Evidence for alternate splicing within the mRNA transcript encoding the DNA damage response kinase ATR.

Proper cellular response to genotoxic insult often requires the activity of one or more members of a family of high-molecular weight protein kinases referred to as phosphatidylinositol-3 kinase (PIK)-like proteins. While catalytic activity is an indispensable part of PIK-like protein function, little is currently known about factors that control their activity and/or functions. This deficiency stems, in large part, from our lack of knowledge concerning functionally significant subdomains within the large non-catalytic domain of these proteins. We have determined that the transcript encoding the PIK-like protein ATR undergoes alternate splicing within the region of the mRNA encoding its non-catalytic domain. This conclusion is based on the sequencing of a human expressed sequence tag clone encoding a portion of the ATR cDNA, and is supported by the results of reverse transcriptase-polymerase chain reaction (RT-PCR) assays conducted on total and polyA+ RNA, as well as sequencing of cloned RT-PCR products. Cloning and sequencing of a segment of human genomic DNA indicated that this event arises from splicing of a single 192 bp exon within the ATR gene. Analysis of several human tissues indicated that alternate ATR transcripts are differentially expressed, suggesting that this region of the ATR protein may be of functional importance.

Ionizing radiation exposure results in up-regulation of Ku70 via a p53/ataxia-telangiectasia-mutated protein-dependent mechanism.

Genome damaging events, such as gamma-irradiation exposure, result in the induction of pathways that activate DNA repair mechanisms, halt cell cycle progression, and/or trigger apoptosis. We have investigated the effects of gamma-irradiation on cellular levels of the Ku autoantigens. Ku70 and Ku80 have been shown to form a heterodimeric complex that can bind tightly to free DNA ends and activate the protein kinase DNA-PKcs. We have found that irradiation results in an up-regulation of cellular levels of Ku70, but not Ku80, and that this enhanced level of Ku70 accumulates within the nucleus. Further, we uncovered that the postirradiation up-regulation of Ku70 utilizes a mechanism that is dependent on both p53 and damage response protein kinase ATM (ataxia-telangiectasia-mutated); however, the activation of DNA-PK does not require Ku70 up-regulation. These findings suggest that Ku70 up-regulation provides the cell with a means of assuring either proper DNA repair or an appropriate response to DNA damage independent of DNA-PKcs activation.