Albert Pastink

Genetic Steps of Mammalian Homologous Repair with Distinct Mutagenic Consequences

ABSTRACT Repair of chromosomal breaks is essential for cellular viability, but misrepair generates mutations and gross chromosomal rearrangements. We investigated the interrelationship between two homologous-repair pathways, i.e., mutagenic single-strand annealing (SSA) and precise homology-directed repair (HDR). For this, we analyzed the efficiency of repair in mammalian cells in which double-strand break (DSB) repair components were disrupted. We observed an inverse relationship between HDR and SSA when RAD51 or BRCA2 was impaired, i.e., HDR was reduced but SSA was increased. In particular, expression of an ATP-binding mutant of RAD51 led to a >90-fold shift to mutagenic SSA repair. Additionally, we found that expression of an ATP hydrolysis mutant of RAD51 resulted in more extensive gene conversion, which increases genetic loss during HDR. Disruption of two other DSB repair components affected both SSA and HDR, but in opposite directions: SSA and HDR were reduced by mutation of Brca1, which, like Brca2, predisposes to breast cancer, whereas SSA and HDR were increased by Ku70 mutation, which affects nonhomologous end joining. Disruption of the BRCA1-associated protein BARD1 had effects similar to those of mutation of BRCA1. Thus, BRCA1/BARD1 has a role in homologous repair before the branch point of HDR and SSA. Interestingly, we found that Ku70 mutation partially suppresses the homologous-repair defects of BARD1 disruption. We also examined the role of RAD52 in homologous repair. In contrast to yeast, Rad52 − / − mouse cells had no detectable HDR defect, although SSA was decreased. These results imply that the proper genetic interplay of repair factors is essential to limit the mutagenic potential of DSB repair.

Targeted Inactivation of Mouse RAD52 Reduces Homologous Recombination but Not Resistance to Ionizing Radiation

ABSTRACT The RAD52 epistasis group is required for recombinational repair of double-strand breaks (DSBs) and shows strong evolutionary conservation. In Saccharomyces cerevisiae, RAD52 is one of the key members in this pathway. Strains with mutations in this gene show strong hypersensitivity to DNA-damaging agents and defects in recombination. Inactivation of the mouse homologue of RAD52in embryonic stem (ES) cells resulted in a reduced frequency of homologous recombination. Unlike the yeast Scrad52 mutant,MmRAD52−/− ES cells were not hypersensitive to agents that induce DSBs. MmRAD52 null mutant mice showed no abnormalities in viability, fertility, and the immune system. These results show that, as in S. cerevisiae, MmRAD52is involved in recombination, although the repair of DNA damage is not affected upon inactivation, indicating that MmRAD52 may be involved in certain types of DSB repair processes and not in others. The effect of inactivating MmRAD52 suggests the presence of genes functionally related to MmRAD52, which can partly compensate for the absence of MmRad52 protein.

Nuclear dynamics of RAD52 group homologous recombination proteins in response to DNA damage.

Recombination between homologous DNA molecules is essential for the proper maintenance and duplication of the genome, and for the repair of exogenously induced DNA damage such as double‐strand breaks. Homologous recombination requires the RAD52 group proteins, including Rad51, Rad52 and Rad54. Upon treatment of mammalian cells with ionizing radiation, these proteins accumulate into foci at sites of DNA damage induction. We show that these foci are dynamic structures of which Rad51 is a stably associated core component, whereas Rad52 and Rad54 rapidly and reversibly interact with the structure. Furthermore, we show that the majority of the proteins are not part of the same multi‐protein complex in the absence of DNA damage. Executing DNA transactions through dynamic multi‐protein complexes, rather than stable holo‐complexes, allows flexibility. In the case of DNA repair, for example, it will facilitate cross‐talk between different DNA repair pathways and coupling to other DNA transactions, such as replication.

The NuRD chromatin–remodeling complex regulates signaling and repair of DNA damage

NuRD is recruited to DNA double-strand breaks, where it promotes RNF8/RNF168 histone ubiquitylation and accumulation of DNA repair factors (see also related paper by Larsen et al. in this issue).

