Enhanced DNA excision repair in CCRF-CEM cells resistant to 1,3-bis(2-chloroethyl)-1-nitrosourea,quantitated using the single cell gel electrophoresis (Comet) assay

Enhanced DNA repair activity is important for the development of cellular resistance to alkylating agents. Here, we quantitated the kinetics of DNA excision repairs initiated by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) in human leukemia CCRF-CEM cells. CEM cells that had been established resistant to BCNU (CEM-R) were evaluated in comparison with parental CEM cells (CEM-S). The excision repair kinetics were quantitated as the amount of DNA single strand breaks, which were generated from the incision/excision of the damaged DNA and were diminished by the rejoining of renewed DNA, using the single cell gel electrophoresis (Comet) assay. CEM-R cells were 10-fold more resistant to BCNU than CEM-S cells, and also showed cross-resistance to melphalan and cisplatin. In response to the treatment with BCNU, both CEM-S and CEM-R cells initiated an incision/excision reaction at the end of the incubation period, and completed the rejoining process within 4 hr. While CEM-S cells could not repair the damage induced by the high concentration of BCNU, CEM-R cells completed the repair process regardless of BCNU concentrations, suggesting enhanced excision repairs in CEM-R cells. The excision repair activity of CEM-R cells was increased with regard to the incision reaction and to the rate of the repair. Similar results were obtained using ultraviolet C, suggesting enhanced nucleotide excision repair in CEM-R cells. Thus, the enhanced DNA excision repairs were successfully quantitated in the resistant leukemic cell line using the Comet assay. The evaluation of the repair activity may predict the sensitivity of cancer cells to chemotherapy and provide a clue to overcome the resistance.     

Influence of O6-methylguanine on DNA damage and cytotoxicity of temozolomide in L1210 mouse leukemia sensitive and resistant to chloroethylnitrosoureas.

Temozolomide is a new anticancer agent which in the early clinical investigation has shown promising antitumor activity. It decomposes spontaneously to the active metabolite of DTIC (MTIC). Temozolomide is more cytotoxic against L1210 than against a subline L1210/BCNU, resistant to chloroethylnitrosoureas. Using [methyl-3H] temozolomide we found that after 1 h exposure the amount of O6-methylguanine (O6mGua) was twice as high in L1210 than in L1210/BCNU whereas the amount of N7 mGua was approximately the same in the two cell lines. O6-alkylguanine DNA alkyltransferase (AT) levels were higher in L1210/BCNU than in L1210, supporting the view that the resistance to methyltriazenes is probably related to the efficient repair of O6mGua in L1210/BCNU. Exposure of L1210/BCNU cells to 0.4 mM O6mGua for 24 h resulted in a depletion of AT and in a higher temozolomide-induced cytotoxicity. In the sensitive cell line L1210, temozolomide activity was not potentiated by O6mGua pretreatment. Moreover, in L1210/BCNU, O6mGua increased DNA single-strand breaks caused by temozolomide, suggesting that O6-guanine alkylation induces an excision repair mechanism in cells depleted in AT.     

Modulation of nitrosourea resistance in human colon cancer by O6-methylguanine.

Human colon cancer is resistant to a variety of alkylating agents including the nitrosoureas. To specifically evaluate nitrosourea resistance, we studied the role of O6-alkylguanine-DNA alkyltransferase (alkyltransferase) which is known to repair nitrosourea-induced cytotoxic DNA damage. Alkyltransferase activity varied over a similar wide range in 25 colon cancer biopsies and 14 colon cancer cell lines but the activity was not correlated with differentiation status, Dukes' classification or in vitro growth characteristics. 1,3-Bis-(2-chloroethyl)-1-nitrosourea (BCNU) resistance and alkyltransferase activity were highly correlated (R2 = 0.929, P less than 0.001) in 7 different colon cancer cell lines, suggesting that the alkyltransferase is an important component of nitrosourea resistance in colon cancer cells. In the BCNU-resistant, high alkyltransferase VACO 6 cell line, inactivation of the alkyltransferase by O6-methylguanine caused a proportional decrease in the BCNU IC50, consistent with that predicted by the regression line. Enzyme inactivation was also associated with a marked increase in DNA cross-link formation. Because alkyltransferase correlates with BCNU resistance in colon cancer, and resistance can be reversed by inactivating the protein, the alkyltransferase may have an important role in nitrosourea resistance in human colon cancer cells. These data provide the rationale for clinical trials in colon cancer with biochemical modulators of the alkyltransferase to increase the therapeutic response to nitrosoureas.     

