REV3L confers chemoresistance to cisplatin in human gliomas: the potential of its RNAi for synergistic therapy

Inhibition of REV3 expression induces persistent DNA damage and growth arrest in cancer cells

REV3 is the catalytic subunit of DNA translesion synthesis polymerase ζ. Inhibition of REV3 expression increases the sensitivity of human cells to a variety of DNA-damaging agents and reduces the formation of resistant cells. Surprisingly, we found that short hairpin RNA-mediated depletion of REV3 per se suppresses colony formation of lung (A549, Calu-3), breast (MCF-7, MDA-MB-231), mesothelioma (IL45 and ZL55), and colon (HCT116 +/-p53) tumor cell lines, whereas control cell lines (AD293, LP9-hTERT) and the normal mesothelial primary culture (SDM104) are less affected. Inhibition of REV3 expression in cancer cells leads to an accumulation of persistent DNA damage as indicated by an increase in phospho-ATM, 53BP1, and phospho-H2AX foci formation, subsequently leading to the activation of the ATM-dependent DNA damage response cascade. REV3 depletion in p53-proficient cancer cell lines results in a G(1) arrest and induction of senescence as indicated by the accumulation of p21 and an increase in senescence-associated β-galactosidase activity. In contrast, inhibition of REV3 expression in p53-deficient cells results in growth inhibition and a G(2)/M arrest. A small fraction of the p53-deficient cancer cells can overcome the G(2)/M arrest, which results in mitotic slippage and aneuploidy. Our findings reveal that REV3 depletion per se suppresses growth of cancer cell lines from different origin, whereas control cell lines and a mesothelial primary culture were less affected. Thus, our findings indicate that depletion of REV3 not only can amend cisplatin-based cancer therapy but also can be applied for susceptible cancers as a potential monotherapy.

REV3L 3'UTR 460 T>C polymorphism in microRNA target sites contributes to lung cancer susceptibility

REV3Lp, the catalytic subunit of DNA polymerase zeta, is the major participant in translesion DNA synthesis. Recent evidence suggests that REV3L has an important role in the maintenance of genome stability despite its mutagenic characteristics. Such a function makes it a cancer susceptibility candidate gene. To investigate association between REV3L polymorphisms and lung cancer risk in a Chinese population, we first genotyped 15 common polymorphisms of the REV3L gene and found that three single nucleotide polymorphisms (rs465646, rs459809 and rs1002481) were significantly associated with lung cancer risk. One of the strongest associations observed was for the 3'-terminal untranslated region (3'UTR) 460 T>C polymorphism (rs465646) (adjusted odds ratio (OR)=0.69 for TC/CC; P=0.007, compared with TT). Similar results were obtained in a subsequent replication study (adjusted OR=0.72; P=0.016). Combined data from the two studies of 1072 lung cancer patients and 1064 cancer-free controls generated an even stronger association (adjusted OR=0.71; P=3.04 × 10(-4)). This 3'UTR 460 T>C variant was predicted to modulate the binding of several micro RNAs. Surface plasmon resonance analysis and luciferase assays showed that the T allele demonstrated a stronger binding affinity for miR-25 and miR-32, resulting in significantly weaker reporter expression levels. Additional experiments revealed that miR-25/32 could downregulate endogenous REV3L. Furthermore, the tumor-suppressing role of REV3L was confirmed by the foci formation assay. These results support our hypothesis that the REV3L rs465646 variant modifies lung cancer susceptibility in Chinese Han population by affecting miRNA-mediated gene regulation.

