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New Potential Therapeutic Approaches by Targeting Rad51- Dependent Homologous Recombination

Written By

Axelle Renodon-Cornière, Pierre Weigel, Magali Le Breton and Fabrice Fleury

Submitted: 08 May 2012 Published: 22 May 2013

DOI: 10.5772/53973

From the Edited Volume

New Research Directions in DNA Repair

Edited by Clark Chen

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1. Introduction

Cellular DNA is constantly exposed to the effects of endogenous or environmental agents such as free radicals, radiation and chemicals. In higher organisms, these nucleic alterations are estimated at several thousands of lesions per cell [1] which can correspond to the loss of bases and also to the breaking of one or both strands of the DNA double helix. Among these DNA breaks, the double-strand break (DSB) is the most harmful because it is the most difficult to repair. A human cell can accumulate up to 50 DSBs per cell cycle [2]. Unrepaired DSBs can have serious consequences such as permanent cell cycle arrest or cell death by apoptosis. Imperfect repair can also lead to major syndromes such as genetic disorders, premature aging or malignant cell generation.

In response to DNA damage, the cell has developed a surveillance and DNA repair network. DSBs of DNA, which are the most severe nucleic acid alterations, are repaired mainly by either non-homologous end-joining (NHEJ) or homologous recombination (HR).

NHEJ repair leads to a direct rejoining of the separated DNA ends [3]. This pathway begins by the binding of the Ku 70/80 heterodimer to DNA ends (Figure 1] which recruits and induces the activation of the DNA-dependent protein kinase catalytic subunit (DNA-PKc). Kinase activity is required for NHEJ since it causes the recruitment of other proteins and promotes the bringing together of DNA ends. Finally, ligase VI and XRCC4/XLF co-factors are involved in the final step of ligation and the generation of DNA repair. This process involves mainly the G0-G1 and S phases of the cell cycle. Its disadvantage is the possible loss of genetic information due to deletions or insertions of nucleic acids during the ligation of DNA ends and thus NHEJ repair is considered error-prone.

DNA repair by HR is more complex and needs a homologous sequence, which can be present in the homologous chromosome or in a gene in multicopy [4]. HR predominates in the S and G2 phases, when the sister chromatids are present and can also be a model for DNA repair [5]. In eukaryotic cells, DNA repair is supported by several protein complexes. Protein ATM (Ataxia Telangiectasia Mutated) has a role in DSB signaling via its activation induced by the MRN protein complex (MRE11-Rad50-NBS1 complex). MRE11 is a 5'-3’ exonuclease that leads to a 3' end of DNA which is required for the process [6]. This resection of single-stranded DNA is followed by the recruitment of many proteins such as RPA, BRCA1, BRCA2, Rad51, Rad52, and Rad54. Rad52 is one of the first to settle on the DSB. BRCA1 then recruits BRCA2, Rad54 and Rad51 to form the nucleoprotein filament with ssDNA, whose role is to move the blade to the homologous sequence required for HR. Rad51 protein is the main element involved in the HR process. This recombinase catalyzes the homology search and the strand exchange with a homologous sequence and thus ensures the accurate repair of the DSB. In eukaryotes, Rad51 recombinase (RecA homolog in Escherichia coli) catalyzes the essential steps of homologous recombination and interacts directly with protein suppressors of breast cancer (BRCA1, BRCA2) [8] and p53 [9] which also indicates the importance of Rad51 in apoptosis.

Figure 1.

Schematic representation of the mechanism of DNA DSB repair by NHEJ and HR (figures taken from [7] ).

HR involves a large number of protein complexes and can be divided into three main stages (Figure 1):

Formation of the HsRad51/DNA nucleofilament or pre-synaptic step. DNA DSBs are resected by nuclease to generate 3’-protruding ends. The complex MRN (MRE11-RAD50-NSB1) contributes to DNA resection which is followed by formation of the replication protein A (RPA) complex. This ssDNA-binding factor removes secondary structures of ssDNA and is subsequently replaced by Rad51. Rad51 is recruited onto ssDNA to form the nucleofilament. Protein mediators such as Rad52 and Rad51 paralogs, Rad51B-C-D, BRCA1/2, facilitate the loading of Rad51 onto the ssDNA. The DNA binding sites of Rad51 are located in the N-terminal domain of each Rad51 monomer [8].

Homologous DNA pairing or synaptic phase. The nucleofilament of Rad51 is involved in the search for homologous DNA. Once a homologous sequence is located, the Rad51 filament invades the duplex DNA and generates a displacement of the homologous DNA strand to form a D-loop.

Exchange and resolution of the DNA intermediate structure or post-synaptic phase. The second 3’ ssDNA overhang anneals to the displaced DNA strand and serves as a model strand for DNA synthesis. Two Holliday Junctions (HJ) are then formed. Their resolution is the final step and generates two dsDNA. HJ can be either resolved or dissolved resulting in crossover or non-crossover products.

It is clear that Rad51 plays an essential role at different levels of HR and several interactions are involved such as Rad51/ssDNA, Rad51/Rad51, Rad51/dsDNA, and Rad51/nucleotide. In addition, Rad51 interacts with its partners involved in HR (e.g. Rad52, Rad54).

Many cancer treatments using chemotherapy or radiotherapy target and disrupt the function of the DNA of tumor cells by inducing adducts or single- or double-strand breaks in DNA. However, these anticancer therapies are often faced with the emergence of radio- and chemoresistance, either induced or intrinsic to cancer cells. Since it was shown that some pathways of DNA repair can remove DNA damage induced by radio- or chemotherapy in cancer cells, these pathways have become potential therapeutic targets to sensitize tumors.

This observation is especially true for the Rad51 protein. A high level of HR induced by overexpression of Rad51 is frequently described in various types of cancer cell, including breast cancer, pancreatic, nonsmall-cell lung carcinoma and leukemia (AML and CML) [9-13]. In these cancer cells, this overexpression provides a degree of cancer resistance by promoting the repair of DSBs induced by cancer treatments [14]. Moreover, it has been shown that the survival of cancer patients expressing higher levels of Rad51 is shorter and that a reduced amount of Rad51, following antisense or ribozyme treatment, increases the effectiveness of cancer treatment by radiotherapy [15-17]. Modulation of HR to potentiate treatment is an option described in many publications [18]. It can be achieved by either acting directly on the recombinase activity of Rad51 or attempting to interfere with the interactions between Rad51 and some of its partners, which are not necessarily related directly to the repair of DNA.

The purpose of this chapter is to review all the chemical modulators that can act directly or indirectly on Rad51-mediated homologous recombination. First, the different steps of Rad51 activity which can be targeted will be detailed. Secondly, the chemical molecules that inhibit Rad51 activity or affect the expression level of Rad51 will be described. Finally, their applications in combination with anticancer treatments will be discussed in order to open up possibilities for counteracting chemo- and radioresistance.

