The fadD gene of Escherichia coli K12 is located close to rnd at 39.6 min of the chromosomal -map and is a new member of the AMP-binding protein family

The fadD gene of Escherichia coli K12 was cloned and sequenced. The gene was identified by its ability to complement the corresponding mutant and by measuring the enzymatic activity after its expression in this mutant. The deduced polypeptide sequence exhibits similarity to other long chain acyl-CoA (coenzyme A) synthetases and a variety of other proteins, which together form a family of AMP-binding proteins. This family is extended by several new members and subdivided into four groups. fadD is assigned to a subgroup that does not include long chain acyl-CoA synthetases from eukaryotic organisms.     

The fatty acid transport protein (FATP1) is a very long chain acyl-CoA synthetase

The primary sequence of the murine fatty acid transport protein (FATP1) is very similar to the multigene family of very long chain (C20-C26) acyl-CoA synthetases. To determine if FATP1 is a long chain acyl coenzyme A synthetase, FATP1-Myc/His fusion protein was expressed in COS1 cells, and its enzymatic activity was analyzed. In addition, mutations were generated in two domains conserved in acyl-CoA synthetases: a 6- amino acid substitution into the putative active site (amino acids 249-254) generating mutant M1 and a 59-amino acid deletion into a conserved C-terminal domain (amino acids 464-523) generating mutant M2. Immunolocalization revealed that the FATP1-Myc/His forms were distributed between the COS1 cell plasma membrane and intracellular membranes. COS1 cells expressing wild type FATP1-Myc/His exhibited a 3-fold increase in the ratio of lignoceroyl-CoA synthetase activity (C24:0) to palmitoyl-CoA synthetase activity (C16:0), characteristic of very long chain acyl-CoA synthetases, whereas both mutant M1 and M2 were catalytically inactive. Detergent-solubilized FATP1-Myc/His was partially purified using nickel-based affinity chromatography and demonstrated a 10-fold increase in very long chain acyl-CoA specific activity (C24:0/C16:0). These results indicate that FATP1 is a very long chain acyl-CoA synthetase and suggest that a potential mechanism for facilitating mammalian fatty acid uptake is via esterification coupled influx.     

Fatty alcohol production in engineered E. coli expressing Marinobacter fatty acyl-CoA reductases

Although successful production of fatty alcohols in metabolically engineered Escherichia coli with heterologous expression of fatty acyl-CoA reductase has been reported, low biosynthetic efficiency is still a hurdle to be overcome. In this study, we examined the characteristics of two fatty acyl-CoA reductases encoded by Maqu_2220 and Maqu_2507 genes from Marinobacter aquaeolei VT8 on fatty alcohol production in E. coli. Fatty alcohols with diversified carbon chain length were obtained by co-expressing Maqu_2220 with different carbon chain length-specific acyl-ACP thioesterases. Both fatty acyl-CoA reductases displayed broad substrate specificities for C12–C18 fatty acyl chains in vivo. The optimized mutant strain of E. coli carrying the modified tesA gene and fadD gene from E. coli and Maqu_2220 gene from Marinobacter aquaeolei VT8 produced fatty alcohols at a remarkable level of 1.725 g/L under the fermentation condition.     

Very long-chain acyl-CoA synthetases. Human "bubblegum" represents a new family of proteins capable of activating very long-chain fatty acids