DNA repair, ADP-ribosylation and pyridine nucleotide metabolism as targets for cancer chemotherapy

DNA repair mechanisms serve as useful targets for modulating the cytotoxic and chemotherapeutic effects of many agents whose mechanism of action involves the induction of DNA damage. For example, the modified base O6-methylguanine can inactivate the repair protein O6-alkylguanine alkyltransferase, thereby sensitizing cells to the cytotoxic effects of clinically useful nitrosoureas such as BCNU. Some of the cytotoxic DNA adducts induced by BCNU are repaired by O6-alkylguanine alkyltransferase; thus, inactivation of the protein by O6-methylguanine converts cells that are relatively resistant to BCNU into sensitive cells. Another cellular enzyme, poly(ADP-ribose) polymerase, responds to DNA strand breaks by cleaving its substrate, NAD+, and using the resultant ADP-ribose moieties to synthesize homopolymers of ADP-ribose. The use of agents such as benzamide derivatives to inhibit enzyme function results in the accumulation of DNA strand breaks and potentiates the tumoricidal effects of some DNA strand-breaking agents such as bleomycin. Poly(ADP-ribose) polymerase can also affect pyridine nucleotide metabolism in a manner that initiates biochemical alterations leading directly to cell death. Thus, the amount of NAD used in the synthesis of poly(ADP-ribose) is dependent on the number of DNA strand breaks present in the cells. DNA damage can sufficiently activate the enzyme to rapidly consume NAD and consequently deplete ATP levels, resulting in the cessation of all energy-dependent functions and cell death. Understanding this biochemical pathway that leads to cell death provides a new basis for modulating chemotherapy. For example, agents such as Tiazofurin and/or 6-aminonicotinamide can each be used to alter pyridine nucleotide metabolism, lower NAD pools and potentiate the cytotoxic effects of other chemotherapeutic agents whose primary target is the induction of DNA damage.     

O~6-苄基鸟嘌呤增强 1,3-二 (2 -氯乙基)-亚硝基脲对人肝癌细胞及其移植瘤的抗肿瘤作用(英文)

应用噻唑蓝 (MTT)法检测 O6-苄基鸟嘌呤(O6- BG)与 1 ,3-二 (2 -氯乙基 ) -亚硝基脲 (BCNU)合用的细胞毒作用及透射电镜检测凋亡细胞的方法研究了 O6- BG对 O6-烷基鸟嘌呤 - DNA烷基转移酶(O6- AGT )阳性的人肝癌细胞 SMMC- 772 1对BCNU细胞毒作用敏感性的影响及其与 BCNU合用治疗移植瘤的协同效果 .结果显示 :1 .5- 6.0 mg· L-1的 O6- BG预先作用 2 h后 ,SMMC- 772 1细胞对 BCNU的敏感性明显增加 ;0 .75- 6.0 mg· L-1的 O6- BG可完全快速地抑制肿瘤细胞的 AGT活性并持续 1 2 h;ip 90 mg· kg-1的 O6- BG预处理 2 h后给予 2 5mg·kg-1的 BCNU治疗 ,可使动物 sc接种的人肝癌移植瘤生长延迟 38.6d,诱导肿瘤细胞凋亡 ,并且可明显抑制肿瘤组织的转移酶活性 .说明 O6- BG与 BCNU合用于 AGT阳性的肿瘤将具有明显的治疗效果     

DNA damage induced by temozolomide signals to both ATM and ATR: role of the mismatch repair system

