Amino acid sequence around the active-site serine residue in the acyltransferase domain of goat mammary fatty acid synthetase

Animal Fatty Acid Synthase: A Chemical Nanofactory

Fatty acids are crucial molecules for most living beings, very well spread and conserved across species. These molecules play a role in energy storage, cell membrane architecture, and cell signaling, the latter through their derivative metabolites. De novo synthesis of fatty acids is a complex chemical process that can be achieved either by a metabolic pathway built by a sequence of individual enzymes, such as in most bacteria, or by a single, large multi-enzyme, which incorporates all the chemical capabilities of the metabolic pathway, such as in animals and fungi, and in some bacteria. Here we focus on the multi-enzymes, specifically in the animal fatty acid synthase (FAS). We start by providing a historical overview of this vast field of research. We follow by describing the extraordinary architecture of animal FAS, a homodimeric multi-enzyme with seven different active sites per dimer, including a carrier protein that carries the intermediates from one active site to the next. We then delve into this multi-enzyme's detailed chemistry and critically discuss the current knowledge on the chemical mechanism of each of the steps necessary to synthesize a single fatty acid molecule with atomic detail. In line with this, we discuss the potential and achieved FAS applications in biotechnology, as biosynthetic machines, and compare them with their homologous polyketide synthases, which are also finding wide applications in the same field. Finally, we discuss some open questions on the architecture of FAS, such as their peculiar substrate-shuttling arm, and describe possible reasons for the emergence of large megasynthases during evolution, questions that have fascinated biochemists from long ago but are still far from answered and understood.

De novo lipogenesis in the liver in health and disease: more than just a shunting yard for glucose

Hepatic de novo lipogenesis (DNL) is the biochemical process of synthesising fatty acids from acetyl‐CoA subunits that are produced from a number of different pathways within the cell, most commonly carbohydrate catabolism. In addition to glucose which most commonly supplies carbon units for DNL, fructose is also a profoundly lipogenic substrate that can drive DNL, important when considering the increasing use of fructose in corn syrup as a sweetener. In the context of disease, DNL is thought to contribute to the pathogenesis of non‐alcoholic fatty liver disease, a common condition often associated with the metabolic syndrome and consequent insulin resistance. Whether DNL plays a significant role in the pathogenesis of insulin resistance is yet to be fully elucidated, but it may be that the prevalent products of this synthetic process induce some aspect of hepatic insulin resistance.

Biochemical characterization of the minimal polyketide synthase domains in the lovastatin nonaketide synthase LovB

The biosynthesis of lovastatin in Aspergillus terreus requires two megasynthases. The lovastatin nonaketide synthase, LovB, synthesizes the intermediate dihydromonacolin L using nine malonyl-coenzyme A molecules, and is a reducing, iterative type I polyketide synthase. The iterative type I polyketide synthase is mechanistically different from bacterial type I polyketide synthases and animal fatty acid synthases. We have cloned the minimal polyketide synthase domains of LovB as standalone proteins and assayed their activities and substrate specificities. The didomain proteins ketosynthase-malonyl-coenzyme A:acyl carrier protein acyltransferase (KS-MAT) and acyl carrier protein-condensation (ACP-CON) domain were expressed solubly in Escherichia coli. The monodomains MAT, ACP and CON were also obtained as soluble proteins. The MAT domain can be readily labeled by [1,2-(14)C]malonyl-coenzyme A and can transfer the acyl group to both the cognate LovB ACP and heterologous ACPs from bacterial type I and type II polyketide synthases. Using the LovB ACP-CON didomain as an acyl acceptor, LovB MAT transferred malonyl and acetyl groups with k(cat)/K(m) values of 0.62 min(-1).mum(-1) and 0.032 min(-1).mum(-1), respectively. The LovB MAT domain was able to substitute the Streptomyces coelicolor FabD in supporting product turnover in a bacterial type II minimal polyketide synthase assay. The activity of the KS domain was assayed independently using a KS-MAT (S656A) mutant in which the MAT domain was inactivated. The KS domain displayed no activity towards acetyl groups, but was able to recognize malonyl groups in the absence of cerulenin. The relevance of these finding to the priming mechanism of fungal polyketide synthase is discussed.