Activation by thioesterification to coenzyme A is a prerequisite for most reactions involving fatty acids. Enzymes catalyzing activation, acyl-CoA synthetases, have been classified by their chain length specificities. The most recently identified family is the very long-chain acyl-CoA synthetases (VLCS). Although several members of this group are capable of activating very long-chain fatty acids (VLCFA), one is a bile acid-CoA synthetase, and others have been characterized as fatty acid transport proteins. It was reported that the Drosophila melanogaster mutant bubblegum (BGM) had elevated VLCFA and that the product of the defective gene had sequence homology to acyl-CoA synthetases. Therefore, we cloned full-length cDNA for a human homolog of BGM, and we investigated the properties of its protein product, hsBG, to determine whether it had VLCS activity. Northern blot analysis showed that hsBG is expressed primarily in brain. Compared with vector-transfected cells, COS-1 cells expressing hsBG had increased acyl-CoA synthetase activity with either long-chain fatty acid (2.4-fold) or VLCFA (2.6-fold) substrates. Despite this increased VLCFA activation, hsBG-expressing cells did not have increased rates of VLCFA degradation. Confocal microscopy showed that hsBG had a cytoplasmic localization in some COS-1 cells expressing the protein, whereas it appeared to associate with plasma membrane in others. Fractionation of these cells revealed that most of the hsBG-dependent acyl-CoA synthetase activity was soluble and not membrane-bound. Immunoaffinity-purified hsBG from transfected COS-1 cells was enzymatically active. hsBG and hsVLCS are only 15% identical, and comparison with sequences of two conserved motifs from all known families of acyl-CoA synthetases revealed that hsBG along with the D. melanogaster and murine homologs comprise a new family of acyl-CoA synthetases. Thus, two protein families are now known that contain enzymes capable of activating VLCFA. Because hsBG is expressed in brain but previously described VLCSs were not highly expressed in this organ, hsBG may play a central role in brain VLCFA metabolism and myelinogenesis.     

Aspergillus nidulans contains six possible fatty acyl-CoA synthetases with FaaB being the major synthetase for fatty acid degradation

Aspergillus nidulans can use a variety of fatty acids as sole carbon and energy sources via its peroxisomal and mitochondrial β-oxidation pathways. Prior to channelling the fatty acids into β-oxidation, they need to be activated to their acyl-CoA derivates. Analysis of the genome sequence identified a number of possible fatty acyl-CoA synthetases (FatA, FatB, FatC, FatD, FaaA and FaaB). FaaB was found to be the major long-chain synthetase for fatty acid degradation. FaaB was shown to localise to the peroxisomes, and the corresponding gene was induced in the presence of short and long chain fatty acids. Deletion of the faaB gene leads to a reduced/abolished growth on a variety of fatty acids. However, at least one additional fatty acyl-CoA synthetase with a preference for short chain fatty acids and a potential mitochondrial candidate (AN4659.3) has been identified via genome analysis.     

Arachidonoyl-CoA synthetase. Separation from nonspecific acyl-CoA synthetase and distribution in various cells and tissues

Arachidonoyl-CoA synthetase was solubilized from a particulate fraction of calf brain and human platelets using 1% Nonidet P-40 and 10 mM EDTA. Arachidonoyl-CoA synthetase from both preparations was separated from nonspecific (long chain) acyl-CoA synthetase (EC 6.2.1.3) by chromatography on hydroxylapatite. To further substantiate that the two acyl-CoA synthetases are distinct proteins, we solubilized enzyme from a mutant cell line lacking arachidonoyl-CoA synthetase and from the parent cell line from which it was derived. These preparations were chromatographed on hydroxylapatite, and the mutant showed an absence of the peak identified as arachidonoyl-CoA synthetase in the parent while retaining the peak of nonspecific acyl-CoA synthetase activity. We have also determined the levels of arachidonoyl and nonspecific acyl-CoA synthetase in 13 different human cells and tissues. Arachidonoyl-CoA synthetase is widely distributed and is present in significantly lower concentrations than nonspecific acyl-CoA synthetase only in adipose tissue and liver.     

Diminished Acyl-CoA Synthetase Isoform 4 Activity in INS 832/13 Cells Reduces Cellular Epoxyeicosatrienoic Acid Levels and Results in Impaired Glucose-stimulated Insulin Secretion