CTG repeat instability and size variation timing in DNA repair-deficient mice

Type 1 myotonic dystrophy is caused by the expansion of an unstable CTG repeat in the DMPK gene. We have investigated the molecular mechanisms underlying the CTG repeat instability by crossing transgenic mice carrying >300 unstable CTG repeats in their human chromatin environment with mice knockout for genes involved in various DNA repair pathways: Msh2 (mismatch repair), Rad52 and Rad54 (homologous recombination) and DNA‐PKcs (non‐homologous end‐joining). Genes of the non‐homologous end‐joining and homologous recombination pathways did not seem to affect repeat instability. Only lack of Rad52 led to a slight decrease in expansion range. Unexpectedly, the absence of Msh2 did not result in stabilization of the CTG repeats in our model. Instead, it shifted the instability towards contractions rather than expansions, both in tissues and through generations. Furthermore, we carefully analyzed repeat transmissions with different Msh2 genotypes to determine the timing of intergenerational instability. We found that instability over generations depends not only on parental germinal instability, but also on a second event taking place after fertilization.

Poly(ADP-ribosyl)ation links the chromatin remodeler SMARCA5/SNF2H to RNF168-dependent DNA damage signaling

Summary Ionizing radiation (IR)-induced DNA double-strand breaks (DSBs) arising in native chromatin elicit an RNF8/RNF168-dependent ubiquitylation response, which triggers the recruitment of various repair factors. Precisely how this response is regulated in the context of chromatin remains largely unexplored. Here, we show that SMARCA5/SNF2H, the catalytic subunit of ISWI chromatin remodeling complexes, is recruited to DSBs in a poly(ADP-ribose) polymerase 1 (PARP1)-dependent manner. Remarkably, PARP activity, although dispensable for the efficient spreading of &ggr;H2AX into damaged chromatin, selectively promotes spreading of SMARCA5, the E3 ubiquitin ligase RNF168, ubiquitin conjugates and the ubiquitin-binding factors RAD18 and the RAP80–BRCA1 complex throughout DSB-flanking chromatin. This suggests that PARP regulates the spatial organization of the RNF168-driven ubiquitin response to DNA damage. In support of this, we show that SMARCA5 and RNF168 interact in a DNA damage- and PARP-dependent manner. RNF168 became poly(ADP-ribosyl)ated after DNA damage, while RNF168 and poly(ADP-ribose) chains were required for SMARCA5 binding in vivo, explaining how SMARCA5 is linked to the RNF168 ubiquitin cascade. Moreover, SMARCA5 was found to regulate the ubiquitin response by promoting RNF168 accumulation at DSBs, which subsequently facilitates efficient ubiquitin conjugation and BRCA1 assembly. Underlining the importance of these findings, we show that SMARCA5 depletion renders cells sensitive to IR and results in DSB repair defects. Our study unveils a functional link between DNA damage-induced poly(ADP-ribosyl)ation, SMARCA5-mediated chromatin remodeling and RNF168-dependent signaling and repair of DSBs.

Identification of conserved pathways of DNA-damage response and radiation protection by genome-wide RNAi

Ionizing radiation is extremely harmful for human cells, and DNA double-strand breaks (DSBs) are considered to be the main cytotoxic lesions induced. Improper processing of DSBs contributes to tumorigenesis, and mutations in DSB response genes underlie several inherited disorders characterized by cancer predisposition. Here, we performed a comprehensive screen for genes that protect animal cells against ionizing radiation. A total of 45 C. elegans genes were identified in a genome-wide RNA interference screen for increased sensitivity to ionizing radiation in germ cells. These genes include orthologs of well-known human cancer predisposition genes as well as novel genes, including human disease genes not previously linked to defective DNA-damage responses. Knockdown of eleven genes also impaired radiation-induced cell-cycle arrest, and seven genes were essential for apoptosis upon exposure to irradiation. The gene set was further clustered on the basis of increased sensitivity to DNA-damaging cancer drugs cisplatin and camptothecin. Almost all genes are conserved across animal phylogeny, and their relevance for humans was directly demonstrated by showing that their knockdown in human cells results in radiation sensitivity, indicating that this set of genes is important for future cancer profiling and drug development.

