A continuous coupled enzyme assay for bacterial malonyl-CoA:acyl carrier protein transacylase (FabD) (original) (raw)
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Biochemistry, 1995
Streptomyces glaucescens, a Gram-positive soil bacterium, produces the polyketide antibiotic tetracenomycin (Tcm) C. To study possible biochemical connections between the biosynthesis of bacterial fatty acids and polyketides, the abundant acyl carrier protein (ACP) detected throughout the growth of the tetracenomycin (Tcm) C-producing S. glaucescens was purified to homogeneity and found to behave like many other ACPs from bacteria and plants (apparent M , of 20 000 on gel filtration chromatography, apparent M, of 3400-4800 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions, and pZ 3.8). By using an oligodeoxynucleotide synthesized in accordance with the sequence of residues 25-36 of the ACP, the fabC gene encoding this protein was cloned, and expression of this gene in Escherichia coli yielded the ACP entirely as the active holoenzyme. Sequence analysis of 4.3 kilobases (kb) of DNA flanking fabC revealed the presence of three other genes oriented in the same transcriptional direction in the orderfabD, fabH, fabC, andfabB. Each of the four genes is predicted to encode proteins with high sequence similarity to the following components of the E. coli fatty acid synthase (FAS): the FabD malonyl-coenzyme A:ACP acyltransferase (MAT), FabH 3-oxoacy1:ACP synthase 111, AcpP ACP, and FabB 3-oxoacy1:ACP synthase I. Expression of the S. glaucescens fabD gene in E. coli produced active MAT able to catalyze in vitro the transfer of radioactive malonate from malonyl-coenzyme A to the E. coli AcpP and S. glaucescens FabC ACPs, as well as to the TcmM ACP component of the Tcm type I1 polyketide synthase [Shen, B., et al. (1992) J. Bacteriol 174, 3818-38211. Expression of
A malonyl-CoA-dependent switch in the bacterial response to a dysfunction of lipid metabolism
Molecular Microbiology, 2008
Bacteria stringently regulate the synthesis of their membrane phospholipids, but the responsible regulatory mechanisms are incompletely understood. Bacillus subtilis FabF, the target of the mycotoxin cerulenin, catalyses the condensation of malonyl-ACP with acyl-ACP to extend the growing acyl chain by two carbons. Here we show that B. subtilis strains containing the fabF1 allele, which codes for the cerulenin-insensitive protein FabF[I108F], overexpressed several genes involved in fatty acid and phospholipid biosynthesis (the fap regulon) and had significantly elevated levels of malonyl-CoA. These results pinpointed FabF[I108F] as responsible for the increased malonyl-CoA production, which in turn acts as an inducer of the fap regulon by impairing the binding of the FapR repressor to its DNA targets. Synthesis of acyl-ACPs by a cell-free fatty acid system prepared from fabF1 cells showed the accumulation of short-and medium-chain acyl-ACPs. These results indicate that the acyl-ACP chain length acceptance of FabF[I108F] is biased towards shorter acyl-ACPs. We also provide evidence that upregulation of FabF[I108F] is essential for survival and for resistance to cerulenin of fabF1 cells. These findings indicate that malonyl-CoA is a key molecule to monitor lipid metabolism functioning and trigger appropriate genetic and biochemical adjustments to relieve dysfunctions of this essential metabolic pathway.
