植烷酸

化合物

植烷酸(英語:Phytanic acid,或3,7,11,15-四甲基十六烷酸)是一种支链脂肪酸,人类可以通过食用乳制品、反刍动物脂肪以及某些鱼类[1]而获得该物质。估计西方饮食每天可以提供50~100毫克的植烷酸[2]。在一项牛津大学做的研究中,食用肉食的个人,平均来说血浆中植烷酸浓度的几何平均数比纯素食主义者高6.7倍[3]

植烷酸
IUPAC名
(7反,11反)-3,7,11,15-四甲基十六烷酸
别名 植烷酸
识别
CAS号 14721-66-5  checkY
PubChem 468706
ChemSpider 411797
SMILES
 
  • CC(C)CCC[C@@H](C)CCC[C@@H](C)CCCC(C)CC(=O)O
MeSH Phytanic+acid
性质
化学式 C20H40O2
摩尔质量 312.53 g·mol⁻¹
若非注明,所有数据均出自标准状态(25 ℃,100 kPa)下。

人类病理学

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不像大多数脂肪酸,植烷酸不能够通过β-氧化被代谢。相反,它在过氧物酶体中经历α-氧化,在那里,它被脱掉一个碳而转换为降植烷酸 [4]。降植烷酸在过氧物酶体经历数轮回β-氧化以形成中链脂肪酸,这样就可以在线粒体中被降解成二氧化碳以及水。

患有成人雷夫叙姆病的个体,由PHYH基因中的突变所导致的常染色体隐性神经障碍妨碍了进行α-氧化的活性,且使得他们的血液以及组织中积累了大量的植烷酸[5]。这常会导致周围神经病变小脑共济失调色素性视网膜炎嗅觉丧失症以及听力丧失[6]

其他生物体中的存在情况

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反刍动物中,摄入的植物在消化道发酵中释放出叶绿醇,这种物质是叶绿素的一部分,之后叶绿醇被转变成植烷酸并被储存于脂肪中[7]。最近,间接的证据已经证明大型类人猿倭黑猩猩黑猩猩属大猩猩以及猩猩),与人不同,在植物的后肠发酵过程中获得数量可观的植烷酸[8]

淡水海绵都含有例如4,8,12-三甲基十三烷酸, 植烷酸以及降植烷酸之类的类萜,这表明这些酸对于海生和淡水海绵来说具有化学分类学意义[9]

昆虫,例如黄栌跳甲,被报道可以使用叶绿醇及其代谢产物(例如植烷酸)作为防止自己被捕食的化学威慑剂[10]。这些化合物摄取自它的宿主植物。

转录调控剂

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植烷酸及其代谢产物被报道说可以结合并激活转录因子过氧化物酶体增殖物激活受体α[11]以及视黄酸受体[12]

参考文献

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  1. ^ Brown, P. J.; et al. The determination of phytanic acid and phytol in certain foods and the application of this knowledge to the choice of suitable convenience foods for patients with Refsum's disease. Journal of Human Nutrition and Dietetics. 1993, 6: 295–305. doi:10.1111/j.1365-277x.1993.tb00375.x. 
  2. ^ Steinberg, D. Phytanic acid storage disease (Refsum's disease). In: Metabolic Basis of Inherited Disease. Edited by Stanbury JB, Wyngarden JB, Fredericksen DS, Goldstein JL, Brown MS, 5th edn. New York: McGraw Hill; 1983: 731-747.
  3. ^ Naomi E. Allen, Philip B. Grace, Annette Ginn, Ruth C. Travis, Andrew W. Roddam, Paul N. Appleby, Timothy Key. Phytanic acid: measurement of plasma concentrations by gas-liquid chromatography-mass spectrometry analysis and associations with diet and other plasma fatty acids. The British Journal of Nutrition. 2008-03, 99 (3): 653–659 [2019-02-12]. ISSN 0007-1145. PMID 17868488. doi:10.1017/S000711450782407X. (原始内容存档于2009-03-01). 
  4. ^ D. M. van den Brink, R. J. A. Wanders. Phytanic acid: production from phytol, its breakdown and role in human disease. Cellular and molecular life sciences: CMLS. 2006-08, 63 (15): 1752–1765 [2019-02-12]. ISSN 1420-682X. PMID 16799769. doi:10.1007/s00018-005-5463-y. 
  5. ^ G. Quintaliani, U. Buoncristiani, A. Orecchini, P. Pierini, R. Ricci, G. P. Reboldi. The Umbria Regional Registry for hemodialyzed and transplanted patients. Preliminary experience with an informatic procedure. Contributions to Nephrology. 1994, 109: 96–99 [2019-02-12]. ISSN 0302-5144. PMID 7956237. 
  6. ^ R. J. A. Wanders, J. C. Komen. Peroxisomes, Refsum's disease and the alpha- and omega-oxidation of phytanic acid. Biochemical Society Transactions. 2007-11, 35 (Pt 5): 865–869 [2019-02-13]. ISSN 0300-5127. PMID 17956234. doi:10.1042/BST0350865. (原始内容存档于2014-10-22). 
  7. ^ N. M. Verhoeven, R. J. Wanders, B. T. Poll-The, J. M. Saudubray, C. Jakobs. The metabolism of phytanic acid and pristanic acid in man: a review. Journal of Inherited Metabolic Disease. 1998-10, 21 (7): 697–728 [2019-02-12]. ISSN 0141-8955. PMID 9819701. (原始内容存档于2016-06-04). 
  8. ^ Paul A. Watkins, Ann B. Moser, Cicely B. Toomer, Steven J. Steinberg, Hugo W. Moser, Mazen W. Karaman, Krishna Ramaswamy, Kimberly D. Siegmund, D. Rick Lee, John J. Ely, Oliver A. Ryder, Joseph G. Hacia. Identification of differences in human and great ape phytanic acid metabolism that could influence gene expression profiles and physiological functions. BMC physiology. 2010-10-08, 10: 19 [2019-02-12]. ISSN 1472-6793. PMC 2964658 . PMID 20932325. doi:10.1186/1472-6793-10-19. (原始内容存档于2014-04-16). 
  9. ^ Rezanka, T.; Dembitsky, V. M. Isoprenoid polyunsaturated fatty acids from freshwater sponges. Journal of Natural Products. 1993, 56: 1898–1904. doi:10.1021/np50101a005. 
  10. ^ Venci, F.V.; Morton, T.C. The shield defense of the sumac flea beetle, Blepharida rhois (Chrysomelidae: Alticinae). Chemoecology. 1998, 8: 25–32. 
  11. ^ J. Gloerich, N. van Vlies, G. A. Jansen, S. Denis, J. P. N. Ruiter, M. A. van Werkhoven, M. Duran, F. M. Vaz, R. J. A. Wanders, S. Ferdinandusse. A phytol-enriched diet induces changes in fatty acid metabolism in mice both via PPARalpha-dependent and -independent pathways. Journal of Lipid Research. 2005-04, 46 (4): 716–726 [2019-02-13]. ISSN 0022-2275. PMID 15654129. doi:10.1194/jlr.M400337-JLR200. 
  12. ^ S. Kitareewan, L. T. Burka, K. B. Tomer, C. E. Parker, L. J. Deterding, R. D. Stevens, B. M. Forman, D. E. Mais, R. A. Heyman, T. McMorris, C. Weinberger. Phytol metabolites are circulating dietary factors that activate the nuclear receptor RXR. Molecular Biology of the Cell. 1996-08, 7 (8): 1153–1166 [2019-02-12]. ISSN 1059-1524. PMC 275969 . PMID 8856661. 

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