Tbx1 is required autonomously for cell survival and fate in the pharyngeal core mesoderm to form the muscles of mastication.

[22q11.2 deletion syndrome]

Velo-cardio-facial /DiGeorge syndrome , also known as 22 q 11 .2 deletion syndrome , is a congenital anomaly disorder characterized by craniofacial anomalies including velo-pharyngeal insufficiency , facial muscle hypotonia and feeding difficulties , in part due to hypoplasia of the branchiomeric muscles . Inactivation of both alleles of mouse Tbx 1 , encoding a T -box transcription factor , deleted on chromosome 22 q 11 .2 , results in reduction or loss of branchiomeric muscles . To identify downstream pathways , we performed gene profiling of microdissected pharyngeal arch one (PA 1 ) from Tbx 1 (+/+) and Tbx 1 (-/-) embryos at stages E 9 .5 (somites 20 -25 ) and E 10 .5 (somites 30 -35 ). Basic helix -loop-helix (bHLH ) transcription factors were reduced , while secondary heart field genes were increased in expression early and were replaced by an increase in expression of cellular stress response genes later , suggesting a change in gene expression patterns or cell populations . Lineage tracing studies using Mesp 1 (Cre ) and T -Cre drivers showed that core mesoderm cells within PA 1 were present at E 9 .5 but were greatly reduced by E 10 .5 in Tbx 1 (-/-) embryos . Using Tbx 1 (Cre ) knock-in mice , we found that cells are lost due to apoptosis , consistent with increase in expression of cellular stress response genes at E 10 .5 . To determine whether Tbx 1 is required autonomously in the core mesoderm , we used Mesp 1 (Cre ) and T -Cre mesodermal drivers in combination with inactivate Tbx 1 and found reduction or loss of branchiomeric muscles from PA 1 . These mechanistic studies inform us that Tbx 1 is required upstream of key myogenic genes needed for core mesoderm cell survival and fate , between E 9 .5 and E 10 .5 , resulting in formation of the branchiomeric muscles .