The mammalian mismatch repair (MMR) system has been implicated in activation of the G(2) checkpoint induced by methylating agents. In an attempt to identify the signaling events accompanying this phenomenon, we studied the response of MMR-proficient and -deficient cells to treatment with the methylating agent temozolomide (TMZ). At low TMZ concentrations, MMR-proficient cells were growth-inhibited, arrested in G(2)/M, and proceeded to apoptosis after the second post-treatment cell cycle. These events were accompanied by activation of the ATM and ATR kinases, and phosphorylation of Chk1, Chk2, and p53. ATM was activated later than ATR and was dispensable for phosphorylation of Chk1, Chk2, and p53 on Ser15 and for triggering of the G(2)/M arrest. However, it conferred protection against cell growth inhibition induced by TMZ. ATR was activated earlier than ATM and was required for an efficient phosphorylation of Chk1 and p53 on Ser15. Moreover, abrogation of ATR function attenuated the TMZ-induced G(2)/M arrest and increased drug-induced cytotoxicity. Treatment of MMR-deficient cells with low TMZ concentrations failed to activate ATM and ATR and to cause phosphorylation of Chk1, Chk2, and p53, as well as G(2)/M arrest and apoptosis. However, all these events occurred in MMR-deficient cells exposed to high TMZ concentrations, albeit with faster kinetics. These results demonstrate that TMZ treatment activates ATM- and ATR-dependent signaling pathways and that this process is absolutely dependent on functional MMR only at low drug concentrations.     

The repair of the tobacco specific nitrosamine derived adduct O6-[4-Oxo-4-(3-pyridyl)butyl]guanine by O6-alkylguanine-DNA alkyltransferase variants

The tobacco specific nitrosamine, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), a potent pulmonary carcinogen, both methylates and pyridyloxobutylates DNA. Both reaction pathways generate promutagenic O6-alkylguanine adducts. These adducts, O6-methylguanine (O6-mG) and O6-[4-oxo-4-(3-pyridyl)butyl]guanine (O6-pobG), are repaired by O6-alkylguanine-DNA alkyltransferase (AGT). In this report, we demonstrate that pyridyloxobutyl DNA adducts are repaired by AGT in a reaction that results in pyridyloxobutyl transfer to the active site cysteine. Because minor changes within the binding pocket of AGT can alter the ability of this protein to repair bulky O6-alkylguanine adducts relative to O6-mG, we explored the ability of AGTs from different species as well as several human AGT variants and mutants to discriminate between O6-mG or O6-pobG adducts. We incubated proteins with equal molar amounts of oligodeoxynucleotides containing site specifically incorporated O6-mG or O6-pobG and measured repair. Bacterial AGTs poorly repaired O6-pobG. Mouse and rat AGT repaired both adducts at comparable rates. Wild-type human AGT, variant I143V/K178R, and mutant N157H repaired O6-mG approximately twice as fast as O6-pobG. Human variant G160R and mutants P140K, Y158H, G156A, and E166G did not repair O6-pobG until all of the O6-mG was removed. To understand the role of adduct structure on relative repair rates, the competition experiments were repeated with two other bulky O6-alkylguanine adducts, O6-butylguanine (O6-buG) and O6-benzylguanine (O6-bzG). The proteins displayed similar repair preference of O6-mG relative to O6-buG as observed with O6-pobG. In contrast, all of the mammalian proteins, except the mutant P140K, preferentially repaired O6-bzG. These studies indicate that the rate of repair of O6-pobG is highly dependent on protein structure. Inefficient repair of O6-pobG by bacterial AGT explains the high mutagenic activity of this adduct in bacterial systems. In addition, differences observed in the repair of this adduct by mammalian proteins may translate into differences in sensitivity to the mutagenic and carcinogenic effects of NNK or other pyridyloxobutylating nitrosamines.     

AKT is activated in an ataxia-telangiectasia and Rad3-related-dependent manner in response to temozolomide and confers protection against drug-induced cell growth inhibition

