XPA: DNA Repair Protein of Significant Clinical Importance.

The nucleotide excision repair (NER) pathway is activated in response to a broad spectrum of DNA lesions, including bulky lesions induced by platinum-based chemotherapeutic agents. Expression levels of NER factors and resistance to chemotherapy has been examined with some suggestion that NER plays a role in tumour resistance; however, there is a great degree of variability in these studies. Nevertheless, recent clinical studies have suggested Xeroderma Pigmentosum group A (XPA) protein, a key regulator of the NER pathway that is essential for the repair of DNA damage induced by platinum-based chemotherapeutics, as a potential prognostic and predictive biomarker for response to treatment. XPA functions in damage verification step in NER, as well as a molecular scaffold to assemble other NER core factors around the DNA damage site, mediated by protein-protein interactions. In this review, we focus on the interacting partners and mechanisms of regulation of the XPA protein. We summarize clinical oncology data related to this DNA repair factor, particularly its relationship with treatment outcome, and examine the potential of XPA as a target for small molecule inhibitors.

Small-Molecule Inhibitor Screen for DNA Repair Proteins.

With the recent interest in targeting the DNA damage response (DDR) and DNA repair, new screening methodologies are needed to broaden the scope of targetable proteins beyond kinases and traditional enzymes. Many of the proteins involved in the DDR and repair impart their activity by making specific contacts with DNA. These protein-nucleic acid interactions represent a tractable target for perturbation with small molecules. We describe a high throughput, solution-based equilibrium binding fluorescence polarization assay that can be applied to a wide array of protein-nucleic acid interactions. The assay is sensitive, stable, and able to identify small molecules capable of blocking DNA-protein interactions.

Design and Structure-Guided Development of Novel Inhibitors of the Xeroderma Pigmentosum Group A (XPA) Protein-DNA Interaction.

XPA is a unique and essential protein required for the nucleotide excision DNA repair pathway and represents a therapeutic target in oncology. Herein, we are the first to develop novel inhibitors of the XPA-DNA interaction through structure-guided drug design efforts. Ester derivatives of the compounds 1 (X80), 22, and 24 displayed excellent inhibitory activity (IC50 of 0.82 ± 0.18 µM and 1.3 ± 0.22 µM, respectively) but poor solubility. We have synthesized novel amide derivatives that retain potency and have much improved solubility. Furthermore, compound 1 analogs exhibited good specificity for XPA over RPA (replication protein A), another DNA-binding protein that participates in the nucleotide excision repair (NER) pathway. Importantly, there were no significant interactions observed by the X80 class of compounds directly with DNA. Molecular docking studies revealed a mechanistic model for the interaction, and these studies could serve as the basis for continued analysis of structure-activity relationships and drug development efforts of this novel target.

New design of nucleotide excision repair (NER) inhibitors for combination cancer therapy.

Many cancer chemotherapy agents act by targeting the DNA of cancer cells, causing substantial damage within their genome and causing them to undergo apoptosis. An effective DNA repair pathway in cancer cells can act in a reverse way by removing these drug-induced DNA lesions, allowing cancer cells to survive, grow and proliferate. In this context, DNA repair inhibitors opened a new avenue in cancer treatment, by blocking the DNA repair mechanisms from removing the chemotherapy-mediated DNA damage. In particular, the nucleotide excision repair (NER) involves more than thirty protein-protein interactions and removes DNA adducts caused by platinum-based chemotherapy. The excision repair cross-complementation group 1 (ERCC1)-xeroderma pigmentosum, complementation group A (XPA) protein (XPA-ERCC1) complex seems to be one of the most promising targets in this pathway. ERCC1 is over expressed in cancer cells and the only known cellular function so far for XPA is to recruit ERCC1 to the damaged point. Here, we build upon our recent advances in identifying inhibitors for this interaction and continue our efforts to rationally design more effective and potent regulators for the NER pathway. We employed in silico drug design techniques to: (1) identify compounds similar to the recently discovered inhibitors, but more effective at inhibiting the XPA-ERCC1 interactions, and (2) identify different scaffolds to develop novel lead compounds. Two known inhibitor structures have been used as starting points for two ligand/structure-hybrid virtual screening approaches. The findings described here form a milestone in discovering novel inhibitors for the NER pathway aiming at improving the efficacy of current platinum-based therapy, by modulating the XPA-ERCC1 interaction.

