A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome

Mark J. Rieder; Glenn E. Green; Sarah S. Park; Brendan D. Stamper; Christopher T. Gordon; Jason M. Johnson; Christopher M. Cunniff; Joshua D. Smith; Sarah B. Emery; Stanislas Lyonnet; Jeanne Amiel; Muriel Holder; Andrew A. Heggie; Michael J. Bamshad; Deborah A. Nickerson; Timothy C. Cox; Anne V. Hing; Jeremy A. Horst; Michael L. Cunningham

doi:10.1016/j.ajhg.2012.04.002

A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome

Mark J. Rieder, Glenn E. Green, Sarah S. Park, Brendan D. Stamper, Christopher T. Gordon, Jason M. Johnson, Christopher M. Cunniff, Joshua D. Smith, Sarah B. Emery, Stanislas Lyonnet, Jeanne Amiel, Muriel Holder, Andrew A. Heggie, Michael J. Bamshad, Deborah A. Nickerson, Timothy C. Cox, Anne V. Hing, Jeremy A. Horst, Michael L. Cunningham

Research output: Contribution to journal › Article › peer-review

69 Scopus citations

Abstract

Auriculocondylar syndrome (ACS) is a rare, autosomal-dominant craniofacial malformation syndrome characterized by variable micrognathia, temporomandibular joint ankylosis, cleft palate, and a characteristic "question-mark" ear malformation. Careful phenotypic characterization of severely affected probands in our cohort suggested the presence of a mandibular patterning defect resulting in a maxillary phenotype (i.e., homeotic transformation). We used exome sequencing of five probands and identified two novel (exclusive to the patient and/or family studied) missense mutations in PLCB4 and a shared mutation in GNAI3 in two unrelated probands. In confirmatory studies, three additional novel PLCB4 mutations were found in multigenerational ACS pedigrees. All mutations were confirmed by Sanger sequencing, were not present in more than 10,000 control chromosomes, and resulted in amino-acid substitutions located in highly conserved protein domains. Additionally, protein-structure modeling demonstrated that all ACS substitutions disrupt the catalytic sites of PLCB4 and GNAI3. We suggest that PLCB4 and GNAI3 are core signaling molecules of the endothelin-1-distal-less homeobox 5 and 6 (EDN1-DLX5/DLX6) pathway. Functional studies demonstrated a significant reduction in downstream DLX5 and DLX6 expression in ACS cases in assays using cultured osteoblasts from probands and controls. These results support the role of the previously implicated EDN1-DLX5/6 pathway in regulating mandibular specification in other species, which, when disrupted, results in a maxillary phenotype. This work defines the molecular basis of ACS as a homeotic transformation (mandible to maxilla) in humans.

Original language	English (US)
Pages (from-to)	907-914
Number of pages	8
Journal	American journal of human genetics
Volume	90
Issue number	5
DOIs	https://doi.org/10.1016/j.ajhg.2012.04.002
State	Published - May 4 2012
Externally published	Yes

ASJC Scopus subject areas

Genetics
Genetics(clinical)

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10.1016/j.ajhg.2012.04.002

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Rieder, M. J., Green, G. E., Park, S. S., Stamper, B. D., Gordon, C. T., Johnson, J. M., Cunniff, C. M., Smith, J. D., Emery, S. B., Lyonnet, S., Amiel, J., Holder, M., Heggie, A. A., Bamshad, M. J., Nickerson, D. A., Cox, T. C., Hing, A. V., Horst, J. A., & Cunningham, M. L. (2012). A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome. American journal of human genetics, 90(5), 907-914. https://doi.org/10.1016/j.ajhg.2012.04.002

Rieder, MJ, Green, GE, Park, SS, Stamper, BD, Gordon, CT, Johnson, JM, Cunniff, CM, Smith, JD, Emery, SB, Lyonnet, S, Amiel, J, Holder, M, Heggie, AA, Bamshad, MJ, Nickerson, DA, Cox, TC, Hing, AV, Horst, JA & Cunningham, ML 2012, 'A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome', American journal of human genetics, vol. 90, no. 5, pp. 907-914. https://doi.org/10.1016/j.ajhg.2012.04.002

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title = "A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome",

abstract = "Auriculocondylar syndrome (ACS) is a rare, autosomal-dominant craniofacial malformation syndrome characterized by variable micrognathia, temporomandibular joint ankylosis, cleft palate, and a characteristic {"}question-mark{"} ear malformation. Careful phenotypic characterization of severely affected probands in our cohort suggested the presence of a mandibular patterning defect resulting in a maxillary phenotype (i.e., homeotic transformation). We used exome sequencing of five probands and identified two novel (exclusive to the patient and/or family studied) missense mutations in PLCB4 and a shared mutation in GNAI3 in two unrelated probands. In confirmatory studies, three additional novel PLCB4 mutations were found in multigenerational ACS pedigrees. All mutations were confirmed by Sanger sequencing, were not present in more than 10,000 control chromosomes, and resulted in amino-acid substitutions located in highly conserved protein domains. Additionally, protein-structure modeling demonstrated that all ACS substitutions disrupt the catalytic sites of PLCB4 and GNAI3. We suggest that PLCB4 and GNAI3 are core signaling molecules of the endothelin-1-distal-less homeobox 5 and 6 (EDN1-DLX5/DLX6) pathway. Functional studies demonstrated a significant reduction in downstream DLX5 and DLX6 expression in ACS cases in assays using cultured osteoblasts from probands and controls. These results support the role of the previously implicated EDN1-DLX5/6 pathway in regulating mandibular specification in other species, which, when disrupted, results in a maxillary phenotype. This work defines the molecular basis of ACS as a homeotic transformation (mandible to maxilla) in humans.",