The phosphatidylinositol 3-kinase/AKT pathway is activated frequently in human cancer, and it has been implicated in tumor cell proliferation, survival, and chemoresistance. In this study, we addressed the role of AKT in cellular responses to the therapeutic methylating agent temozolomide (TMZ), and we investigated the possible link between TMZ-induced modulation of AKT function and activation of ataxia-telangiectasia and Rad3-related (ATR)- and ataxia telangiectasia mutated (ATM)-dependent signaling pathways. We found that clinically relevant concentrations of TMZ caused activation of endogenous AKT in lymphoblastoid cells, and in colon and breast cancer cells, and that this molecular event required a functional mismatch repair system. Transfection of a dominant-negative kinase-dead form of AKT1 into breast cancer cells abrogated TMZ-induced activation of endogenous AKT, and it markedly enhanced cell sensitivity to the drug. Likewise, exposure of the MMR-proficient cell lines to the AKT inhibitor D-3-deoxy-2-O-methyl-myo inositol 1-[(R)-2-methoxy-3-(octadecyloxy)-propyl hydrogen phosphate] (SH-5) impaired AKT phosphorylation in response to TMZ, and it significantly increased cell chemosensitivity. Furthermore, small interfering RNA (siRNA)-mediated reduction of AKT1 expression in colon cancer cells potentiated the growth inhibitory effects of TMZ. Inhibition of ATM expression in colon cancer cells by siRNA did not impair TMZ-induced activation of AKT, whereas siRNA-mediated inhibition of ATR prevented AKT activation in response to the drug and increased cell chemosensitivity. These results strongly support the hypothesis that clinical benefit could be obtained by combining TMZ with inhibitors of the AKT pathway. Moreover, they provide the first evidence of a novel function of ATR as an upstream activator of AKT in response to DNA damage induced by O(6)-guanine-methylating agents.     

S-alkylthiolation of O6-methylguanine-DNA-methyltransferase (MGMT) to sensitize cancer cells to anticancer therapy

O6-methylguanine DNA methyltransferase/O6-alkylguanine DNA alkyltransferase (MGMT/AGT) removes alkyl adducts from the O6-position of guanine in DNA. Expression of MGMT in human cancers has been associated with resistance to therapies using alkylating agents. MGMT promoter methylation regulates its expression and response to alkylating agents. A combination of O6-benzylguanine-based inhibitors of MGMT with alkylating agents improved the efficacy. However, this is associated with enhanced cytotoxicity and the induction of GC to AT transition mutations presumably also in progenitor/stem cells. A few recent studies have described analogs of O6-benzylguanine targeting defined pathways of cancer cells that can be used to improve the selectivity of O6-benzylguanine-based inhibitors for cancer cells. Therefore, MGMT inhibitor targeting represents a reliable strategy for improving cancer therapy with alkylating agents.     

The therapeutic potential of O6-alkylguanine DNA alkyltransferase inhibitors

Resistance to O(6-)alkylating agents can be overcome by depletion of the DNA repair protein, O(6)-alkylguanine DNA alkyltransferase. Inhibitors of this protein act as pseudosubstrates and, so far, O(6)-benzylguanine and lomeguatrib have been tested in clinical trials. Inherently non-toxic, optimum doses for protein depletion have been established for both agents. Myelosuppression of alkylating agents is significantly enhanced when used in combination with these agents, necessitating significant reductions in standard doses. Consequently, no improvement in efficacy is seen. Strategies to limit myelotoxicity are complex and will be very difficult to apply clinically. O(6)-alkylguanine DNA alkyltransferase inhibition may also potentiate the toxicity of other agents such as cyclophosphamide and irinotecan. Other mechanisms of DNA repair are also important and drugs targeting some of these systems are in early phase clinical trials.     

2-amino-O4-benzylpteridine derivatives: potent inactivators of O6-alkylguanine-DNA alkyltransferase

2-amino-O4-benzylpteridine (1), 2-amino-O4-benzyl-6,7-dimethylpteridine (2), 2-amino-O4-benzyl-6-hydroxymethylpteridine (4), 2-amino-O4-benzylpteridine-6-carboxylic acid (5), 2-amino-O4-benzyl-6-formylpteridine (6), and O4-benzylfolic acid (7) are shown to be as potent or more potent inactivators of the human DNA repair protein O6-alkylguanine-DNA alkyltransferase (alkyltransferase) in vitro than O6-benzylguanine, the prototype alkyltransferase inactivator currently in clinical trials. Additionally, the negatively charged (at physiological pH) inactivators 2-amino-O4-benzylpteridine-6-carboxylic acid (5) and O4-benzylfolate (7) are far more water soluble than O6-benzylguanine. The activity of O4-benzylfolic acid (7) is particularly noteworthy because it is roughly 30 times more active than O6-benzylguanine against the wild-type alkyltransferase and is even capable of inactivating the P140K mutant alkyltransferase that is resistant to inactivation by O6-benzylguanine. All the pteridine derivatives except 2-amino-O4-benzylpteridine-6-carboxylic acid are effective in enhancing cell killing by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU). However, the effectiveness of O4-benzylfolate as an adjuvant for cell killing by BCNU appears to be a function of a cell's alpha-folate receptor expression. Thus, O4-benzylfolate is least effective as an adjuvant in A549 cells (which express little if any receptor), is moderately effective in HT29 cells (which express low levels of the receptor), but is very effective in KB cells (which are known to express high levels of the alpha-folate receptor). Therefore, O4-benzylfolic acid shows promise as an agent for possible tumor-selective alkyltransferase inactivation, which suggests it may prove to be superior to O6-benzylguanine as a chemotherapy adjuvant.     