Glucose-stimulated insulin secretion (GSIS) in pancreatic beta-cells is potentiated by fatty acids (FA). The initial step in the metabolism of intracellular FA is the conversion to acyl-CoA by long chain acyl-CoA synthetases (Acsls). Because the predominantly expressed Acsl isoforms in INS 832/13 cells are Acsl4 and -5, we characterized the role of these Acsls in beta-cell function by using siRNA to knock down Acsl4 or Acsl5. Compared with control cells, an 80% suppression of Acsl4 decreased GSIS and FA-potentiated GSIS by 32 and 54%, respectively. Knockdown of Acsl5 did not alter GSIS. Acsl4 knockdown did not alter FA oxidation or long chain acyl-CoA levels. With Acsl4 knockdown, incubation with 17 mm glucose increased media epoxyeicosatrienoic acids (EETs) and reduced cell membrane levels of EETs. Further, exogenous EETs reduced GSIS in INS 832/13 cells, and in Acsl4 knockdown cells, an EET receptor antagonist partially rescued GSIS. These results strongly suggest that Acsl4 activates EETs to form EET-CoAs that are incorporated into glycerophospholipids, thereby sequestering EETs. Exposing INS 832/13 cells to arachidonate or linoleate reduced Acsl4 mRNA and protein expression and reduced GSIS. These data indicate that Acsl4 modulates GSIS by regulating the levels of unesterified EETs and that arachidonate controls the expression of its activator Acsl4.     

The Acetylation Motif in AMP-Forming Acyl Coenzyme A Synthetases Contains Residues Critical for Acetylation and Recognition by the Protein Acetyltransferase Pat of Rhodopseudomonas palustris

The AMP-forming acyl coenzyme A (acyl-CoA) synthetases are a large class of enzymes found in both anabolic and catabolic pathways that activate fatty acids to acyl-CoA molecules. The protein acetyltransferase (Pat) from Rhodopseudomonas palustris (RpPat) inactivates AMP-forming acyl-CoA synthetases by acetylating the ε-amino group of a conserved, catalytic lysine residue. In all of the previously described RpPat substrates, this lysine residue is located within a PX₄GK motif that has been proposed to be a recognition motif for RpPat. Here, we report five new substrates for RpPat, all of which are also AMP-forming acyl-CoA synthetases. This finding supports the idea that Pat enzymes may have evolved to control the activity of this family of enzymes. Notably, RpPat did not acetylate the wild-type long-chain acyl-CoA synthetase B (RpLcsB; formerly Rpa2714) enzyme of this bacterium. However, a single amino acid change two residues upstream of the acetylation site was sufficient to convert RpLcsB into an RpPat substrate. The results of mutational and functional analyses of RpLcsB and RpPimA variants led us to propose PK/RTXS/T/V/NGKX₂K/R as a substrate recognition motif. The underlined positions within this motif are particularly important for acetylation by RpPat. The first residue, threonine, is located 4 amino acids upstream of the acetylation site. The second residue can be S/T/V/N and is located two positions upstream of the acetylation site. Analysis of published crystal structures suggests that the side chains of these two residues are very close to the acetylated lysine residue, indicating that they may directly interact with RpPat.     

FadD from Pseudomonas putida CA-3 Is a True Long-Chain Fatty Acyl Coenzyme A Synthetase That Activates Phenylalkanoic and Alkanoic Acids