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2. Rad51 activity in homologous recombination

Human Rad51 (Homo sapiens Rad51 or HsRad51) is composed of 339 amino acids. It is the eukaryotic homolog of the RecA protein in prokaryotes. Homologs of the human recombinase are highly conserved between species: 98.8% similarity with Mus musculus Rad51 (MmRad51] and 81% with Saccharomyces cerevisiae Rad51 (ScRad51) [19,20].

To date, no complete structure of the HsRad51 protein has been determined. The crystalline structure of ScRad51 truncated at 79 N-terminal amino acids [21], one structure of Pyrococcus furiosus RadA [22], and five RadA of Methanococcus voltae [23,24] and Sulfolobus solfataricus [25] have been determined.

Figure 2.

MvRadA subunit structure (PDB 1XU4). The N-terminal domain and the polymerization motif are colored in cyan and yellow, respectively. The putative DNA binding L1 and L2 loops are highlighted in orange and red. The Walker A and B motifs, corresponding to the ATP binding site, are labeled in blue and purple, respectively.

RadA and Rad51 are composed of two domains: a small N-terminal domain and a C-terminal domain entitled the core domain. The structures of the two HsRad51 domains were resolved by NMR [8] and crystallography [26], respectively.

The C-terminal domain of HsRad51 was crystallized in the form of a fusion protein comprising the BRC4 motif of BRCA2 protein (residues 1517-1551), a flexible linker and the central domain of HsRad51 (residues 97-339). The co-crystallization of HsRad51 with the BRC4 motif indicated the existence of a polymerization sequence located at the subunit-subunit interface of Rad51 [26]. The C-terminal domain contains an ATPase domain comprising units of Walker A (Hs: 127-134) and Walker B (Hs: 217-222) which are essential for ATP binding while loops L1 (Hs: 230-236) and L2 (Hs: 269-287) are involved in DNA binding.

The N-terminal domain of HsRad51 interacts with double-stranded DNA by a helix-hairpin-helix structure (residues 61-69). This type of protein-DNA interaction is conserved among many proteins interacting with DNA [27]. These sites of interaction, illustrated in Figure 2, are necessary for the formation of the nucleofilament, which is the key step of the recombinase activity of Rad51 (Figure 1). Nucleofilament formation is accompanied by a stretch modification of the DNA helix. The nucleofilament can adopt several conformations, only one of which is active for DNA strand exchange. The extended conformation is the functional form of the filament.

The conformation of the Rad51 filament depends on nucleotides: ATP promotes the extended conformation whereas ADP stabilizes the compressed form. Most of the structures have been solved in the presence of ATP analogs. Thus the conversion of an extended conformation to a compressed conformation accompanies the hydrolysis of ATP [28,29].

Several HsRad51 studies have also shown that ammonium sulfate [30], calcium [28,29] and AMPPNP [29] significantly increase the effectiveness of the strand exchange reaction in vitro by promoting the formation of an extended filament, which confirms that this structural form is the functional conformation of Rad51.

Since Rad51 protein is central to HR, all chemical molecules able to disrupt the interaction sites of Rad51 directly will also be able to modulate DNA repair by HR. Other ways of modulating HR via Rad51 are possible. Figure 3 presents the main ways and the catalytic steps of Rad51 being targeted to modulate HR.

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3. Specific molecules targeting Rad51

The great majority of compounds identified as inhibitors of Rad51 have been selected by high-throughput screening from chemical libraries.

3.1. Modulators of Rad51 recombinase activity

This chemical group acts directly on the catalytic steps of Rad51 recombinase activity.

Figure 3.

Intracellular pathways and catalytic steps of Rad51 as potential targets to modulate HR. (a) and (b) - The modulation of transcription and translation of Rad51 leads to changes in the recombinase activity and hence to the modification of HR repair. (c) - The intracellular localization and the delivery of Rad51 to the DNA damage sites are required for the HR process. Rad51 cellular distribution has an important regulatory role in HR and any element able to modulate the nuclear translocation of Rad51 is also able to modulate HR. (d) - Finally, molecules acting on the steps of Rad51 activity will target recombinase activity and HR-mediated DNA repair.

Figure 4.

Structure of chemical molecules modulating the Rad51 recombinase activity.

3.1.1. 4’-Diisothiocyanostilbene-2,2’-disulfonic acid or DIDS

DIDS (Figure 4) is a molecule known since the early 1970s for its ability to inhibit ionic channels and membrane transporters [31].

In the context of HR, Ishida T. et al. [32] have shown that DIDS can also inhibit in vitro the binding of Rad51 to DNA. In fact, strand exchange reactions are inhibited in the presence of DIDS. This process is dependent on salt concentration since the addition of 0.2 M KCl to the reaction medium changes the behavior of the inhibition. In the absence of KCl, increasing the concentration of DIDS gradually inhibits strand exchange with an IC50 (without KCl) close to 2 μM when the Rad51 concentration is 6 μM. In the presence of 0.2 M KCl, inhibition is considered to be shifted: the addition of DIDS has no effect up to a concentration of 1 μM. In this condition, the IC50 (with KCl) is close to 5 μM in the presence of Rad51 at 6 μM concentration. The interaction between Rad51 and DIDS probably involves electrostatic strength.

It has also been observed that the inhibition of the binding of Rad51 to ssDNA is not changed in the presence or absence of ATP. As previously described, HsRad51 contains a binding site for ATP and ATPase activity [33]. Analysis of the ATPase activity of Rad51 shows that ATP hydrolysis is greatly decreased when the protein is not bound to DNA. However, according to the results of Ishida and collaborators, Rad51 is able to hydrolyze ATP in the presence of DIDS and without DNA. The assumption is that this activation by DIDS of an asynchronous ATPase function results from the inhibition of the binding of Rad51 to DNA, which is ATP-dependent. However, Amunugama et al. [34] showed that the presence of ATP bound to Rad51 is required during strand exchange. In contrast, ATP hydrolysis does not appear to be essential for recombination. Hence, inactivation of the ATPase activity by DIDS cannot alone explain the mechanism of inhibition of Rad51.

DIDS interacts physically with Rad51 and dissociates it from ssDNA by competing with ssDNA for Rad51 binding.

3.1.2. Metatungstate

Metatungstate is a polyoxometalate (POM) consisting of 12 tungsten oxoanions (Figure 4) which dissociate into monotungstates in aqueous alkaline solution. This molecule is mainly used as a catalytic agent for chemical reactions of hydrocarbons.

