The Consequences of Rad51 Overexpression for Normal and Tumor Cells

The Consequences of Rad51 Overexpression for Normal and Tumor Cells

dna repair 7 (2008) 686–693 available at www.sciencedirect.com journal homepage: www.elsevier.com/locate/dnarepair Mini review The consequences of Rad51 overexpression for normal and tumor cells Hannah L. Klein ∗ Department of Biochemistry, New York University School of Medicine, NYU Medical Center, 550 First Avenue, New York, NY 10016, United States article info abstract Article history: The Rad51 recombinase is an essential factor for homologous recombination and the Received 11 December 2007 repair of DNA double strand breaks, binding transiently to both single stranded and double Accepted 12 December 2007 stranded DNA during the recombination reaction. The use of a homologous recombination Published on line 1 February 2008 mechanism to repair DNA damage is controlled at several levels, including the binding of Rad51 to single stranded DNA to form the Rad51 nucleofilament, which is controlled through Keywords: the action of DNA helicases that can counteract nucleofilament formation. Overexpression Rad51 protein of Rad51 in different organisms and cell types has a wide assortment of consequences, rang- Overexpression of Rad51 ing from increased homologous recombination and increased resistance to DNA damaging Genomic instability agents to disruption of the cell cycle and apoptotic cell death. Rad51 expression is increased Tumor cell drug resistance in p53-negative cells, and since p53 is often mutated in tumor cells, there is a tendency for Homologous recombination Rad51 to be overexpressed in tumor cells, leading to increased resistance to DNA damage Gene targeting and drugs used in chemotherapies. As cells with increased Rad51 levels are more resis- tant to DNA damage, there is a selection for tumor cells to have higher Rad51 levels. While increased Rad51 can provide drug resistance, it also leads to increased genomic instability and may contribute to carcinogenesis. © 2007 Elsevier B.V. All rights reserved. Contents 1. Introduction .................................................................................................................. 687 2. Fungal systems............................................................................................................... 687 2.1. Schizosaccharomyces pombe ............................................................................................ 687 2.2. Saccharomyces cerevisiae ............................................................................................... 687 3. Drosophila .................................................................................................................... 688 4. Regulation of RAD51 expression in mammalian systems.................................................................. 688 5. Rad51 overexpression in human tumors and cell lines .................................................................... 689 6. Effects of Rad51 overexpression on recombination in mammalian cells.................................................. 690 7. Conclusions .................................................................................................................. 691 Acknowledgement ........................................................................................................... 691 References .................................................................................................................... 691 ∗ Tel.: +1 212 263 5778; fax: +1 212 263 8166. E-mail address: [email protected]. 1568-7864/$ – see front matter © 2007 Elsevier B.V. All rights reserved. doi:10.1016/j.dnarep.2007.12.008 dna repair 7 (2008) 686–693 687 proportion of cells displaying the “cut” phenotype was related 1. Introduction to the level of Rhp51 overexpression. The cell morphology sug- gested that overexpression of Rhp51 induced a DNA damage DNA double strand breaks (DSBs) occur through several checkpoint prior to mitosis. This was accompanied by a dis- sources; through the action of exogenous agents such as ioniz- ruption of microtubule attachments to the chromosomes. A ing radiation, through inhibition of DNA topoisomerases, and FACS analysis showed that a large fraction of cells had a 1C from endogenous programmed events such as V(D)J recom- DNA content, indicative of a delay in entering into S phase. bination in the immunoglobulin genes and Spo11-promoted The authors suggest that DNA replication is interfered when meiotic recombination [1]. DSBs can be repaired by end join- Rhp51 is overexpressed. As overexpression of a mutant form ing pathways that do not utilize significant homology at the of Rhp51 that is most likely defective in binding to DNA based broken ends, or through homologous recombination (HR), on an identical mutation in the Saccharomyces cerevisiae Rad51 which