脂肪酸合酶

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脂肪酸合酶英语:Fatty acid synthase)是一个具有多种功能的酶系统,在哺乳动物中,其分子量高达272kDa。在脂肪酸合酶中,底物和中间产物分子在各个功能结构域(可以位于同一酶分子,也可以位于不同酶分子)中传递直到完成脂肪酸的整个合成过程。[1][2][3][4][5]

目录

代谢功能

脂肪酸是脂肪族类酸,在能量运输和储存、细胞结构、提供激素合成的中间物等多个方面发挥着关键作用。脂肪酸的合成需要将乙酰辅酶A和丙二酸单酰辅酶A通过一系列的克莱森缩合反应然后脱羧(生物素辅酶)来完成。在脂肪链的延伸过程中,通过连续的酮还原酶脱水酶以及烯脂酰ACP还原酶的作用,加入的酮基(酰基)被还原为完全饱和的脂肪链。延伸中的脂肪链在这些酶活性位点之间循环传递时,共价连接在酰基载体蛋白磷酸泛酰巯基乙胺(phophopantetheine)辅基上,并通过硫酯酶的作用而被释放。

分类

脂肪酸合酶被分为两大类:

结构

哺乳动物中的脂肪酸合酶含有两个等同的多功能单链(形成同源二聚体),每一条氨基酸链的N端区域含有三个催化结构域(酮脂酰合成酶、脱水酶和单酰/乙酰转移酶),而C端区域则含有四个结构域(醇还原酶、酮脂酰还原酶、酰基载体蛋白和硫酯酶),这两个区域被中间600个氨基酸残基组成的核心区域所分隔。[6][7]

脂肪酸合酶组构的传统模型(“头对尾”模型)大部分是基于双功能试剂1,3-dibromopropanone(DBP)能够将一个脂肪酸合酶单体上的酮脂酰合成酶结构域活性位点上的半胱氨酸(Cys161)的巯基和另一个单体上的载体蛋白结构域中的磷酸泛酰巯基乙胺辅基联接在一起的现象。[8][9]

但对脂肪酸合酶二聚体所进行的突变研究发现酮脂酰合成酶和单酰/乙酰转移酶结构域可以与二聚体中任何一个单体上的载体蛋白共同作用;[10][11] 而对于DBP联接实验结果的再分析显示酮脂酰合成酶的活性位点Cys161的巯基可以被联接到任一单体中载体蛋白4'-磷酸泛酰巯基乙胺的巯基上。[12]。而且,近来发现只含有一个完整单体的异源二聚化的脂肪酸合酶能够进行棕榈酸酯的合成。[13] 以上的这些实验结果与之前的“头对尾”模型并不相符,于是另一个模型被提出:两个单体上的酮脂酰合成酶和单酰/乙酰转移酶结构域位于接近脂肪酸合酶二聚体中心的位置,在这一位置上,它们能够与任一单体中的载体蛋白接触。[14]

调控

脂肪酸合酶的代谢与体内平衡是由上游刺激因子(Upstream Stimulatory Factor)和固醇调节元件结合蛋白(sterol regulatory element binding protein-1c,SREBP-1c)进行转录调控,以对进食行为和胰岛素做出反应。[15][16]

疾病相关

脂肪酸合酶的基因可能是一个癌基因[17]癌症研究中发现,脂肪酸合酶的水平在乳腺癌中发生上调,它可以作为不准确癌症诊断的指标,也是化疗中的潜在靶标。[18][19]

