Mutation of foxl1 Results in Reduced Cartilage Markers in a Zebrafish Model of Otosclerosis

Bone diseases such as otosclerosis (conductive hearing loss) and osteoporosis (low bone mineral density) can result from the abnormal expression of genes that regulate cartilage and bone development. The forkhead box transcription factor FOXL1 has been identified as the causative gene in a family with autosomal dominant otosclerosis and has been reported as a candidate gene in GWAS meta-analyses for osteoporosis. This potentially indicates a novel role for foxl1 in chondrogenesis, osteogenesis, and bone remodelling. We created a foxl1 mutant zebrafish strain as a model for otosclerosis and osteoporosis and examined jaw bones that are homologous to the mammalian middle ear bones, and mineralization of the axial skeleton. We demonstrate that foxl1 regulates the expression of collagen genes such as collagen type 1 alpha 1a and collagen type 11 alpha 2, and results in a delay in jawbone mineralization, while the axial skeleton remains unchanged. foxl1 may also act with other forkhead genes such as foxc1a, as loss of foxl1 in a foxc1a mutant background increases the severity of jaw calcification phenotypes when compared to each mutant alone. Our zebrafish model demonstrates atypical cartilage formation and mineralization in the zebrafish craniofacial skeleton in foxl1 mutants and demonstrates that aberrant collagen expression may underlie the development of otosclerosis.

[1]  Yong Feng,et al.  A novel variant in FOXC1 associated with atypical Axenfeld-Rieger syndrome , 2021, BMC Medical Genomics.

[2]  Yongheng Chen,et al.  Toward a mechanistic understanding of DNA binding by forkhead transcription factors and its perturbation by pathogenic mutations , 2021, Nucleic acids research.

[3]  Curtis R. French Mechanistic Insights into Axenfeld–Rieger Syndrome from Zebrafish foxc1 and pitx2 Mutants , 2021, International journal of molecular sciences.

[4]  P. Hu,et al.  A pathogenic deletion in Forkhead Box L1 (FOXL1) identifies the first otosclerosis (OTSC) gene , 2021, Human genetics.

[5]  M. Salanga,et al.  Genotype to Phenotype: CRISPR Gene Editing Reveals Genetic Compensation as a Mechanism for Phenotypic Disjunction of Morphants and Mutants , 2021, International journal of molecular sciences.

[6]  O. Lehmann,et al.  The Axenfeld–Rieger Syndrome Gene FOXC1 Contributes to Left–Right Patterning , 2021, Genes.

[7]  J. W. Von den Hoff,et al.  Zebrafish Models of Craniofacial Malformations: Interactions of Environmental Factors , 2020, Frontiers in Cell and Developmental Biology.

[8]  N. Segil,et al.  Foxc1 establishes enhancer accessibility for craniofacial cartilage differentiation , 2020, bioRxiv.

[9]  A. Groves,et al.  Uncovering the secreted signals and transcription factors regulating the development of mammalian middle ear ossicles , 2020, Developmental dynamics : an official publication of the American Association of Anatomists.

[10]  P. Trainor,et al.  The development, patterning and evolution of neural crest cell differentiation into cartilage and bone. , 2020, Bone.

[11]  S. Fukuhara,et al.  Dual role of Jam3b in early hematopoietic and vascular development , 2019, Development.

[12]  L. Zhu,et al.  foxc1 is required for embryonic head vascular smooth muscle differentiation in zebrafish. , 2019, Developmental biology.

[13]  M. Koo,et al.  Low Hemoglobin Is Associated With Low Bone Mineral Density and High Risk of Bone Fracture in Male Adults: A Retrospective Medical Record Review Study , 2019, American journal of men's health.

[14]  D. Stainier,et al.  Genetic compensation triggered by mutant mRNA degradation , 2019, Nature.

[15]  Curtis R. French,et al.  Loss of foxc1 in zebrafish reduces optic nerve size and cell number in the retinal ganglion cell layer , 2019, Vision Research.