Mammalian cells expressing Escherichia coli O6-alkylguanine-DNA alkyltransferases are hypersensitive to dibromoalkanes.

The effect of expression of the DNA repair protein, O6-alkylguanine-DNA alkyltransferase, on the growth inhibitory effects of the dibromoalkanes (DBA) dibromomethane (DBM) and dibromoethane (DBE) was determined in Chinese hamster lung fibroblasts transfected with and expressing high levels of the Escherichia coli alkyltransferase (ATase) genes. These included the ogt gene and complete or truncated versions of the E. coli ada gene encoding either O6-alkylguanine (O6-alkG) or alkylphosphotriester (alkPT) ATase activities. The functional activity of the ATase in these cells was demonstrated by in vitro assay of cell extracts using 3H-methylated DNA as a substrate, and by the protection they provided against the growth inhibitory effects of methylating agents N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and N-methyl-N-nitrosourea (MNU) and the chloroethylating agent 1, 3-bis(2-chloroethyl)-1-nitrosourea (BCNU). However, cells expressing the full length or the O6-alkG ATase region, but not the alkPT ATase region, of Ada were found to be more sensitive to the growth inhibitory effects of the DBA; Ogt expression sensitized cells to DBM but not significantly to DBE. Addition of DBA to cell extracts depleted O6-alkG ATase activity on the methylated DNA substrate, but had no effect on alkPT ATase activity. This suggests that ATase-mediated sensitization of the intact cells may be related to the inactivation of the ATase protein. Addition to the cell culture medium of GSH or buthionine sulfoximine in attempts to augment or deplete cellular levels of GSH had no marked effect on the ATase-mediated sensitization to DBA. This suggests that rather than GSH-mediated DNA damage, the effect may be mediated by a DNA adduct caused by the oxidative metabolic pathway. These observations indicate that expression of ATase may have a detrimental effect on cellular sensitivity to environmentally relevant alkylating agents.     

Decreased cisplatin damage-dependent DNA synthesis in cellular extracts of mismatch repair deficient cells

The proficiency of both nucleotide excision repair (NER) and DNA mismatch repair (MMR) influences cellular sensitivity to cisplatin (cis-diamminedichloroplatinum). To gain further insight into how MMR may influence platinum drug sensitivity, the effect of loss of MMR on repair synthesis was measured in vitro by a commonly used method that relies on whole-cell extracts to drive [alpha-32P]dATP incorporation into cisplatin-damaged plasmid DNA. Extracts evaluated include those from cells with or without functional hMLH1 (HCT116+ch2 versus HCT116+ch3, respectively) and hMSH2 (HEC59 versus HEC59+ch2, respectively). Loss of MMR in the HCT116 system was associated with a 2.8-fold reduction in cisplatin damage-specific DNA synthesis, whereas it was associated with a 3.0-fold reduction in the HEC59 system, suggesting that a decrease in the ability to repair cisplatin-damaged DNA accompanies loss of MMR. An in vitro DNA excision assay that utilized a substrate containing a site-specific cisplatin adduct was performed. Using this highly NER-specific assay, no significant difference was apparent between the extracts derived from NER-proficient versus -deficient cells. These and other data lead us to suggest that the increase in apparent repair synthesis in platinum-damaged plasmids by extracts from MMR-proficient versus -deficient cellular extracts may reflect a distinct and possibly adverse DNA synthetic process rather than productive NER.     