Structural and functional organization of the animal fatty acid synthase

The entire pathway of palmitate synthesis from malonyl-CoA in mammals is catalyzed by a single, homodimeric, multifunctional protein, the fatty acid synthase. Each subunit contains three N-terminal domains, the beta-ketoacyl synthase, malonyl/acetyl transferase and dehydrase separated by a structural core from four C-terminal domains, the enoyl reductase, beta-ketoacyl reductase, acyl carrier protein and thiosterase. The kinetics and specificities of the substrate loading reaction catalyzed by the malonyl/acetyl transferase, the condensation reaction catalyzed by beta-ketoacyl synthase and chain-terminating reaction catalyzed by the thioesterase ensure that intermediates do not leak off the enzyme, saturated chains exclusively are elongated and palmitate is released as the major product. Only in the fatty acid synthase dimer do the subunits adopt conformations that facilitate productive coupling of the individual reactions for fatty acid synthesis at the two acyl carrier protein centers. Introduction of a double tagging and dual affinity chromatographic procedure has permitted the engineering and isolation of heterodimeric fatty acid synthases carrying different mutations on each subunit. Characterization of these heterodimers, by activity assays and chemical cross-linking, has been exploited to map the functional topology of the protein. The results reveal that the two acyl carrier protein domains engage in substrate loading and condensation reactions catalyzed by the malonyl/acetyl transferase and beta-ketoacyl synthase domains of either subunit. In contrast, the reactions involved in processing of the beta-carbon atom, following each chain elongation step, together with the release of palmitate, are catalyzed by the cooperation of the acyl carrier protein with catalytic domains of the same subunit. These findings suggest a revised model for the fatty acid synthase in which the two polypeptides are oriented such that head-to-tail contacts are formed both between and within subunits.

Differential affinity labeling of the two subunits of the homodimeric animal fatty acid synthase allows isolation of heterodimers consisting of subunits that have been independently modified

To explore the domain interactions that are required for catalytic activity of the multifunctional, homodimeric fatty acid synthase (FAS), we have formulated a strategy that allows isolation of modified dimers containing independently mutated subunits. Either a hexahistidine or a FLAG octapeptide tag was incorporated into the FAS at either the amino terminus, within an internal noncatalytic domain, or at the carboxyl terminus. The presence of the tags had no effect on the activity of the wild-type FAS. His-tagged dimers were mixed with FLAG-tagged dimers, and the subunits were randomized to produce a mixture of His-tagged homodimers, FLAG-tagged homodimers, and doubly tagged heterodimers. The doubly tagged heterodimers could be purified to homogeneity by chromatography on an anti-FLAG immunoaffinity column followed by a metal ion chelating column. This procedure for isolation of FAS heterodimers was utilized to determine whether the two centers for fatty acid synthesis in the FAS dimer can function independently of each other. Doubly tagged heterodimers, consisting of one wild-type subunit and one subunit in which the thioesterase activity had been eliminated, either by mutation or by treatment with phenylmethanesulfonyl fluoride, have 50% of the wild-type thioesterase activity and, in the presence of substrates, accumulate a long chain fatty acyl moiety on the modified subunit, thus blocking further substrate turnover at this center. Nevertheless, the ability of the heterodimer to synthesize fatty acids is also 50% of the wild-type FAS, demonstrating that an individual center for fatty acid synthesis has the same activity when paired with either a functional or nonfunctional catalytic center.

Characterisation of genes involved in biosynthesis of coronafacic acid, the polyketide component of the phytotoxin coronatine

Coronafacic acid (CFA) is the polyketide component of coronatine (COR), a phytotoxin produced by the plant pathogen, Pseudomonas syringae. In the present study we have determined the nucleotide sequence of a 3.92-kb DNA fragment involved in CFA biosynthesis. Analysis of the sequence revealed four complete open reading frames (ORFs) designated cfa1 to cfa4 and one incomplete ORF (cfa5), all transcribed in the same direction. The predicted translation products of cfa1, cfa2 and cfa3 showed relatedness to acyl carrier proteins, fatty acid dehydrases and beta-ketoacylsynthases, respectively, which are required for polyketide synthesis. cfa1 was subcloned, its sequence was confirmed, and it was overexpressed in E. coli to yield a peptide with an apparent molecular mass of 6 kDa.