author = "Rieder, {Mark J.} and Green, {Glenn E.} and Park, {Sarah S.} and Stamper, {Brendan D.} and Gordon, {Christopher T.} and Johnson, {Jason M.} and Cunniff, {Christopher M.} and Smith, {Joshua D.} and Emery, {Sarah B.} and Stanislas Lyonnet and Jeanne Amiel and Muriel Holder and Heggie, {Andrew A.} and Bamshad, {Michael J.} and Nickerson, {Deborah A.} and Cox, {Timothy C.} and Hing, {Anne V.} and Horst, {Jeremy A.} and Cunningham, {Michael L.}",

note = "Funding Information: This study was supported by grants from the NIH-NHGRI Next Generation Mendelian Genetics (HG005608, M.J.R., D.A.N., M.J.B.), the Jean Renny Endowment for Craniofacial Medicine, the Laurel Foundation Center for Craniofacial Research (M.L.C.), NIH-NIDCD (P30-DC05188, G.E.G.), and the E-Rare CRANIRARE project (S.L.). ",

year = "2012",

month = may,

day = "4",

doi = "10.1016/j.ajhg.2012.04.002",

language = "English (US)",

volume = "90",

pages = "907--914",

journal = "American journal of human genetics",

issn = "0002-9297",

publisher = "Cell Press",

number = "5",

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TY - JOUR

T1 - A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome

AU - Rieder, Mark J.

AU - Green, Glenn E.

AU - Park, Sarah S.

AU - Stamper, Brendan D.

AU - Gordon, Christopher T.

AU - Johnson, Jason M.

AU - Cunniff, Christopher M.

AU - Smith, Joshua D.

AU - Emery, Sarah B.

AU - Lyonnet, Stanislas

AU - Amiel, Jeanne

AU - Holder, Muriel

AU - Heggie, Andrew A.

AU - Bamshad, Michael J.

AU - Nickerson, Deborah A.

AU - Cox, Timothy C.

AU - Hing, Anne V.

AU - Horst, Jeremy A.

AU - Cunningham, Michael L.

N1 - Funding Information: This study was supported by grants from the NIH-NHGRI Next Generation Mendelian Genetics (HG005608, M.J.R., D.A.N., M.J.B.), the Jean Renny Endowment for Craniofacial Medicine, the Laurel Foundation Center for Craniofacial Research (M.L.C.), NIH-NIDCD (P30-DC05188, G.E.G.), and the E-Rare CRANIRARE project (S.L.).

PY - 2012/5/4

Y1 - 2012/5/4

N2 - Auriculocondylar syndrome (ACS) is a rare, autosomal-dominant craniofacial malformation syndrome characterized by variable micrognathia, temporomandibular joint ankylosis, cleft palate, and a characteristic "question-mark" ear malformation. Careful phenotypic characterization of severely affected probands in our cohort suggested the presence of a mandibular patterning defect resulting in a maxillary phenotype (i.e., homeotic transformation). We used exome sequencing of five probands and identified two novel (exclusive to the patient and/or family studied) missense mutations in PLCB4 and a shared mutation in GNAI3 in two unrelated probands. In confirmatory studies, three additional novel PLCB4 mutations were found in multigenerational ACS pedigrees. All mutations were confirmed by Sanger sequencing, were not present in more than 10,000 control chromosomes, and resulted in amino-acid substitutions located in highly conserved protein domains. Additionally, protein-structure modeling demonstrated that all ACS substitutions disrupt the catalytic sites of PLCB4 and GNAI3. We suggest that PLCB4 and GNAI3 are core signaling molecules of the endothelin-1-distal-less homeobox 5 and 6 (EDN1-DLX5/DLX6) pathway. Functional studies demonstrated a significant reduction in downstream DLX5 and DLX6 expression in ACS cases in assays using cultured osteoblasts from probands and controls. These results support the role of the previously implicated EDN1-DLX5/6 pathway in regulating mandibular specification in other species, which, when disrupted, results in a maxillary phenotype. This work defines the molecular basis of ACS as a homeotic transformation (mandible to maxilla) in humans.

AB - Auriculocondylar syndrome (ACS) is a rare, autosomal-dominant craniofacial malformation syndrome characterized by variable micrognathia, temporomandibular joint ankylosis, cleft palate, and a characteristic "question-mark" ear malformation. Careful phenotypic characterization of severely affected probands in our cohort suggested the presence of a mandibular patterning defect resulting in a maxillary phenotype (i.e., homeotic transformation). We used exome sequencing of five probands and identified two novel (exclusive to the patient and/or family studied) missense mutations in PLCB4 and a shared mutation in GNAI3 in two unrelated probands. In confirmatory studies, three additional novel PLCB4 mutations were found in multigenerational ACS pedigrees. All mutations were confirmed by Sanger sequencing, were not present in more than 10,000 control chromosomes, and resulted in amino-acid substitutions located in highly conserved protein domains. Additionally, protein-structure modeling demonstrated that all ACS substitutions disrupt the catalytic sites of PLCB4 and GNAI3. We suggest that PLCB4 and GNAI3 are core signaling molecules of the endothelin-1-distal-less homeobox 5 and 6 (EDN1-DLX5/DLX6) pathway. Functional studies demonstrated a significant reduction in downstream DLX5 and DLX6 expression in ACS cases in assays using cultured osteoblasts from probands and controls. These results support the role of the previously implicated EDN1-DLX5/6 pathway in regulating mandibular specification in other species, which, when disrupted, results in a maxillary phenotype. This work defines the molecular basis of ACS as a homeotic transformation (mandible to maxilla) in humans.

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AN - SCOPUS:84860748491

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ER -

A human homeotic transformation resulting from mutations in PLCB4 and GNAI3 causes auriculocondylar syndrome

Abstract

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