O6-(4-bromothenyl)guanine (PaTrin-2), a novel inhibitor of O6-alkylguanine DNA alkyl-transferase, increases the inhibitory activity of temozolomide against human acute leukaemia cells in vitro.

Anti-tumour activity of triazene compounds of clinical interest [i.e. dacarbazine and temozolomide (TMZ)] relies mainly on the generation of methyl adducts to purine bases of DNA. Two DNA repair enzyme systems, i.e. the O6-guanine-alkyl-transferase (MGMT) and mismatch repair (MMR), play a predominant role in conditioning the cytotoxic effects of triazenes. In particular, high levels of MGMT associated with target cells are responsible of resistance to triazenes. On the contrary, the presence of MMR is required for the cytotoxic effects of these compounds. Previous studies performed by our group and a more recent clinical investigation reported by Karen Seiter, pointed out that triazene compounds could play an important role in the treatment of refractory acute leukaemia. Leukaemia blasts, especially of lymphoblastic leukaemia, show frequently high levels of MGMT activity. Therefore, it reasonable to hypothesize that combined treatment of leukaemia patients with triazene compounds along with MGMT inhibitors could lead to a better control of the disease. PaTrin-2 (O6-(4-bromothenyl)guanine, PAT) is a potent and scarcely toxic MGMT inhibitor recently introduced in clinical trials. This drug is used in combination with triazene compounds in order to augment their anti-tumour efficacy against neoplastic cells endowed with high MGMT activity. The present report describes, for the first time, pre-clinical in vitro studies on the cytotoxic activity of combined treatment with PAT+TMZ against long-term cultured leukaemia cells and primary leukaemia blasts obtained from patients with acute lymphoblastic leukaemia or acute myeloblastic leukaemia. The results point out that, both in long-term cultured leukaemia cell lines and in primary blast samples, PAT could improve dramatically the sensitivity of malignant cells to the cytotoxic effects of TMZ. This sensitizing effect is detectable when leukaemia cells show resistance mechanisms based on a MGMT-proficient phenotype. On the contrary, when resistance to TMZ is dependent on MMR deficiency, no influence of PAT can be detected in various experimental conditions. In conclusion, these results appear to provide disease-oriented rational basis to design novel clinical protocols for the treatment of acute leukaemia with combined administration of PAT and triazene compounds.     

Role of pre- and post-replicative mismatch repair in cytotoxicity of methylating antitumor agents (a review)

The review considers modern data on the pre- and post-replicative repair of DNA damage induced by methylating agents such as N-methyl-N-nitrosourea, temozolomide, procarbazine, dacarbazine, and aranoza. These drugs are used in the treatment of various types of tumors including Hodgkin’s disease, brain tumors, disseminated melanoma, and lymphoproliferative diseases. Resistance (both intrinsic and acquired) to methylating agents is an important problem in cancer chemotherapy. The cytotoxicity of methylating agents depends on O6-methylguanine-DNA-methyltransferase (MGMT) activity (prereplicative repair). Several preclinical and clinical studies have demonstrated that postreplicative mismatch repair (MMR) is responsible to a high degree for the tumor cell resistance to the methylating agents. MMR in experimental studies is determined using expression of the main proteins hMLH1, hMSH2, and hMSH6 involved in the activity of the MMR system. Resistance to methylating agents is due to hypermethylation of promoters of the corresponding genes. The deficiency of hMLH1, hMSH2, and hMSH6 in tumors and lymphocytes after pre-operative neoadjuvant chemotherapy may serve as an independent predictor of poor prognosis in the development of disease. Translated from Khimiko-Farmatsevticheskii Zhurnal, Vol. 43, No. 2, pp. 3–6, February, 2009.     

Triazene compounds: mechanism of action and related DNA repair systems.

