Dll3 and Notch1 genetic interactions model axial segmental and craniofacial malformations of human birth defects

Kathleen M. Loomes; Stacey A. Stevens; Megan L. O'Brien; Dorian M. Gonzalez; Matthew J. Ryan; Michelle Segalov; Nicholas J. Dormans; Mizuho S. Mimoto; Joshua D. Gibson; William Sewell; Alyssa A. Schaffer; Hyun Duck Nah; Eric F. Rappaport; Stephen Pratt; Sally L. Dunwoodie; Kenro Kusumi

doi:10.1002/dvdy.21296

Dll3 and Notch1 genetic interactions model axial segmental and craniofacial malformations of human birth defects

Kathleen M. Loomes, Stacey A. Stevens, Megan L. O'Brien, Dorian M. Gonzalez, Matthew J. Ryan, Michelle Segalov, Nicholas J. Dormans, Mizuho S. Mimoto, Joshua D. Gibson, William Sewell, Alyssa A. Schaffer, Hyun Duck Nah, Eric F. Rappaport, Stephen Pratt, Sally L. Dunwoodie, Kenro Kusumi

Life Sciences, School of (SOLS)

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

37 Scopus citations

Abstract

Mutations in the Notch1 receptor and delta-like 3 (Dll3) ligand cause global disruptions in axial segmental patterning. Genetic interactions between members of the notch pathway have previously been shown to cause patterning defects not observed in single gene disruptions. We examined Dll3-Notch1 compound mouse mutants to screen for potential gene interactions. While mice heterozygous at either locus appeared normal, 30% of Dll3-Notch1 double heterozygous animals exhibited localized, segmental anomalies similar to human congenital vertebral defects. Unexpectedly, double heterozygous mice also displayed statistically significant reduction of mandibular height and elongation of maxillary hard palate. Examination of somitestage embryos and perinatal anatomy and histology did not reveal any organ defects, so we used microarray-based analysis of Dll3 and Notch1 mutant embryos to identify gene targets that may be involved in notch-regulated segmental or craniofacial development. Thus, Dll3-Notch1 double heterozygous mice model human congenital scoliosis and craniofacial disorders.

Original language	English (US)
Pages (from-to)	2943-2951
Number of pages	9
Journal	Developmental Dynamics
Volume	236
Issue number	10
DOIs	https://doi.org/10.1002/dvdy.21296
State	Published - Oct 2007

Keywords

Craniofacial
Dll3
Hard palate
Mandible
Notch pathway
Notch1
Segmentation
Skeletal
Somite
Vertebral

ASJC Scopus subject areas

Developmental Biology

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Loomes, K. M., Stevens, S. A., O'Brien, M. L., Gonzalez, D. M., Ryan, M. J., Segalov, M., Dormans, N. J., Mimoto, M. S., Gibson, J. D., Sewell, W., Schaffer, A. A., Nah, H. D., Rappaport, E. F., Pratt, S., Dunwoodie, S. L., & Kusumi, K. (2007). Dll3 and Notch1 genetic interactions model axial segmental and craniofacial malformations of human birth defects. Developmental Dynamics, 236(10), 2943-2951. https://doi.org/10.1002/dvdy.21296

Loomes, KM, Stevens, SA, O'Brien, ML, Gonzalez, DM, Ryan, MJ, Segalov, M, Dormans, NJ, Mimoto, MS, Gibson, JD, Sewell, W, Schaffer, AA, Nah, HD, Rappaport, EF, Pratt, S, Dunwoodie, SL & Kusumi, K 2007, 'Dll3 and Notch1 genetic interactions model axial segmental and craniofacial malformations of human birth defects', Developmental Dynamics, vol. 236, no. 10, pp. 2943-2951. https://doi.org/10.1002/dvdy.21296