A fatty acyl coenzyme A synthetase (FadD) from Pseudomonas putida CA-3 is capable of activating a wide range of phenylalkanoic and alkanoic acids. It exhibits the highest rates of reaction and catalytic efficiency with long-chain aromatic and aliphatic substrates. FadD exhibits higher k_cat and K_m values for aromatic substrates than for the aliphatic equivalents (e.g., 15-phenylpentadecanoic acid versus pentadecanoic acid). FadD is inhibited noncompetitively by both acrylic acid and 2-bromooctanoic acid. The deletion of the fadD gene from P. putida CA-3 resulted in no detectable growth or polyhydroxyalkanoate (PHA) accumulation with 10-phenyldecanoic acid, decanoic acid, and longer-chain substrates. The results suggest that FadD is solely responsible for the activation of long-chain phenylalkanoic and alkanoic acids. While the CA-3ΔfadD mutant could grow on medium-chain substrates, a decrease in growth yield and PHA accumulation was observed. The PHA accumulated by CA-3ΔfadD contained a greater proportion of short-chain monomers than did wild-type PHA. Growth of CA-3ΔfadD was unaffected, but PHA accumulation decreased modestly with shorter-chain substrates. The complemented mutant regained 70% to 90% of the growth and PHA-accumulating ability of the wild-type strain depending on the substrate. The expression of an extra copy of fadD in P. putida CA-3 resulted in increased levels of PHA accumulation (up to 1.6-fold) and an increase in the incorporation of longer-monomer units into the PHA polymer.Fatty acyl coenzyme A (CoA) synthetases (FACS; fatty acid:CoA ligases; EC 6.2.1.3) are ATP-, CoA-, and Mg²⁺-dependent enzymes that activate alkanoic acids to CoA esters for β oxidation (Fig. ​(Fig.11 ) (2, 17). FACS are widely distributed in both prokaryotic and eukaryotic organisms and exhibit a broad substrate specificity (34). FadD is a cytoplasmic membrane-associated FACS (7), with sizes ranging from 47 kDa to 62 kDa (2, 14). There is a lack of biochemical information on FadD with a preference for long-chain aromatic and aliphatic substrates. In the current study we purify and characterize for the first time a true long-chain FadD with activity toward both phenylalkanoic and alkanoic acids.Open in a separate windowFIG. 1.FadD activation of fatty acids to their CoA derivatives proceeds through ATP-dependent covalent binding of AMP to fatty acid with the release of inorganic pyrophosphate, followed by C-S bond formation to obtain fatty acyl-CoA ester and subsequent release of AMP. FadD requires the presence of Mg²⁺ ions to be active (2, 17).It is known that bacteria such as Pseudomonas putida can accumulate the biological polyester polyhydroxyalkanoate (PHA) from aromatic as well as aliphatic alkanoic acids (5, 6, 42, 45). The presence of aromatic monomers in the PHA polymer suggests that a FadD with activity toward aromatic substrates is present in these PHA-accumulating strains. Garcia et al. knocked out an acyl-CoA synthetase in P. putida U with a high homology to long-chain fadD products from Escherichia coli and Pseudomonas fragi (6). Garcia et al. also showed that the mutant was not capable of growth or PHA accumulation with aromatic and aliphatic substrates having between 5 and 10 carbons in their acyl chain, indicating that it is a general and not a long-chain acyl-CoA ligase (6). In a follow-up study, Olivera et al. showed that the fadD mutants reverted to wild-type characteristics within 3 days of incubation, indicating that fadD could be replaced by the activity of a second enzyme (25). Indeed, two fadD gene homologues have been identified in P. putida U, namely, fadD1 and fadD2, with fadD2 being expressed only when fadD1 is inactivated (25). A putative FadD in P. putida KT2440 is encoded by PP_4549 (24), but the protein has not been studied nor has the effect of fadD (PP_4549) expression/disruption been examined. In the current study the knockout and complementation of fadD from P. putida CA-3 demonstrated that its activity is critical for growth and PHA accumulation with long-chain aromatic and aliphatic alkanoic acids and that the activity is not replaced by a second enzyme. While reports have shown that PHA polymerase greatly affects PHA monomer composition (30, 40), no evidence of the specific effect of FACS on PHA accumulation so far exists.We describe here the purification, kinetic characterization, gene deletion, and homologous expression of FadD from P. putida CA-3. This is a fundamental study of the activity and physiological role of FACS activity in aromatic and aliphatic alkanoic acid activation and PHA accumulation.     

Molecular determinants of the yeast Arc1p-aminoacyl-tRNA synthetase complex assembly

Eukaryotic aminoacyl-tRNA synthetases are usually organized into high-molecular-weight complexes, the structure and function of which are poorly understood. We have previously described a yeast complex containing two aminoacyl-tRNA synthetases, methionyl-tRNA synthetase and glutamyl-tRNA synthetase, and one noncatalytic protein, Arc1p, which can stimulate the catalytic efficiency of the two synthetases. To understand the complex assembly mechanism and its relevance to the function of its components, we have generated specific mutations in residues predicted by a recent structural model to be located at the interaction interfaces of the N-terminal domains of all three proteins. Recombinant wild-type or mutant forms of the proteins, as well as the isolated N-terminal domains of the two synthetases, were overexpressed in bacteria, purified and used for complex formation in vitro and for determination of binding affinities using surface plasmon resonance. Moreover, mutant proteins were expressed as PtA or green fluorescent protein fusion polypeptides in yeast strains lacking the endogenous proteins in order to monitor in vivo complex assembly and their subcellular localization. Our results show that the assembly of the Arc1p-synthetase complex is mediated exclusively by the N-terminal domains of the synthetases and that the two enzymes bind to largely independent sites on Arc1p. Analysis of single-amino-acid substitutions identified residues that are directly involved in the formation of the complex in yeast cells and suggested that complex assembly is mediated predominantly by van der Waals and hydrophobic interactions, rather than by electrostatic forces. Furthermore, mutations that abolish the interaction of methionyl-tRNA synthetase with Arc1p cause entry of the enzyme into the nucleus, proving that complex association regulates its subcellular distribution. The relevance of these findings to the evolution and function of the multienzyme complexes of eukaryotic aminoacyl-tRNA synthetases is discussed.     

