Fatty acid synthase

Fatty acid synthase
Identifiers
EC number 2.3.1.85
CAS number 9045-77-6
Databases
IntEnz IntEnz view
BRENDA BRENDA entry
ExPASy NiceZyme view
KEGG KEGG entry
MetaCyc metabolic pathway
PRIAM profile
PDB structures RCSB PDB PDBe PDBsum
Gene Ontology AmiGO / EGO
FASN
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
Aliases FASN, fatty acid synthase, Fasn, A630082H08Rik, FAS, OA-519, SDR27X1, Fatty acid synthase
External IDs MGI: 95485 HomoloGene: 55800 GeneCards: FASN
RNA expression pattern


More reference expression data
Orthologs
Species Human Mouse
Entrez

2194

14104

Ensembl

ENSG00000169710

ENSMUSG00000025153

UniProt

P49327

P19096

RefSeq (mRNA)

NM_004104

NM_007988

RefSeq (protein)

NP_004095.4

NP_032014.3

Location (UCSC) Chr 17: 82.08 – 82.1 Mb Chr 11: 120.81 – 120.82 Mb
PubMed search [1] [2]
Wikidata
View/Edit HumanView/Edit Mouse

Fatty acid synthase (FAS) is an enzyme that in humans is encoded by the FASN gene.[3][4][5][6]

Fatty acid synthase is a multi-enzyme protein that catalyzes fatty acid synthesis. It is not a single enzyme but a whole enzymatic system composed of two identical 272 kDa multifunctional polypeptides, in which substrates are handed from one functional domain to the next.[7][8][9][10]

Its main function is to catalyze the synthesis of palmitate (C16:0, a long-chain saturated fatty acid) from acetyl-CoA and malonyl-CoA, in the presence of NADPH.[6]

Metabolic function

Fatty acids are aliphatic acids fundamental to energy production and storage, cellular structure and as intermediates in the biosynthesis of hormones and other biologically important molecules. They are synthesized by a series of decarboxylative Claisen condensation reactions from acetyl-CoA and malonyl-CoA. Following each round of elongation the beta keto group is reduced to the fully saturated carbon chain by the sequential action of a ketoreductase (KR), dehydratase (DH), and enoyl reductase (ER). The growing fatty acid chain is carried between these active sites while attached covalently to the phosphopantetheine prosthetic group of an acyl carrier protein (ACP), and is released by the action of a thioesterase (TE) upon reaching a carbon chain length of 16 (palmitidic acid).

Classes

There are two principal classes of fatty acid synthases.

The mechanism of FAS I and FAS II elongation and reduction is the same, as the domains of the FAS II enzymes are largely homologous to their domain counterparts in FAS I multienzyme polypeptides. However, the differences in the organization of the enzymes - integrated in FAS I, discrete in FAS II - gives rise to many important biochemical differences.[13]

The evolutionary history of fatty acid synthases are very much intertwined with that of polyketide synthases (PKS). Polyketide synthases use a similar mechanism and homologous domains to produce secondary metabolite lipids. Furthermore, polyketide synthases also exhibit a Type I and Type II organization. FAS I in animals is thought to have arisen through modification of PKS I in fungi, whereas FAS I in fungi and the CMN group of bacteria seem to have arisen separately through the fusion of FAS II genes.[11]

Structure

Mammalian FAS consists of a homodimer of two identical protein subunits, in which three catalytic domains in the N-terminal section (-ketoacyl synthase (KS), malonyl/acetyltransferase (MAT), and dehydrase (DH)), are separated by a core region of 600 residues from four C-terminal domains (enoyl reductase (ER), -ketoacyl reductase (KR), acyl carrier protein (ACP) and thioesterase (TE)).[14][15]

The conventional model for organization of FAS (see the 'head-to-tail' model on the right) is largely based on the observations that the bifunctional reagent 1,3-dibromopropanone (DBP) is able to crosslink the active site cysteine thiol of the KS domain in one FAS monomer with the phosphopantetheine prosthetic group of the ACP domain in the other monomer.[16][17] Complementation analysis of FAS dimers carrying different mutations on each monomer has established that the KS and MAT domains can cooperate with the ACP of either monomer.[18][19] and a reinvestigation of the DBP crosslinking experiments revealed that the KS active site Cys161 thiol could be crosslinked to the ACP 4'-phosphopantetheine thiol of either monomer.[20] In addition, it has been recently reported that a heterodimeric FAS containing only one competent monomer is capable of palmitate synthesis.[21]

The above observations seemed incompatible with the classical 'head-to-tail' model for FAS organization, and an alternative model has been proposed, predicting that the KS and MAT domains of both monomers lie closer to the center of the FAS dimer, where they can access the ACP of either subunit (see figure on the top right).[22]

A low resolution X-ray crystallography structure of both pig (homodimer)[23] and yeast FAS (heterododecamer)[24] along with a ~6 Å resolution electron cryo-microscopy (cryo-EM) yeast FAS structure [25] have been solved.