uses homology at the broken ends to intact sequences protein [9,10] did not inhibit cell growth, interference with in the genome to repair the breaks. When HR is used for replication and cell growth requires that the overexpressed repair, in eukaryotes it is promoted by the recombinase Rad51, Rhp51 be bound to DNA rather than causing a defect by bind- which binds to 3’-tailed single strands at the end of DSBs ing to other protein factors and depleting these from their in a helical fashion and promotes pairing with homologous normal cellular compartment and function. DNA sequences as a prelude to strand invasion and repair of the DSBs [1–4]. Since eukaryotic genomes contain dis- 2.2. Saccharomyces cerevisiae persed repeated DNA, repair of DSBs through HR can occur not only through an interaction with the sister chromatid or Several studies have reported on the effects of Rad51 overex- the homolog chromosome, but also with repeats on nonho- pression in S. cerevisiae. Since the level of overexpression varies molog chromosomes (sometimes called ectopic HR). Ectopic in these studies, in some cases Rad51 overexpression has been HR can result in genomic rearrangements and instability. It more deleterious than in other cases. Rad51 interacts with follows then that mitotic HR must be regulated to ensure that the mediator proteins Rad52, Rad55, and Rad57, which over- DSB repair is not mutagenic. come the inhibitory effect of RPA binding to ssDNA in in vitro Although the regulation of mitotic HR is not fully under- reactions for Rad51 nucleofilament formation [11–13]. Overex- stood, we are now beginning to appreciate the role that Rad51 pression of Rad51 can suppress the in vivo effects of non-null expression levels play in regulating HR, as Rad51 overexpres- rad52 mutations [14–17],orrad55 and rad57 deletion muta- sion is found in human tumors, and its increase is related to tions [18]. The assays for suppression involve DNA damage p53 function. Rad51 performs a vital function during the nor- resistance and an increase in recombination rates. In no case mal cell cycle as the RAD51 knockout in chicken and mouse was any deleterious effect of Rad51 overexpression reported, cells is lethal [5–7]. However, too much Rad51 protein also although the level of overexpression ranged from twofold to has deleterious consequences. These findings emphasize that what is estimated to be at least a 10-fold increase in protein Rad51 expression and activity must be carefully regulated. In levels. Rad51 overexpression was also able to partially rescue fungal systems where Rad51 is not essential, mutations that the meiotic defects of rad52 mutants, using spore viability as reduce or destroy Rad51 activity result in increased sensitiv- a measure of successful meioses. ity to DNA damaging agents that create DSBs, a reduction S. cerevisiae has a meiotic-specific Rad51 paralog called in spontaneous mitotic HR rates, an increase in genomic Dmc1, which acts together with Hop2 to promote meiotic rearrangements and an inability to complete meiotic recom- crossing over. dmc1 and hop2 mutants are defective in meiotic bination. Thus HR is an essential feature of a normal cell crossing over and have greatly reduced spore formation and cycle, but must be held in check to prevent unwanted rear- viability. These defects can be counteracted by overexpression rangements. Increased Rad51 expression in tumor cells also of Rad51 [19]. While excess Rad51 could complement meiotic has the unwanted effect of bestowing increased resistance to mutants and promote HR under these mutant conditions, it DNA damage, rendering the cells resistant to drug therapies. did not enhance HR in wildtype cells. Here we review the effects of Rad51 overexpression in yeasts, Rad51 is a dynamic protein that forms nucleofilaments on Drosophila, and mammalian systems. ssDNA in preparation for HR, then is bound to dsDNA after homologous strand invasion to form a D-loop, the synapsis intermediate, and finally is removed from DNA to allow com- 2. Fungal systems pletion of the HR repair reaction by gap filling strand synthesis. To insure that only appropriate DNA lesions are targeted for 2.1. Schizosaccharomyces pombe HR repair during mitotic growth, cells have devised various mechanisms to prevent inappropriate Rad51 nucleofilament The Rad51 homolog, Rhp51, has been overexpressed in wild- formation. In S. cerevisiae this is achieved through the action of type S. pombe cells and results in disruption of the cell cycle [8]. the Srs2 DNA helicase, which acts as a translocase to antago- The expression level ranged from 80-fold to 700-fold over the nize and disassemble Rad51 nucleofilaments [1]. Thus it might normal level of Rhp51, using an inducible promoter. As the be anticipated that there is a fine balance between Rad51 pro- level of

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