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     

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.     

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.     

The role of isocyanates in the toxicity of antitumour haloalkylnitrosoureas

The cytotoxicity of the antitumour nitrosoureas BCNU and CCNU and the isocyanates which they liberate (chloroethylisocyanate and cyclohexylisocyanate respectively) has been measured utilising an in vitro-in vivo bioassay. Lines of the TLX5 lymphoma and L1210 leukaemia were used which were either sensitive or resistant to nitrosoureas in vivo. An estimated logarithmic cell kill produced by each compound in vitro (before injecting the cells into animals) was calculated by reference to assays of the survival time of animals given from 2 × 10⁵ to 2 × 10⁰ cells of each line. Resistance to both BCNU and CCNU was observed in vitro in the cell lines of the TLX5 lymphoma made resistant to either BCNU or a dimethyltriazene in vivo. The latter tumour was cross-resistant in vivo to nitrosoureas. Resistance in vitro to nitrosoureas was also observed in a line of L1210 leukaemia which had had resistance to BCNU induced in vivo. The nitrosourea resistant TLX5 lymphomas were cross-resistant in vitro to both cyclohexylisocyanate and chloroethylisocyanate whereas the nitrosourea resistant L1210 line showed no cross-resistance to cyclohexylisocyanate and marginal cross-resistance to chloroethylisocyanate. The results suggest that the TLX5 lymphoma, which is naturally resistant to alkylating agents of the 2-chloroethylamine type, may be sensitive in vivo to nitrosoureas as a consequence of the intracellular release of isocyanates. This hypothesis was supported by the finding that the resistant TLX5 lymphoma showed no cross-resistance to other electrophilic agents, for example formaldehyde, monomethyltriazene or HN2. The transport of nitrosoureas into the sensitive and resistant cell lines was similar in profile and there was no difference in the concentration of non-protein thiols.     

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.     

Studies of the mechanism of action of the tumour-inhibitory nitrosoureas.

BCNU [1,3 bis-(2-chloroethyl)-1-nitrosourea] and some related nitrosoureas have been shown to have a wide spectrum of action against a number of transplanted rodent tumours. No correlation was found between the chemical instability of a nitrosourea and its antitumour activity. Unlike difunctional alkylating agents, the nitrosoureas inhibit the incorporation of tritiated precursors in DNA, RNA and protein to equal extents, the inhibition of tritiated thymidine incorporation into DNA occurring within 5 min of incubating cells with BCNU. Although the biological half life of BCNU was found to be very short (15 min by bioassay) a single injection was as effective against the established and widely-disseminated TLX5 lymphoma as against the early transplant. BCNU interfered specifically with the incorporation of labelled thymidine triphosphate into DNA, but no inhibition of DNA polymerase could be demonstrated at physiological dose levels. In their mechanism of action and in their biological properties the tumour inhibitory nitrosoureas are quite distinct from the bifunctional alkylating agents.     

Formation and disappearance of DNA interstrand cross-links in human colon tumor cell lines with different levels of resistance to chlorozotocin.

Three human colon tumor (HCT) cell lines, designated C, Moser and 116, exhibiting a gradation of resistance to chlorozotocin, a glucose-linked chloroethylnitrosourea (1-, 2.9-, and 5.8-fold respectively) were examined to assess the determinants of drug sensitivity. Although the O6-alkylguanine-DNA transferase content was relatively higher in the most resistant 116 cells than in the sensitive cell line C, its level in Moser cells did not correlate with the intermediate chlorozotocin sensitivity. Glutathione content in these tumor cell lines did not show a parallelism with drug resistance. The ethidium bromide fluorescence assay was used to quantitate the kinetics of DNA interstrand cross-link formation and its removal after drug exposure. The peak levels of DNA interstrand cross-links induced in HCT cells correlated with their resistance to chlorozotocin with cross-link indices of 0.03, 0.10 and 0.20, respectively, for 116, Moser and C cell lines. All three cell lines demonstrated DNA cross-link repair to different extents. While the smaller number of cross-links formed in resistant 116 and Moser cells were eliminated in a rapid phase of repair, the lesions formed at a much greater frequency in C cells remained largely unrepaired. These results draw attention to the role of increased DNA cross-link repair as a mechanism of nitrosourea resistance in the HCT cells studied.     

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.     

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.     

