Point Mutations in GLI3 Lead to Misregulation of its Subcellular Localization

Background Mutations in the transcription factor GLI3, a downstream target of Sonic Hedgehog (SHH) signaling, are responsible for the development of malformation syndromes such as Greig-cephalopolysyndactyly-syndrome (GCPS), or Pallister-Hall-syndrome (PHS). Mutations that lead to loss of function of the protein and to haploinsufficiency cause GCPS, while truncating mutations that result in constitutive repressor function of GLI3 lead to PHS. As an exception, some point mutations in the C-terminal part of GLI3 observed in GCPS patients have so far not been linked to loss of function. We have shown recently that protein phosphatase 2A (PP2A) regulates the nuclear localization and transcriptional activity a of GLI3 function. Principal Findings We have shown recently that protein phosphatase 2A (PP2A) and the ubiquitin ligase MID1 regulate the nuclear localization and transcriptional activity of GLI3. Here we show mapping of the functional interaction between the MID1-α4-PP2A complex and GLI3 to a region between amino acid 568-1100 of GLI3. Furthermore we demonstrate that GCPS-associated point mutations, that are located in that region, lead to misregulation of the nuclear GLI3-localization and transcriptional activity. GLI3 phosphorylation itself however appears independent of its localization and remains untouched by either of the point mutations and by PP2A-activity, which suggests involvement of an as yet unknown GLI3 interaction partner, the phosphorylation status of which is regulated by PP2A activity, in the control of GLI3 subcellular localization and activity. Conclusions The present findings provide an explanation for the pathogenesis of GCPS in patients carrying C-terminal point mutations, and close the gap in our understanding of how GLI3-genotypes give rise to particular phenotypes. Furthermore, they provide a molecular explanation for the phenotypic overlap between Opitz syndrome patients with dysregulated PP2A-activity and syndromes caused by GLI3-mutations.

[1]  George J. Feldman,et al.  Opitz G/BBB syndrome, a defect of midline development, is due to mutations in a new RING finger gene on Xp22 , 1997, Nature Genetics.

[2]  D. Kalderon,et al.  Proteolysis of the Hedgehog Signaling Effector Cubitus interruptus Requires Phosphorylation by Glycogen Synthase Kinase 3 and Casein Kinase 1 , 2002, Cell.

[3]  A. Joyner,et al.  A mouse model of Greig cephalapolysyndactyly syndrome: the extra-toes J mutation contains an intragenic deletion of the Gli3 gene , 1998, Nature Genetics.

[4]  A. Joyner,et al.  All mouse ventral spinal cord patterning by hedgehog is Gli dependent and involves an activator function of Gli3. , 2004, Developmental cell.

[5]  Yina Li,et al.  Shh and Gli3 are dispensable for limb skeleton formation but regulate digit number and identity , 2002, Nature.

[6]  U. Rüther,et al.  The Shh-independent activator function of the full-length Gli3 protein and its role in vertebrate limb digit patterning. , 2007, Developmental biology.

[7]  L. Biesecker,et al.  GLI3 frameshift mutations cause autosomal dominant Pallister-Hall syndrome , 1997, Nature Genetics.

[8]  E. Zackai,et al.  Molecular and clinical analyses of Greig cephalopolysyndactyly and Pallister-Hall syndromes: robust phenotype prediction from the type and position of GLI3 mutations. , 2005, American journal of human genetics.

[9]  Philip A Beachy,et al.  Hedgehog-Regulated Processing of Gli3 Produces an Anterior/Posterior Repressor Gradient in the Developing Vertebrate Limb , 2000, Cell.

[10]  A. Schier,et al.  Zebrafish Gli3 functions as both an activator and a repressor in Hedgehog signaling. , 2005, Developmental biology.

[11]  J. Concordet,et al.  Multisite protein kinase A and glycogen synthase kinase 3beta phosphorylation leads to Gli3 ubiquitination by SCFbetaTrCP. , 2006, Molecular and cellular biology.

[12]  A. Joyner,et al.  Gli 1 can rescue the in vivo function of Gli 2 , 2022 .

[13]  Jens Böse,et al.  Dorsal-ventral patterning of the spinal cord requires Gli3 transcriptional repressor activity. , 2002, Genes & development.

[14]  Yasunori Tanaka,et al.  Sonic Hedgehog-induced Activation of the Gli1Promoter Is Mediated by GLI3* , 1999, The Journal of Biological Chemistry.

[15]  Chi-Chung Hui,et al.  Interplays of Gli2 and Gli3 and their requirement in mediating Shh-dependent sclerotome induction , 2003, Development.

[16]  Yong Pan,et al.  A Novel Protein-processing Domain in Gli2 and Gli3 Differentially Blocks Complete Protein Degradation by the Proteasome* , 2007, Journal of Biological Chemistry.

[17]  C. Chiang,et al.  Specification of ventral neuron types is mediated by an antagonistic interaction between Shh and Gli3 , 2000, Nature Neuroscience.