Li and colleagues [35] have demonstrated that the metatungstate structure can bind in vitro to MvRadA protein, a homolog of Rad51 from Archaea Methanococcus voltae (MvRadA). The main contact zones established between the protein and metatungstate concern the L1 loop region with Arg218 and Arg230 and the L2 loop region with Arg224 of RadA. Both these L1 and L2 domains including Tyr232 and Phe203 are involved in DNA binding. It should be noted that the same pattern is found in HsRad51 [36]. In the MvRadA filament, these locations result in a distribution of molecules of tungstates on the longitudinal axis of rotation. It is shown that these tungsten clusters interact between the DNA-binding loops L1 and L2 stabilizing the inactive conformation of Rad51 [23,24,37].

Tungstate binding to MvRadA induces several effects on the functions of the recombinase protein activity. ATPase activity decreases by about 90% with equimolar amounts of MvRadA and metatungstate. By using gel electrophoresis in vitro, binding assays of MvRadA to ssDNA reveal that metatungstate inhibits ssDNA binding (IC50 = 0.13 µM for 1 μM MvRadA). The same in vitro assays using dsDNA also show an inhibition with a similar IC50 whereas the IC50 value of metatungstate for strand exchange activity is 0.5 µM in the presence of KCl. These observations indicate that, in vitro, metatungstate can inhibit the ssDNA and dsDNA binding of MvRadA, thus inactivating the functions essential for HR. As mentioned previously, the inactivation of ATPase activity does not alone explain the inhibition of Rad51 functions and probably those of RadA. It is therefore suggested that metatungstate acts as a competitive inhibitor of DNA binding by MvRadA.

Metatungstate is a potent inhibitor of ATPase and strand exchange activities of MvRadA and other experiments performed with HsRad51 have shown a significant increase in the IC50 of metatungstate for HsRad51 as compared with that for MvRadA (IC50RadA = 0.5 µM and IC50Rad51 = 30 µM)[35].

3.1.3. Halenaquinone

Xestoquinone and halenaquinone molecules (Figure 4) are extracted from the marine sponge Xestospongia exigua. These molecules are similar except that xestoquinone does not contain the oxygen at the C-3 position in contrast to halenaquinone. Only halenaquinone presents inhibitory properties of phosphatidylinositol 3-kinase [38] and some anti-proliferative features [39].

Takaku et al. tested 160 crude extract fractions from marine sponge and used the D-loop formation assay to detect the homologous-pairing activity of Rad51. The authors reported that the halenaquinone inhibits HR at DNA pairing and D-loop formation stages but no inhibitory effect was observed with xestoquinone [40]. By Surface Plasmon Resonance (SPR) measurement, they showed that both halenaquinone and xestoquinone are able to bind to Rad51 but the affinity between halenaquinone and Rad51 is higher than between xestoquinone and Rad51. This result can explain the efficient inhibition of Rad51-mediated homologous pairing by halenaquinone.

Takaku and collaborators then examined whether both molecules affect ssDNA and dsDNA binding by Rad51. By an electrophoretic mobility shift approach, halenaquinone was found to inhibit Rad51-dsDNA binding specifically, but not Rad51-ssDNA binding. Interestingly, the authors showed that halenaquinone inhibits the secondary dsDNA binding by the Rad51-ssDNA complex. These results suggest that halenaquinone probably interacts near the dsDNA-binding site of Rad51. It can therefore inhibit the ternary complex formation containing ssDNA, dsDNA and Rad51 which promotes the DNA homologous pairing step during the HR process. In contrast, neither ssDNA binding nor dsDNA binding by Rad51 was affected by the presence of xestoquinone.

The authors then studied the intracellular effects of halenaquinone on the Ionizing Radiation (IR)-induced formation of Rad51 foci. When human cells were exposed to IR and treated with halenaquinone, Rad51 foci formation was significantly decreased. This result indicates that halenaquinone destabilizes the Rad51 foci, probably by inhibiting the ternary complex formation. Halenaquinone may be useful in medical research as a potential inhibitor of HR.

3.1.4. Compound B02 and derivatives

By high-throughput screening based on the quenching fluorescence method, Huang and colleagues have investigated the identification of specific inhibitors of the Rad51 strand exchange activity [18]. From 200,000 small molecules of the NIH repository, 174 compounds were positives and, after supplementary analyses and different controls, 13 molecules were identified as potential inhibitors of Rad51 with an inhibition higher than 30%. The IC50 values for the most potent inhibitors of Rad51-induced D-loop formation were determined.

Among these molecules, both compounds A04 and A10 were found to be inhibitors for Rad51 and RecA and their IC50 values were 5 µM and 26.6 µM, respectively. Another compound, the B02 molecule, was found to disrupt Rad51 binding to DNA and nucleoprotein filament formation. Although the B02 molecule presents an IC50 (27.4 µM) higher than A04 or A10, this molecule has a higher specificity for HsRad51.

Moreover, the study of B02 derivatives has revealed an efficient inactivation of Rad51 by both B02-3a and B02-3b, which contain an ethyl and an m-methylphenyl group, respectively (instead of the benzyl group located in the B02 molecule) (Figure 4). Modification of the pyridin radical of B02 suppresses the Rad51-induced D-loop inhibition, which demonstrates the importance of these chemical groups. The recent in vivo work of the same team has shown that B02 inhibits DSB-induced HR and increases cell sensitivity to the ICL agents, cisplatin and mitomycin C [41].

3.1.5. Compound RI-1 or 3-chloro-1-(3,4-dichlorophenyl)-4-(4-morpholinyl)-1H-pyrrole-2,5-dione

From a screening of 10,000 molecules of Chembridge DIVERSetTM, the RI-1 compound was identified as an inhibitor of HsRad51 [42]. A first screening by fluorescence polarization (FP) enabled molecules that can bind to HsRad51 to be selected. A second screening based on the inhibition of homologous recombination in a cell line of human osteosarcoma (U20S) was used and eight molecules were identified. A final test with the human embryonic kidney cell line (HEK293) identified RI-1, whose action is the specific inactivation of HsRad51.

RI-1 is composed of a chloromaleimide moiety (Figure 4) which promotes covalent binding to the thiol group of Rad51 cysteine 319 by a Michael addition mechanism. This binding potentiates the inhibition of the polymerization of HsRad51 during nucleofilament formation. It should be noted that the binding site is located on a surface which is highly conserved among mammalian homologs of Rad51. Experiments with Saccharomyces cerevisiae Rad51 (ScRad51) also show a fixation on the corresponding cysteine target (C377). However, this site is not present in RecA and inhibition was not found. RI-1 is potentially a specific inhibitor for mammalian homologs of Rad51. The binding site is located on the interface between two monomers of HsRad51 so it inhibits the polymerization of Rad51 onto ssDNA [21]. It is known that cysteine 319 is located in an ATP-binding loop [23], therefore the binding of RI-1 may disrupt the interaction of Rad51 with ATP. Moreover, this interaction area is also involved in the binding of other HR repair proteins such as Rad52 and Rad54 [43]. The IC50 of RI-1 is from 5 to 30 µM depending on the HsRad51 intracellular concentration. A synergistic anticancer effect is also observed for the association of RI-1 with mitomycin C (MMC) in U20S, HeLa, MCF-7 and SH2038 cell lines.

