ABE1377 Sigma-AldrichAnti-RAD18 Antibody

Breast cancer gene 1 (BRCA1) deficient cells not only are hypersensitive to double-strand breaks but also are hypersensitive to UV irradiation and other agents that cause replication blockade; however, the molecular mechanisms behind these latter sensitivities are largely unknown. Here, we report that BRCA1 promotes cell survival by directly regulating the DNA damage tolerance pathway in response to agents that create cross-links in DNA. We show that BRCA1 not only promotes efficient mono- and polyubiquitination of proliferating cell nuclear antigen (PCNA) by regulating the recruitment of replication protein A, Rad18, and helicase-like transcription factor to chromatin but also directly recruits translesion polymerases, such as Polymerase eta and Rev1, to the lesions through protein-protein interactions. Our data suggest that BRCA1 plays a critical role in promoting translesion DNA synthesis as well as DNA template switching.

Maintaining the integrity of spermatogenic stem cells is essential to transfer genetic information to a descendant. However, knowledge of maintenance of genetic stability in stem cells is still limited. RAD18 is critical for postreplication repair through mono- and multi-ubiquitination of proliferating cell nuclear antigen (PCNA) to maintain genomic stability. Mammalian RAD18 is highly expressed in the spermatocytes and the nuclei of a few spermatogonia in adult mice. To elucidate the physiological function of RAD18, we analyzed a phenotype of Rad18-/- mice. The mice were born and appeared to grow normally. Although the mice were fertile, fertility and testis weight decreased with age. Histological examination revealed normal spermatogenesis in almost all seminiferous tubules in Rad18-/- testes at 2 months old, and abnormal sperm could not be detected in the epididymis. However, 25% of the tubules lost almost all germ cells at 12 months. The seminiferous tubules frequently retained only late differentiated phase germ cells, suggesting that the exhaustion of spermatogonial stem cells leads to the loss of all germ cells in the seminiferous tubules. Wild-type germ cells were successfully transplanted into and colonized in the seminiferous tubules of aged Rad18-/- mice, indicating that Sertoli cells have a normal supportive function even in aged testes. We conclude that RAD18 is intrinsically required for the long-term maintenance of spermatogenesis.

Rad18 is involved in postreplication repair mainly through monoubiquitination of proliferating cell nuclear antigen (PCNA). Here we show that Rad18 protein was detected in human cells as two major bands at 75 and 85 kDa by Western blot. The bands were identified as nonubiquitinated and monoubiquitinated forms of Rad18, respectively, by mass spectrometry. Multiple ubiquitinated bands of Rad18 were detected in vitro in the presence of E1, E2 (Rad6), and methylated ubiquitin, indicating that Rad18 was monoubiquitinated at multiple sites through autoubiquitination. Rad18 self-associates, and this interaction was abolished by replacing one of the conserved cysteine residues with phenylalanine in the zinc finger domain (C207F). In the C207F mutant Rad18, monoubiquitination of Rad18 was not observed in vivo, suggesting that self-association was critical for monoubiquitination. Monoubiquitinated Rad18 was detected mainly in the cytoplasm, whereas nonubiquitinated Rad18 was detected predominantly in the nuclei. Furthermore, Rad18 was shown to be polyubiquitinated in cells treated with proteasome inhibitors. Purified Rad18 was also polyubiquitinated in an in vitro system containing E1, E2 (Rad6), and ubiquitin, and it was degraded by the addition of proteasomes. These results suggest that the amount of Rad18 in the nucleus is regulated differentially by mono- and polyubiquitination.

In lower eukaryotes, Rad18 plays a crucial role in postreplication repair. Previously, we isolated a human homologue of RAD18 (hRAD18) and showed that human cells overexpressing hRad18 protein with a mutation in the RING finger motif are defective in postreplication repair. Here, we report the construction of RAD18-knockout mouse embryonic stem cells by gene targeting. These cells had almost the same growth rate as wild-type cells and manifested phenotypes similar to those of human cells expressing mutant Rad18 protein: hypersensitivity to multiple DNA damaging agents and a defect in postreplication repair. Mutation was not induced in the knockout cells with any higher frequencies than in wild-type cells, as shown by ouabain resistance. In the knockout cells, spontaneous sister chromatid exchange (SCE) occurred with twice the frequency observed in normal cells. After mild DNA damage, SCE was threefold higher in the knockout cells, while no increase was observed in normal cells. Stable transformation efficiencies were approximately 20-fold higher in knockout cells, and gene targeting occurred with approximately 40-fold-higher frequency than in wild-type cells at the Oct3/4 locus. These results indicate that dysfunction of Rad18 greatly increases both the frequency of homologous as well as illegitimate recombination, and that RAD18 contributes to maintenance of genomic stability through postreplication repair.