A novel, general radioimmunoassay for acyl carrier proteins

A radioimmunoassay (RIA) for acyl carrier proteins (ACP) is described that is based on the competitive binding between [3H]acyl-ACP and unlabeled ACP of the same species. The radiolabeled antigen, [3H]palmitoyl-ACP, is enzymatically synthesized by Escherichia coli acyl-ACP synthetase. Because acyl-ACP synthetase can specifically radiolabel ACP in crude extracts from several plant sources, the use of this enzyme to prepare [3H]acyl-ACP obviates the need for pure preparations of each ACP. Preparation of [3H]acyl-ACP with a specific activity of 15 Ci/mmol allows RIA detection of total ACP in crude plant extracts at the nanogram level. Because antibodies against spinach ACP partially crossreact with ACP from many plant sources, RIAs for other plant species can be constructed using only one preparation of antibody. ACP preparations from safflower, soybean, avocado, corn, and E. coli show a decreasing order of partial immunocross-reactivity with spinach ACP-specific antiserum, as examined by RIA using spinach [3H]palmitoyl-ACP.     

Rapid in Vivo Acylation of Acyl Carrier Protein with Exogenous Fatty Acids in Spirodela oligorrhiza

Posttranslational acylation of several chloroplast proteins with palmitic acid was recently demonstrated in Spirodela oligorrhiza (AK Mattoo, M Edelman [1987] Proc Natl Acad Sci USA 84: 1497-1501). We have now identified an in vivo acylated, soluble protein having an apparent M_r of 10 kilodaltons on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as an acylated form of acyl carrier protein (ACP). This 10-kilodalton protein is present in low abundance, and its acylation is light-stimulated. Turnover of the acyl moiety but not the apo-protein is rapid in the light. The acylated 10-kilodalton protein coelectrophoreses with in vitro synthesized palmitoyl-acyl carrier protein and is immunoprecipitated from soluble extracts with an antibody raised against spinach ACP. Cerulenin, an inhibitor of β-ketoacyl-ACP synthetase, inhibited in vivo acylation of Spirodela ACP. Cell-free extracts of Spirodela plants were able to catalyze the transfer of palmitate from palmitoyl-CoA to ACP, suggesting the existence in higher plants of a pathway for acylation of ACP that involves transacylation from acyl-CoA.     

Purification and characterization of recombinant spinach acyl carrier protein I expressed in Escherichia coli

Expression of plant acyl carrier protein (ACP) in Escherichia coli at levels above that of constitutive E. coli ACP does not appear to substantially alter bacterial growth or fatty acid metabolism. The plant ACP expressed in E. coli contains pantetheine and approximately 50% is present in vivo as acyl-ACP. We have purified and characterized the recombinant spinach ACP-I. NH2-terminal amino acid sequencing indicated identity to authentic spinach ACP-I, and there was no evidence for terminal methionine or formylmethionine. Recombinant ACP-I was found to completely cross-react immunologically with polyclonal antibody raised to spinach ACP-I. Recombinant ACP-I was a poor substrate for E. coli fatty acid synthesis. In contrast, Brassica napus fatty acid synthetase gave similar reaction rates with both recombinant and E. coli ACP. Similarly, malonyl-coenzyme A:acyl carrier protein transacylase isolated from E. coli was only poorly able to utilize the recombinant ACP-I while the same enzyme from B. napus reacted equally well with either E. coli ACP or recombinant ACP-I. E. coli acyl-ACP synthetase showed a higher reaction rate for recombinant ACP-I than for E. coli ACP. Expression of spinach ACP-I in E. coli provides, for the first time, plant ACP in large quantities and should aid in both structural analysis of this protein and in investigations of the many ACP-dependent reactions of plant lipid metabolism.     

Expression of an active spinach acyl carrier protein-I/protein-A gene fusion

A synthetic gene encoding spinach acyl carrier protein I (ACP-I) was fused to a gene encoding the Fc-binding portion of staphylococcal protein A. This gene fusion, under the control of the P_R promoter, was expressed at high levels in Escherichia coli producing a 42 kDa fusion protein. This fusion protein was phosphopantethenylated in E. coli. In vitro the ACP portion of the fusion protein was able to participate in acyl ACP synthetase reactions, plant malonyl-CoA:ACP transacylase (MCT) reactions, and plant fatty acid synthetase (FAS) reactions. Inhibitory effects of high ACP concentrations on in vitro plant FAS were observed with the unfused ACP-1 but not with the fusion protein. As with unfused ACP-I, the fusion protein was a poor substrate for E. coli FAS reactions. When injected into rabbits, the fusion protein was also able to generate antiserum to spinach ACP-I.     

