Abstract
Transcription factors PAX9 and MSX1 play crucial roles in the development of permanent teeth at the bud stage, and their loss-of-function variants have been associated with congenital tooth agenesis. We sequenced the coding regions of the PAX9 and MSX1 genes from nine patients with non-syndromic tooth agenesis, and identified a missense mutation, P20L, of PAX9 in a single familial case involving three patients in two generations. Identical mutation was previously reported by other authors, but has not been characterized in detail. The mutation was located in a highly conserved N-terminal subdomain of the paired domain and co-segregated as a heterozygote with tooth agenesis. The patients showed defects primarily in the first and second molars, which is typical for cases attributable to PAX9 mutation. Luciferase reporter assay using the 2.3-kb promoter region of BMP4 and electrophoretic mobility shift assay using the CD19-2(A-ins) sequence revealed that P20L substitution eliminated most of the transactivation activity and specific DNA binding activity of PAX9 under the experimental conditions we employed, while some residual activity of the mutant was evident in the former assay. The hypomorphic nature of the variant may explain the relatively mild phenotype in this case, as compared with other PAX9 pathogenic variants such as R26W.
Highlights
Tooth agenesis is a very common congenital abnormality in humans, with a reported prevalence in the permanent dentition ranging from 1.6% to 9.6% depending on severity and the types of missing teeth [1,2,3]
Congenital tooth agenesis may be associated with other phenotypic features in some cases, whereas it may be isolated in others
By sequencing of the PAX9 coding regions in all nine patients, we identified a transition mutation, NM_006194.3:c.59C>T, that results in a proline to leucine amino acid substitution, P20L
Summary
Tooth agenesis is a very common congenital abnormality in humans, with a reported prevalence in the permanent dentition ranging from 1.6% to 9.6% depending on severity and the types of missing teeth [1,2,3]. Since the development of teeth, as well as that of other organs in the body, is controlled by coordinated action of numerous gene products, defects in any single component may potentially result in tooth absence or malformation. These mechanistic developmental networks or their components are often shared by multiple organs.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