3.1.6. Compound RS-1 (Rad51-Stimulatory-1) or 3-[(benzylamino)sulfonyl]-4-bromo-N-(4-bromophenyl)benzamide)

In contrast to inhibitors, few molecules stimulating HR have been reported. However, by screening 10,000 molecules (Chembridge DIVERSetTM) using the FP method described above, Connell et al. identified a molecule, RS-1, which stimulates Rad51 binding onto ssDNA and increases the stability of the nucleofilament [44].

In the presence of RS-1 (Figure 4), the nucleofilament is in the active form characterized by the long length of the Rad51-ssDNA complex (100Å). The presence of nucleotide cofactors is also important since ATP is required for RS-1 to stimulate the formation of the active filament. However, RS-1 does not stimulate Rad51 by inhibiting its ATPase activity since it has no effect on the Rad51-dependent hydrolysis of ATP.

The RS-1-induced extension of the Rad51-ssDNA nucleofilament stimulates the exchange step of DNA strands, which can be evaluated by estimating D-loop formation. In the presence of non-hydrolyzable ATP or Ca2+, RS-1 increases D-loop formation by 5 to 11 times [28,44]. The stimulatory action of RS-1 is specific to HsRad51, since no effect with E. coli RecA or ScRad51 was found. This stimulation was then analyzed at the cellular level.

An analysis of cell survival (neonatal human fibroblasts) showed that the cells are more resistant to cisplatin treatment in the presence of 7.5 μM RS-1. This result is probably due to the ability of RS-1 to stimulate HR in response to DNA-damage agents like cisplatin.

3.2. Chemical modulators of Rad51 expression

3.2.1. Methotrexate drug

The structure of methotrexate (Figure 5) is similar to that of the folate metabolic precursor of coenzyme tetrahydrofolate (FH4) involved in the synthesis of nucleic bases. Methotrexate is a molecule used as an inhibitor of dihydrofolate reductase and acts in nucleic base synthesis occurring during the S phase of the cell cycle, as well as in non-restorative homologous recombination [45]. Therefore, methotrexate targets the S phase and the functions of HR by reducing the rate of repair of DNA damage, which can be shown by comet assay [46]. The study conducted by Du and colleagues [47] found that the inhibition of the formation of HsRad51 foci was effective in the presence of methotrexate in a human osteosarcoma cell line (HOS) after irradiation. This inhibition seems to be related to the Rad51 protein expression level, which is significantly decreased by the treatment. In addition, it was observed that the expression levels of BRCA2 and Rad52 were therefore not affected by methotrexate. It induces a specific downregulation of HsRad51. It should be noted that the treatment of HOS cells with 0.1 µM methotrexate causes a decrease in the transcription of 70% and > 95% of HsRad51 after 12 and 24 hours, respectively. However, these studies cannot determine the interactions involved in decreasing the mRNA levels of HsRad51.

3.2.2. Phenylhydroxamic acid or PCI-24781

Phenylhydroxamic acid (Figure 5) belongs to the inhibitory molecules of histone deacetylases (HDACs) used for their antitumor activities [48]. In particular, PCI-24781 inhibits HDAC2, which is one of the HDAC family involved in the regulation of the factors of HR. According to the work of Adimoolam et al. [49], inhibition of HDAC by PCI-24781 reduces the expression of Rad51 in the cell line derived from human colorectal carcinoma (HTC116) and thus reduces the HR response to DSBs induced by therapy. The first observation by immunofluorescence showed a complete inhibition of the formation of HsRad51 foci in the presence of PCI-24781 after irradiation and an apoptosis rate of 7% with 0.2 µM. After 24 hours, the level of protein synthesis in the absence or presence of 0.2 mM PCI-24781 showed a decrease in transcription of 60% BRCA1 and 80% for both BRCA2 and HsRad51. BRCA2 protein is also involved in the DNA repair protein complex with Rad51 [50]. The HR inhibition observed results in an additive effect of the reductions in expression levels of Rad51 and BRCA2. Moreover, the fall in BRCA2 in the nuclear compartment probably removes the inhibition of caspase-3 protease, which is able to cleave Rad51 and thus to inactivate HR DNA repair [51]. Therefore, PCI-24781 may indirectly activate the cleavage of Rad51 in addition to inducing a decrease in its synthesis. Interestingly, PCI-24781 induces the expression of the gene of the GADD45y protein which is a factor of cellular growth arrest [52]. This third effect of PCI-24781 can limit the growth of tumor cells.

Figure 5.

Structure of chemical modulators of Rad51 transcription and its nuclear translocation.

3.2.3. Prodigiosin

Prodigiosin is a tripyrrole red pigment (Figure 5) from bacteria Serratia marcescens. Recently, immunosuppressive and anticancer properties have been identified for this molecule [53-55]. The first action of prodigiosin is an increase in DNA DSBs, which probably results from the inhibition of both topoisomerase I and II [56]. Lu and collaborators described a significant reduction in the level of HsRad51 protein and mRNA in breast tumor cell lines (MCF-7, MDA-MB-231, T- 47D, A549, HCT116) in the presence of 50 nM prodigiosin [57]. The downregulation of Rad51 is mainly induced by lowering mRNA expression and not by proteasome-mediated Rad51 degradation. Although the tumor suppressor protein p53 is known as a repressor of Rad51 [58], prodigiosin downregulates Rad51 in a p53-independent manner. This result is an advantage for the prodigiosin-mediated therapy of cancer in which p53 is deficient compared to molecules such as flavopiridole or roscovitine, which need an activation of this protein. On the other hand, prodigiosin activates JNK and p38-MAPK signaling pathways, which are known to mediate the pro-apoptotic effect of numerous anticancer drugs [59]. By using specific inhibitors of both these signaling pathways, Lu and collaborators have shown that the level of Rad51 mRNA is restored. This result confirms the involvement of JNK and p38-MAPK signaling pathways in the prodigiosin-induced Rad51 downregulation. However, this is in contradiction with the work of Chuang et al. [60], which showed that the activation of p53-MAPK could increase the level of Rad51 protein, improving its stability and not significantly altering the level of HsRad51 mRNA. Similarly, Ko and colleagues [61] have shown a decrease in mRNA levels of HsRad51 with curcumin treatment and an inactive ERK/p38-MAPK signaling pathway. Although the Rad51 downregulation mechanism is not fully understood, prodigiosin seems to be a potent suppressor of Rad51 which may be used to overcome HR-mediated drug resistance in cancer.