[16]  Ronald Y. Kwon,et al.  Using zebrafish to study skeletal genomics. , 2019, Bone.

[17]  D. Bergen,et al.  Zebrafish as an Emerging Model for Osteoporosis: A Primary Testing Platform for Screening New Osteo-Active Compounds , 2019, Front. Endocrinol..

[18]  V. Lefebvre Roles and regulation of SOX transcription factors in skeletogenesis. , 2019, Current topics in developmental biology.

[19]  R. Akhtar,et al.  Zebrafish as a model to study bone maturation: Nanoscale structural and mechanical characterization of age-related changes in the zebrafish vertebral column. , 2018, Journal of the mechanical behavior of biomedical materials.

[20]  J. Crump,et al.  Fox proteins are modular competency factors for facial cartilage and tooth specification , 2018, Development.

[21]  M. Seifi,et al.  Axenfeld‐Rieger syndrome , 2018, Clinical genetics.

[22]  G. Carballo,et al.  A highlight on Sonic hedgehog pathway , 2018, Cell Communication and Signaling.

[23]  Jingjing Zhang,et al.  Application of bone transgenic zebrafish in anti‐osteoporosis chemical screening , 2018, Animal models and experimental medicine.

[24]  N. Tanaka,et al.  Roles of the Hedgehog Signaling Pathway in Epidermal and Hair Follicle Development, Homeostasis, and Cancer , 2017, Journal of developmental biology.

[25]  Didier Y. R. Stainier,et al.  Genetic compensation: A phenomenon in search of mechanisms , 2017, PLoS genetics.

[26]  S. Komarova,et al.  Bone Health in Patients With Hematopoietic Disorders of Bone Marrow Origin: Systematic Review and Meta‐ Analysis , 2017, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[27]  K. Stankunas,et al.  Shh promotes direct interactions between epidermal cells and osteoblast progenitors to shape regenerated zebrafish bone , 2017, Development.

[28]  P. Witten,et al.  Small teleost fish provide new insights into human skeletal diseases. , 2017, Methods in cell biology.

[29]  H. Deng,et al.  Replication of Caucasian Loci Associated with Osteoporosis-related Traits in East Asians , 2016, Journal of bone metabolism.

[30]  H. Dere,et al.  Relation of otosclerosis and osteoporosis: A bone mineral density study. , 2016, Auris, nasus, larynx.

[31]  K. Kaestner,et al.  Foxl1-Expressing Mesenchymal Cells Constitute the Intestinal Stem Cell Niche , 2015, Cellular and molecular gastroenterology and hepatology.

[32]  H. Aburatani,et al.  Distinct effects of Hoxa2 overexpression in cranial neural crest populations reveal that the mammalian hyomandibular-ceratohyal boundary maps within the styloid process. , 2015, Developmental biology.

[33]  C. Kimmel,et al.  Building the backbone: the development and evolution of vertebral patterning , 2015, Development.

[34]  G. Banfi,et al.  Danio rerio: the Janus of the bone from embryo to scale. , 2015, Clinical cases in mineral and bone metabolism : the official journal of the Italian Society of Osteoporosis, Mineral Metabolism, and Skeletal Diseases.

[35]  A. Lassar,et al.  A pathway to bone: signaling molecules and transcription factors involved in chondrocyte development and maturation , 2015, Development.

[36]  B. Olsen,et al.  Bone development. , 2015, Bone.

[37]  Lindsey Mork,et al.  Zebrafish Craniofacial Development: A Window into Early Patterning. , 2015, Current topics in developmental biology.

[38]  H. Deng,et al.  Genome-wide Association Studies for Osteoporosis: A 2013 Update , 2014, Journal of bone metabolism.

[39]  Stefan Schulte-Merker,et al.  A bone to pick with zebrafish. , 2013, BoneKEy reports.

