Assessment of cellular responses mediated by temozolomide combined with metoxiamina, an inhibitor of DNA repair, in glioblastoma cell lines. / Avaliação da resposta celular mediada pelo quimioterápico temozolomida associada ao inibidor do reparo do DNA metoxiamina em linhagens de glioblastoma.

AUTOR(ES)
DATA DE PUBLICAÇÃO

2009

RESUMO

Gliomas represent more than 70% of primary brain tumors. Even following an aggressive therapies, the mean survival rate of patients with these tumors is less than one year after diagnosis. Chemotherapy based on alkyklating agents, such as temozolomide (TMZ) has been reported to increase the survival rate. N7-metyl-G and N3-metyl-A adducts comprise more than 80% of the DNA lesions induced by TMZ and are processed by the base excision repair process (BER). There is evidence in the literature suggesting that the resistance to TMZ could be caused, in part, by an efficient repair by BER pathway, although few studies have focused on this subject. Metoxiamine (MX) is an effective BER inhibitor, which has been investigated as a conceivable treatment for different kinds of tumor, due to its synergistic effect with antitumoral drugs, such as TMZ. In the present study, the cellular responses to TMZ treatment associated or not with MX were evaluated in giloblastoma (GBM) cell lines. Several parameters were analyzed, such as cytotoxicity (24 h), cellular survival (120 h) and clonogenic efficiency (10 days after treatment), DNA damage and repair kinetics (after 2, 6, 12 and 24 h of recovery time), apoptosis induction (24, 48 and 72 h) and alterations in gene expression (24, 48 e 72h) for genes playing role in BER pathway. The treatment with TMZ 100 -1000 M (during 24 h) was cytotoxic for all GBM cell lines tested (U87, U343, U251, U138 and T98G), as analyzed after 120 h, with the T98G cell line being be the most resistant to TMZ; besides, T98G was the only one to present significant differences (p 0,05) in survival rates measured between TMZ treatment and TMZ combined with MX. Thus, T98G cells were selected for the subsequent experiments and for the study of the pathways implicated in TMZ resistance. The clonogenic efficiency of T98G cells was reduced under TMZ treatment (100 - 800 M) with significant differences for treatments above 400 M. In addition, the combined treatment TMZ plus MX significantly increased the cytotoxic effects, even for the lowest concentration. The comet assay showed higher percentage of DNA damage for both treatment modalities (TMZ and TMZ+MX) at 2 and 6 h of recovery, with significant differences between treatments for 2 h. Following 12 and 24 h of recovery, the amount of DNA damage reached the control levels, indicating the repair of DNA breaks. Apoptosis induction in T98G cells showed the highest frequency (24.2%) at 72h for 600 M TMZ, while the highest apoptosis induction (47.7%) was observed for the same concentration combined to MX. Quantitative gene expression analysis performed for three genes, APE1, FEN1 and XRCC1, showed a reduced expression of APE1 and FEN1 for the combined treatment. Western blot analysis demonstrated that APE1 was less expressed for all kind of treatments, probably due to AP-sites blockade caused by the inhibitor MX. In addition, FEN1 showed low levels of expression at 48h and 72h, indicating the inhibition of BER pathway downstream to the AP removal by APE1. On the other hand, PCNA expression was higher for the combined treatment (24h and mainly 48h), suggesting its induction probably due to increased DNA damage. Therefore, the present results demonstrated that the association of TMZ with MX interfered with the expression of proteins involved in BER, thus, reducing the clonogenic efficiency of T98G cells, probably as a consequence of the high production of unrepaired DNA-MX adducts, leading to cell death, including apoptosis. These data show that the modulation of BER is a promising strategy for magnifying the therapeutic impact of TMZ, and in the next future, this strategy may embrace the option to establish novel and efficient therapy protocols for the treatment of gliomas with alkylating agents.

ASSUNTO(S)

glioblastoma metoxiamina. resistência ao tratamento temozolomide resistance to the treatmen metoxiamina. temozolomida ber ber glioblastoma

ACESSO AO ARTIGO

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