Expression in Escherichia coli and refolding of the malonyl-/acetyltransferase domain of the multifunctional animal fatty acid synthase

A cDNA encoding residues 429-815 of the multifunctional rat fatty acid synthase has been expressed in Escherichia coli and the recombinant protein refolded in vitro as a catalytically active malonyl-/acetyltransferase. Kinetic properties of the refolded recombinant enzyme were indistinguishable from those of a transferase preparation derived from the natural fatty acid synthase by limited proteolysis, indicating that the transferase domain is capable of folding correctly as an independent protein. Replacement of the active site Ser-581 (full-length fatty acid synthase numbering) with alanine completely eliminated catalytic activity, whereas replacement with cysteine resulted in retention of about 1% activity. The wild type transferase was extremely susceptible to inhibition by diethyl pyrocarbonate, and protection against inhibition was afforded by both malonyl- and acetyl-CoA. Replacement of the highly conserved residue His-683 with Ala reduced activity by 99.95%, and the residual activity was relatively unaffected by diethyl pyrocarbonate. The rate of acylation of the active site serine residue was also reduced by several orders of magnitude in the His-683 --> Ala mutant. These results indicate that His-683 plays an essential role in catalysis, likely by accepting a proton from the active site serine, thus increasing its nucleophilicity.

Functional analysis of putative beta-ketoacyl:acyl carrier protein synthase and acyltransferase active site motifs in a type II polyketide synthase of Streptomyces glaucescens

The significance of potential active site motifs for acyltransferase and beta-ketoacyl:acyl carrier protein synthase regions within the TcmK protein was investigated by determining the effects of mutations in the proposed active sites on the production of tetracenomycins F2 and C. In a Streptomyces glaucescens tcmGHI JKLMNO null mutant, plasmids carrying the S351A mutation produced high amounts of tetracenomycin F2 but plasmids carrying the C173A or C173S mutation or the H350L-S351A double mutation produced no detectable amount of any known intermediate. In a tcmK mutant, plasmids with the S351A mutation restored high production of tetracenomycin C and plasmids carrying the other mutations were able to complement the chromosomal defect to some extent. None of the mutations affected the amount of TcmK produced.

Molecular structure of the multifunctional fatty acid synthetase gene of Brevibacterium ammoniagenes: its sequence of catalytic domains is formally consistent with a head-to-tail fusion of the two yeast genes FAS1 and FAS2

The Brevibacterium ammoniagenes fatty acid synthetase (FAS) gene was isolated from a series of overlapping clones by both immunological and plaque hybridization screening of two independent gene libraries. From the isolated DNA a contiguous segment of 10,549 bp was sequenced in both directions. The sequenced DNA contained a very long (9312 nucleotides) open reading frame coding for a protein of 3104 amino acids and with a molecular mass of 327,466 daltons. Based on characteristic sequence motifs known from other FAS systems, seven different FAS active centres were identified at distinct locations within the polypeptide chain. Only one component enzyme, the 3-hydroxydecanoyl beta, gamma-dehydratase, has not yet been localized definitively within the gene. Translation is presumed to start from a GUG triplet located 25 nucleotides downstream of the transcriptional initiation site. There is a canonical Shine-Dalgarno sequence just before this start codon. Comparison of the B. ammoniagenes FAS sequence with those of other known fatty acid synthetases revealed a particularly high degree of similarity to the products of the two yeast genes, FAS1 and FAS2 (30% identical and 46% identical plus closely related amino acids). This similarity extends over the entire length of the genes and involves not only the primary sequences of individual component enzymes but also their sequential order within the multifunctional proteins. These data, together with those on the structure of other fatty acid synthetases, are interpreted in terms of a contribution of both primary structure and subunit cooperation to a conserved topology of functional domains common to all type I FAS complexes.

