyase. The acyl exchange and cleavage functions, probably catalysed by the alpha and beta-subunits, were measured with acyl-CoA derivatives which were able to substitute for the natural acyl carrier. 5. The results demonstrate that citramalate lyase is an enzyme complex with structure and functions closely resembling those of citrate lyase. Although the similarity between citramalate lyase and citrate lyases from various organisms suggests a close evolutionary relationship, these occur in very different, unrelated bacteria. A parallel situation found in the distribution of the nitrogenase system among procaryotes is discussed.     

The architecture of the animal fatty acid synthetase complex. IV. Mapping of active centers and model for the mechanism of action

The fatty acid synthetase of animal tissue consists of two subunits, each containing seven catalytic centers and an acyl carrier site. Proteolytic cleavage patterns indicate that the subunit is arranged into three major domains, I, II, and III. Domain I contains the NH2-terminal end of the polypeptide and the catalytic sites of beta-ketoacyl synthetase (condensing enzyme) and the acetyl-and malonyl-transacylases. This domain, therefore, functions as a site for acetyl and malonyl substrate entry into the process of fatty acid synthesis and acts in part as the site of carbon-carbon condensation, resulting in chain elongation. Domain II is the medial domain and contains the beta-ketoacyl and enoyl reductases, probably the dehydratase, and the 4'-phosphopantetheine prosthetic group of the acyl carrier protein site. Domain II, therefore, is designated as the reduction domain where the keto carbon is reduced to methylene carbon by sequential processes of reduction, dehydration, and reduction again. Throughout these processes, the acyl group is attached to the pantetheine-SH of the acyl carrier protein. The latter site is distal to the cysteine-SH of the beta-ketoacyl synthetase, constitutes the 15000-dalton polypeptide at the COOH-terminal end of Domain II, and connects to Domain III. When the growing chain reaches C16 carbon length, the fatty acyl group is released by the thioesterase activity, which is contained in Domain III. A functional model is proposed based on the aforementioned results and the recent evidence that the synthetase subunits are arranged in a head-to-tail fashion, such that the pantetheine-SH of the acyl carrier protein of one subunit and the cysteine-SH of the beta-ketoacyl synthetase of the second subunit are juxtaposed. In this model, a palmitate synthesizing site contains Domain I of one subunit and Domains II and III of the second subunit. Therefore, even though each subunit contains all of the partial activities of the reaction sequence, the actual palmitate synthesizing unit consists of one-half of a subunit interacting with the complementary half of the other subunit.     

Apo- and holofatty acid synthetases from pigeon liver

Two forms (an apo- and a holoenzyme) of the fatty acid synthetase complex from pigeon liver were separated by affinity chromatography on a Sepharose-?-aminocaproyl pantetheine column. The difference between these enzymes is the presence or absence of the prosthetic group, 4′-phosphopantetheine. Due to the absence of the prosthetic group, apofatty acid synthetase lacks the overall ability to synthesize fatty acids, and it has no β-ketoacyl synthetase (condensing enzyme) activity. These two forms of enzyme were shown to be homogeneous and they behaved identically on DEAE-cellulose chromatography, gel filtration, sucrose density gradient centrifugation, disc gel electrophoresis, and immunodiffusion. The isolation and purification of an apoacyl carrier protein are also reported. The apoacyl carrier protein lacks β-alanine and it has no sulfhydryl group, indicating therefore that the acyl carrier protein from apofatty acid synthetase does not have a 4′-phosphopantetheine group. The transfer of 4′-phosphopantetheine from CoA to apofatty acid synthetase was effected by an enzyme system present in the supernatant of pigeon liver homogenate. The resulting product of this reaction was the holofatty acid synthetase. The reverse reaction, the formation of apo- from holofatty acid synthetase, was also demonstrated. The physiological significance of this system is suggested from studies carried out on fasting and refeeding of pigeons. At early times of refeeding (0–4 h) there is a large amount of apoenzyme. The amount of holofatty acid synthetase increases after 4 h of refeeding and the apofatty acid synthetase decreases. When pigeons are refasted, after refeeding for 48 h, the amount of apoenzyme increases and the holoenzyme decreases.     