Molecular mechanisms of cisplatin resistance

Platinum-based drugs, and in particular cis-diamminedichloroplatinum(II) (best known as cisplatin), are employed for the treatment of a wide array of solid malignancies, including testicular, ovarian, head and neck, colorectal, bladder and lung cancers. Cisplatin exerts anticancer effects via multiple mechanisms, yet its most prominent (and best understood) mode of action involves the generation of DNA lesions followed by the activation of the DNA damage response and the induction of mitochondrial apoptosis. Despite a consistent rate of initial responses, cisplatin treatment often results in the development of chemoresistance, leading to therapeutic failure. An intense research has been conducted during the past 30 years and several mechanisms that account for the cisplatin-resistant phenotype of tumor cells have been described. Here, we provide a systematic discussion of these mechanism by classifying them in alterations (1) that involve steps preceding the binding of cisplatin to DNA (pre-target resistance), (2) that directly relate to DNA-cisplatin adducts (on-target resistance), (3) concerning the lethal signaling pathway(s) elicited by cisplatin-mediated DNA damage (post-target resistance) and (4) affecting molecular circuitries that do not present obvious links with cisplatin-elicited signals (off-target resistance). As in some clinical settings cisplatin constitutes the major therapeutic option, the development of chemosensitization strategies constitute a goal with important clinical implications.

Suppression of Rev3, the catalytic subunit of Pol{zeta}, sensitizes drug-resistant lung tumors to chemotherapy

Platinum-based chemotherapeutic drugs are front-line therapies for the treatment of non-small cell lung cancer. However, intrinsic drug resistance limits the clinical efficacy of these agents. Recent evidence suggests that loss of the translesion polymerase, Polζ, can sensitize tumor cell lines to cisplatin, although the relevance of these findings to the treatment of chemoresistant tumors in vivo has remained unclear. Here, we describe a tumor transplantation approach that enables the rapid introduction of defined genetic lesions into a preclinical model of lung adenocarcinoma. Using this approach, we examined the effect of impaired translesion DNA synthesis on cisplatin response in aggressive late-stage lung cancers. In the presence of reduced levels of Rev3, an essential component of Polζ, tumors exhibited pronounced sensitivity to cisplatin, leading to a significant extension in overall survival of treated recipient mice. Additionally, treated Rev3-deficient cells exhibited reduced cisplatin-induced mutation, a process that has been implicated in the induction of secondary malignancies following chemotherapy. Taken together, our data illustrate the potential of Rev3 inhibition as an adjuvant therapy for the treatment of chemoresistant malignancies, and highlight the utility of rapid transplantation methodologies for evaluating mechanisms of chemotherapeutic resistance in preclinical settings.

Error-prone translesion synthesis mediates acquired chemoresistance

The development of cancer drug resistance is a persistent clinical problem limiting the successful treatment of disseminated malignancies. However, the molecular mechanisms by which initially chemoresponsive tumors develop therapeutic resistance remain poorly understood. Error-prone translesional DNA synthesis (TLS) is known to underlie the mutagenic effects of numerous anticancer agents, but little is known as to whether mutation induced by this process is ultimately relevant to tumor drug resistance. Here, we use a tractable mouse model of B-cell lymphoma to interrogate the role of error-prone translesional DNA synthesis in chemotherapy-induced mutation and resistance to front-line chemotherapy. We find that suppression of Rev1, an essential TLS scaffold protein and dCMP transferase, inhibits both cisplatin- and cyclophosphamide-induced mutagenesis. Additionally, by performing repeated cycles of tumor engraftment and treatment, we show that Rev1 plays a critical role in the development of acquired cyclophosphamide resistance. Thus, chemotherapy not only selects for drug-resistant tumor population but also directly promotes the TLS-mediated acquisition of resistance-causing mutations. These data provide an example of an alteration that prevents the acquisition of drug resistance in tumors in vivo. Because TLS also represents a critical mechanism of DNA synthesis in tumor cells following chemotherapy, these data suggest that TLS inhibition may have dual anticancer effects, sensitizing tumors to therapy as well as preventing the emergence of tumor chemoresistance.