Acyl-CoA-binding and transport, an alternative function for diazepam binding inhibitor (DBI), which is identical with acyl-CoA-binding protein

Acyl-CoA binding protein (ACBP) was originally identified as an artifact in a preparation of fatty acid binding protein. The amino acid sequence of ACBP from bovine, rat and human liver is identical to the sequence of diazepam binding inhibitor (DBI) from these species. ACBP and DBI are therefore one and the same protein. The tertiary structure of ACBP in solution has been determined by 2D-NMR. ACBP consists of 4 alpha-helixes, covering the sequence from amino acid 2-11, 20-38, 51-62 and 72-85, respectively. The protein is folded so that it forms a boomerang type of structure with helix 1 and 2 arranged antiparallel in the one arm of the boomerang, helix 3 and the non-helical part between helix 2 and 3 form the second arm in the boomerang. Helix 4 is located in an angle behind helix 1 and 2. NMR measurements of chemical shifts, induced by acyl-CoA binding, indicate that the binding site is located in the bottom of the V formed between the two arms of the boomerang. This location of the binding site is confirmed with affinity labelling with radioactive photoreactive acyl-CoA esters. ACBP does not bind free CoA or free fatty and short chain acyl-CoA esters (C2-C8). The affinity increases with increasing length of the acyl chain from C10-C20 and drops again in acyl-CoA esters with 22 and 24 carbon in the acyl chain.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleotide sequence of the lipase gene lip2 from the antarctic psychrotroph Moraxella TA144 and site-specific mutagenesis of the conserved serine and histidine residues

The lip2 gene from the antarctic psychotroph Moraxella TA144 was sequenced. The primary structure of the Lip2 preprotein deduced from the nucleotide sequence is composed of 433 amino acids with a predicted Mr of 47,222. This enzyme contains a Ser-centered consensus sequence and a conserved His-Gly dipeptide found in most lipase amino-terminal domains. These sequences are involved in the lipase active site conformation since substitution of the conserved Ser or His residues by Ala and Gln, respectively, results in the loss of both lipase and esterase activities. Structural factors that would allow proper enzyme flexibility at low temperatures are discussed. It is suggested that only subtle changes in the primary structure of these psychrotrophic enzymes can account for their ability to catalyze lipolysis at temperatures close to 0 degrees C.

Biosynthesis of the Escherichia coli siderophore enterobactin: sequence of the entF gene, expression and purification of EntF, and analysis of covalent phosphopantetheine

The sequence of the entF gene which codes for the serine activating enzyme in enterobactin biosynthesis is reported. The gene encodes a protein with a calculated molecular weight of 142,006 and shares homologies with the small subunits of gramicidin S synthetase and tyrocidine synthetase. We have subcloned and overexpressed entF in a multicopy plasmid and attempted to demonstrate L-serine-dependent ATP-[32P]PPi exchange activity and its participation in enterobactin biosynthesis, but the overexpressed enzyme appears to be essentially inactive in crude extract. A partial purification of active EntF from wild-type Escherichia coli, however, has confirmed the expected activities of EntF. In a search for possible causes for the low level of activity of the overexpressed enzyme, we have discovered that EntF contains a covalently bound phosphopantetheine cofactor.

Acyl-CoA-binding protein (ACBP) and its relation to fatty acid-binding protein (FABP): an overview

Acyl-CoA-binding protein is a 10 Kd protein which binds medium- and long-chain acyl-CoA esters with high affinity. The concentration in liver is 2-4 times the acyl-CoA concentration. ACBP has much greater affinity for acyl-CoA than FABP. FABP from bovine heart and liver is unable to compete with multilamellar liposomes, Lipidex and microsomal membrane in binding acyl-CoA esters, whereas ACBP effectively extracts acyl-CoA from all those sources. Previously published results on the effect of FABP on acyl-CoA metabolism need to be reevaluated due to possible contamination with ACBP. Recently it was discovered that ACBP is identical to a putative neurotransmitter diazepam binding inhibitor. The possibility therefore exists that ACBP has more than one function.