Klebsiella pneumoniae genes for citrate lyase and citrate lyase ligase: localization, sequencing, and expression

In the course of studies on anaerobic citrate metabolism in Klebsiella pneumoniae, the DNA region upstream of the gene for the sodium-dependent citrate carrier (dtS) was investigated. Nucleotide sequence analysis revealed a cluster of five new genes that were oriented inversely to citS and probaby form an operon. The genes were named citCDEFG. Based on known protein sequence data, the gene products derived from citD, citE and citF could be identified as the λ-, β-, and α-subunits of citrate lyase, respectively. This enzyme catalyses the cleavage of citrate to oxaloacetate and acetate. The gene product derived from citC (calculated M_r 36476) exhibited no obvious similarity to other proteins. In the presence of acetate and ATP, cell extracts from a citC-expressing Escherichia coli strain were able to reactivate purified citrate lyase from K. pneumoniae that had been inactivated by chemical deacetylation of the prosthetic group. This represents 5-phosphoribosyi-dephospho-acetyl-coenzyme A which is covalently bound to serine-14 of the acyl carrier protein (λ-subunit). CitC was thus identified as acetate:SH-citrate lyase ligase. The function of the gene product derived from citG (M_r 32 645) has not yet been identified. Expression of the CitCDEFG gene cluster in E. coli led to the formation of citrate lyase which was active only in the presence of acetyl-coenzyme A, a compound known to substitute for the prosthetic group. These and other data strongly indicated that the enzyme synthesized in E. coli lacked its prosthetic group. Thus, additional genes besides citCDEFG appear to be required for the formation of holo-citrate lyase.     

Turnover of the 4'-phosphopantetheine prosthetic group of acyl carrier protein

Acyl carrier protein is an essential cofactor in fatty acid biosynthesis, and in contrast to the stability of the protein moiety during growth, its 4'-phosphopantetheine prosthetic group is metabolically active. The biosynthetic incorporation of deuterium into nonexchangeable positions of acyl carrier protein was found to enhance the sensitivity of the protein to pH-induced hydrodynamic expansion. This constitutional isotope effect was exploited to separate deuterated from normal acyl carrier protein by conformationally sensitive gel electrophoresis, thus providing the analytical framework for separating pre-existing (deuterated) from newly synthesized acyl carrier protein in pulse-chase experiments. The rate of acyl carrier protein prosthetic group turnover was found to depend on the intracellular concentration of coenzyme A. At low coenzyme A levels, prosthetic group turnover was four times faster than the rate of new acyl carrier protein biosynthesis but at the higher coenzyme A concentrations characteristic of logarithmic growth, turnover was an order of magnitude slower, amounting to approximately 25% of the acyl carrier protein pool per generation. These observations suggest that the acyl carrier protein prosthetic group turnover cycle may be related to coenzyme A metabolism rather than to lipid biosynthesis.     

Domains of Escherichia coli acyl carrier protein important for membrane-derived-oligosaccharide biosynthesis.

Acyl carrier protein participates in a number of biosynthetic pathways in Escherichia coli: fatty acid biosynthesis, phospholipid biosynthesis, lipopolysaccharide biosynthesis, activation of prohemolysin, and membrane-derived oligosaccharide biosynthesis. The first four pathways require the protein's prosthetic group, phosphopantetheine, to assemble an acyl chain or to transfer an acyl group from the thioester linkage to a specific substrate. By contrast, the phosphopantetheine prosthetic group is not required for membrane-derived oligosaccharide biosynthesis, and the function of acyl carrier protein in this biosynthetic scheme is currently unknown. We have combined biochemical and molecular biological approaches to investigate domains of acyl carrier protein that are important for membrane-derived oligosaccharide biosynthesis. Proteolytic removal of the first 6 amino acids from acyl carrier protein or chemical synthesis of a partial peptide encompassing residues 26 to 50 resulted in losses of secondary and tertiary structure and consequent loss of activity in the membrane glucosyltransferase reaction of membrane-derived oligosaccharide biosynthesis. These peptide fragments, however, inhibited the action of intact acyl carrier protein in the enzymatic reaction. This suggests a role for the loop regions of the E. coli acyl carrier protein and the need for at least two regions of the protein for participation in the glucosyltransferase reaction. We have purified acyl carrier protein from eight species of Proteobacteria (including representatives from all four subgroups) and characterized the proteins as active or inhibitory in the membrane glucosyltransferase reaction. The complete or partial amino acid sequences of these acyl carrier proteins were determined. The results of site-directed mutagenesis to change amino acids conserved in active, and altered in inactive, acyl carrier proteins suggest the importance of residues Glu-4, Gln-14, Glu-21, and Asp-51. The first 3 of these residues define a face of acyl carrier protein that includes the beginning of the loop region, residues 16 to 36. Additionally, screening for membrane glucosyltransferase activity in membranes from bacterial species that had acyl carrier proteins that were active with E. coli membranes revealed the presence of glucosyltransferase activity only in the species most closely related to E. coli. Thus, it seems likely that only bacteria from the Proteobacteria subgroup gamma-3 have periplasmic glucans synthesized by the mechanism found in E. coli.     

