TY - JOUR
T1 - Telomere shortening is associated with malformation in p53-deficient mice after irradiation during specific stages of development
AU - Bekaert, Sofie
AU - Derradji, Hanane
AU - De Meyer, Tim
AU - Michaux, Arlette
AU - Buset, Jasmine
AU - Neefs, Mieke
AU - Mergeay, Max
AU - Jacquet, Paul
AU - Van Oostveldt, Patrick
AU - Baatout, Sarah
N1 - Score = 10
PY - 2005/8
Y1 - 2005/8
N2 - The natural ends of linear chromosomes, the telomeres, recruit specific proteins in the formation of protective caps that preserve the integrity of the genome. Unprotected chromosomes induce DNA damage checkpoint cascades and ultimately lead to senescence both in mouse and man in a p53 dependent manner and initial telomere length setting therefore determines the proliferative capacity of each cell. Yet, only little information is available on telomere biology during embryonic development. We have previously shown that the p53 gene plays a crucial role in the development of malformations (exencephaly, gastroschisis, polydactyly, cleft palate and dwarfism) in control and irradiated mouse embryos. Here, we investigated telomere biology and the outcome of radiation exposure in wild type (p53+/+) and p53-mutant (p53+/- and -/-) C57BL mouse foetuses irradiated at three different developmental stages. We show that telomeres are significantly shorter in malformed foetuses as compared to normal counterparts. In addition, our results indicate that the observed telomere attrition is primarily associated with p53-deficiency but is also modulated by irradiation, more specifically during the gastrulation and organogenesis stages. In conclusion, we formulate a hypothesis in which telomere shortening is linked to the absence of p53 in mouse foetuses and that when, in the presence of shorter telomeres, these foetuses are irradiated, the chance for the occurrence of developmental defects increases substantially.
AB - The natural ends of linear chromosomes, the telomeres, recruit specific proteins in the formation of protective caps that preserve the integrity of the genome. Unprotected chromosomes induce DNA damage checkpoint cascades and ultimately lead to senescence both in mouse and man in a p53 dependent manner and initial telomere length setting therefore determines the proliferative capacity of each cell. Yet, only little information is available on telomere biology during embryonic development. We have previously shown that the p53 gene plays a crucial role in the development of malformations (exencephaly, gastroschisis, polydactyly, cleft palate and dwarfism) in control and irradiated mouse embryos. Here, we investigated telomere biology and the outcome of radiation exposure in wild type (p53+/+) and p53-mutant (p53+/- and -/-) C57BL mouse foetuses irradiated at three different developmental stages. We show that telomeres are significantly shorter in malformed foetuses as compared to normal counterparts. In addition, our results indicate that the observed telomere attrition is primarily associated with p53-deficiency but is also modulated by irradiation, more specifically during the gastrulation and organogenesis stages. In conclusion, we formulate a hypothesis in which telomere shortening is linked to the absence of p53 in mouse foetuses and that when, in the presence of shorter telomeres, these foetuses are irradiated, the chance for the occurrence of developmental defects increases substantially.
KW - Early development
KW - Gastrula
KW - Irradiation
KW - Malformations
KW - Organogenesis
KW - p53
KW - Rodents
KW - Telomere length
KW - Teratogenesis
UR - http://ecm.sckcen.be/OTCS/llisapi.dll/open/ezp_27297
U2 - 10.1016/j.dnarep.2005.05.010
DO - 10.1016/j.dnarep.2005.05.010
M3 - Article
C2 - 15990362
SN - 1568-7864
VL - 4
SP - 1028
EP - 1037
JO - DNA Repair
JF - DNA Repair
IS - 9
ER -