However, when the copy number of the mutant allele increased from one (Fgfr3(TD/+) to two (Fgfr3(TD/TD), the retardation of bone growth became more severe and showed phenotypes resembling those of achondroplasia patients, characterized by a dramatically reduced proliferation of growth plate cartilage, macrocephaly and shortening of the long bones, which was most pronounced in the femur.
Our aim was to characterize the cardiac phenotype of male knock-out mice that are deficient in alpha-galactosidase A activity, as a model for Fabry disease and test the efficacy of Enzyme Replacement Therapy with agalsidase-beta.
Thus, our study sheds light on the poorly understood role of ATM in the pathogenesis of glucose intolerance in A-T patients and provides insight into the role of ATM in glucose metabolism.
ATM, the gene mutated in the human immunodeficiency disorder ataxia-telangiectasia (A-T), plays a central role in recognizing ionizing radiation damage in DNA and in controlling several cell cycle checkpoints.
Motor incoordination, immune deficiencies, and an increased risk of cancer are the characteristic features of the hereditary disease ataxia-telangiectasia (A-T), which is caused by mutations in the ATM gene.
ATM+/- fibroblasts and thymocytes showed intermediately defective responses to irradiation but no growth defect, suggesting that the increased cancer risk of AT heterozygotes could be attributable to poor checkpoint function.
We previously generated a mouse model with a mutation in the murine Atm gene that recapitulates many aspects of the childhood neurodegenerative disease ataxia-telangiectasia.
Initial evaluation of the ATM knockout animals indicates that inactivation of the mouse ATM gene recreates much of the phenotype of ataxia-telangiectasia.