[40]  Xuelin Huang,et al.  An improvement of the 2ˆ(-delta delta CT) method for quantitative real-time polymerase chain reaction data analysis. , 2013, Biostatistics, bioinformatics and biomathematics.

[41]  Kunzheng Wang,et al.  Foxc2 regulates osteogenesis and angiogenesis of bone marrow mesenchymal stem cells , 2013, BMC Musculoskeletal Disorders.

[42]  Jingjing Sun,et al.  Foxc1 controls the growth of the murine frontal bone rudiment by direct regulation of a Bmp response threshold of Msx2 , 2013, Development.

[43]  A. Tucker,et al.  Evolution of the mammalian middle ear and jaw: adaptations and novel structures , 2013, Journal of anatomy.

[44]  D. Ornitz,et al.  Development of the endochondral skeleton. , 2013, Cold Spring Harbor perspectives in biology.

[45]  E. Fransen,et al.  COL1A1 association and otosclerosis: A meta‐analysis , 2012, American journal of medical genetics. Part A.

[46]  P. Frommolt,et al.  Attenuated BMP1 function compromises osteogenesis, leading to bone fragility in humans and zebrafish. , 2012, American journal of human genetics.

[47]  Stefan Schulte-Merker,et al.  Not all bones are created equal - using zebrafish and other teleost species in osteogenesis research. , 2011, Methods in cell biology.

[48]  A. Kung Novel genetic loci associated with osteoporosis , 2010 .

[49]  S. Kuratani,et al.  History of studies on mammalian middle ear evolution: a comparative morphological and developmental biology perspective. , 2010, Journal of experimental zoology. Part B, Molecular and developmental evolution.

[50]  Stephen L. Johnson,et al.  A gain of function mutation causing skeletal overgrowth in the rapunzel mutant. , 2009, Developmental biology.

[51]  Yurii S. Aulchenko,et al.  Twenty bone mineral density loci identified by large-scale meta-analysis of genome-wide association studies , 2009, Nature Genetics.

[52]  H. Choi,et al.  The forkhead transcription factor Foxc2 stimulates osteoblast differentiation. , 2009, Biochemical and biophysical research communications.

[53]  J. Freeman,et al.  RNA isolation from embryonic zebrafish and cDNA synthesis for gene expression analysis. , 2009, Journal of visualized experiments : JoVE.

[54]  Z. Tümer,et al.  PRACTICAL GENETICS In association with Axenfeld – Rieger syndrome and spectrum of PITX 2 and FOXC 1 mutations , 2009 .

[55]  M. Katoh,et al.  Transcriptional regulation of WNT2B based on the balance of Hedgehog, Notch, BMP and WNT signals. , 2009, International journal of oncology.

[56]  Sridhar Hannenhalli,et al.  The evolution of Fox genes and their role in development and disease , 2009, Nature Reviews Genetics.

[57]  Uma M. Muthurajan,et al.  Nucleosome-binding affinity as a primary determinant of the nuclear mobility of the pioneer transcription factor FoxA. , 2009, Genes & development.

[58]  K. Kaestner,et al.  FoxF1 and FoxL1 Link Hedgehog Signaling and the Control of Epithelial Proliferation in the Developing Stomach and Intestine* , 2009, Journal of Biological Chemistry.

[59]  K. Markou,et al.  An overview of the etiology of otosclerosis , 2008, European Archives of Oto-Rhino-Laryngology.

[60]  P. Santisteban,et al.  The Forkhead Factor FoxE1 Binds to the Thyroperoxidase Promoter during Thyroid Cell Differentiation and Modifies Compacted Chromatin Structure , 2007, Molecular and Cellular Biology.

[61]  M. Katoh Networking of WNT, FGF, Notch, BMP, and Hedgehog Signaling Pathways during Carcinogenesis , 2007, Stem Cell Reviews.