Actinobacterial Acyl Coenzyme A Synthetases Involved in Steroid Side-Chain Catabolism

Bacterial steroid catabolism is an important component of the global carbon cycle and has applications in drug synthesis. Pathways for this catabolism involve multiple acyl coenzyme A (CoA) synthetases, which activate alkanoate substituents for β-oxidation. The functions of these synthetases are poorly understood. We enzymatically characterized four distinct acyl-CoA synthetases from the cholate catabolic pathway of Rhodococcus jostii RHA1 and the cholesterol catabolic pathway of Mycobacterium tuberculosis. Phylogenetic analysis of 70 acyl-CoA synthetases predicted to be involved in steroid metabolism revealed that the characterized synthetases each represent an orthologous class with a distinct function in steroid side-chain degradation. The synthetases were specific for the length of alkanoate substituent. FadD19 from M. tuberculosis H37Rv (FadD19_Mtb) transformed 3-oxo-4-cholesten-26-oate (k_cat/K_m = 0.33 × 10⁵ ± 0.03 × 10⁵ M⁻¹ s⁻¹) and represents orthologs that activate the C₈ side chain of cholesterol. Both CasG_RHA1 and FadD17_Mtb are steroid-24-oyl-CoA synthetases. CasG and its orthologs activate the C₅ side chain of cholate, while FadD17 and its orthologs appear to activate the C₅ side chain of one or more cholesterol metabolites. CasI_RHA1 is a steroid-22-oyl-CoA synthetase, representing orthologs that activate metabolites with a C₃ side chain, which accumulate during cholate catabolism. CasI had similar apparent specificities for substrates with intact or extensively degraded steroid nuclei, exemplified by 3-oxo-23,24-bisnorchol-4-en-22-oate and 1β(2′-propanoate)-3aα-H-4α(3″-propanoate)-7aβ-methylhexahydro-5-indanone (k_cat/K_m = 2.4 × 10⁵ ± 0.1 × 10⁵ M⁻¹ s⁻¹ and 3.2 × 10⁵ ± 0.3 × 10⁵ M⁻¹ s⁻¹, respectively). Acyl-CoA synthetase classes involved in cholate catabolism were found in both Actinobacteria and Proteobacteria. Overall, this study provides insight into the physiological roles of acyl-CoA synthetases in steroid catabolism and a phylogenetic classification enabling prediction of specific functions of related enzymes.     

A flagellar-specific ATPase (FliI) is necessary for flagellar export in Helicobacter pylori

Although flagellar motility is essential for the colonisation of the stomach by Helicobacter pylori, little is known about the regulation of flagellar biosynthesis in this organism. We have identified a gene in H. pylori, designated fliI, whose deduced amino acid sequence revealed extensive homology with the FliI/LcrB/InvC family of proteins which energise the export of flagellar and other virulence factors in several bacterial species. An isogenic mutant of fliI was non-motile and synthesised reduced amounts of flagellin and hook protein subunits. The majority (>99%) of mutant cells were completely aflagellate. These results suggest that FliI is a novel ATPase involved in flagellar export in H. pylori.     