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4. Modulation of Rad51 by inactivation of nuclear translocation

4.1. Nuclear Localization Signal

Eukaryotic proteins are expressed in the cytoplasm. If their functions are carried out in the nucleus, they have to pass through the nuclear membrane. In contrast to small biomolecules, numerous proteins larger than 20 Kda require active transport via a signal peptide of recognition: a Nuclear Localization Signal (NLS) [62]. This signal peptide may be recognized by karyopherins [63] to form a nuclear protein complex (NPC) [64,65]. Proteins involved in HR are not exempt from this obligation for nuclear translocation. Thus, it is useful to analyze the possibility of blocking the passage of Rad51 through the nuclear membrane and thereby inhibit HR. Rad51 protein does not contain an NLS so its nuclear translocation requires an association with another protein. Interestingly, among the Rad51 paralogs, Rad51C has an NLS [66] as do Rad54 [67] and Rad52 [68] proteins. Other proteins related to DNA repair such as BRCA2 have been reported as being involved in Rad51 transport [69]. The mechanism of Rad51 transport is not clearly understood although Rad51C seems to be an interesting candidate. In particular, Gildemeister and colleagues have found that Rad51C deficiency significantly reduces the amount of Rad51 in the nucleus before and after DNA damage [69]. Another option is protein kinase B or AKT-1 protein kinase which is involved in the cytoplasmic sequestration of Rad51 [70]. The modulation of Rad51 transport offers an excellent tool to potentiate anticancer therapy through inhibition of Rad51 nuclear translocation.

4.2. AKT-1 kinase and BRCA1 proteins

Activation of AKT-1 promotes cell proliferation and the activated form is regularly found in cancer cells. In addition, to reducing malignant cell division, the inhibition of the AKT-1 signaling pathway has been investigated for the purpose of co-therapeutic approaches [71]. AKT activation occurs through a series of successive phosphorylation steps at thr-450, thr-308 and ser-473 by JNK kinases, phosphoinositide-dependent kinase 1 and by several kinases (PKD2 and others), respectively [72]. Plo and collaborators have demonstrated another aspect of the activation of AKT-1 in HR DNA repair of chemotherapy-induced DSBs [70]. This group studied the level of HsRad51 and BRCA1 in cell lines MCF7 and MDA-MB-231 and observed a decreased level in the nucleus while both these proteins accumulated in the cytoplasm. Although the HsRad51 and BRCA1 features are not modified, AKT-1 activation induces a retention signal of these proteins in the cytoplasm. Thus, their absence in the nucleus confers a deficiency of recombinase activity. The retention mechanism is still unknown, but it seems to be related to AKT-1-mediated BRCA1 NLS phosphorylation. In fact, it has been observed that AKT-1 phosphorylates BRCA1 on two sites located in the region of the NLS [73] and some mutations of these sites show a suppression of nuclear translocation of Rad51 and BRCA1, irrespective of the activated AKT-1. In this context, an activator of AKT-1 phosphorylation, such as methylglyoxal (Figure 5) [74,75] may promote the cytoplasmic sequestration of Rad51.

4.3. Modulation of the interaction between Rad51 and BRCA2

Human BRCA2 protein is constituted of 3418 amino acids (384 kDa) and contains several interaction domains. There is an interaction site with N-terminal RPA and in the central region of BRCA2 there are 8 repeated motifs called BRC motifs [76]. BRC1, BRC4, BRC7 and BRC8 motifs are able to interact with Rad51 with different affinities [77]. Pellegrini et al. [26] have shown that the BRC4 motif interacts with HsRad51 by mimicking the motif of Rad51 which is responsible for its polymerization. These BRC motifs can bind monomeric or oligomeric forms of Rad51 in a cell cycle-dependent manner and in response to DNA damage. HsRad51 regulation is also mediated by serine 3291 of the BRCA2 C-terminal domain. In the absence of DNA damage, this serine is phosphorylated by CDK1 whereas it is in a dephosphorylated form with inactivated CDK1. The ser-3291 can bind only to the oligomeric form in the nucleoprotein filament. This binding plays a role in stabilizing the Rad51-DNA complex since the phosphorylation of ser-3291 inhibits oligomerization in the absence of DSB and then synchronizes the repair mechanism [78]. It has been proposed that the BRCA2 protein is directly involved in the nuclear transport of Rad51 [50]. The pancreatic adenocarcinoma cell line CAPAN-1 is known to be defective in BRCA2 [79]. It has a deletion of the BRCA2 domains for DNA repair and the nuclear localization signals [80]. Rad51 exhibits impaired nuclear translocation in CAPAN-1. Therefore, it has been proposed that Rad51 requires BRCA2 for its nuclear translocation and that C-terminally trunkated BRCA2 retains Rad51 in the cytoplasm. BRCA2-Rad51 interaction is also essential in the HR process and many works have described those derivative peptides of BRCA2 that are able to mimic and bind to this interaction site [81-83]. Small molecules have been proposed to disrupt the interaction and two patents have been deposited [84]. By using the two-hybrid system in yeast, Lee and Chen suggested several molecules from a drug screening. Two hydrophobic molecules (phenylsulfonyl indolyl isoquinoline derivatives) IBR1 and IBR2 (Figure 5) were found to be able to disrupt the interaction and can thus potentiate anticancer treatments. The authors suggest that the benzene ring of IBR2 interacts in the hydrophobic pocket of Rad51 which is involved in the subunit-subunit interaction during filament formation and also in the interaction with the BRC4 motif of BRCA2. This phenyl moiety of IBR2 may be a competitor with the Rad51 F86 or BRC4 F1524 [85].

The authors also analyzed the effect of IBR2 at cellular level. After irradiation, breast cancer cells (MCF-7) presented a lower number of Rad51 foci than when these cells were pre-treated with IBR2. Another result was the fast degradation of Rad51 in the treated cells where the HR was impaired. This work, which is ongoing, has led to the development and synthesis of other IBR2 analogs [85,86].

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5. Conclusion

DNA repair by homologous recombination is now a potential target in cancer therapy. The induction of DNA damage is one of the means of action against uncontrolled cell proliferation systems, while repairs are causes of resistance to radio- and chemotherapy. DNA repair is frequently found to be deregulated in tumor cells. Rad51 is the central protein of HR and its expression level is correlated with resistance to chemotherapeutic drugs. This observation suggests that targeted inhibition of Rad51 through small chemical molecules may improve the response to drug treatment by reducing HR.

Among antitumoral strategies, several studies have proposed numerous molecules that inhibit the recombinase activity; these are described in Figure 6.

DIDS and metatungstate are molecules that deregulate the ATPase activity of Rad51. DIDS thus causes a random hydrolysis of ATP without ssDNA-bound Rad51, while metatungstate inhibits the ATPase activity. The ATPase center is located at the Rad51 subunit-subunit interface which binds and hydrolyzes ATP and regulates the conformation of the DNA binding site. Although both molecules act differently, they induce an inhibition of the binding of Rad51 onto DNA.