[18]  R. Lurz,et al.  Active Transport of the Ubiquitin Ligase MID1 along the Microtubules Is Regulated by Protein Phosphatase 2A , 2008, PloS one.

[19]  K. Grzeschik,et al.  GLI3 zinc-finger gene interrupted by translocations in Greig syndrome families , 1991, Nature.

[20]  S. Schweiger,et al.  Protein phosphatase 2A and rapamycin regulate the nuclear localization and activity of the transcription factor GLI3. , 2008, Cancer research.

[21]  L. Biesecker,et al.  GLI3 mutations in human disorders mimic Drosophila cubitus interruptus protein functions and localization. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[22]  S. Ishii,et al.  Mediator Modulates Gli3-Dependent Sonic Hedgehog Signaling , 2006, Molecular and Cellular Biology.

[23]  R. Mo,et al.  Gli3 null mice display glandular overgrowth of the developing stomach , 2005, Developmental dynamics : an official publication of the American Association of Anatomists.

[24]  Norbert Perrimon,et al.  Hedgehog signal transduction: recent findings. , 2002, Current opinion in genetics & development.

[25]  M. Matise,et al.  Transduction of graded Hedgehog signaling by a combination of Gli2 and Gli3 activator functions in the developing spinal cord , 2004, Development.

[26]  A. Ballabio,et al.  MID2, a homologue of the Opitz syndrome gene MID1: similarities in subcellular localization and differences in expression during development. , 1999, Human molecular genetics.

[27]  A. Ashworth,et al.  FXY2/MID2, a gene related to the X-linked Opitz syndrome gene FXY/MID1, maps to Xq22 and encodes a FNIII domain-containing protein that associates with microtubules. , 1999, Genomics.

[28]  Joachim Klose,et al.  Two‐dimensional electrophoresis of proteins: An updated protocol and implications for a functional analysis of the genome , 1995, Electrophoresis.

[29]  H. Kondoh,et al.  Overlapping positive and negative regulatory elements determine lens-specific activity of the delta 1-crystallin enhancer , 1993, Molecular and cellular biology.

[30]  J. Concordet,et al.  Multisite Protein Kinase A and Glycogen Synthase Kinase 3β Phosphorylation Leads to Gli3 Ubiquitination by SCFβTrCP , 2006, Molecular and Cellular Biology.

[31]  Andreas Kulozik,et al.  Regulation of the MID1 protein function is fine-tuned by a complex pattern of alternative splicing , 2004, Human Genetics.

[32]  R Rizzo,et al.  Point mutations throughout the GLI3 gene cause Greig cephalopolysyndactyly syndrome. , 1999, Human molecular genetics.

[33]  L. Biesecker Strike three for GLI3 , 1998, Nature Genetics.

[34]  D. Donnai,et al.  De novo GLI3 mutation in acrocallosal syndrome: broadening the phenotypic spectrum of GLI3 defects and overlap with murine models , 2002, Journal of medical genetics.

[35]  M. Kalff-Suske,et al.  Point mutations in human GLI3 cause Greig syndrome. , 1997, Human molecular genetics.

[36]  H. Brunner,et al.  From syndrome families to functional genomics , 2004, Nature Reviews Genetics.

[37]  A. Joyner,et al.  Gli1 can rescue the in vivo function of Gli2. , 2001, Development.

[38]  A. Rosenthal,et al.  Hedgehog signal transduction: from flies to vertebrates. , 1999, Experimental cell research.

[39]  H. Ropers,et al.  MID1, mutated in Opitz syndrome, encodes an ubiquitin ligase that targets phosphatase 2A for degradation , 2001, Nature Genetics.

[40]  Rolf Zeller,et al.  Progression of Vertebrate Limb Development Through SHH-Mediated Counteraction of GLI3 , 2002, Science.

[41]  U. Rüther,et al.  Opposing gradients of Gli repressor and activators mediate Shh signaling along the dorsoventral axis of the inner ear , 2007, Development.

[42]  T. Kornberg,et al.  Phosphorylation of the fused protein kinase in response to signaling from hedgehog. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[43]  S. Schweiger,et al.  Alternative polyadenylation signals and promoters act in concert to control tissue-specific expression of the Opitz Syndrome gene MID1 , 2007, BMC Molecular Biology.

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

[45]  A. McMahon,et al.  A direct requirement for Hedgehog signaling for normal specification of all ventral progenitor domains in the presumptive mammalian spinal cord. , 2002, Genes & development.

[46]  Qihong Zhang,et al.  Gli2 and Gli3 Localize to Cilia and Require the Intraflagellar Transport Protein Polaris for Processing and Function , 2005, PLoS genetics.

[47]  M. Nakafuku,et al.  A binding site for Gli proteins is essential for HNF-3beta floor plate enhancer activity in transgenics and can respond to Shh in vitro. , 1997, Development.