Homologous recombination (HR) is a source of genomic instability and the loss of heterozygosity in mitotic cells. Since these events pose a severe health risk, it is important to understand the molecular events that cause spontaneous HR. In eukaryotes, high levels of HR are a normal feature of meiosis and result from the induction of a large number of DNA double-strand breaks (DSBs). By analogy, it is generally believed that the rare spontaneous mitotic HR events are due to repair of DNA DSBs that accidentally occur during mitotic growth. Here we provide the first direct evidence that most spontaneous mitotic HR in Saccharomyces cerevisiae is initiated by DNA lesions other than DSBs. Specifically, we describe a class of rad52 mutants that are fully proficient in inter- and intra-chromosomal mitotic HR, yet at the same time fail to repair DNA DSBs. The conclusions are drawn from genetic analyses, evaluation of the consequences of DSB repair failure at the DNA level, and examination of the cellular re-localization of Rad51 and mutant Rad52 proteins after introduction of specific DSBs. In further support of our conclusions, we show that, as in wild-type strains, UV-irradiation induces HR in these rad52 mutants, supporting the view that DNA nicks and single-stranded gaps, rather than DSBs, are major sources of spontaneous HR in mitotic yeast cells.
YFP yellow fluorescent protein CFP cyan fluorescent protein RFP red fluorescent protein DIC differential interference contrast DSB DNA double-strand break FACS fluorescence-activated cell sorting HR homologous recombination This research was supported by the Danish Natural Science Research Council (M.L.), the Danish Technical Research Council (U.H.M.), the Alfred Benzon Foundation (U.H.M.), and NIH grants GM50237 and GM67055 and the Tonnessen Foundation
Head and neck squamous cell carcinoma (HNSCC) is a debilitating and deadly disease that is only cured 50% of the time. A better understanding of the molecular mechanisms involved in HNSCC progression may lead to earlier detection and improved cure rates. CD44 is a ubiquitous transmembrane glycoprotein comprising a family of alternatively spliced isoforms involved in cell migration and cell proliferation. CD44 isoforms containing the variant 3 (v3) exon include a growth factor binding site and may be involved in tumor progression. To characterize CD44v3-containing isoforms expression in HNSCC we purified RNA from four HNSCC cell lines and performed RT-PCR using junction primer strategies followed by gel elecrophoresis. Cloning and sequencing of HNSCC cell line PCR products revealed two isoforms. One of these, CD44v3-10, has been previously described. The other isoform, CD44v3, has not been characterized in HNSCC tissues. To further study this isoform, we purified RNA from 19 HNSCC tissues, 7 normal margin tissues and 5 true normal tissues. Following reverse-transcription, we performed quantitative PCR using junction primers specific for CD44v3. Results show that HNSCC tumor tissues expressed mean CD44v3 levels that were elevated 4.5 times more than true normal tissues (p < 0.01). Mean CD44v3 values for HNSCC tumors were 0.43 +/- 0.44 while mean levels for true normal tissues were 0.10 +/- 0.11. Levels in tumor tissue did not vary significantly with tumor characteristics such as site, stage, prior treatment, or nodal status. In addition, to characterize the role of this molecule plays in tumor progression, we overexpressed CD44v3 in a HNSCC cell line. Our results indicate that although higher levels of CD44v3 did not affect the rate of proliferation, a significant increase in migration was observed. CD44v3 may provide a target for future diagnostic and therapeutic interventions for HNSCC.
The sequence of the Saccharomyces cerevisiae RAD52 gene contains five potential translation start sites and protein-blot analysis typically detects multiple Rad52 species with different electrophoretic mobilities. Here we define the gene products encoded by RAD52. We show that the multiple Rad52 protein species are due to promiscuous choice of start codons as well as post-translational modification. Specifically, Rad52 is phosphorylated both in a cell cycle-independent and in a cell cycle-dependent manner. Furthermore, phosphorylation is dependent on the presence of the Rad52 C terminus, but not dependent on its interaction with Rad51. We also show that the Rad52 protein can be translated from the last three start sites and expression from any one of them is sufficient for spontaneous recombination and the repair of gamma-ray-induced double-strand breaks.
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