Rapid purification of enzymes of fatty acid biosynthesis from rat adipose tissue

Acetyl CoA carboxylase, ATP-citrate lyase and fatty acid synthetase were purified to homogeneity by a simple procedure. The purification method consists of polymerization of acetyl CoA carboxylase with citrate followed by avidin-Sepharose affinity chromatography. ATP-citrate lyase and fatty acid synthetase were isolated as by-products of acetyl CoA carboxylase purification and are separated from each other by chromatography on DE-52. ATP-citrate lyase was further purified by CoA-agarose affinity chromatography and fatty acid synthetase was purified on Bio-Gel A-1.5m. Purified ATP-citrate lyase, acetyl CoA carboxylase and fatty acid synthetase had specific activities of 9.9, 2.8 and 1.8 U/mg respectively with an over all recovery of 30, 25 and 50% respectively. Using these purified enzymes, we found that ATP-citrate lyase and acetyl CoA carboxylase were phosphorylated in vitro by both cAMP-dependent protein kinase and ATP-citrate lyase kinase whereas fatty acid synthetase was not phosphorylated by these protein kinases.     

On the structure of the prosthetic group of citrate (pro-3S)-lyase.

The prosthetic group of citrate (pro-3S)-lyase from Klebsiella aerogenes as well as Streptococcus diacetilactis was obtained eigher by beta elimination or pronase digestion of the enzyme and purified by DEAE-cellulose chromatography. The compound was shown to contain 3 mol of PO4, 2 mol of ribose, and 1 mol of sulfhydryl/mol of adenine. 5'-AMP and dephospho-CoA are components of the prosthetic group. The evidence obtained so far support our proposed structure of 3' (or 2') leads to 1'-(5'-phosphoribosyl)dephospho-CoA for the prosthetic group of citrate lyase. The presence of one phosphomonoester group in the compound isolated after beta elimination and the absence of the same in the compound isolated after pronase digestion indicated that the prosthetic group is attached to the enzyme through a phosphodiester bond. Analyses of the pyruvate released by beta elimination and subsequent acid hydrolysis of the peptide-bound prosthetic group and its degradation products showed that the phosphodiester linkage is between the hydroxyl group of a serine residue of the protein and the 5'-PO4 group of the second ribose.     

Rapid Purification of Enzymes of Fatty Acid Biosynthesis from Rat Adipose Tissue

Abstract

Acetyl CoA carboxylase, ATP-citrate lyase and fatty acid synthetase were purified to homogeneity by a simple procedure. The purification method consists of polymerization of acetyl CoA carboxylase with citrate followed by avidin-Sepharose affinity chromatography. ATP-citrate lyase and fatty acid synthetase were isolated as by-products of acetyl CoA carboxylase purification and are separated from each other by chromatography on DE-52. ATP-citrate lyase was further purified by CoA-agarose affinity chromatography and fatty acid synthetase was purified on Bio-Gel A-1.5m. Purified ATP-citrate lyase, acetyl CoA carboxylase and fatty acid synthetase had specific activities of 9.9, 2.8 and 1.8 U/mg respectively with an over all recovery of 30, 25 and 50% respectively. Using these purified enzymes, we found that ATP-citrate lyase and acetyl CoA carboxylase were phosphorylated in vitro by both cAMP-dependent protein kinase and ATP-citrate lyase kinase whereas fatty acid synthetase was not phosphorylated by these protien kinases.     