Substrate shuttling mechanism

The solved structures of yeast FAS and mammalian FAS show two distinct organization of highly conserved catalytic domains/enzymes in this multi-enzyme cellular machine. Yeast FAS has a highly efficient rigid barrel-like structure with 6 reaction chambers which synthesize fatty acids independently, while the mammalian FAS has an open flexible structure with only two reaction chambers. However, in both cases the conserved ACP acts as the mobile domain responsible for shuttling the intermediate fatty acid substrates to various catalytic sites. A first direct structural insight into this substrate shuttling mechanism was obtained by cryo-EM analysis, where ACP is observed bound to the various catalytic domains in the barrel-shaped yeast fatty acid synthase.[25] The cryo-EM results suggest that the binding of ACP to various sites is asymmetric and stochastic, as also indicated by computer-simulation studies[26]

FAS revised model with positions of polypeptides, three catalytic domains and their corresponding reactions, visualization by Kosi Gramatikoff. Note that FAS is only active as a homodimer rather than the monomer pictured.
FAS 'head-to-tail' model with positions of polypeptides, three catalytic domains and their corresponding reactions, visualization by Kosi Gramatikoff.

Regulation

Metabolism and homeostasis of fatty acid synthase is transcriptionally regulated by Upstream Stimulatory Factors (USF1 and USF2) and sterol regulatory element binding protein-1c (SREBP-1c) in response to feeding/insulin in living animals.[27][28]

Although liver X receptor (LXRs) modulate the expression of sterol regulatory element binding protein-1c (SREBP-1c) in feeding, regulation of FAS by SREBP-1c is USF-dependent.[28][29][30][31]

Acylphloroglucinols isolated from the fern Dryopteris crassirhizoma show a fatty acid synthase inhibitory activity.[32]

Clinical significance

The gene that codes for FAS has been investigated as a possible oncogene.[33] FAS is upregulated in breast cancers and as well as being an indicator of poor prognosis may also be worthwhile as a chemotherapeutic target.[34][35] FAS may also be involved in the production of an endogenous ligand (biochemistry) for the nuclear receptor PPARalpha, the target of the fibrate drugs for hyperlipidemia,[36] and is being investigated as a possible drug target for treating the metabolic syndrome.[37]

In some cancer cell lines, this protein has been found to be fused with estrogen receptor alpha (ER-alpha), in which the N-terminus of FAS is fused in-frame with the C-terminus of ER-alpha.[6]

An association with uterine leiomyomata has been reported.[38]

See also

References

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  2. "Mouse PubMed Reference:".
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  4. Jayakumar A, Tai MH, Huang WY, al-Feel W, Hsu M, Abu-Elheiga L, Chirala SS, Wakil SJ (Oct 1995). "Human fatty acid synthase: properties and molecular cloning". Proc Natl Acad Sci U S A. 92 (19): 8695–9. doi:10.1073/pnas.92.19.8695. PMC 41033Freely accessible. PMID 7567999.
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  6. 1 2 3 "Entrez Gene: FASN fatty acid synthase".
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  25. 1 2 Gipson P, Mills DJ, Wouts R, Grininger M, Vonck J, Kühlbrandt W (May 2010). "Direct structural insight into the substrate-shuttling mechanism of yeast fatty acid synthase by electron cryomicroscopy". Proc. Natl. Acad. Sci. U.S.A. 107 (20): 9164–9. doi:10.1073/pnas.0913547107. PMC 2889056Freely accessible. PMID 20231485.
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  30. Yoshikawa T, Shimano H, Amemiya-Kudo M, Yahagi N, Hasty AH, Matsuzaka T, Okazaki H, Tamura Y, Iizuka Y, Ohashi K, Osuga J, Harada K, Gotoda T, Kimura S, Ishibashi S, Yamada N (May 2001). "Identification of liver X receptor-retinoid X receptor as an activator of the sterol regulatory element-binding protein 1c gene promoter". Mol. Cell. Biol. 21 (9): 2991–3000. doi:10.1128/MCB.21.9.2991-3000.2001. PMC 86928Freely accessible. PMID 11287605.
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  36. Chakravarthy MV, Lodhi IJ, Yin L, Malapaka RR, Xu HE, Turk J, Semenkovich CF (August 2009). "Identification of a physiologically relevant endogenous ligand for PPARalpha in liver.". Cell. 138 (3): 476–88. doi:10.1016/j.cell.2009.05.036. PMC 2725194Freely accessible. PMID 19646743.
  37. Wu M, Singh SB, Wang J, Chung CC, Salituro G, Karanam BV, Lee SH, Powles M, Ellsworth KP, Lassman ME, Miller C, Myers RW, Tota MR, Zhang BB, Li C (March 2011). "Antidiabetic and antisteatotic effects of the selective fatty acid synthase (FAS) inhibitor platensimycin in mouse models of diabetes.". Proc Natl Acad Sci U S A. 108 (13): 5378–83. doi:10.1073/pnas.1002588108. PMC 3069196Freely accessible. PMID 21389266.
  38. Eggert SL, Huyck KL, Somasundaram P, Kavalla R, Stewart EA, Lu AT, Painter JN, Montgomery GW, Medland SE, Nyholt DR, Treloar SA, Zondervan KT, Heath AC, Madden PA, Rose L, Buring JE, Ridker PM, Chasman DI, Martin NG, Cantor RM, Morton CC (2012). "Genome-wide linkage and association analyses implicate FASN in predisposition to uterine leiomyomata". Am J Hum Genet. 91 (4): 621–8. doi:10.1016/j.ajhg.2012.08.009. PMC 3484658Freely accessible. PMID 23040493.

Further reading

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