Purification and characterization of acyl carrier protein from two cyanobacteria species

The acyl carrier protein (ACP), an essential protein cofactor for fatty acid synthesis, has been isolated from two cyanobacteria: the filamentous, heterocystous, Anabaena variabilis (ATCC 29211) and the unicellular Synechocystis 6803 (ATCC 27184). Both ACPs have been purified to homogeneity utilizing a three-column procedure. Synechocystis 6803 ACP was purified 1800-fold with 67% yield, while A. variabilis ACP was purified 1040-fold with 50% yield. Yields of 13.0 micrograms ACP/g Synechocystis 6803 and 9.0 micrograms ACP/g A. variabilis were achieved. Amino acid analysis indicated that these ACPs were highly charged acidic proteins similar to other known ACPs. Sequence analysis revealed that both cyanobacterial ACPs were highly conserved with both spinach and Escherichia coli ACP at the phosphopantetheine prosthetic group region. Examining the probability of alpha-helix and beta-turn regions in various ACPs, showed that cyanobacterial ACPs were more closely related to E. coli ACP than spinach ACP I. Immunoblot analysis and a competitive binding assay for ACP illustrated that both ACPs bound poorly to spinach ACP I antibody. SDS/PAGE and native PAGE of Synechocystis 6803 ACP and A. variabilis ACP showed that cyanobacteria ACPs co-migrated with E. coli ACP and had relative molecular masses of 18,100 and 17,900 respectively. Both native and urea gel analysis of acyl-ACP products from fatty acid synthase reactions demonstrated that bacterial ACPs and plant ACP gave essentially the same metabolic products when assayed using either bacterial or plant fatty acid synthase. A. variabilis and Synechocystis 6803 ACP could be acylated using E. coli acyl ACP synthetase.     

Preparation of fatty-acylated derivatives of acyl carrier protein using Vibrio harveyi acyl-ACP synthetase.

A simple two-step purification of Vibrio harveyi fatty acyl-acyl carrier protein (acyl-ACP) synthetase, which is useful for the quantitative preparation and analysis of fatty-acylated derivatives of ACP, is described. Acyl-ACP synthetase can be partially purified from extracts of this bioluminescent bacterium by Cibacron blue chromatography and Sephacryl S-300 gel filtration and is stable for months at -20 degrees C in the presence of glycerol. Incubation of ACP from Escherichia coli with ATP and radiolabeled fatty acids (6 to 16 carbons in length) in the presence of the enzyme resulted in quantitative conversion to biologically active acylated derivatives. The enzyme reaction can be monitored by a filter disk assay to quantitate levels of ACP or by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography to detect ACP in cell extracts. With its broad fatty acid chain length specificity and optimal activity in mild nondenaturing buffers, the soluble V. harveyi acyl-ACP synthetase provides an attractive alternative to current chemical and enzymatic methods of acyl-ACP preparation and analysis.     

Synthesis, cloning, and expression in Escherichia coli of a spinach acyl carrier protein-I gene

A synthetic gene of 268 bp encoding the 82 amino acid spinach acyl carrier protein (ACP)-I was constructed based on the known amino acid sequence. Two gene fragments, one encoding the amino-terminal portion and the other the carboxy-terminal portion of the protein, were assembled from synthetic oligonucleotides and inserted into the phage M13mp19. These partial gene constructions were joined and inserted into the plasmid pTZ19R. DNA sequencing confirmed the accuracy of the constructions. The synthetic gene was then subcloned into the Escherichia coli expression vector pKK233-2, under the control of the trc promoter. Western blot analysis and radioimmunoassay indicated that E. coli cells carrying this plasmid produced up to 6 mg/liter of a protein which was immunologically cross-reactive and similar in electrophoretic mobility to authentic spinach acyl carrier protein. The bacterial cells were able to attach the phosphopantetheine prosthetic group to the synthetic plant gene product allowing it to be acylated in vitro by acyl-ACP synthetase.     