Substitution of aminomethyl at the meta-position enhances the inactivation of O6-alkylguanine-DNA alkyltransferase by O6-benzylguanine

O(6)-Benzylguanine is an irreversible inactivator of O(6)-alkylguanine-DNA alkyltransferase currently in clinical trials to overcome alkyltransferase-mediated resistance to certain cancer chemotherapeutic alkylating agents. In order to produce more soluble alkyltransferase inhibitors, we have synthesized three aminomethyl-substituted O(6)-benzylguanines and the three methyl analogs and found that the substitution of aminomethyl at the meta-position greatly enhances inactivation of alkyltransferase, whereas para-substitution has little effect and ortho-substitution virtually eliminates activity. Molecular modeling of their interactions with alkyltransferase provided a molecular explanation for these results. The square of the correlation coefficient (R(2)) obtained between E-model scores (obtained from GLIDE XP/QPLD docking calculations) vs log(ED(50)) values via a linear regression analysis was 0.96. The models indicate that the ortho-substitution causes a steric clash interfering with binding, whereas the meta-aminomethyl substitution allows an interaction of the amino group to generate an additional hydrogen bond with the protein.     

Mechanisms underlying resistance to streptozotocin in Mer+ and Mer- human tumor lines

Streptozotocin (STZ) is a monofunctional nitrosourea employed in the treatment of patients with islet cell tumors. To analyze the role of DNA repair mechanisms in causing resistance to STZ, we evaluated the cytotoxicity by this agent in three human tumor lines that differ with respect to their abilities to repair N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) damaged virus (the Mer phenotype). HT-29, A2182, and BE human tumor lines are high, intermediate and low, respectively, with regard to features that define the Mer phenotype. Our results demonstrated that the order of resistance to STZ is HT-29 greater than A2182 greater than BE. The degree of inhibition of DNA synthesis by STZ was in the following order: BE greater than A2182 greater than HT-29. O6-Alkyltransferase activity was increased markedly in HT-29 cells compared to A2182 cells which, in turn, had significantly increased levels compared to the BE line. Other potential factors such as 3-methyladenine DNA glycosylase activity, the induction by STZ of single-stranded DNA breaks, and the kinetics of repair of these breaks do not clearly underlie differences in cytotoxicity among the three tumor lines. However, increased topoisomerase II activity, as well as enhanced sensitivity to agents that interact with topoisomerase II, was present in A2182 cells compared to BE cells. These findings demonstrate that while O6-alkyltransferase contributes to resistance to STZ in some Mer+ tumor lines, other mechanisms may also contribute to resistance to this agent.     

Protection by Salvia extracts against oxidative and alkylation damage to DNA in human HCT15 and CO115 cells

DNA damage induced by oxidative and alkylating agents contributes to carcinogenesis, leading to possible mutations if replication proceeds without proper repair. However, some alkylating agents are used in cancer therapy due to their ability to induce DNA damage and subsequently apoptosis of tumor cells. In this study, the genotoxic effects of oxidative hydrogen peroxide (H?O?) and alkylating agents N-methyl-N-nitrosourea (MNU) and 1,3-bis-(2-chloroethyl)-1-nitosourea (BCNU) agents were examined in two colon cell lines (HCT15 and CO115). DNA damage was assessed by the comet assay with and without lesion-specific repair enzymes. Genotoxic agents were used for induction of DNA damage in both cell lines. Protective effects of extracts of three Salvia species, Salvia officinalis (SO), Salvia fruticosa (SF), and Salvia lavandulifolia (SL), against DNA damage induced by oxidative and alkylating agents were also determined. SO and SF protected against oxidative DNA damage in HCT15 cells. SO and SL decreased DNA damage induced by MNU in CO115 cells. In addition to chemopreventive effects of sage plant extracts, it was also important to know whether these plant extracts may interfere with alkylating agents such as BCNU used in cancer therapy, decreasing their efficacy. Our results showed that sage extracts tested and rosmarinic acid (RA), the main constituent, protected CO115 cells from DNA damage induced by BCNU. In HCT15 cells, only SF induced a reduction in BCNU-induced DNA damage. Sage water extracts and RA did not markedly change DNA repair protein expression in either cell line. Data showed that sage tea protected colon cells against oxidative and alkylating DNA damage and may also interfere with efficacy of alkylating agents used in cancer therapy.     

Mechanism of action of the nitrosoureas -- III. Reactions of bis-chloroethyl nitrosourea and bis-fluoroethyl nitrosourea with adenosine.