The Drosophila melanogaster DmRAD54 Gene Plays a Crucial Role in Double-Strand Break Repair after P-Element Excision and Acts Synergistically with Ku70 in the Repair of X-Ray Damage

ABSTRACT The RAD54 gene has an essential role in the repair of double-strand breaks (DSBs) via homologous recombination in yeast as well as in higher eukaryotes. A Drosophila melanogasterstrain deficient in the RAD54 homolog DmRAD54is characterized by increased X-ray and methyl methanesulfonate (MMS) sensitivity. In addition, DmRAD54 is involved in the repair of DNA interstrand cross-links, as is shown here. However, whereas X-ray-induced loss-of-heterozygosity (LOH) events were completely absent in DmRAD54−/− flies, treatment with cross-linking agents or MMS resulted in only a slight reduction in LOH events in comparison with those in wild-type flies. To investigate the relative contributions of recombinational repair and nonhomologous end joining in DSB repair, aDmRad54 −/−/DmKu70 −/−double mutant was generated. Compared with both single mutants, a strong synergistic increase in X-ray sensitivity was observed in the double mutant. No similar increase in sensitivity was seen after treatment with MMS. Apparently, the two DSB repair pathways overlap much less in the repair of MMS-induced lesions than in that of X-ray-induced lesions. Excision of P transposable elements inDrosophila involves the formation of site-specific DSBs. In the absence of the DmRAD54 gene product, no male flies could be recovered after the excision of a single P element and the survival of females was reduced to 10% compared to that of wild-type flies. P-element excision involves the formation of two DSBs which have identical 3′ overhangs of 17 nucleotides. The crucial role of homologous recombination in the repair of these DSBs may be related to the very specific nature of the breaks.

Characterization of RAD52 homologs in the fission yeast Schizosaccharomyces pombe.

The RAD52 gene of Saccharomyces cerevisiae is essential for repair of DNA double-strand breaks (DSBs) by homologous recombination. Inactivation of this gene confers hypersensitivity to DSB-inducing agents and defects in most forms of recombination. The rad22+ gene in Schizosaccharomyces pombe (here referred to as rad22A+) has been characterized as a homolog of RAD52 in fission yeast. Here, we report the identification of a second RAD52 homolog in Schizosaccharomyces pombe, called rad22B+. The amino acid sequences of Rad22A and Rad22B show significant conservation (38% identity). Deletion mutants of respectively, rad22A and rad22B, show different phenotypes with respect to sensitivity to X-rays and the ability to perform homologous recombination as measured by the integration of plasmid DNA. Inactivation of rad22A+ leads to a severe sensitivity to X-rays and a strong decrease in recombination (13-fold), while the rad22B mutation does not result in a decrease in homologous recombination or a change in radiation sensitivity. In a rad22A-rad22B double mutant the radiation sensitivity is further enhanced in comparison with the rad22A single mutant. Overexpression of the rad22B+ gene results in partial suppression of the DNA repair defects of the rad22A mutant strain. Meiotic recombination and spore viability are only slightly affected in either single mutant, but outgrowth of viable spores is almost 31-fold reduced in the rad22A-rad22B double mutant. The results obtained imply a crucial role for rad22A+ in repair and recombination in vegetative cells just like RAD52 in S. cerevisiae. The rad22B+ gene presumably has an auxiliary role in the repair of DSBs. The drastic reduced spore viability in the double mutant suggests that meiosis in S. pombe is dependent on the presence of either rad22A+ or rad22B+.

Isolation and genetic characterisation of the Drosophila homologue of (SCE)REV3, encoding the catalytic subunit of DNA polymerase ζ

Abstract In Drosophila , about 30 mutants are known that show hypersensitivity to the methylating agent methyl methane sulfonate (MMS). Addition of this agent to the medium results in an increased larval mortality of the mutants. Using a P-insertion mutagenesis screen, three MMS-sensitive mutants on chromosome II were isolated. One of these is allelic to the known EMS-induced mus205 (mutagen sensitive) mutant. In the newly isolated mutant, a P-element is detected in region 43E by in situ hybridisation. The localisation of mus205 to this region was confirmed by deficiency mapping. The gene was cloned and shows strong homology to the Saccharomyces cerevisiae REV3 gene. The REV3 gene encodes the catalytic subunit of DNA polymerase ζ , involved in translesion synthesis. The P-element is inserted in the first exon of the mus205 gene resulting in an aberrant mRNA, encoding a putative truncated protein containing only the first 13 of the 2130 aa native Drosophila protein. The mus205 mutant is hypersensitive to alkylating agents and UV, but not to ionising radiation. In contrast to reported data, in germ cells, the mutant has no effect on mutability by X-rays, NQO and alkylating agents. In somatic cells, the mutant shows no effect on MMS-induced mutations and recombinations. This phenotype of the Drosophila mus205 mutant is strikingly different from the phenotype of the yeast rev3 mutant, which is hypomutable after UV, X-rays, NQO and alkylating agents.