Inhibition of the Rad51 polymerization is also interesting since it directly affects filament formation. The compound RI-1 can bind to the thiol group of cys-319 which inhibits the interaction between monomers of Rad51.

Figure 6.

Potential inhibitors of Rad51-mediated HR repair: Methotrexate (100nM), Prodigiosin (100nM) and PCI-24781 (200nM) treatments reduce the levels of Rad51 mRNA between 20% and 50% in cancer cells. The decrease of Rad51 transcript level also induces an inhibition of Rad51 foci formation [47,49,57]. A 10µM concentration of DIDS significantly inhibits the binding of Rad51 to DNA, leading to the strand exchange inhibition [32]. RI-1 and B02 (20µM) decreases 50% of DNA binding by Rad51 and disrupts the formation of Rad51 foci after DNA damage in cells [18,42]. IBR2 (20µM) inhibits the Rad51 oligomerization in vitro by binding to Rad51 hydrophobic pocket [85]. 20µM of RS-1 promotes the binding of Rad51 to DNA [44]. Halenaquinone (30μM) inhibits the step of DNA homologous pairing mediated by Rad51 in vitro and the Rad51 foci formation after irradiation of cells [40]. It is noteworthy that in vitro IC50 values depend on the protein concentration and technical conditions, which makes difficult to compare them each other and to values obtained in cells.

Halenaquinone modulates the recombinase activity by inhibiting the binding of the Rad51-ssDNA complex with dsDNA. The hypothesis is that the presence of halenaquinone destabilizes the Rad51-ssDNA binding or the interaction between Rad51 subunits. This instability results in a disassembly of the complex, before the recognition of the homologous sequence. Compound B02 is also capable of modulating the function of Rad51 by disrupting Rad51 binding to DNA and formation of the nucleoprotein filament. Moreover, this compound increases cell sensitivity to DNA damaging agents and to PARP1 inhibitors. Thus, small molecules acting directly on the recombinase activity steps offer a potential development for new anticancer treatment associated with chemo- or radiotherapy. Another approach is to decrease the expression of the RAD51 gene. For these purposes, several studies have demonstrated that methotrexate and molecule PCI-24781 significantly reduce the synthesis of Rad51 mRNA. Note that only the effects on mRNA levels were observed but the mechanism of transcription control remains unclear.

Prodigiosin also decreases the level of Rad51 mRNA which seems to be related to the activation of the JNK and p58-MAPK signaling pathways. Therefore, chemical compounds that up- and downregulate Rad51 production and/or activity may be useful for the suppression of tumor progression but the therapeutic applications of this strategy are currently inconceivable and unlikely. The last mode of action focuses on the transport of Rad51 from cytoplasm to nucleus. Rad51 is a protein whose nuclear functions require partners to facilitate its entry into the nucleus. It has been noted that the activation of the anti-apoptotic protein AKT-1 inactivates the nuclear translocation of Rad51 and BRCA1. The mechanism is still poorly understood but retention in the cytoplasm causes a significant decrease in HR. Several studies also suggest that BRCA2 is involved in this transport. Molecules such as IBR, which interfere with the Rad51-BRCA2 interaction, may induce cytoplasmic sequestration of Rad51 which decreases HR. These molecules capable of inhibiting the transport of Rad51 appear attractive candidates.

Most of these Rad51 inhibitors have been identified from screening libraries. These small molecules were tested in vitro and in cellular models but it will be necessary to quantify their efficacy, identify their toxicities and their potentially additional pharmacokinetic and pharmacological properties by animal assays. An understanding of toxicities, adverse effects, and special dosing considerations of existing anticancer compounds is important to the design of effective drug combinations and to the interpretation of the toxicological profile of new chemical entities.

Afterwards, a major challenge is to design new analogues to these molecules that will be more selective for Rad51 so that their efficacy will be improved and their potential toxicities will be decreased. The process of identifying and selecting these analogues has undergone a sea change in the recent decades with the development of solid-state and combinatorial chemistry and computer modeling of drug–target interactions.

By sensitizing cells to DNA damage, Rad51 inhibitors open up new perspectives in the search for agents capable of suppressing homologous recombination and thereby potentiating chemo- and radiotherapy treatments for cancer. Moreover, these molecules may be not only instrumental in the development of combination anticancer therapies but also excellent tools to analyze Rad51 activities and cellular functions.

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Acknowledgments

This work was supported by grants from the Ligue contre le Cancer Comité de Loire Atlantique et de Vendée and the Région pays de la Loire (CIMath project). We thank G. Levillain for his help.

