Occurrence of apoAcyl carrier protein and an S-alkylation-resistant form of holoAcyl carrier protein in Escherichia coli.

The 4′-phosphopantetheine prosthetic group of holoacyl carrier protein (holoACP) in Escherichia coli turns over independently of the apoprotein, due to the activities of holoACP hydrolase and holoACP synthetase. There is no measurable pool of apoACP in pantothenate-supplemented cells of a pantothenate-requiring mutant, but extended incubation on deficient medium, with exhaustion of cellular coenzyme A (CoA), leads to slow accumulation of the apoprotein. It is concluded that, although the activities of the synthetase and hydrolase are about equal in crude extracts, in the cells an excess synthetase activity maintains ACP completely as holoACP unless cells are artifically depleted of CoA, the donor of the 4′-phosphopantetheine group. About 20% of the holoACP in normal cells was designated as “holoACP esters,” being resistant to S-alkylation unless first treated with neutral hydroxylamine; this proportion increased to about 80% in pantothenate starvation. A preliminary attempt to identify acyl portions from this material was unsuccessful. The proportion of this material was not elevated in other strains under conditions which show feedback inhibition of fatty acid biosynthesis in vivo.     

Desaturation of trans-octadecenoyl-acyl carrier protein by stearoyl-acyl carrier protein delta9 desaturase

Positional isomers of mono-unsaturated 18:1-ACP have been used as substrates for stearoyl-acyl carrier protein delta9 desaturase to test whether a C-H bond abstraction from either the C-9 or C-10 position could lead to rearranged products diagnostic for the production of an allylic radical intermediate. The reconstituted enzyme complex was able to desaturate trans-delta11-18:1-ACP and trans-delta7-18:1-ACP, but not trans-delta9-18:1-ACP, or any of the corresponding cis-isomers. Enzymatic desaturation of trans-delta11-18:1-ACP gave a single product, cis-delta9,trans-delta11-18:2-ACP, as characterized by gas chromatography-electron ionization mass spectrometry of the molecular ions, the fragmentation products of pyrrolidide and 4,4-dimethyloxazoline derivatives, and by comparison of chromatographic retention times with authentic standards. Reaction of trans-delta7-18:1-ACP gave two enzymic products, trans-delta7,cis-delta9-18:2 (approximately 80%) and trans-delta7,cis-delta11-18:2 (approximately 20%). The major product was likely formed in a reaction identical to that of 18:0-ACP desaturation, while the minor product was likely formed by alternative placement of the C-10 and C-11 positions of the substrate analog in a cis configuration relative to the diiron oxidant. Since none of the products observed are indicative of rearrangements originating with an allylic radical, a discussion of the origins and possible implications of these results is presented.     

Altered molecular form of acyl carrier protein associated with beta-ketoacyl-acyl carrier protein synthase II (fabF) mutants.

Acyl carrier protein (ACP) is a required cofactor for fatty acid synthesis in Escherichia coli. Mutants lacking beta-ketoacyl-ACP synthase II activity (fabF1 or fabF3) possessed a different molecular species of ACP (F-ACP) that was separated from the normal form of the protein by conformationally sensitive gel electrophoresis. Synthase I mutants contained the normal protein. Complementation of fabF1 mutants with an F' factor harboring the wild-type synthase II allele resulted in the appearance of normal ACP, whereas complementation with an F' possessing the fabF2 allele (a mutation that produces a synthase II enzyme with altered catalytic activity) resulted in the production of both forms of ACP. The structural difference between F-ACP and ACP persisted after the removal of the 4'-phosphopantetheine prosthetic group, and both forms of the protein had identical properties in an in vitro fatty acid synthase assay. Both ACP and F-ACP were purified to homogeneity, and their primary amino acid sequences were determined. The two ACP species were identical but differed from the sequence reported for E. coli E-15 ACP in that an Asn instead of an Asp was at position 24 and an Ile instead of a Val was at position 43. Therefore, F-ACP appears to be a modification of ACP that is detected when beta-ketoacyl-ACP synthase II activity is impaired.     

Biotin carboxyl carrier protein in barley chloroplast membranes.

