Aberrant activation of fatty acid synthesis suppresses primary cilium formation and distorts tissue development.

Aberrant activation of fatty acid synthesis is a key feature of many advanced human cancers. Unlike in classical lipogenic tissues, this process has been implicated in membrane production required for rapid cell proliferation. Here, to gain further insight into the consequences of tumor-associated fatty acid synthesis, we have mimicked the lipogenic phenotype of cancer cells in Xenopus embryos by microinjection of RNA encoding the lipogenic transcription factor sterol regulatory element binding protein 1c (SREBP1c). Dramatic morphologic changes were observed that could be linked to alterations in Wnt and Hedgehog signaling, and ultimately to a distortion of the primary cilium. This is a sophisticated microtubular sensory organelle that is expressed on the surface of nearly every cell type and that is lost in many cancers. SREBP1c-induced loss of the primary cilium could be confirmed in mammalian Madin-Darby canine kidney (MDCK) cells and was mediated by changes in the supply of fatty acids. Conversely, inhibition of fatty acid synthesis in highly lipogenic human prostate cancer cells restored the formation of the primary cilium. Lipid-induced ciliary loss was associated with mislocalization of apical proteins, distortion of cell polarization, and aberrant epithelial tissue development as revealed in three-dimensional cultures of MDCK cells and in the developing mouse prostate. These data imply that tumor-associated lipogenesis, in addition to rendering cells more autonomous in terms of lipid supply, disturbs cilium formation and contributes to impaired environmental sensing, aberrant signaling, and distortion of polarized tissue architecture, which are all hallmarks of cancer.

[1]  J. Chapple,et al.  Can faulty antennae increase adiposity? The link between cilia proteins and obesity. , 2009, The Journal of endocrinology.

[2]  N. Katsanis,et al.  The Vertebrate Primary Cilium in Development, Homeostasis, and Disease , 2009, Cell.

[3]  M. Korc,et al.  Pancreatic cancer and precursor pancreatic intraepithelial neoplasia lesions are devoid of primary cilia. , 2009, Cancer research.

[4]  D. Sheff,et al.  Deciliation is associated with dramatic remodeling of epithelial cell junctions and surface domains. , 2009, Molecular biology of the cell.

[5]  E. Voest,et al.  All along the watchtower: is the cilium a tumor suppressor organelle? , 2008, Biochimica et biophysica acta.

[6]  M. Loda,et al.  Overexpression of fatty acid synthase is associated with palmitoylation of Wnt1 and cytoplasmic stabilization of β-catenin in prostate cancer , 2008, Laboratory Investigation.

[7]  Claudio R. Santos,et al.  SREBP Activity Is Regulated by mTORC1 and Contributes to Akt-Dependent Cell Growth , 2008, Cell metabolism.

[8]  E. Golemis,et al.  Cell cycle-dependent ciliogenesis and cancer. , 2008, Cancer research.

[9]  Ralph J Deberardinis,et al.  Brick by brick: metabolism and tumor cell growth. , 2008, Current opinion in genetics & development.

[10]  Ping Chen,et al.  Ciliary proteins link basal body polarization to planar cell polarity regulation , 2008, Nature Genetics.

[11]  Amy E. Shyer,et al.  Kif3a constrains β-catenin-dependent Wnt signalling through dual ciliary and non-ciliary mechanisms , 2008, Nature Cell Biology.

[12]  S. Fisher,et al.  Disruption of the basal body compromises proteasomal function and perturbs intracellular Wnt response , 2007, Nature Genetics.

[13]  J. Menéndez,et al.  Fatty acid synthase and the lipogenic phenotype in cancer pathogenesis , 2007, Nature Reviews Cancer.

[14]  J. Swinnen,et al.  Chemical inhibition of acetyl-CoA carboxylase induces growth arrest and cytotoxicity selectively in cancer cells. , 2007, Cancer research.

[15]  M. T. ter Beest,et al.  A bipartite signal regulates the faithful delivery of apical domain marker podocalyxin/Gp135. , 2007, Molecular biology of the cell.