Biosynthesis of the prosthetic group of citrate lyase

Citrate lyase (EC 4.1.3.6) catalyzes the cleavage of citrate to acetate and oxaloacetate and is composed of three subunits (alpha, beta, and gamma). The gamma-subunit serves as an acyl carrier protein (ACP) and contains the prosthetic group 2'-(5' '-phosphoribosyl)-3'-dephospho-CoA, which is attached via a phosphodiester linkage to serine-14 in the enzyme from Klebsiella pneumoniae. In this work, we demonstrate by genetic and biochemical studies with citrate lyase of Escherichia coli and K. pneumoniae that the conversion of apo-ACP into holo-ACP is dependent on the two proteins, CitX (20 kDa) and CitG (33 kDa). In the absence of CitX, only apo-ACP was synthesized in vivo, whereas in the absence of CitG, an adenylylated ACP was produced, with the AMP residue attached to serine-14. The adenylyltransferase activity of CitX could be verified in vitro with purified CitX and apo-ACP plus ATP as substrates. Besides ATP, CTP, GTP, and UTP also served as nucleotidyl donors in vitro, showing that CitX functions as a nucleotidyltransferase. The conversion of apo-ACP into holo-ACP was achieved in vitro by incubation of apo-ACP with CitX, CitG, ATP, and dephospho-CoA. ATP could not be substituted with GTP, CTP, UTP, ADP, or AMP. In the absence of CitG or dephospho-CoA, AMP-ACP was formed. Remarkably, it was not possible to further convert AMP-ACP to holo-ACP by subsequent incubation with CitG and dephospho-CoA. This demonstrates that AMP-ACP is not an intermediate during the conversion of apo- into holo-ACP, but results from a side activity of CitX that becomes effective in the absence of its natural substrate. Our results indicate that holo-ACP formation proceeds as follows. First, a prosthetic group precursor [presumably 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA] is formed from ATP and dephospho-CoA in a reaction catalyzed by CitG. Second, holo-ACP is formed from apo-ACP and the prosthetic group precursor in a reaction catalyzed by CitX.     

Reevaluation of citrate lyase from Escherichia coli

The subunit structure of citrate lyase from Escherichia coli was shown to be similar to that of all other lyases investigated so far. The three different subunits with molecular masses of 55.5 kDa, (large subunit) 35 kDa (medium-sized subunit) and 12.5 kDa (small subunit, acyl carrier protein) occurred in a ratio of 1:1:1. Using high-pressure liquid chromatography, it was possible to demonstrate that the reported large acyl carrier protein, with a molecular mass of 85 kDa was a contaminating protein associated with citrate lyase multienzyme complex; it could be removed by anion-exchange chromatography with Q-Sepharose. The typical two configurations of citrate lyase, the 'star' form and the 'ring' form with a diameter of 14.3 nm and 15.4 nm, respectively, could be detected by electron microscopy.     

Relationship between fatty acid binding proteins,acetyl-CoA formation and fatty acid synthesis in developing human placenta

The relationship between fatty acid binding proteins, ATP citrate lyase activity and fatty acid synthesis in developing human placenta has been studied. Fatty acid binding proteins reverse the inhibitory efect of palmitoyl-CoA and oleate on ATP citrate lyase and fatty acid synthesis. In the absence of these inhibitors fatty acid binding proteins activate ATP citrate lyase and stimulate [ 1-¹⁴ C] acetate incorporation into placental fatty acids indicating binding of endogenous inhibitors by these proteins. Thus these proteins regulate the supply of acetyl-CoA as well as the synthesis of fatty acids from that substrates. As gestation proceeds and more lipids are required by the developing placenta fatty acid binding protein content, activity of ATP citrate lyase and rate of fatty acid synthesis increase indicating a cause and efect relationship between the demand of lipids and supply of precursor fatty acids during human placental development.     