References

  1. 1. Jackson, S. P., and Bartek, J. (2009) Nature 461, 1071-1078
  2. 2. Vilenchik, M. M., and Knudson, A. G. (2003) Proc Natl Acad Sci U S A 100, 12871-12876
  3. 3. Krejci, L., Chen, L., Van Komen, S., Sung, P., and Tomkinson, A. (2003) Prog Nucleic Acid Res Mol Biol 74, 159-201
  4. 4. Shinohara, A., and Ogawa, T. (1995) Trends Biochem Sci 20, 387-391
  5. 5. Takata, M., Sasaki, M. S., Sonoda, E., Morrison, C., Hashimoto, M., Utsumi, H., Yamaguchi-Iwai, Y., Shinohara, A., and Takeda, S. (1998) EMBO J 17, 5497-5508
  6. 6. Uziel, T., Lerenthal, Y., Moyal, L., Andegeko, Y., Mittelman, L., and Shiloh, Y. (2003) EMBO J 22, 5612-5621
  7. 7. Rass, E., Grabarz, A., Bertrand, P., and Lopez, B. S. (2012) Cancer Radiother 16, 1-10
  8. 8. Aihara, H., Ito, Y., Kurumizaka, H., Yokoyama, S., and Shibata, T. (1999) J Mol Biol 290, 495-504
  9. 9. Bearss, D. J., Lee, R. J., Troyer, D. A., Pestell, R. G., and Windle, J. J. (2002) Cancer Res 62, 2077-2084
  10. 10. Raderschall, E., Stout, K., Freier, S., Suckow, V., Schweiger, S., and Haaf, T. (2002) Cancer Res 62, 219-225
  11. 11. Slupianek, A., Hoser, G., Majsterek, I., Bronisz, A., Malecki, M., Blasiak, J., Fishel, R., and Skorski, T. (2002) Mol Cell Biol 22, 4189-4201
  12. 12. Maacke, H., Opitz, S., Jost, K., Hamdorf, W., Henning, W., Kruger, S., Feller, A. C., Lopens, A., Diedrich, K., Schwinger, E., and Sturzbecher, H. W. (2000) Int J Cancer 88, 907-913
  13. 13. Maacke, H., Jost, K., Opitz, S., Miska, S., Yuan, Y., Hasselbach, L., Luttges, J., Kalthoff, H., and Sturzbecher, H. W. (2000) Oncogene 19, 2791-2795
  14. 14. Vispe, S., Cazaux, C., Lesca, C., and Defais, M. (1998) Nucleic Acids Res 26, 2859-2864
  15. 15. Ohnishi, T., Taki, T., Hiraga, S., Arita, N., and Morita, T. (1998) Biochem Biophys Res Commun 245, 319-324
  16. 16. Christodoulopoulos, G., Malapetsa, A., Schipper, H., Golub, E., Radding, C., and Panasci, L. C. (1999) Clin Cancer Res 5, 2178-2184
  17. 17. Collis, S. J., Tighe, A., Scott, S. D., Roberts, S. A., Hendry, J. H., and Margison, G. P. (2001) Nucleic Acids Res 29, 1534-1538
  18. 18. Huang, F., Motlekar, N. A., Burgwin, C. M., Napper, A. D., Diamond, S. L., and Mazin, A. V. (2011) ACS Chem Biol 6, 628-635
  19. 19. Barlow, A. L., Benson, F. E., West, S. C., and Hulten, M. A. (1997) EMBO J 16, 5207-5215
  20. 20. Haaf, T., Golub, E. I., Reddy, G., Radding, C. M., and Ward, D. C. (1995) Proc Natl Acad Sci U S A 92, 2298-2302
  21. 21. Conway, A. B., Lynch, T. W., Zhang, Y., Fortin, G. S., Fung, C. W., Symington, L. S., and Rice, P. A. (2004) Nat Struct Mol Biol 11, 791-796
  22. 22. Shin, D. S., Pellegrini, L., Daniels, D. S., Yelent, B., Craig, L., Bates, D., Yu, D. S., Shivji, M. K., Hitomi, C., Arvai, A. S., Volkmann, N., Tsuruta, H., Blundell, T. L., Venkitaraman, A. R., and Tainer, J. A. (2003) EMBO J 22, 4566-4576
  23. 23. Wu, Y., Qian, X., He, Y., Moya, I. A., and Luo, Y. (2005) J Biol Chem 280, 722-728
  24. 24. Wu, Y., He, Y., Moya, I. A., Qian, X., and Luo, Y. (2004) Mol Cell 15, 423-435
  25. 25. Ariza, A., Richard, D. J., White, M. F., and Bond, C. S. (2005) Nucleic Acids Res 33, 1465-1473
  26. 26. Pellegrini, L., Yu, D. S., Lo, T., Anand, S., Lee, M., Blundell, T. L., and Venkitaraman, A. R. (2002) Nature 420, 287-293
  27. 27. Doherty, A. J., Serpell, L. C., and Ponting, C. P. (1996) Nucleic Acids Res 24, 2488-2497
  28. 28. Bugreev, D. V., and Mazin, A. V. (2004) Proc Natl Acad Sci U S A 101, 9988-9993
  29. 29. Ristic, D., Modesti, M., van der Heijden, T., van Noort, J., Dekker, C., Kanaar, R., and Wyman, C. (2005) Nucleic Acids Res 33, 3292-3302
  30. 30. Sigurdsson, S., Trujillo, K., Song, B., Stratton, S., and Sung, P. (2001) J Biol Chem 276, 8798-8806
  31. 31. Makara, G. B., Stark, E., Karteszi, M., Palkovits, M., and Rappay, G. (1981) Am J Physiol 240, E441-446
  32. 32. Ishida, T., Takizawa, Y., Kainuma, T., Inoue, J., Mikawa, T., Shibata, T., Suzuki, H., Tashiro, S., and Kurumizaka, H. (2009) Nucleic Acids Res 37, 3367-3376
  33. 33. Stark, J. M., Hu, P., Pierce, A. J., Moynahan, M. E., Ellis, N., and Jasin, M. (2002) J Biol Chem 277, 20185-20194
  34. 34. Amunugama, R., He, Y., Willcox, S., Forties, R. A., Shim, K. S., Bundschuh, R., Luo, Y., Griffith, J., and Fishel, R. (2011) J Biol Chem 287, 8724-8736
  35. 35. Li, Y., He, Y., and Luo, Y. (2009) Biochemistry 48, 6805-6810
  36. 36. Matsuo, Y., Sakane, I., Takizawa, Y., Takahashi, M., and Kurumizaka, H. (2006) FEBS J 273, 3148-3159
  37. 37. Qian, X., Wu, Y., He, Y., and Luo, Y. (2005) Biochemistry 44, 13753-13761
  38. 38. Fujiwara, H., Matsunaga, K., Saito, M., Hagiya, S., Furukawa, K., Nakamura, H., and Ohizumi, Y. (2001) Eur J Pharmacol 413, 37-45
  39. 39. Schmitz, F. J., and Bloor, S. (1988) J.Org.Chem 53, 3922-3925
  40. 40. Takaku, M., Kainuma, T., Ishida-Takaku, T., Ishigami, S., Suzuki, H., Tashiro, S., van Soest, R. W., Nakao, Y., and Kurumizaka, H. (2011) Genes Cells 16, 427-436
  41. 41. Huang, F., Mazina, O. M., Zentner, I. J., Cocklin, S., and Mazin, A. V. (2012) J Med Chem 55, 3011-3020
  42. 42. Budke, B., Logan, H. L., Kalin, J. H., Zelivianskaia, A. S., Cameron McGuire, W., Miller, L. L., Stark, J. M., Kozikowski, A. P., Bishop, D. K., and Connell, P. P. (2012) Nucleic Acids Res
  43. 43. Krejci, L., Damborsky, J., Thomsen, B., Duno, M., and Bendixen, C. (2001) Mol Cell Biol 21, 966-976