Biotin localized in barley chloroplast lamellae is covalently bound to a single protein with an approximate molecular weight of 21 000. It contains one mole of biotin per mole of protein and functions as a carboxyl carrier in the acetyl-CoA carboxylase reaction. The protein was obtained by solubilization of the lamellae in phenol/acetic acid/8 M urea. Feeding barley seedlings with [14C]-biotin revealed that the vitamin is not degraded into respiratory substrates by the plant, but is specifically incorporated into biotin carboxyl carrier protein.     

Localization of acyl carrier protein in Escherichia coli.

Acyl carrier protein was localized by immunoelectron microscopy in the cytoplasm of Escherichia coli. These data are inconsistent with the previous report of an association between acyl carrier protein and the inner membrane (H. Van den Bosch, J.R. Williamson, and P.R. Vagelos, Nature [London] 228:338-341, 1970). Moreover, bacterial membranes did not bind a significant amount of acyl carrier protein or its thioesters in vitro. A thioesterase activity specific for long-chain acyl-acyl carrier protein was associated with the inner membrane.     

Solution structure of B. subtilis acyl carrier protein

BACKGROUND: Acyl carrier protein (ACP) is a fundamental component of fatty acid biosynthesis in which the fatty acid chain is elongated by the fatty acid synthetase system while attached to the 4'-phosphopantetheine prosthetic group (4'-PP) of ACP. Activation of ACP is mediated by holo-acyl carrier protein synthase (ACPS) when ACPS transfers the 4'-PP moiety from coenzyme A (CoA) to Ser36 of apo-ACP. Both ACP and ACPS have been identified as essential for E. coli viability and potential targets for development of antibiotics. RESULTS: The solution structure of B. subtilis ACP (9 kDa) has been determined using two-dimensional and three-dimensional heteronuclear NMR spectroscopy. A total of 22 structures were calculated by means of hybrid distance geometry-simulated annealing using a total of 1,050 experimental NMR restraints. The atomic rmsd about the mean coordinate positions for the 22 structures is 0.45 +/- 0.08 A for the backbone atoms and 0.93 +/- 0.07 A for all atoms. The overall ACP structure consists of a four alpha-helical bundle in which 4'-PP is attached to the conserved Ser36 that is located in alpha helix II. CONCLUSIONS: Structural data were collected for both the apo and holo forms of ACP that suggest that the two forms of ACP are essentially identical. Comparison of the published structures for E. coli ACP and actinorhodin polyketide synthase acyl carrier protein (act apo-ACP) from Streptomyces coelicolor A3(2) with B. subtilis ACP indicates similar secondary structure elements but an extremely large rmsd between the three ACP structures (>4.3 A). The structural difference between B. subtilis ACP and both E. coli and act apo-ACP is not attributed to an inherent difference in the proteins, but is probably a result of a limitation in the methodology available for the analysis for E. coli and act apo-ACP. Comparison of the structure of free ACP with the bound form of ACP in the ACP-ACPS complex reveals a displacement of helix II in the vicinity of Ser36. The induced perturbation of ACP by ACPS positions Ser36 proximal to coenzyme A and aligns the dipole of helix II to initiate transfer of 4'-PP to ACP.     

Plant holo-(acyl carrier protein) synthase.

1. An improved method was developed for the assay of plant holo-(acyl carrier protein) synthase activity, using Escherichia coli acyl-(acyl carrier protein) synthetase as a coupling enzyme. 2. Holo-(acyl carrier protein) synthase was partially purified from spinach (Spinacia oleracea) leaves by a combination of (NH4)2SO4 fractionation and anion-exchange and gel-permeation chromatography. 3. The partially purified enzyme had a pH optimum of 8.2 and Km values of 2 microM, 72 microM and 3 mM for apo-(acyl carrier protein), CoA and Mg2+ respectively. Synthase activity was inhibited in vitro by the reaction product 3',5'-ADP. 4. Results from the fractionation of spinach leaf and developing castor-oil-seed (Ricinus communis) endosperm cells were consistent with a cytosolic localization of holo-(acyl carrier protein) synthase activity in plant cells.     