Virtual screening and biological evaluation of inhibitors targeting the XPA-ERCC1 interaction.

BACKGROUND: Nucleotide excision repair (NER) removes many types of DNA lesions including those induced by UV radiation and platinum-based therapy. Resistance to platinum-based therapy correlates with high expression of ERCC1, a major element of the NER machinery. The interaction between ERCC1 and XPA is essential for a successful NER function. Therefore, one way to regulate NER is by inhibiting the activity of ERCC1 and XPA. METHODOLOGY/PRINCIPAL FINDINGS: Here we continued our earlier efforts aimed at the identification and characterization of novel inhibitors of the ERCC1-XPA interaction. We used a refined virtual screening approach combined with a biochemical and biological evaluation of the compounds for their ability to interact with ERCC1 and to sensitize cells to UV radiation. Our findings reveal a new validated ERCC1-XPA inhibitor that significantly sensitized colon cancer cells to UV radiation indicating a strong inhibition of the ERCC1-XPA interaction. CONCLUSIONS: NER is a major factor in acquiring resistance to platinum-based therapy. Regulating the NER pathway has the potential of improving the efficacy of platinum treatments. One approach that we followed is to inhibit the essential interaction between the two NER elements, ERCC1 and XPA. Here, we performed virtual screening against the ERCC1-XPA interaction and identified novel inhibitors that block the XPA-ERCC1 binding. The identified inhibitors significantly sensitized colon cancer cells to UV radiation indicating a strong inhibition of the ERCC1-XPA interaction.

Cyclosporin A inhibits nucleotide excision repair via downregulation of the xeroderma pigmentosum group A and G proteins, which is mediated by calcineurin inhibition.

Cyclosporin A (CsA) inhibits nucleotide excision repair (NER) in human cells, a process that contributes to the skin cancer proneness in organ transplant patients. We investigated the mechanisms of CsA-induced NER reduction by assessing all xeroderma pigmentosum (XP) genes (XPA-XPG). Western blot analyses revealed that XPA and XPG protein expression was reduced in normal human GM00637 fibroblasts exposed to 0.1 and 0.5 µm CsA. Interestingly, the CsA treatment reduced XPG, but not XPA, mRNA expression. Calcineurin knockdown in GM00637 fibroblasts using RNAi led to similar results suggesting that calcineurin-dependent signalling is involved in XPA and XPG protein regulation. CsA-induced reduction in NER could be complemented by the overexpression of either XPA or XPG protein. Likewise, XPA-deficient fibroblasts with stable overexpression of XPA (XP2OS-pCAH19WS) did not show the inhibitory effect of CsA on NER. In contrast, XPC-deficient fibroblasts overexpressing XPC showed CsA-reduced NER. Our data indicate that the CsA-induced inhibition of NER is a result of downregulation of XPA and XPG protein in a calcineurin-dependent manner.

Identification of novel small molecule inhibitors of the XPA protein using in silico based screening.

The nucleotide excision repair pathway catalyzes the removal of bulky adduct damage from DNA and requires the activity of more than 30 individual proteins and complexes. A diverse array of damage can be recognized and removed by the NER pathway including UV-induced adducts and intrastrand adducts induced by the chemotherapeutic compound cisplatin. The recognition of DNA damage is complex and involves a series of proteins including the xeroderma pigmentosum group A and C proteins and the UV-damage DNA binding protein. The xeroderma pigmentosum group A protein is unique in the sense that it is required for both transcription coupled and global genomic nucleotide excision repair. In addition, xeroderma pigmentosum group A protein is required for the removal of all types of DNA lesions repaired by nucleotide excision repair. Considering its importance in the damage recognition process, the minimal information available on the mechanism of DNA binding, and the potential that inhibition of xeroderma pigmentosum group A protein could enhance the therapeutic efficacy of platinum based anticancer drugs, we sought to identify and characterize small molecule inhibitors of the DNA binding activity of the xeroderma pigmentosum group A protein. In silico screening of a virtual small molecule library resulted in the identification of a class of molecules confirmed to inhibit the xeroderma pigmentosum group A protein-DNA interaction. Biochemical analysis of inhibition with varying DNA substrates revealed a common mechanism of xeroderma pigmentosum group A protein DNA binding to single-stranded DNA and cisplatin-damaged DNA.