Solution structure and backbone dynamics of the holo form of the frenolicin acyl carrier protein

During polyketide biosynthesis, acyl carrier proteins (ACPs) perform the central role of transferring polyketide intermediates between active sites of polyketide synthase. The 4'-phosphopantetheine prosthetic group of a holo-ACP is a long and flexible arm that can reach into different active sites and provide a terminal sulfhydryl group for the attachment of acyl groups through a thioester linkage. We have determined the solution structure and characterized backbone dynamics of the holo form of the frenolicin acyl carrier protein (fren holo-ACP) by nuclear magnetic resonance (NMR). Unambiguous assignments were made for 433 hydrogen atoms, 333 carbon atoms, and 84 nitrogen atoms, representing a total of 94.6% of the assignable atoms in this protein. From 879 meaningful NOEs and 45 angle constraints, a family of 24 structures has been calculated. The solution structure is composed of three major alpha-helices packed in a bundle with three additional short helices in intervening loops; one of the short helices slowly exchanges between two conformations. Superposition of the major helical regions on the mean structure yields average atomic rmsd values of 0.49 +/- 0.09 and 0.91 +/- 0.08 A for backbone and non-hydrogen atoms, respectively. Although the three-helix bundle fold is conserved among acyl carrier proteins involved in fatty acid synthases and polyketide synthases, a detailed comparison revealed that ACPs from polyketide biosynthetic pathways are more related to each other in tertiary fold than to their homologues from fatty acid biosynthetic pathways. Comparison of the free form of ACPs (NMR structures of fren ACP and the Bacillus subtilis ACP) with the substrate-bound form of ACP (crystal structure of butyryl-ACP from Escherichia coli) suggests that conformational exchange plays a role in substrate binding.     

Fatty acid synthetase from chloroplasts of soybean cotyledons: ACP activation and CoA inhibition

Fatty acid synthetase from chloroplasts of soybean cotyledons was activated by preincubation with acyl carrier protein and dithiothreitol. The synthetase reaction had a 3–10 min lag which was not eliminated by the preincubation. Acetyl-CoA and malonyl-CoA had no effect on the activation. Fatty acid synthetase from spinach chloroplasts was neither activated by preincubation nor had a lag. The variability of the activity of the soybean enzyme with preincubation suggested that the fatty acid synthetase was present in two forms and that the acyl carrier protein caused conversion to the active form. This fatty acid synthetase and the same synthetase from spinach chloroplasts were inhibited by CoA. The type of inhibition by CoA in soybean was competitive with respect to malonyl-CoA and the Ki was 80μM.     

Functional analysis of an interspecies chimera of acyl carrier proteins indicates a specialized domain for protein recognition

The nodulation protein NodF of Rhizobium shows 25% identity to acyl carrier protein (ACP) from Escherichia coli (encoded by the gene acpP). However, NodF cannot be functionally replaced by AcpP. We have investigated whether NodF is a substrate for various E. coli enzymes which are involved in the synthesis of fatty acids. NodF is a substrate for the addition of the 4′-phosphopantetheine prosthetic group by holo-ACP synthase. The K_m value for NodF is 61?μM, as compared to 2?μM for AcpP. The resulting holo-NodF serves as a substrate for coupling of malonate by malonyl-CoA:ACP transacylase (MCAT) and for coupling of palmitic acid by acyl-ACP synthetase. NodF is not a substrate for β-keto-acyl ACP synthase III (KASIII), which catalyses the initial condensation reaction in fatty acid biosynthesis. A chimeric gene was constructed comprising part of the E.coliacpP gene and part of the nodF gene. Circular dichroism studies of the chimeric AcpP-NodF (residues 1–33 of AcpP fused to amino acids 43–93 of NodF) protein encoded by this gene indicate a similar folding pattern to that of the parental proteins. Enzymatic analysis shows that AcpP-NodF is a substrate for the enzymes holo-ACP synthase, MCAT and acyl-ACP synthetase. Biological complementation studies show that the chimeric AcpP-NodF gene is able functionally to replace NodF in the root nodulation process in Vicia sativa. We therefore conclude that NodF is a specialized acyl carrier protein whose specific features are encoded in the C-terminal region of the protein. The ability to exchange domains between such distantly related proteins without affecting conformation opens exciting possibilities for further mapping of the functional domains of acyl carrier proteins (i. e., their recognition sites for many enzymes).     