Photocontrol of gibberellin metabolism in situ in maize

Two forms of spinach acyl carrier protein (ACP-I and ACP-II) have recently been characterized and found to be expressed in a tissue-specific manner (JB Ohlrogge, TM Kuo, 1985 J Biol Chem 260: 8032). To examine possible different functions for these ACP isoforms, we have tested purified preparations of spinach leaf ACP-I and ACP-II and Escherichia coli ACP in several in vitro reactions of fatty acid metabolism. Total de novo fatty acid synthesis and malonyl-CoA:ACP transacylase do not appear to discriminate between acyl carrier protein isoforms. In contrast, the K_m of oleoyl-ACP thioesterase for oleoyl-ACP-II is 10-fold higher than for oleoyl-ACP-I, whereas the K_m of acyl-ACP glycerol-3-phosphate acyl transferase is 5-fold higher for oleoyl-ACP-I than for oleoyl-ACP-II. A characterization of these reactions and a possible role for ACP isoforms in regulation of fatty acid metabolism in plants are described.     

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).     

Expression of constitutive and tissue-specific acyl carrier protein isoforms in Arabidopsis

We have characterized the occurrence and expression of multiple acyl carrier protein (ACP) isoforms in Arabidopsis thaliana (L.) Heynh ecotype Columbia. Immunoblot analysis of ACPs from Arabidopsis tissues separated by native polyacrylamide gel electrophoresis and 1 molar urea polyacrylamide gel electrophoresis revealed a complex pattern of multiple ACP isoforms. All tissues examined (leaves, roots, and seeds) expressed at least three forms of ACP. The immunoblot identifications of ACP bands were confirmed by acylation of ACP extracts with Escherichia coli acyl-ACP synthetase. A full-length cDNA clone has been isolated that has 70% identity with a previously characterized Arabidopsis genomic ACP clone (ACP-1) (MA Post-Beittenmiller, A Hloušek-Radojčić, JB Ohlrogge [1989] Nucleic Acids Res 17: 1777). Based on RNA blot analysis, the cDNA clone represents an ACP that is expressed in leaves, seeds, and roots. In order to identify the protein products of each known ACP gene, their mature coding sequences have been expressed in E. coli. Using polymerase chain reactions, exons II and III of the genomic ACP-1 clone and the mature coding sequences of the ACP-2 cDNA clone were subcloned into E. coli expression vectors. Site-directed mutagenesis was used to convert the amino acid sequence of the ACP-2 cDNA clone to that of the A2 clone of Lamppa and Jacks ([1991] Plant Mol Biol 16: 469-474), ACP-3. The three E. coli-expressed proteins have different mobilities on polyacrylamide gel electrophoresis gels and each comigrates with a different Arabidopsis ACP isoform expressed in leaves, seeds, and roots. Thus, all of the three cloned ACPs appear to be constitutively expressed Arabidopsis ACPs. In addition to these three ACP isoforms, protein blots indicate that seed, leaf, and root each express one or more tissue-specific isoforms.     

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.     

Structural homology of spinach acyl carrier protein and Escherichia coli acyl carrier protein based on NMR data

Acyl carrier proteins (ACPs) from spinach and from Escherichia coli have been used to demonstrate the utility of proton NMR for comparison of homologous structures. The structure of E. coli ACP had been previously determined and modeled as a rapid equilibrium among multiple conformational forms (Kim and Prestegard, Biochemistry 28:8792–8797, 1989). Spinach ACP showed two slowly exchanging forms and could be manipulated into one form for structural study. Here we compare this single form to postulated multiple forms of E. coli ACP using the limited amount of NOE data available for the spinach protein. A number of long-range NOE contacts were present between homologous residues in both spinach and E. coli ACP, suggesting tertiary structural homology. To allow a more definitive structural comparison, a method was developed to use spinach ACP NOE constraints to search for regions of structural divergence from two postulated forms of E. coli ACP. The homologous regions of the two protein sequences were aligned, additional distance constraints were extracted from the E. coli structure, and these were mapped onto the spinach sequence. These distance constraints were combined with experimental NOE constraints and a distance geometry simulated annealing protocol was used to test for compatibility of the constraints. All of the experimental spinach NOE constraints could be successfully combined with the E. coli data, confirming the general hypothesis of structural homology. A better fit was obtained with one form, suggesting a preferential stabilization of that form in the spinach case. Proteins 27:131–143 © 1997 Wiley-Liss, Inc.     