Antimony impairs nucleotide excision repair: XPA and XPE as potential molecular targets.

Trivalent antimony is a known genotoxic agent classified as a possible human carcinogen by the International Agency for Research on Cancer (IARC) and as an animal carcinogen by the German MAK Commission. Nevertheless, the underlying mechanism for its genotoxicity remains elusive. Because of the similarities between antimony and arsenic, the inhibition of DNA repair has been a promising hypothesis. Investigations on the removal of DNA lesions now revealed a damage specific impairment of nucleotide excision repair (NER). After irradiation of A549 human lung carcinoma cells with UVC, a higher number of cyclobutane pyrimidine dimers (CPD) remained in the presence of SbCl(3), whereas processing of the 6-4 photoproducts (6-4PP) and benzo[a]pyrene diol epoxide (BPDE)-induced DNA adducts was not impaired. Nevertheless, cell viability was reduced in a more than additive mode after combined treatment of SbCl(3) with UVC as well as with BPDE. In search of the molecular targets, a decrease in gene expression and protein level of XPE was found, which is known to be indispensable for the recognition of CPD. Moreover, trivalent antimony was shown to interact with the zinc finger domain of XPA, another NER protein, since SbCl(3) mediated a concentration dependent release of zinc from a peptide consistent with this domain. In the cellular system, association of XPA to and dissociation from damaged DNA was diminished in the presence of SbCl(3). These results show for the first time that trivalent antimony interferes with proteins involved in nucleotide excision repair and partly impairs this pathway, pointing to an indirect mechanism in the genotoxicity of trivalent antimony.

The role of Bcl-x(L) protein in nucleotide excision repair-facilitated cell protection against cisplatin-induced apoptosis.

Many anticancer drugs target the genomic DNA of cancer cells by generating DNA damage and inducing apoptosis. DNA repair protects cells against DNA damage-induced apoptosis. Although the mechanisms of DNA repair and apoptosis have been extensively studied, the mechanism by which DNA repair prevents DNA damage-induced apoptosis is not fully understood. We studied the role of the antiapoptotic Bcl-x(L) protein in nucleotide excision repair (NER)-facilitated cell protection against cisplatin-induced apoptosis. Using both normal human fibroblasts (NF) and NER-defective xeroderma pigmentosum group A (XPA) and group G (XPG) fibroblasts, we demonstrated that a functional NER is required for cisplatin-induced transcription of the bcl-x(l) gene. The results obtained from our Western blots revealed that the cisplatin treatment led to an increase in the level of Bcl-x(L) protein in NF cells, but a decrease in the level of Bcl-x(L) protein in both XPA and XPG cells. The results of our immunofluorescence staining indicated that a functional NER pathway was required for cisplatin-induced translocation of NF-kappaB p65 from cytoplasm into nucleus, indicative of NF-kappaB activation. Given the important function of NF-kappaB in regulating transcription of the bcl-x(l) gene and the Bcl-x(L) protein in preventing apoptosis, these results suggest that NER may protect cells against cisplatin-induced apoptosis by activating NF-kappaB, which further induces transcription of the bcl-x(l) gene, resulting in an accumulation of Bcl-x(L) protein and activation of the cell survival pathway that leads to increased cell survival under cisplatin treatment.

Multiple shRNA expressions in a single plasmid vector improve RNAi against the XPA gene.

To improve the efficiency of stable knockdown with short hairpin RNA (shRNA), we inserted multiple shRNA expression sequences into a single plasmid vector. In this study, the DNA repair factor XPA was selected as a target gene since it is not essential for cell viability and it is easy to check the functional knockdown of this gene. The efficiency of knockdown was compared among single and triple expression vectors. The single shRNA-expressing vector caused limited knockdown of the target protein in stable transfectants, however, the multiple expression vectors apparently increased the frequency of knockdown transfectants. There were correlations between the knockdown level and marker expression in multiple-expressing transfectants, whereas poorer correlations were observed in single vector transfectants. Multiple-transfectants exhibited reduced efficiency of repair of UV-induced DNA damage and an increased sensitivity to ultraviolet light-irradiation. We propose that multiple shRNA expression vectors might be a useful strategy for establishing knockdown cells.