Scientific Reports
Acetyl-CoA carboxylases (ACCs) are enzyme complexes generally composed of three catalytic domains and distributed in all organisms. In prokaryotes and plastids of most plants, these domains are encoded in distinct subunits forming heteromeric complexes. Distinctively, cytosolic ACCs from eukaryotes and plastids of graminaceous monocots, are organized in a single multidomain polypeptide. Until now, no multidomain ACCs had been discovered in bacteria. Here, we show that a putative multidomain ACC in Saccharopolyspora erythraea is encoded by the sace_4237 gene, representing the first prokaryotic ACC homodimeric multidomain complex described. The SACE_4237 complex has both acetyl-CoA and propionyl-CoA carboxylase activities. Importantly, we demonstrate that sace_4237 is essential for S. erythraea survival as determined by the construction of a sace_4237 conditional mutant. Altogether, our results show that this prokaryotic homodimeric multidomain ACC provides malonyl-CoA for de novo fatty acid biosynthesis. Furthermore, the data presented here suggests that evolution of these enzyme complexes, from single domain subunits to eukaryotic multidomain ACCs, occurred in bacteria through domain fusion. Acetyl-CoA carboxylases (ACC)s catalyse the carboxylation of acetyl-CoA to malonyl-CoA (E.C. 6.4.1.2), the first step in fatty acid biosynthesis in prokaryotes and eukaryotes 1,2. Carboxylation of acetyl-CoA to malonyl-CoA is the rate-limiting step in de novo fatty-acid biosynthesis and ACCs have long been used as targets to control metabolic disorders such as obesity, metabolic syndrome and infectious diseases 2,3. Recently, up-regulation of ACC was found in human cancerogenic tumors, suggesting this enzyme as a potential target for the treatment of cancer 4. In archaea, ACCs are part of the 3-hydroxypropionate pathway, involved in autotrophic carbon fixation 5. ACCs belong to the biotin-dependent carboxylase protein family. The two-step reaction mechanism of ACCs involves an ATP-dependent formation of carboxybiotin followed by the transfer of the carboxyl moiety to acetyl-CoA. Both steps are performed by three main functional components, a biotin carboxyl carrier protein (BCCP), a biotin carboxylase domain (BC) and a carboxyl transferase domain (CT). Domain arrangement varies amongst different biotin-dependent carboxylases and from one organism to another 1. Structural studies have described new non-catalytic domains 6,7. In bacteria, the ACC model derives from the Escherichia coli complex. Cronan et al. (1972) described the role of ACCs in fatty acid biosynthesis by isolating thermosensitive E. coli mutants capable of growing at restricted temperatures only when the media was supplemented with saturated and unsaturated fatty acids 8. Further characterization of the conditional mutants allowed for the identification of four genes encoding different components of the multi-subunit ACC from E. coli, which later became a "model bacterial ACC" 9,10. The E. coli ACC contains three domains encoded in four proteins: the BC domain, the BCCP component and two independent peptides (α and ß) that form the functional CT domain.
Journal of Bacteriology, 2000
A universal set of genes encodes the components of the dissociated, type II, fatty acid synthase system that is responsible for producing the multitude of fatty acid structures found in bacterial membranes. We examined the biochemical basis for the production of branched-chain fatty acids by gram-positive bacteria. Two genes that were predicted to encode homologs of the β-ketoacyl-acyl carrier protein synthase III of Escherichia coli (eFabH) were identified in the Bacillus subtilis genome. Their protein products were expressed, purified, and biochemically characterized. Both B. subtilis FabH homologs, bFabH1 and bFabH2, carried out the initial condensation reaction of fatty acid biosynthesis with acetyl-coenzyme A (acetyl-CoA) as a primer, although they possessed lower specific activities than eFabH. bFabH1 and bFabH2 also utilized iso- and anteiso-branched-chain acyl-CoA primers as substrates. eFabH was not able to accept these CoA thioesters. Reconstitution of a complete round of ...
Chemistry & Biology, 2010
It remains unclear whether in a bacterial fatty acid synthase (FAS) acyl chain transfer is a programmed or diffusion controlled and random action. Acyl carrier protein (ACP), which delivers all intermediates and interacts with all synthase enzymes, is the key player in this process. High-resolution structures of intermediates covalently bound to an ACP representing each step in fatty acid biosynthesis have been solved by solution NMR. These include hexanoyl-, 3-oxooctanyl-, 3R-hydroxyoctanoyl-, 2-octenoyl-, and octanoyl-ACP from Streptomyces coelicolor FAS. The high-resolution structures reveal that the ACP adopts a unique conformation for each intermediate driven by changes in the internal fatty acid binding pocket. The binding of each intermediate shows conserved structural features that may ensure effective molecular recognition over subsequent rounds of fatty acid biosynthesis.