The multifunctional 6-methylsalicylic acid synthase gene of Penicillium patulum. Its gene structure relative to that of other polyketide synthases

6-Methylsalicylic acid synthase (MSAS) from Penicillium patulum is a homomultimer of a single, multifunctional protein subunit. The enzyme is induced, at the transcriptional level, during the end of the logarithmic growth phase. After approximately 150-fold purification, a homogeneous enzyme preparation was obtained exhibiting, upon SDS gel electrophoresis, a subunit molecular mass of 188 kDa. By immunological screening of a genomic P. patulum DNA expression library, the MSAS gene together with its flanking sequences was isolated; 7131 base pairs of the cloned genomic DNA were sequenced. Within this sequence the MSAS gene was identified as a 5322-bp-long open reading frame coding for a protein of 1774 amino acids and 190,731 Da molecular mass. Transcriptional initiation and termination sites were determined both by primer extension studies and from cDNA sequences specially prepared for the 5' and 3' portions of the gene. The same cDNA sequences revealed the presence of a 69-bp intron within the N-terminal part of the MSAS gene. The intron contains the canonical GT and AG dinucleotides at its 5'- and 3'-splice junctions. An internal TACTGAC sequence, resembling the TACTAAC consensus element of Saccharomyces cerevisiae introns is suggested to represent the branch point of the lariat splicing intermediate. When compared to other known polyketide synthases, distinct amino acid sequence similarities of limited lengths were observed with some, though not all, of them. A comparatively low degree of similarity was detected to the yeast and Penicillium FAS or to the plant chalcone and resveratrol synthases. In contrast, a significantly higher sequence similarity was found between MSAS and the rat fatty acid synthase, especially at their transacylase, 2-oxoacyl reductase, 2-oxoacyl synthase and acyl carrier protein domains. Besides several dissimilar, interspersed regions probably coding for MSAS- and FAS-specific functions, the sequential order of the similar domains was colinear in both enzymes. The low similarity between the two P. patulum polyketide synthases, MSAS and FAS, possibly supports a convergent rather than a divergent evolution of both multienzyme proteins.

Amino acid sequences of substrate-binding sites in chicken liver fatty acid synthase

The amino acid sequences of three essential regions of chicken liver fatty acid synthase have been determined: that around 4'-phosphopantetheine ("carrier" site), the substrate "loading" site containing serine, and a "waiting" site for the growing fatty acid containing cysteine. The amino acid sequence of the 4'-phosphopantetheine region was determined for the acetyl-, malonyl-, hydroxybutyryl-, and butyryl-enzyme with peptides obtained by hydrolysis of the enzyme with trypsin and Staphylococcus aureus (V8) protease. The sequence region around the essential serine was obtained for the acetyl- and malonyl-enzyme. The N-terminus of the tryptic peptide was blocked. However, the same sequence is obtained for the acetyl- and malonyl-peptide after S. aureus protease digestion, suggesting that the enzyme contains a single acyl transferase rather than two separate transacylases. The sequence around the cysteine was obtained by use of a radioactive iodoacetamide label. An unusual sequence of three serines adjacent to the cysteine was found. The strong similarities between peptides from different species for all three of the regions suggest that the multifunctional polypeptides from yeast and animals have evolved from the monofunctional enzymes of lower species.

Decarboxylation of malonyl-CoA by lactating bovine mammary fatty acid synthase

1. A pronounced malonyl-CoA decarboxylase activity of bovine mammary fatty acid synthase results in the formation of acetyl-CoA and not of triacetic acid lactone as in the reaction by yeast and pigeon liver synthase. 2. This activity is unaffected by the dissociation of the enzyme and is insensitive to its modification by iodoacetamide, N-ethylmaleimide, p-hydroxymercuribenzoate or 2-chloroacetyl-CoA. 3. A 50% inhibition of the activity observed on the depletion of free CoA from the medium indicates that at least part of the reaction occurs only after the acylation of the enzyme with the malonyl group. 4. A parallel reaction without such a transfer also appears to occur simultaneously.