[16]  P. Satir,et al.  Overview of structure and function of mammalian cilia. , 2007, Annual review of physiology.

[17]  Keith Gull,et al.  Centriole/basal body morphogenesis and migration during ciliogenesis in animal cells , 2006, Journal of Cell Science.

[18]  K. Gaus,et al.  FAPP2, cilium formation, and compartmentalization of the apical membrane in polarized Madin–Darby canine kidney (MDCK) cells , 2006, Proceedings of the National Academy of Sciences.

[19]  Wallace F. Marshall,et al.  Cilia: Tuning in to the Cell's Antenna , 2006, Current Biology.

[20]  J. Reiter,et al.  The Primary Cilium as the Cell's Antenna: Signaling at a Sensory Organelle , 2006, Science.

[21]  J. Swinnen,et al.  Increased lipogenesis in cancer cells: new players, novel targets , 2006, Current opinion in clinical nutrition and metabolic care.

[22]  F. Kuhajda,et al.  Fatty acid synthase and cancer: new application of an old pathway. , 2006, Cancer research.

[23]  Tae Joo Park,et al.  Ciliogenesis defects in embryos lacking inturned or fuzzy function are associated with failure of planar cell polarity and Hedgehog signaling , 2006, Nature Genetics.

[24]  Didier Y. R. Stainier,et al.  Vertebrate Smoothened functions at the primary cilium , 2005, Nature.

[25]  Jayanta Debnath,et al.  Modelling glandular epithelial cancers in three-dimensional cultures , 2005, Nature Reviews Cancer.

[26]  J. Ericsson,et al.  Hyperphosphorylation regulates the activity of SREBP1 during mitosis. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[27]  K. Anderson,et al.  Cilia and Hedgehog responsiveness in the mouse. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[28]  Aimin Liu,et al.  Mouse intraflagellar transport proteins regulate both the activator and repressor functions of Gli transcription factors , 2005, Development.

[29]  Massimo Loda,et al.  Fatty acid synthase: A metabolic oncogene in prostate cancer? , 2004, Journal of cellular biochemistry.

[30]  M. Krasnow,et al.  Tube Morphogenesis Making and Shaping Biological Tubes , 2003, Cell.

[31]  Keith E. Mostov,et al.  Building epithelial architecture: insights from three-dimensional culture models , 2002, Nature Reviews Molecular Cell Biology.

[32]  J. Swinnen,et al.  Stimulation of tumor-associated fatty acid synthase expression by growth factor activation of the sterol regulatory element-binding protein pathway , 2000, Oncogene.

[33]  M. Foretz,et al.  Sterol regulatory element binding protein-1c is a major mediator of insulin action on the hepatic expression of glucokinase and lipogenesis-related genes. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[34]  S. Chirala,et al.  Human acetyl-CoA carboxylase: characterization, molecular cloning, and evidence for two isoforms. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[35]  D. Moore,et al.  Cyclopamine, a steroidal alkaloid, disrupts development of cranial neural crest cells in Xenopus , 1995, Developmental dynamics : an official publication of the American Association of Anatomists.

[36]  L. Abu‐Elheiga,et al.  ヒトアセチルCoAカルボキシラーゼ 特性化,分子クローニングおよび2つのイソフォームの証拠 , 1995 .

[37]  H. Weintraub,et al.  Expression of achaete-scute homolog 3 in Xenopus embryos converts ectodermal cells to a neural fate. , 1994, Genes & development.

[38]  H Irschik,et al.  The soraphens: a family of novel antifungal compounds from Sorangium cellulosum (Myxobacteria). I. Soraphen A1 alpha: fermentation, isolation, biological properties. , 1994, The Journal of antibiotics.

[39]  H. Reichenbach,et al.  Antibiotics from Gliding Bacteria. Part 54. Isolation and Structure Elucidation of Soraphen A1α, a Novel Antifungal Macrolide from Sorangium cellulosum. , 1993 .

[40]  R. Moon,et al.  Interactions between Xwnt-8 and Spemann organizer signaling pathways generate dorsoventral pattern in the embryonic mesoderm of Xenopus. , 1993, Genes & development.