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title = "Dll3 and Notch1 genetic interactions model axial segmental and craniofacial malformations of human birth defects",

abstract = "Mutations in the Notch1 receptor and delta-like 3 (Dll3) ligand cause global disruptions in axial segmental patterning. Genetic interactions between members of the notch pathway have previously been shown to cause patterning defects not observed in single gene disruptions. We examined Dll3-Notch1 compound mouse mutants to screen for potential gene interactions. While mice heterozygous at either locus appeared normal, 30% of Dll3-Notch1 double heterozygous animals exhibited localized, segmental anomalies similar to human congenital vertebral defects. Unexpectedly, double heterozygous mice also displayed statistically significant reduction of mandibular height and elongation of maxillary hard palate. Examination of somitestage embryos and perinatal anatomy and histology did not reveal any organ defects, so we used microarray-based analysis of Dll3 and Notch1 mutant embryos to identify gene targets that may be involved in notch-regulated segmental or craniofacial development. Thus, Dll3-Notch1 double heterozygous mice model human congenital scoliosis and craniofacial disorders.",

keywords = "Craniofacial, Dll3, Hard palate, Mandible, Notch pathway, Notch1, Segmentation, Skeletal, Somite, Vertebral",

author = "Loomes, {Kathleen M.} and Stevens, {Stacey A.} and O'Brien, {Megan L.} and Gonzalez, {Dorian M.} and Ryan, {Matthew J.} and Michelle Segalov and Dormans, {Nicholas J.} and Mimoto, {Mizuho S.} and Gibson, {Joshua D.} and William Sewell and Schaffer, {Alyssa A.} and Nah, {Hyun Duck} and Rappaport, {Eric F.} and Stephen Pratt and Dunwoodie, {Sally L.} and Kenro Kusumi",

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AU - Loomes, Kathleen M.

AU - Stevens, Stacey A.

AU - O'Brien, Megan L.

AU - Gonzalez, Dorian M.

AU - Ryan, Matthew J.

AU - Segalov, Michelle

AU - Dormans, Nicholas J.

AU - Mimoto, Mizuho S.

AU - Gibson, Joshua D.

AU - Sewell, William

AU - Schaffer, Alyssa A.

AU - Nah, Hyun Duck

AU - Rappaport, Eric F.

AU - Pratt, Stephen

AU - Dunwoodie, Sally L.

AU - Kusumi, Kenro

PY - 2007/10

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N2 - Mutations in the Notch1 receptor and delta-like 3 (Dll3) ligand cause global disruptions in axial segmental patterning. Genetic interactions between members of the notch pathway have previously been shown to cause patterning defects not observed in single gene disruptions. We examined Dll3-Notch1 compound mouse mutants to screen for potential gene interactions. While mice heterozygous at either locus appeared normal, 30% of Dll3-Notch1 double heterozygous animals exhibited localized, segmental anomalies similar to human congenital vertebral defects. Unexpectedly, double heterozygous mice also displayed statistically significant reduction of mandibular height and elongation of maxillary hard palate. Examination of somitestage embryos and perinatal anatomy and histology did not reveal any organ defects, so we used microarray-based analysis of Dll3 and Notch1 mutant embryos to identify gene targets that may be involved in notch-regulated segmental or craniofacial development. Thus, Dll3-Notch1 double heterozygous mice model human congenital scoliosis and craniofacial disorders.

AB - Mutations in the Notch1 receptor and delta-like 3 (Dll3) ligand cause global disruptions in axial segmental patterning. Genetic interactions between members of the notch pathway have previously been shown to cause patterning defects not observed in single gene disruptions. We examined Dll3-Notch1 compound mouse mutants to screen for potential gene interactions. While mice heterozygous at either locus appeared normal, 30% of Dll3-Notch1 double heterozygous animals exhibited localized, segmental anomalies similar to human congenital vertebral defects. Unexpectedly, double heterozygous mice also displayed statistically significant reduction of mandibular height and elongation of maxillary hard palate. Examination of somitestage embryos and perinatal anatomy and histology did not reveal any organ defects, so we used microarray-based analysis of Dll3 and Notch1 mutant embryos to identify gene targets that may be involved in notch-regulated segmental or craniofacial development. Thus, Dll3-Notch1 double heterozygous mice model human congenital scoliosis and craniofacial disorders.

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Dll3 and Notch1 genetic interactions model axial segmental and craniofacial malformations of human birth defects

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