Molecular cloning and sequence analysis of complementary DNA encoding rat mammary gland medium-chain S-acyl fatty acid synthetase thio ester hydrolase

Poly(A)+ RNA from pregnant rat mammary glands was size-fractionated by sucrose gradient centrifugation, and fractions enriched in medium-chain S-acyl fatty acid synthetase thio ester hydrolase (MCH) were identified by in vitro translation and immunoprecipitation. A cDNA library was constructed, in pBR322, from enriched poly(A)+ RNA and screened with two oligonucleotide probes deduced from rat MCH amino acid sequence data. Cross-hybridizing clones were isolated and found to contain cDNA inserts ranging from approximately 1100 to 1550 base pairs (bp). A 1550-bp cDNA insert, from clone 43H09, was confirmed to encode MCH by hybrid-select translation/immunoprecipitation studies and by comparison of the amino acid sequence deduced from the DNA sequence of the clone to the amino acid sequence of the MCH peptides. Northern blot analysis revealed the size of the MCH mRNA to be 1500 nucleotides, and it is therefore concluded that the 1550-bp insert (including G X C tails) of clone 43H09 represents a full- or near-full-length copy of the MCH gene. The rat MCH sequence is the first reported sequence of a thioesterase from a mammalian source, but comparison of the deduced amino acid sequences of MCH and the recently published mallard duck medium-chain S-acyl fatty acid synthetase thioesterase reveals significant homology. In particular, a seven amino acid sequence containing the proposed active serine of the duck thioesterase is found to be perfectly conserved in rat MCH.

A novel acyl-CoA-binding protein from bovine liver. Effect on fatty acid synthesis

Bovine liver was shown to contain a hitherto undescribed medium-chain acyl-CoA-binding protein. The protein co-purifies with fatty-acid-binding proteins, but was, unlike these proteins, unable to bind fatty acids. The protein induced synthesis of medium-chain acyl-CoA esters on incubation with goat mammary-gland fatty acid synthetase. The possible function of the protein is discussed.

The pentafunctional FAS1 gene of yeast: its nucleotide sequence and order of the catalytic domains

FAS1, the structural gene of the pentafunctional fatty acid synthetase subunit beta in Saccharomyces cerevisiae has been sequenced. Its reading frame represents an intron-free nucleotide sequence of 5,535 base pairs, corresponding to a protein of 1,845 amino acids with a molecular weight of 205,130 daltons. In addition to the coding sequence, 1,468 base pairs of its 5'-flanking region were determined. S1 nuclease mapping revealed two transcriptional initiation sites; 5 and 36 base pairs upstream of the translational start codon. Within the flanking sequences two TATATAAA boxes, several A-rich and T-rich blocks and a TAG...TATGTT...TATGTT...TTT sequence were found and are discussed as transcriptional initiation and termination signals, respectively. The order of catalytic domains in the cluster gene was established by complementation of defined fas1 mutants with overlapping FAS1 subclones. Acetyl transferase (amino acids 1-468) is located proximal to the N-terminus of subunit beta, followed by the enoyl reductase (amino acids 480-858), the dehydratase (amino acids 1,134-1,615) and the malonyl/palmityl transferase (amino acids 1,616-1,845) domains. One major inter-domain region of about 276 amino acids with so far unknown function was found between the enoyl reductase and dehydratase domains. The substrate-binding serine residues of acetyl, malonyl and palmityl transferases were identified within the corresponding domains. Significant sequence homologies exist between the acyl transferase active sites of yeast and animal fatty acid synthetases. Similarly, a putative sequence of the enoyl reductase active site was identified.

Evidence that the medium-chain acyltransferase of lactating-goat mammary-gland fatty acid synthetase is identical with the acetyl/malonyltransferase

Competitive binding experiments with malonyl-CoA and [1-14C]acetyl-CoA, [1-14C]butyryl-CoA or [1-14C]decanoyl-CoA indicate that all these substrates are transferred to lactating-goat mammary-gland fatty acid synthetase by the same transferase. Isolation and determination of the amino acid sequence of [1-14C]decanoyl-labelled CNBr-cleavage peptide from the decanoyltransferase site showed that this transferase is identical with the acetyl/malonyltransferase.