Hypomyelinating leukodystrophy-associated mutation of RARS leads it to the lysosome,inhibiting oligodendroglial morphological differentiation

Pelizaeus-Merzbacher disease (PMD) is a central nervous system (CNS) demyelinating disease in human, currently known as prototypic hypomyelinating leukodystrophy 1 (HLD1). The gene responsible for HLD1 encodes proteolipid protein 1 (PLP1), which is the major myelin protein produced by oligodendrocytes. HLD9 is an autosomal recessive disorder responsible for the gene differing from the plp1 gene. The hld9 gene encodes arginyl-tRNA synthetase (RARS), which belongs to a family of cytoplasmic aminoacyl-tRNA synthetases. Herein we show that HLD9-associated missense mutation of Ser456-to-Leu (S456L) localizes RARS proteins as aggregates into the lysosome but not into the endoplasmic reticulum (ER) and the Golgi body. In contrast, wild-type proteins indeed distribute throughout the cytoplasm. Expression of S456L mutant constructs in cells decreases lysosome-related signaling through ribosomal S6 protein phosphorylation, which is known to be required for myelin formation. Cells harboring the S456L mutant constructs fail to exhibit phenotypes with myelin web-like structures following differentiation in FBD-102b cells, as part of the mammalian oligodendroglial cell model, whereas parental cells exhibit them. Collectively, HLD9-associated RARS mutant proteins are specifically localized in the lysosome with downregulation of S6 phosphorylation involved in myelin formation, inhibiting differentiation in FBD-102b cells. These results present some of the molecular and cellular pathological mechanisms for defect in myelin formation underlying HLD9.     

The ACBP gene family in Rhodnius prolixus: Expression,characterization and function of RpACBP-1

The acyl-CoA-binding proteins (ACBP) constitute a family of conserved proteins that bind acyl-CoA with high affinity and protect it from hydrolysis. Thus, ACBPs may have essential roles in basal cellular lipid metabolism. The genome of the insect Rhodnius prolixus encodes five ACBP genes similar to those described for other insect species. The qPCR analysis revealed that these genes have characteristic expression profiles in insect organs, suggesting that they have specific roles in insect physiology. Recombinant RpACBP-1 was able to bind acyl-CoA in an in vitro gel-shift assay. Moreover, heterologous RpACBP-1 expression in acb1Δ mutant yeast rescued the multi-lobed vacuole phenotype, indicating that RpACBP-1 acts as a bona fide acyl-CoA-binding protein. RpACBP-1 knockdown using RNAi caused triacylglycerol accumulation in the insect posterior midgut and a reduction in the number of deposited eggs. The amount of stored triacylglycerol was reduced in flight muscle, and the incorporation of fatty acids in cholesteryl esters was increased in the fat body. These results showed that RpACBP-1 participates in several lipid metabolism steps in R. prolixus.     

System-wide studies of N-lysine acetylation in Rhodopseudomonas palustris reveal substrate specificity of protein acetyltransferases

N-lysine acetylation is a posttranslational modification that has been well studied in eukaryotes and is likely widespread in prokaryotes as well. The central metabolic enzyme acetyl-CoA synthetase is regulated in both bacteria and eukaryotes by acetylation of a conserved lysine residue in the active site. In the purple photosynthetic α-proteobacterium Rhodopseudomonas palustris, two protein acetyltransferases (RpPat and the newly identified RpKatA) and two deacetylases (RpLdaA and RpSrtN) regulate the activities of AMP-forming acyl-CoA synthetases. In this work, we used LC/MS/MS to identify other proteins regulated by the N-lysine acetylation/deacetylation system of this bacterium. Of the 24 putative acetylated proteins identified, 14 were identified more often in a strain lacking both deacetylases. Nine of these proteins were members of the AMP-forming acyl-CoA synthetase family. RpPat acetylated all nine of the acyl-CoA synthetases identified by this work, and RpLdaA deacetylated eight of them. In all cases, acetylation occurred at the conserved lysine residue in the active site, and acetylation decreased activity of the enzymes by >70%. Our results show that many different AMP-forming acyl-CoA synthetases are regulated by N-lysine acetylation. Five non-acyl-CoA synthetases were identified as possibly acetylated, including glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and Rpa1177, a putative 4-oxalocrotonate tautomerase. Neither RpPat nor RpKatA acetylated either of these proteins in vitro. It has been reported that Salmonella enterica Pat (SePat) can acetylate a number of metabolic enzymes, including GAPDH, but we were unable to confirm this claim, suggesting that the substrate range of SePat is not as broad as suggested previously.