Control of Lipid Synthesis during Soybean Seed Development: Enzymic and Immunochemical Assay of Acyl Carrier Protein

During soybean seed (Glycine max, var Am Soy 71) development, the rate of lipid biosynthesis per seed increases greatly. As the seed reaches maturity, lipid synthesis declines. To study the controls over the oil synthesis and storage process, we have chosen acyl carrier protein (ACP) as a representative marker for the fatty acid synthetase pathway. We have quantitated soybean ACP levels by both enzymic and immunochemical methods. Escherichia coli acyl-ACP synthetase was used as an assay for enzymically active ACP. Total ACP protein was determined by immunoassay using antibodies prepared in rabbits against spinach ACP. These antibody preparations also bind ACP isolated from soybeans, allowing development of a radioimmunoassay based on competition with [³H]palmitoyl-ACP. The enzymic and immunochemical measurement of ACP at various stages of seed development have indicated that ACP activity and ACP antigen increase markedly in correlation with the in vivo increase in lipid synthesis. These results indicate that a major control over the increase in lipid synthesis arises through regulation of the levels of the fatty acid biosynthetic proteins. However, as the seed reaches maturity and lipid biosynthesis declines, ACP per seed remains relatively high. In the mature seed, we found that more than 95% of the ACP is localized in the cotyledons, less than 5% is in the axis, and less than 1% is in the seed coat.     

A high yield optimized method for the production of acylated ACPs enabling the analysis of enzymes involved in P. falciparum fatty acid biosynthesis

The natural substrates of the enzymes involved in type-II fatty acid biosynthesis (FAS-II) are acylated acyl carrier proteins (acyl-ACPs). The state of the art method to produce acyl-ACPs involves the transfer of a phosphopantetheine moiety from CoA to apo-ACP by E. coli holo-ACP synthase (EcACPS), yielding holo-ACP which subsequently becomes thioesterified with free fatty acids by the E. coli acyl-ACP synthase (EcAAS). Alternatively, acyl-ACPs can be synthesized by direct transfer of acylated phosphopantetheine moieties from acyl-CoA to apo-ACP by means of EcACPS. The need for native substrates to characterize the FAS-II enzymes of P. falciparum prompted us to investigate the potential and limit of the two methods to efficiently acylate P. falciparum ACP (PfACP) with respect to chain length and β-modification and in preparative amounts. The EcAAS activity is found to be independent from the oxidation state at the β-position and accepts fatty acids as substrates with chain lengths starting from C8 to C20, whereas EcACPS accepts very efficiently acyl-CoAs with chain lengths up to C16, and with decreasing activity also longer chains (C18 to C20). Methods were developed to synthesize and purify preparative amounts of high quality natural substrates that are fully functional for the enzymes of the P. falciparum FAS-II system.     

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). Received: 22 September 1997 / Accepted: 31 October 1997     

A soluble fatty acyl-acyl carrier protein synthetase from the bioluminescent bacterium Vibrio harveyi

An enzyme catalyzing the ligation of long chain fatty acids to bacterial acyl carrier protein (ACP) has been detected and partially characterized in cell extracts of the bioluminescent bacterium Vibrio harveyi. Acyl-ACP synthetase activity (optimal pH 7.5-8.0) required millimolar concentrations of ATP and Mg2+ and was slightly activated by Ca2+, but was inhibited at high ionic strength and by Triton X-100. ACP from either Escherichia coli (apparent Km = 20 microM) or V. harveyi was used as a substrate. Of the [14C]fatty acids tested as substrates (8-18 carbons), a preference for fatty acids less than or equal to 14 carbons in length was observed. Vibrio harveyi acyl-ACP synthetase appears to be a soluble hydrophilic enzyme on the basis of subcellular fractionation and Triton X-114 phase partition assay. The enzyme was not coinduced with luciferase activity or light emission in vivo during the late exponential growth phase in liquid culture. Acyl-ACP synthetase activity was also detected in extracts from the luminescent bacterium Vibrio fischeri, but not Photobacterium phosphoreum. The cytosolic nature and enzymatic properties of V. harveyi acyl-ACP synthetase indicate that it may have a different physiological role than the membrane-bound activity of E. coli, which has been implicated in phosphatidylethanolamine turnover. Acyl-ACP synthetase activity in V. harveyi could be involved in the intracellular activation and elongation of exogenous fatty acids that occurs in this species or in the reactivation of free myristic acid generated by luciferase.     