Triazene compounds of clinical interest (i.e. dacarbazine and temozolomide) are a group of alkylating agents with similar chemical, physical, antitumour and mutagenic properties. Their mechanism of action is mainly related to methylation of O(6)-guanine, mediated by methyldiazonium ion, a highly reactive derivative of the two compounds. The cytotoxic/mutagenic effects of these drugs are based on the presence of DNA O(6)-methylguanine adducts that generate base/base mismatches with cytosine and with thymine. These adducts lead to cell death, or if the cell survives, provoke somatic point mutations represented by C:G-->T:A transition in DNA helix. Triazene compounds have excellent pharmacokinetic properties and limited toxicity. Dacarbazine requires hepatic activation whereas temozolomide is spontaneously converted into active metabolite in aqueous solution at physiological pH. Moreover, temozolomide is fully active when administrated orally (100% bioavailability). The biological effects of triazene compounds and cell resistance to them depend on at least three DNA repair systems, (a) O(6)-alkylguanine-DNA-alkyltransferase, called also methyl-guanine methyl-transferase (MGMT); (b) mismatch repair (MMR), and (c) base excision repair (BER). MGMT is a small enzyme-like protein that removes small alkyl adducts from the O(6) position of DNA guanine through a stoichiometric and auto-inactivating reaction. This reaction consists in a covalent transfer of the alkyl group from the alkylated site in DNA to an internal cysteine residue of MGMT protein. High levels of MGMT are responsible for normal and tumour cell resistance to triazenes. Therefore, pre-treatment with MGMT inhibitors - i.e. O(6)-benzylguanine or O(6)-(4-bromotenyl)guanine (Lomeguatrib) - is followed by a great increase in the activity of triazenes against target cells expressing high MGMT levels. MMR is represented by a protein complex dedicated to the repair of biosynthetic errors generated during DNA replication. The MMR system recognizes base mismatches and insertion-deletion loops, cuts the nucleotide sequence containing the lesion, and restores the correct base sequence. Therefore, not only MGMT but also MMR is involved in target cell susceptibility to triazenes. However, the system does not suppress, but instead promotes the cytotoxic effects of triazenes. In fact, MMR is not able to repair the incorrect base pairing determined by treatment with triazenes and, according to a predominant hypothesis, it causes reiterated "futile" attempts of damage repair leading to the activation of cell cycle arrest and apoptosis. BER removes lesions due to cellular metabolism, or to physical or chemical agents. BER is able to repair N(7)-methylguanine and N(3)-methyladenine determined by treatment with triazenes. Therefore, triazene compounds can also kill tumour cells by a N(3)-methyladenine-mediated mechanism if BER activity is inhibited by chemical agents (i.e. PARP inhibitors). In conclusion, in selected cases, triazenes can represent a therapeutic alternative to treatment of neoplastic diseases including haematological malignancies. Moreover, the susceptibility of neoplastic cells to these compounds can be substantially increased through pharmacological modulation of the expression level and functional activity of DNA repair enzymes.     

Differences in the rate of repair of O6-alkylguanines in different sequence contexts by O6-alkylguanine-DNA alkyltransferase

O6-alkylguanine-DNA alkyltransferase (AGT) repairs O6-alkylguanine residues at different rates depending on the identity of the alkyl group as well as the sequence context. To elucidate the mechanism(s) underlying the differences in rates, we examined the repair of five alkyl groups in three different sequence contexts. The kinact and Km values were determined by measuring the rates of repair of oligodeoxynucleotide duplexes containing the O6-alkylguanine residues with various concentrations of AGT in excess. The time course of the reactions all followed pseudo-first-order kinetics except for one of the O6-ethylguanine substrates, which could be analyzed in a two-phase exponential equation. The differences in rates of repair between the different alkyl groups and the different sequence contexts are dependent on rates of alkyl transfer and not substrate recognition. The relative rates of reaction are in general benzyl>methyl>ethyl>2-hydroxyethyl>4-(3-pyridyl)-4-oxobutyl, but the absolute rates are dependent on sequence. The kinact values between benzyl and 4-(3-pyridyl)-4-oxobutyl range from 2300 to 350000 depending on sequence. The sequence-dependent variation in kinact varied the most for O6-[4-(3-pyridyl)-4-oxobutyl]guanine, which ranged from 0.022 to 0.000016 s(-1). The results are consistent with a mechanism in which the O6-alkylguanine can bind to AGT in either a reactive or an unreactive orientation, the proportion of which depends on the sequence context.     

DNA repair as regulatory factor in the organotropy of alkylating carcinogens.