[62]  Mb Walker,et al.  A two-color acid-free cartilage and bone stain for zebrafish larvae , 2007, Biotechnic & histochemistry : official publication of the Biological Stain Commission.

[63]  B. Thisse,et al.  High-resolution in situ hybridization to whole-mount zebrafish embryos , 2007, Nature Protocols.

[64]  W. Arnold,et al.  Expression of collagens in the otosclerotic bone. , 2007, Advances in oto-rhino-laryngology.

[65]  K. Arai,et al.  Transcriptional Repressor foxl1 Regulates Central Nervous System Development by Suppressing shh Expression in Zebra Fish , 2006, Molecular and Cellular Biology.

[66]  C. Kimmel,et al.  Early Hedgehog signaling from neural to oral epithelium organizes anterior craniofacial development , 2006, Development.

[67]  M. Akimenko,et al.  Sonic Hedgehog Signalling in the Developing and Regenerating Fins of Zebrafish , 2006 .

[68]  Thomas F Schilling,et al.  Hedgehog signaling is required for cranial neural crest morphogenesis and chondrogenesis at the midline in the zebrafish skull , 2005, Development.

[69]  D. Rice,et al.  Foxc1 integrates Fgf and Bmp signalling independently of twist or noggin during calvarial bone development , 2005, Developmental dynamics : an official publication of the American Association of Anatomists.

[70]  Xu Cao,et al.  BMP signaling in skeletal development. , 2005, Biochemical and biophysical research communications.

[71]  S. Bandinelli,et al.  Bone density and hemoglobin levels in older persons: results from the InCHIANTI study , 2005, Osteoporosis International.

[72]  S. Merchant,et al.  Association between osteoporosis and otosclerosis in women , 2004, The Journal of Laryngology & Otology.

[73]  T. Schilling,et al.  Development of cartilage and bone. , 2004, Methods in cell biology.

[74]  W. Arnold,et al.  Etiopathogenesis of Otosclerosis , 2002, ORL.

[75]  F. Altruda,et al.  Hemopexin: structure, function, and regulation. , 2002, DNA and cell biology.

[76]  Thomas D. Schmittgen,et al.  Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. , 2001, Methods.

[77]  V. Frenkel,et al.  Visualizing normal and defective bone development in zebrafish embryos using the fluorescent chromophore calcein. , 2001, Developmental biology.

[78]  J. Delanghe,et al.  Hemopexin: a review of biological aspects and the role in laboratory medicine. , 2001, Clinica chimica acta; international journal of clinical chemistry.

[79]  M. Noda,et al.  Bone Morphogenetic Protein Regulation of Forkhead/Winged Helix Transcription Factor Foxc2 (Mfh1) in a Murine Mesodermal Cell Line C1 and in Skeletal Precursor Cells , 2001, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[80]  B. Hogan,et al.  The murine winged helix transcription factors, Foxc1 and Foxc2, are both required for cardiovascular development and somitogenesis. , 2001, Genes & development.

[81]  A. McMahon,et al.  Indian hedgehog couples chondrogenesis to osteogenesis in endochondral bone development. , 2001, The Journal of clinical investigation.

[82]  M. Bronner‐Fraser,et al.  Inhibition of Sonic hedgehog signaling in vivo results in craniofacial neural crest cell death , 1999, Current Biology.

[83]  R. Lorenc,et al.  [Genetic factors in osteoporosis]. , 1998, Polski merkuriusz lekarski : organ Polskiego Towarzystwa Lekarskiego.

[84]  B. Hogan,et al.  The winged helix transcription factor MFH1 is required for proliferation and patterning of paraxial mesoderm in the mouse embryo. , 1997, Genes & development.

[85]  N. Ueno,et al.  Conservation of BMP signaling in zebrafish mesoderm patterning , 1997, Mechanisms of Development.

[86]  C. Kimmel,et al.  Stages of embryonic development of the zebrafish , 1995, Developmental dynamics : an official publication of the American Association of Anatomists.