The purification and function of acetyl coenzyme A:acyl carrier protein transacylase

When individual enzyme activities of the fatty acid synthetase (FAS) system were assayed in extracts from five different plant tissues, acetyl-CoA:acyl carrier protein (ACP) transacylase and beta-ketoacyl-ACP synthetases I and II had consistently low specific activities in comparison with the other enzymes of the system. However, two of these extracts synthesized significant levels of medium chain fatty acids (rather than C16 and C18 acid) from [14C]malonyl-CoA; these extracts had elevated levels of acetyl-CoA:ACP transacylase. To explore the role of the acetyl transacylase more carefully, this enzyme was purified some 180-fold from spinach leaf extracts. Varying concentrations of the transacylase were then added either to spinach leaf extracts or to a completely reconstituted FAS system consisting of highly purified enzymes. The results suggested that: (a) acetyl-CoA:ACP transacylase was the enzyme catalyzing the rate-limiting step in the plant FAS system; (b) increasing concentration of this enzyme markedly increased the levels of the medium chain fatty acids, whereas increase of the other enzymes of the FAS system led to increased levels of stearic acid synthesis; and (c) beta-ketoacyl-ACP synthetase I was not involved in the rate-limiting step. It is suggested that modulation of the activity of acetyl-CoA:ACP transacylase may have important implications in the type of fatty acid synthesized, as well as the amount of fatty acids formed.     

Purification and characterization of beta-ketoacyl-ACP synthetase I from Spinacia oleracea leaves

beta-Ketoacyl-acyl carrier protein (ACP) synthetase I was purified 180-fold from crude extracts of spinach leaves. The purified preparation was completely free from other component enzymes of the de novo fatty acid synthetase (FAS) system. Its molecular weight was estimated to be 56,000 by gel filtration. The apparent Km value for malonyl-CoA in the presence of ACP and malonyl-CoA:ACP transacylase was 4 microM. Purified synthetase I was highly active with acyl-ACP having chain lengths from C2 to C14, with hexanoyl-ACP being the most effective substrate, but palmitoyl-ACP was far less effective and stearoyl-ACP almost inactive. The antibiotic, cerulenin, strongly inhibited synthetase I activity. The inhibition by cerulenin was protected by prior incubation with hexanoyl-ACP, decanoyl-ACP, and myristoyl-ACP. The synthetase was inhibited by 1 mM p-CMB and 5 mM NEM, but not by 1 mM arsenite.     

Improvement of free fatty acid production in Escherichia coli using codon-optimized Streptococcus pyogenes acyl-ACP thioesterase

Fatty acyl–acyl carrier protein (ACP) thioesterase (acyl-ACP TE) from Streptococcus pyogenes (strain MGAS10270) was codon-optimized and expressed in Escherichia coli K-12 W3110 and Escherichia coli K-12 MG1655. By employing codon-optimized S. pyogenes acyl-ACP TE to improve the total free fatty acids (FFAs) and to tailor the composition of FFAs, high-specificity production of saturated fatty acids (C12, C14) and unsaturated fatty acids (C18:1 C18:2) was achieved in recombinants. E. coli SGJS41 and SGJS46 (codon-optimized acyl-ACP TE of S. pyogenes) demonstrated the highest intracellular total FFA content (339 mg/l vs 342 mg/l); in particular, the content of C12 and C14 FFAs was about 3–5 fold, and the content of C18:1 and C18:2 FFAs was about 8–42 fold higher than that in the control E. coli and E. coli JES1017 (original acyl-ACP TE of S. pyogenes).     

Identification of a key residue in the conformational stability of acyl carrier protein

Conformational flexibility of acyl carrier protein (ACP) is important for its ability to interact with multiple enzymes in bacterial fatty acid metabolism. We have recently shown that, unlike the prototypical ACP from Escherichia coli, the more acidic Vibrio harveyi ACP is largely unfolded at physiological pH. Mutations D18K, A75H and A75H/D18K were made in recombinant V. harveyi ACP (rACP) to determine the importance of basic residues Lys-18 and His-75 in maintaining the native conformation of E. coli ACP. Both D18K and A75H ACPs were fatty acylated by acyl-ACP synthetase, showing that neither mutation grossly alters tertiary structure. Circular dichroism (CD) indicated that rACP refolded upon addition of MgCl(2) at 100-fold lower concentrations (<1 mM) than KCl, suggesting that divalent cations stabilize rACP by interaction at specific sites. Surprisingly, mutants A75H and A75H/D18K exhibited native-like conformation in the absence of MgCl(2), while the D18K mutant was comparable to rACP. Moreover, the alpha-helical content of A75H, A75H/D18K and E. coli ACPs was more sensitive than that of rACP or D18K ACP to modification by the histidine-selective reagent diethylpyrocarbonate. Together, these results suggest that the partial positive charge of His-75 may be important in maintaining the conformational stability of E. coli ACP at a neutral pH.