2-Acylglycerolphosphoethanolamine acyltransferase/acyl-acyl carrier protein synthetase is a membrane-associated acyl carrier protein binding protein

Two enzymatic activities, 2-acylglycerolphosphoethanolamine (2-acyl-GPE) acyltransferase and acyl-acyl carrier protein (acyl-ACP) synthetase, were solubilized and purified from Escherichia coli membranes. Electrophoretic analysis of the final product of the purification procedure revealed a single protein species with an apparent molecular mass of 27 kilodaltons. The ratio of acyltransferase to synthetase activities remained the same throughout the purification scheme indicating that both activities were catalyzed by the same enzyme. 2-Acyl-GPE acyltransferase exhibited an apparent ACP Km of 64 nM under standard assay conditions that increased to 10 microM when the assay was conducted in the presence of 0.4 M LiCl. Acyl-ACP synthetase activity was not detected in the absence of 0.4 M LiCl, and the apparent ACP Km for this reaction was 16 microM. Direct evidence that ACP was a subunit of the acyltransferase/synthetase was obtained by the adsorption of both catalytic activities to an ACP-Sepharose affinity column and by the binding of [3H]ACP to the purified enzyme preparation. The apparent Km for acyl-ACP was 13 microM, and the rate of acyl transfer from this acyl donor was enhanced by the addition of 0.4 M LiCl indicating that the exchange of enzyme-bound ACP for acyl-ACP was a determinant factor in the rate of phosphatidylethanolamine formation from acyl-ACP. These data indicate that the 2-acyl-GPE acyltransferase and acyl-ACP synthetase reactions are catalyzed by the same membrane protein that possesses a high affinity binding site for soluble ACP.     

Beta-Ketoacyl-acyl carrier protein synthetase. Characterization of the acyl-enzyme intermediate.

Beta-Ketoacyl-acyl carrier protein (ACP) synthetase catalyzes the condensation reaction of fatty acid synthesis in Escherichia coli. The homogeneous enzyme reacts with hexanoyl-CoA to form hexanoyl-enzyme which was isolated and characterized. Hexanoyl-enzyme contains 2 mol of hexanoate/mol of enzyme (molecular weight 66,000); it is liable at alkaline pH, and it reacts with neutral hydroxylamine to form hexanoyl hydroxamic acid. Hexanoate was cleaved from the enzyme when hexanoyl-enzyme was subjected to performic acid oxidation. These properties indicate that hexanoyl-enzyme is a thioester. Studies of the circular dichroism spectra of fully acylated and nonacylated forms of the enzyme indicated that the secondary structure of the enzyme is relatively unperturbed by the presence of the hexanoyl groups. An alpha helical content of 65% was estimated for the enzyme from the circular dichroism spectrum. Hexanoyl-enzyme is active in both partial reactions that comprise the beta-ketoacyl-ACP synthetase reaction; it reacts with ACP to form hexanoyl-ACP and with malonyl-ACP to form beta-ketooctanoyl-ACP. Although the hexanoate of hexanoyl-enzyme is transferred very rapidly to ACP, the physiological acceptor in this reaction, it is also transferred very slowly to CoA, dithiothreitol, and 2-mercaptoethanol, indicating that the enzyme can react nonspecifically with a number of unrelated mercaptans.     

Sterol carrier protein2. Identification of adrenal sterol carrier protein2 and site of action for mitochondrial cholesterol utilization

Addition of homogeneous rat liver sterol carrier protein2 (SCP2) or an adrenal cytosolic fraction enhanced pregnenolone production by adrenal mitochondria. Pretreatment of SCP2 or adrenal cytosol with anti-SCP2 IgG abolished the stimulatory effect of both preparations on mitochondrial pregnenolone output. Incubation of mitochondria with aminoglutethimide, which blocks interaction of cholesterol with inner membrane cytochrome P-450scc, resulted in decreased pregnenolone production and a decreased level of mitoplast cholesterol. Addition of SCP2 to the incubation media caused an almost 2-fold increase in cholesterol associated with the mitoplast, but did not enhance mitochondrial pregnenolone production. Studies with reconstituted cytochrome P-450scc in phospholipid vesicles also suggested that SCP2 did not affect interaction of cholesterol with the hemoprotein. Treatment of rats with cycloheximide alone or with adrenocorticotropic hormone resulted in a dramatic increase in mitochondrial cholesterol. However, these mitochondria did not exhibit increased levels of pregnenolone output under control incubation conditions. When SCP2 was included in the mitochondrial incubation media, pregnenolone production was significantly increased over that observed with adrenal mitochondria from untreated or adrenocorticotropic hormone-treated rats. The results imply that SCP2 enhances mitochondrial pregnenolone production by improving transfer of mitochondrial cholesterol to cytochrome P-450scc on the inner membrane, but does not directly influence the interaction of substrate with the hemoprotein.