Cloning,expression, characterization,and interaction of two components of a human mitochondrial fatty acid synthase. Malonyltransferase and acyl carrier protein

The possibility that human cells contain, in addition to the cytosolic type I fatty acid synthase complex, a mitochondrial type II malonyl-CoA-dependent system for the biosynthesis of fatty acids has been examined by cloning, expressing, and characterizing two putative components. Candidate coding sequences for a malonyl-CoA:acyl carrier protein transacylase (malonyltransferase) and its acyl carrier protein substrate, identified by BLAST searches of the human sequence data base, were located on nuclear chromosomes 22 and 16, respectively. The encoded proteins localized exclusively in mitochondria only when the putative N-terminal mitochondrial targeting sequences were present as revealed by confocal microscopy of HeLa cells infected with appropriate green fluorescent protein fusion constructs. The mature, processed forms of the mitochondrial proteins were expressed in Sf9 cells and purified, the acyl carrier protein was converted to the holoform in vitro using purified human phosphopantetheinyltransferase, and the functional interaction of the two proteins was studied. Compared with the dual specificity malonyl/acetyltransferase component of the cytosolic type I fatty acid synthase, the type II mitochondrial counterpart exhibits a relatively narrow substrate specificity for both the acyl donor and acyl carrier protein acceptor. Thus, it forms a covalent acyl-enzyme complex only when incubated with malonyl-CoA and transfers exclusively malonyl moieties to the mitochondrial holoacyl carrier protein. The type II acyl carrier protein from Bacillus subtilis, but not the acyl carrier protein derived from the human cytosolic type I fatty acid synthase, can also function as an acceptor for the mitochondrial transferase. These data provide compelling evidence that human mitochondria contain a malonyl-CoA/acyl carrier protein-dependent fatty acid synthase system, distinct from the type I cytosolic fatty acid synthase, that resembles the type II system present in prokaryotes and plastids. The final products of this system, yet to be identified, may play an important role in mitochondrial function.     

Purification and properties of citrate lyase from Streptococcus diacetilactis.

Citrate lyase from Streptococcus diacetilactis has been purified to yield a protein that was homogeneous as judged by sedimentation velocity and sedimentation equilibrium experiments. The enzyme's sedimentation coefficient is 16.8 S and its molecular weight is around 585,000. It contains three nonidentical subunits of about 53,000, 34,000, and 10,000 daltons. The enzyme in its active form contains an acetyl group which turns over during the citrate cleavage reaction. Removal of the acetyl group inactivates the enzyme. The deacetyl enzyme can be partially reactivated by acetylation with acetic anhydride. The enzyme undergoes slow "reaction-inactivation." The rate of inactivation is first order and the rate constant of inactivation is much lower than that for a similar inactivation process of the citrate lyase from Klebsiella aerogenes. Like the latter enzyme it contains stoichiometric amounts of phosphopantothenate. The enzyme is inactivated at pH greater than 8.1 and the presence of citrate provides protection against this inactivation. Sedimentation studies of the enzyme at pH 8.7 indicate that the enzyme is dissociated, which may account for the inactivation. The enzyme is immunologically different from citrate lyases of K. aerogenes and Escherichia coli.     

Cerulenin resistance in a cerulenin-producing fungus. III. Studies on active-site peptides of fatty acid synthetase from Cephalosporium caerulens

Active-site peptides of acetyl transferase, condensing enzyme and acyl carrier protein in the neighborhood of the prosthetic group, 4'-phosphopantetheine, of Cephalosporium caerulens fatty acid synthetase were investigated. The enzyme was reacted with [14C]acetyl-CoA or [14C]iodoacetamide. 14C-Labeled enzyme was digested with pepsin, trypsin or both. 14C-Labeled peptides were isolated by several purification procedures. The amino acid sequence of the active site of condensing enzyme was determined to be Tyr-Gln-Val-Glu-Ser-Cys-Pro-Ile-Leu-Glu-Gly-Lys and that of acetyl transferase was Phe-Ser-Gly-Ala-Thr-Gly-His-Ser-Gln-Gly. The amino acid composition around the 4'-phosphopantetheine-carrying serine was determined to be Asx2, Thr, Ser, Glx3, Gly2, Ala, Ile, Leu3, and Lys. When these active-site peptides were compared with those of Saccharomyces cerevisiae synthetase, a high degree of homology was observed in the active-site peptides of the acetyl transferase and acyl carrier protein domains. However, that of the condensing enzyme domain gave lower homology. These findings may support the assumption that the low reactivity of cerulenin with C. caerulens synthetase is a consequence of the structure of the condensing enzyme domain.