参见

参考文献

  1. Alberts, A.W., Strauss, A.W., Hennessy, S. & Vagelos, P.R. Regulation of synthesis of hepatic fatty acid synthetase: binding of fatty acid synthetase antibodies to polysomes. Proc. Natl. Acad. Sci. USA 72, 3956−3960
  2. Stoops, J.K. et al. Presence of two polypeptide chains comprising fatty acid synthetase. Proc. Natl. Acad. Sci. USA 72, 1940−1944 (1975)
  3. Smith, S., Agradi, E., Libertini, L. & Dileepan, K.N. Specific release of the thioesterase component of the fatty acid synthetase multienzyme complex by limited trypsinization. Proc. Natl. Acad. Sci. USA 73, 1184−1188 (1976)
  4. Wakil, S.J. Fatty acid synthase, a proficient multifunctional enzyme. Biochemistry 28, 4523−4530 (1989)
  5. Smith, S., Witkowski, A. & Joshi, A.K. Structural and functional organization of the animal fatty acid synthase. Prog. Lipid Res. 42, 289−317
  6. Chirala, S.S., Jayakumar, A., Gu, Z.W. & Wakil, S.J. Human fatty acid synthase: role of interdomain in the formation of catalytically active synthase dimer. Proc. Natl. Acad. Sci. USA 98, 3104−3108 (2001)
  7. Smith, S. The animal fatty acid synthase: one gene, one polypeptide, seven enzymes. FASEB J. 8, 1248−1259 (1994)
  8. Stoops, J.K. & Wakil, S.J. Animal fatty acid synthetase. A novel arrangement of the -ketoacyl synthetase sites comprising domains of the two subunits. J. Biol. Chem. 256, 5128−5133 (1981)
  9. Stoops, J.K. & Wakil, S.J. Animal fatty acid synthetase. Identification of the residues comprising the novel arrangement of the -ketoacyl synthetase site and their role in its cold inactivation. J. Biol. Chem. 257, 3230−3235
  10. Joshi, A.K., Rangan, V.S. & Smith, S. 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. J. Biol. Chem. 273, 4937−4943 (1998)
  11. Rangan, V.S., Joshi, A.K. & Smith, S. Mapping the functional topology of the animal fatty acid synthase by mutant complementation in vitro. Biochemistry 40, 10792−10799 (2001)
  12. Witkowski, A. et al. Dibromopropanone cross-linking of the phosphopantetheine and active-site cysteine thiols of the animal fatty acid synthase can occur both inter- and intrasubunit. Reevaluation of the side-by-side, antiparallel subunit model. J. Biol. Chem. 274, 11557−11563 (1999)
  13. Joshi, A.K., Rangan, V.S., Witkowski, A. & Smith, S. Engineering of an active animal fatty acid synthase dimer with only one competent subunit. Chem. Biol. 10, 169−173 (2003)
  14. Asturias FJ et al., Structure and molecular organization of mammalian fatty acid synthase. Nature Structural & Molecular Biology 12, 225 - 232 (2005) PMID 15711565
  15. Paulauskis JD, Sul HS.Hormonal regulation of mouse fatty acid synthase gene transcription in liver.J Biol Chem. 1989 Jan 5;264(1):574-7.
  16. Latasa MJ, Griffin MJ, Moon YS, Kang C, Sul HS. Occupancy and function of the -150 sterol regulatory element and -65 E-box in nutritional regulation of the fatty acid synthase gene in living animals.Mol Cell Biol. 2003 Aug;23(16):5896-907.
  17. Baron A, Migita T, Tang D, Loda M. Fatty acid synthase: a metabolic oncogene in prostate cancer?. J Cell Biochem. 2004, 91 (1): 47–53. doi:10.1002/jcb.10708. PMID 14689581. 
  18. Hunt DA. Lane HM. Zygmont ME. Dervan PA. Hennigar RA. MRNA stability and overexpression of fatty acid synthase in human breast cancer cell lines. [Journal Article] Anticancer Research. 27(1A):27-34, 2007 Jan-Feb. UI: 17352212
  19. Gansler TS. Hardman W 3rd. Hunt DA. Schaffel S. Hennigar RA. Increased expression of fatty acid synthase (OA-519) in ovarian neoplasms predicts shorter survival. [Journal Article] Human Pathology. 28(6):686-92, 1997 Jun. UI: 9191002

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