Analysis of specialized DNA polymerases expression in human gliomas: association with prognostic significance

Aberrant activation of the translesion DNA synthesis (TLS) pathway has been suggested to play a role in tumorigenesis by promoting genetic mutations. We therefore examined glioma specimens for the expression of specialized DNA polymerases involved in TLS and assessed their prognostic significance. The expression levels of DNA polymerase κ (Pol κ), Pol ι, and Pol η were assessed in 40 primary glioma samples and 10 normal brain samples using quantitative real-time PCR and Western blot analysis. Their prognostic significance was evaluated using a population-based tissue microarray derived from a cohort of 104 glioma patients. Overexpression of Pol κ and Pol ι was observed in 57.5% (23-40) and 27.5% (11-40) of patients, respectively, whereas no significant expression of Pol η was seen in the specimens. Immunohistochemical studies revealed positive Pol κ and Pol ι staining in 72 (69.2%) and 33 (31.7%) of the 104 glioma specimens, respectively. Pol κ expression was associated with advanced stages of the disease. Both Pol κ- and Pol ι-positive staining were associated with shorter survival in glioma patients (P < .001 and P = .014, respectively). A multivariate survival analysis identified Pol κ as an independent prognostic factor for glioma patients (P < .001). These findings demonstrate, for the first time, that the expression of Pol κ and Pol ι is deregulated in gliomas, and upregulation of Pol κ is associated with poorer prognosis in glioma patients.

Chk2 down-regulation by promoter hypermethylation in human bulk gliomas

AIMS

Gliomas account for 80% of malignant brain tumors. DNA damage response and subsequent checkpoint control pathways could maintain the integrity of the genome and thus defend tumorigenesis. Four kinases, ATM, ATR, ChK1 and Chk2 are the damage sensors and the early effectors in DNA damage responses. Given their importance, we investigated the transcriptional regulation of these four genes.

MAIN METHODS

Tissues from ten normal brains and thirty human gliomas were utilized for mRNA analysis via real-time PCR. Another twelve normal brain tissues and forty gliomas were used for confirmation. Methylation-specific PCR (MSP) was used to determine the methylation status of the Chk2 promoter. Quantitative chromatin immunoprecipitation (ChIP) was used to measure the influence of methylation on Sp1 binding.

KEY FINDINGS

We found that the expression of ATR, ChK1 and Chk2 in gliomas was significantly down-regulated relative to the normal brain tissues. The most significant reduction of expression was of the Chk2 gene, whose expression was approximately 10-fold decreased in gliomas (P<0.0001). Down-regulation of Chk2 was validated in the second real-time PCR analysis. This reduction in expression was partially due to promoter methylation. The Chk2 proximal promoter recruited Sp1 for transcriptional activation. We found that hypermethylation of the Chk2 promoter undermined the binding of the transcriptional factor Sp1.

SIGNIFICANCE

Our results indicate that Chk2 methylation could be involved in glioma carcinogenesis and Chk2 expression may potentially be used for the diagnosis of glioma.

The translesion polymerase Rev3L in the tolerance of alkylating anticancer drugs

Temozolomide and fotemustine, representing methylating and chloroethylating agents, respectively, are used in the treatment of glioma and malignant melanoma. Because chemoresistance of these tumors is a common phenomenon, identification of the underlying mechanisms is needed. Here we show that Rev3L, the catalytic subunit of the translesion DNA polymerase zeta, mediates resistance to both temozolomide and fotemustine. Rev3L knockout cells are hypersensitive to both agents. It is remarkable that cells heterozygous for Rev3L showed an intermediate sensitivity. Rev3L is not involved in the tolerance of the toxic O6-methylguanine lesion. However, a possible role of Rev3L in the tolerance of O6-chloroethylguanine or the subsequently formed N1-guanine-N3-cytosine interstrand cross-link is shown. Rev3L had no influence on base excision repair (BER) of the N-alkylation lesions but is very likely to be involved in the tolerance of N-alkylations or apurinic/apyrimidinic sites originating from them. We also show that Rev3L exerts its protective effect in replicating cells and that loss of Rev3L leads to a significant increase in DNA double-strand breaks after temozolomide and fotemustine treatment. These data show that Rev3L contributes to temozolomide and fotemustine resistance, thus acting in concert with O6-methylguanine-DNA methyltransferase, BER, mismatch repair, and double-strand break repair in defense against simple alkylating anticancer drugs.