Journal of Biological Chemistry, 2002
Fatty acyl-CoA synthetase (FACS, fatty acid:CoA ligase, AMP forming; EC 6.2.1.3) plays a central role in intermediary metabolism by catalyzing the formation of fatty acyl-CoA. In Escherichia coli this enzyme, encoded by the fadD gene, is required for the coupled import and activation of exogenous long-chain fatty acids. The E. coli FACS (FadD) contains two sequence elements, which comprise the ATP/AMP signature motif (213 YTG-GTTGVAKGA 224 and 356 GYGLTE 361) placing it in the superfamily of adenylate-forming enzymes. A series of sitedirected mutations were generated in the fadD gene within the ATP/AMP signature motif site to evaluate the role of this conserved region to enzyme function and to fatty acid transport. This approach revealed two major classes of fadD mutants with depressed enzyme activity: 1) those with 25-45% wild type activity (fadD G216A , fadD T217A , fadD G219A , and fadD K222A) and 2) those with 10% or less wild-type activity (fadD Y213A , fadD T214A , and fadD E361A). Using anti-FadD sera, Western blots demonstrated the different mutant forms of FadD that were present and had localization patterns equivalent to the wild type. The defect in the first class was attributed to a reduced catalytic efficiency although several mutant forms also had a reduced affinity for ATP. The mutations resulting in these biochemical phenotypes reduced or essentially eliminated the transport of exogenous long-chain fatty acids. These data support the hypothesis that the FACS FadD functions in the vectorial movement of exogenous fatty acids across the plasma membrane by acting as a metabolic trap, which results in the formation of acyl-CoA esters.
1999
A DNA fragment containing the Pseudomonas aeruginosa fabD (encoding malonyl-coenzyme A [CoA]:acyl carrier protein [ACP] transacylase), fabG (encoding -ketoacyl-ACP reductase), acpP (encoding ACP), and fabF (encoding -ketoacyl-ACP synthase II) genes was cloned and sequenced. This fab gene cluster is delimited by the plsX (encoding a poorly understood enzyme of phospholipid metabolism) and pabC (encoding 4-amino-4-deoxychorismate lyase) genes; the fabF and pabC genes seem to be translationally coupled. The fabH gene (encoding -ketoacyl-ACP synthase III), which in most gram-negative bacteria is located between plsX and fabD, is absent from this gene cluster. A chromosomal temperature-sensitive fabD mutant was obtained by site-directed mutagenesis that resulted in a W258Q change. A chromosomal fabF insertion mutant was generated, and the resulting mutant strain contained substantially reduced levels of cis-vaccenic acid. Multiple attempts aimed at disruption of the chromosomal fabG gene were unsuccessful. We purified FabD as a hexahistidine fusion protein (H 6 -FabD) and ACP in its native form via an ACP-intein-chitin binding domain fusion protein, using a novel expression and purification scheme that should be applicable to ACP from other bacteria. Matrix-assisted laser desorption-ionization spectroscopy, native polyacrylamide electrophoresis, and amino-terminal sequencing revealed that (i) most of the purified ACP was properly modified with its 4phosphopantetheine functional group, (ii) it was not acylated, and (iii) the amino-terminal methionine was removed. In an in vitro system, purified ACP functioned as acyl acceptor and H 6 -FabD exhibited malonyl-CoA:ACP transacylase activity.
Microbiology (Reading, England), 2002
The two acyl-homoserine lactones (AHLs) N-(butyryl)-L-homoserine lactone and N-[3-oxododecanoyl]-L-homoserine lactone (3-oxo-C(12)-HSL) are required for quorum sensing in Pseudomonas aeruginosa. These AHLs derive their invariant lactone rings from S-adenosylmethionine and their variable acyl chains from the cellular acyl-acyl carrier protein (ACP) pool. This reaction is catalysed by specific AHL synthases, which exhibit acyl chain specificity. Culture supernatants of P. aeruginosa contain multiple 3-oxo-AHLs that differ in their acyl chain lengths but their physiological role, if any, remains unknown. An in vitro fatty acid-3-oxo-AHL synthesis system was established utilizing purified P. aeruginosa Fab proteins, ACP and the LasI 3-oxo-AHL synthase. In the presence of excess protein, substrates and cofactors, this system produced almost exclusively 3-oxo-C(12)-HSL. When the beta-ketoacyl-ACP reductase (FabG) catalysed step was made rate-limiting by switching from the preferred NADPH ...