  44. 44. Jayathilaka, K., Sheridan, S. D., Bold, T. D., Bochenska, K., Logan, H. L., Weichselbaum, R. R., Bishop, D. K., and Connell, P. P. (2008) Proc Natl Acad Sci U S A 105, 15848-15853
  45. 45. Mariani, B. D., Slate, D. L., and Schimke, R. T. (1981) Proc Natl Acad Sci U S A 78, 4985-4989
  46. 46. Ostling, O., and Johanson, K. J. (1984) Biochem Biophys Res Commun 123, 291-298
  47. 47. Du, L. Q., Du, X. Q., Bai, J. Q., Wang, Y., Yang, Q. S., Wang, X. C., Zhao, P., Wang, H., Liu, Q., and Fan, F. Y. (2012) J Cancer Res Clin Oncol 138, 811-818
  48. 48. Buggy, J. J., Cao, Z. A., Bass, K. E., Verner, E., Balasubramanian, S., Liu, L., Schultz, B. E., Young, P. R., and Dalrymple, S. A. (2006) Mol Cancer Ther 5, 1309-1317
  49. 49. Adimoolam, S., Sirisawad, M., Chen, J., Thiemann, P., Ford, J. M., and Buggy, J. J. (2007) Proc Natl Acad Sci U S A 104, 19482-19487
  50. 50. Davies, A. A., Masson, J. Y., McIlwraith, M. J., Stasiak, A. Z., Stasiak, A., Venkitaraman, A. R., and West, S. C. (2001) Mol Cell 7, 273-282
  51. 51. Brown, E. T., Robinson-Benion, C., and Holt, J. T. (2008) Radiat Res 169, 595-601
  52. 52. Zhang, X., Sun, H., Danila, D. C., Johnson, S. R., Zhou, Y., Swearingen, B., and Klibanski, A. (2002) J Clin Endocrinol Metab 87, 1262-1267
  53. 53. Chang, C. C., Chen, W. C., Ho, T. F., Wu, H. S., and Wei, Y. H. (2011) J Biosci Bioeng 111, 501-511
  54. 54. Pandey, R., Chander, R., and Sainis, K. B. (2009) Curr Pharm Des 15, 732-741
  55. 55. Perez-Tomas, R., Montaner, B., Llagostera, E., and Soto-Cerrato, V. (2003) Biochem Pharmacol 66, 1447-1452
  56. 56. Montaner, B., Castillo-Avila, W., Martinell, M., Ollinger, R., Aymami, J., Giralt, E., and Perez-Tomas, R. (2005) Toxicol Sci 85, 870-879
  57. 57. Lu, C. H., Lin, S. C., Yang, S. Y., Pan, M. Y., Lin, Y. W., Hsu, C. Y., Wei, Y. H., Chang, J. S., and Chang, C. C. (2012) Toxicol Lett 212, 83-89
  58. 58. Lazaro-Trueba, I., Arias, C., and Silva, A. (2006) Cell Cycle 5, 1062-1065
  59. 59. Fan, M., and Chambers, T. C. (2001) Drug Resist Updat 4, 253-267
  60. 60. Chuang, S. M., Wang, L. H., Hong, J. H., and Lin, Y. W. (2008) Toxicol Appl Pharmacol 230, 290-297
  61. 61. Ko, J. C., Tsai, M. S., Weng, S. H., Kuo, Y. H., Chiu, Y. F., and Lin, Y. W. (2011) Toxicol Appl Pharmacol 255, 327-338
  62. 62. Adam, S. A., Marr, R. S., and Gerace, L. (1990) J Cell Biol 111, 807-816
  63. 63. Radu, A., Blobel, G., and Moore, M. S. (1995) Proc Natl Acad Sci U S A 92, 1769-1773
  64. 64. Ryan, K. J., and Wente, S. R. (2000) Curr Opin Cell Biol 12, 361-371
  65. 65. Gorlich, D., and Kutay, U. (1999) Annu Rev Cell Dev Biol 15, 607-660
  66. 66. French, C. A., Tambini, C. E., and Thacker, J. (2003) J Biol Chem 278, 45445-45450
  67. 67. Golub, E. I., Kovalenko, O. V., Gupta, R. C., Ward, D. C., and Radding, C. M. (1997) Nucleic Acids Res 25, 4106-4110
  68. 68. Shen, Z., Cloud, K. G., Chen, D. J., and Park, M. S. (1996) J Biol Chem 271, 148-152
  69. 69. Gildemeister, O. S., Sage, J. M., and Knight, K. L. (2009) J Biol Chem 284, 31945-31952
  70. 70. Plo, I., Laulier, C., Gauthier, L., Lebrun, F., Calvo, F., and Lopez, B. S. (2008) Cancer Res 68, 9404-9412
  71. 71. Martelli, A. M., Evangelisti, C., Chiarini, F., Grimaldi, C., Manzoli, L., and McCubrey, J. A. (2009) Expert Opin Investig Drugs 18, 1333-1349
  72. 72. Xiao, L., Gong, L. L., Yuan, D., Deng, M., Zeng, X. M., Chen, L. L., Zhang, L., Yan, Q., Liu, J. P., Hu, X. H., Sun, S. M., Liu, J., Ma, H. L., Zheng, C. B., Fu, H., Chen, P. C., Zhao, J. Q., Xie, S. S., Zou, L. J., Xiao, Y. M., Liu, W. B., Zhang, J., Liu, Y., and Li, D. W. (2010) Cell Death Differ 17, 1448-1462
  73. 73. Altiok, S., Batt, D., Altiok, N., Papautsky, A., Downward, J., Roberts, T. M., and Avraham, H. (1999) J Biol Chem 274, 32274-32278
  74. 74. Chang, T., Wang, R., Olson, D. J., Mousseau, D. D., Ross, A. R., and Wu, L. (2011) FASEB J 25, 1746-1757
  75. 75. Jia, X., Chang, T., Wilson, T. W., and Wu, L. (2012) PLoS One 7, e36610
  76. 76. Bork, P., Blomberg, N., and Nilges, M. (1996) Nat Genet 13, 22-23
  77. 77. Wong, A. K., Pero, R., Ormonde, P. A., Tavtigian, S. V., and Bartel, P. L. (1997) J Biol Chem 272, 31941-31944
  78. 78. Davies, O. R., and Pellegrini, L. (2007) Nat Struct Mol Biol 14, 475-483
  79. 79. Jasin, M. (2002) Oncogene 21, 8981-8993
  80. 80. Holt, J. T., Toole, W. P., Patel, V. R., Hwang, H., and Brown, E. T. (2008) Cancer Genet Cytogenet 186, 85-94
  81. 81. Chen, C. F., Chen, P. L., Zhong, Q., Sharp, Z. D., and Lee, W. H. (1999) J Biol Chem 274, 32931-32935
  82. 82. Nomme, J., Renodon-Corniere, A., Asanomi, Y., Sakaguchi, K., Stasiak, A. Z., Stasiak, A., Norden, B., Tran, V., and Takahashi, M. (2011) J Med Chem 53, 5782-5791
  83. 83. Nomme, J., Takizawa, Y., Martinez, S. F., Renodon-Corniere, A., Fleury, F., Weigel, P., Yamamoto, K., Kurumizaka, H., and Takahashi, M. (2008) Genes Cells 13, 471-481
  84. 84. Lee, W.-H. C. L. (2006) Compositions and methods for disruption of BRCA2-Rad51 interaction. USA
  85. 85. Lee, W.-H., Chen, P.-L., Zhou, L., and Zhu, J. (2009) Compositions and methods related to Rad51 inactivation in the treatment of neoplastic diseases and especially CML. the regents of the university of California, CA, US, USA
  86. 86. Qiu, X. L., Zhu, J., Wu, G., Lee, W. H., and Chamberlin, A. R. (2009) J Org Chem 74, 2018-2027

Written By

Axelle Renodon-Cornière, Pierre Weigel, Magali Le Breton and Fabrice Fleury

Submitted: 08 May 2012 Published: 22 May 2013