Monofunctional alkylating agents which react predominantly at nitrogen atoms in DNA bases (e.g. alkyl methanesulphonates, dialkylsulfates) are generally weak carcinogens whereas compounds which lead extensively to oxygen alkylation (e.g. alkylnitrosoureas, dialkylnitrosamines, dialkyl-aryltriazenes) often exhibit a strong carcinogenic activity. O6-Alkylation of guanine is a promutagenic DNA modification possibly involved in the initiation of malignant transformation. O6-Alkylguanine can be enzymically excised and in the rat the induction of neural, renal and colonic tumors by alkylnitrosoureas, 3,3-dimethyll-phenyltriazene, dimethylnitrosamine and 1,2-dimethylhydrazine correlates with an excision repair deficiency in the target tissue. However, species and strain differences in the response to these carcinogens are not paralleled by differences in the excision repair capacity for O6-alkylguanine. Preliminary data suggest that in rat liver there is an inducible enzyme for the removal of O6-alkylguanine from DNA.     

Biochemical changes associated with a multidrug-resistant phenotype of a human glioma cell line with temozolomide-acquired resistance

Temozolomide (TMZ) is a newly approved alkylating agent for the treatment of malignant gliomas. To investigate resistance mechanisms in a multidrug therapeutic approach, a TMZ-resistant human glioma cell line, SF188/TR, was established by stepwise exposure of human SF188 parental cells to TMZ for approximately 6 months. SF188/TR showed 6-fold resistance to TMZ and cross-resistance to a broad spectrum of other anticancer agents that included 3-5-fold resistance to melphalan (MEL), gemcitabine (GEM), paclitaxel (PAC), methotrexate (MTX), and doxorubicin (DOX), and 1.6-2-fold resistance to cisplatin (CDDP) and topotecan (TPT). Alkylguanine alkyltransferase (AGT) activity was increased significantly in the resistant cell line compared with the parental cell line (P<0.05), whereas no significant differences occurred in the cellular uptake of TMZ and PAC between resistant and parental cells. Depletion of AGT by O(6)-benzylguanine significantly increased the cytotoxicity of TMZ in both the sensitive and resistant cell lines, but did not influence the cytotoxicity of the other drugs tested. Treatment with TMZ caused SF188 cells to accumulate in S phase, whereas SF188/TR cells were unaffected. Expression of Bcl-2 family members in SF188/TR cells compared with SF188 cells indicated that the pro-apoptotic proteins (i.e. Bad, Bax, Bcl-X(S)) were reduced 2-4-fold in the resistant cell line, whereas the anti-apoptotic proteins Bcl-2 and Bcl-X(L) were expressed at similar levels in both cell lines. In conclusion, the mechanism of resistance of SF188/TR cells to TMZ involved increased activity of AGT, a primary resistance mechanism, whereas the broad cross-resistance pattern to other anticancer drugs was due to a common secondary resistance mechanism related to alterations in the relative expression of the pro-apoptotic and anti-apoptotic proteins.     

alpha-Difluoromethylornithine effects on nitrosourea-induced cytotoxicity and crosslinking in a methylation excision repair positive (MER+) human cell line

We investigated the cytotoxic effects of nitrosoureas with and without a 42-hr preincubation with the ornithine decarboxylase (EC 4.1.1.17) inhibitor alpha-difluoromethylornithine (DFMO, 1 mM) in a MER+ (methylation excision repair positive) human cell line. DFMO combined with a chloroethyl nitrosourea [1,3-bis-(2-chloroethyl)-1-nitrosourea (BCNU) or 1-(2-chloroethyl)-1-nitrosourea (CNU)] yielded increased toxicity with D37 ratios of 1.9 and 3.3 respectively. There was no enhanced toxicity with the monofunctional nitrosourea 1-ethyl-1-nitrosourea (ENU). BCNU or CNU did not induce DNA-DNA interstrand crosslinks in cells with or without a DFMO pretreatment. DNA single-strand breakage was not increased by addition of DFMO. BCNU-induced DNA-protein crosslinking was decreased in cells pretreated with DFMO. These findings are similar to those in MER- cells in that the chloroethyl carbonium alkylating species is required for the enhanced cytotoxicity seen with DFMO. The ability to form DNA interstrand crosslinks, however, does not appear to be necessary for this toxicity enhancement.