Previous papers in this series have provided evidence for the formation of haloethyl nucleoside derivatives from the interaction of the therapeutic nitrosoureas with cytidine and guanosine. Such derivatives could be important in explaining the cytotoxic action of bis-chloroethyl nitrosourea (BCNU), bis-fluoroethyl nitrosourea (BFNU), and related therapeutic agents. We now report the formation of 1-haloethyl adenosines from the reaction of BCNU and BFNU with adenosine. These 1-substituted haloethyl adenosines cyclize to form 1,N⁶-ethanoadenosine: 1-chloroethyladenosine with a half-life of 20 min in neutral aqueous solution at 37°, and 1-fluoroethyladenosine with a half-life of 20 hr under the same conditions. 1-Hydroxyethyladenosine is also a major product of the reaction of either BCNU or BFNU with adenosine, but it is not formed from the hydrolysis of either 1-haloethyladenosine. Accordingly, a reaction mechanism involving a cyclized nitrosourea derivative is proposed to explain the formation of this and other hydroxyethyl nucleosides.     

Beta-glucuronidase-cleavable prodrugs of O6-benzylguanine and O6-benzyl-2'-deoxyguanosine

Glucuronic acid linked prodrugs of O(6)-benzylguanine and O(6)-benzyl-2'-deoxyguanosine were synthesized. The prodrugs were found to be quite stable at physiological pH and were more than 200-fold less active as inactivators of O(6)-alkylguanine-DNA alkyltransferase (alkyltransferase) than either O(6)-benzylguanine or O(6)-benzyl-2'-deoxyguanosine. Beta-glucuronidase from both Escherichia coli and bovine liver cleaved the prodrugs efficiently to release O(6)-benzylguanine and O(6)-benzyl-2'-deoxyguanosine, respectively. In combination with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), the prodrugs were not effective adjuvants for HT29 cell killing. However, as expected, incubation of these prodrugs with beta-glucuronidase in the culture medium led to much more efficient cell killing by BCNU as a result of the liberation of the more potent inactivators, O(6)-benzylguanine and O(6)-benzyl-2'-deoxyguanosine. These prodrugs may be useful for prodrug monotherapy of necrotic tumors that liberate beta-glucuronidase or for antibody-directed enzyme prodrug therapy with antibodies that can deliver beta-glucuronidase to target tumor cells.     

Formation and persistence of O(6)-methylguanine in the mouse colon following treatment with 1,2-dimethylhydrazine as measured by an O(6)-alkylguanine-DNA alkyltransferase inactivation assay

Female SWR mice were treated with 1,2-dimethylhydrazine (DMH: 6.8 mg/kg i.p. injection) once weekly for up to 10 weeks, a dosing regime that produced tumours principally within the distal colon (Jackson et al., 1999. Carcinogenesis 20, 509-513). O(6)-Methylguanine (O(6)-MeG) levels, measured using a simple [3H]-based O(6)-alkylguanine-DNA alkyltransferase (ATase) inactivation assay, ranged from 0.6 to 16.7 fmol/microg DNA with: (i) highest levels in the distal colon; and (ii) higher levels after 68 mg/kg total DMH than 6.8 mg/kg DMH. Basal ATase activity varied between 0.97 and 1.22 fmol/microg DNA within the colon but was not associated with adduct levels or tumour induction. After 6.8 mg/kg DMH, the half life of O(6)-MeG in colonic tissue was 36-42 h whereas after 68 mg/kg DMH, t1/2 was approximately 25, 57 and 96 h in the proximal, mid and distal colon, respectively. Tumour induction was thus associated with the levels and persistence of O(6)-MeG in the distal colon.     

Protection of CHO cells by mutant forms of O6-alkylguanine-DNA alkyltransferase from killing by 1,3-bis-(2-chloroethyl)-1-nitrosourea (BCNU) plus O6-benzylguanine or O6-benzyl-8-oxoguanine.

O6-Benzylguanine (BG) is an inactivator of human O6-alkylguanine-DNA alkyltransferase (AGT) currently undergoing clinical trials to enhance cancer chemotherapy by alkylating agents. Mutant forms of AGT resistant to BG in vitro were expressed in CHO cells to determine if they could impart resistance to killing by the combination of BG and 1,3-bis-(2-chloroethyl)-1-nitrosourea (BCNU). All the BG-resistant mutant proteins tested (P140A, P140K, P138M/V139L/P140K, G156A, P140A/G160R, and G160R) showed a reduced rate of reaction with methylated DNA substrates in vitro. However, when expressed in equal amounts in CHO cells, mutants P140A, P140K, P138M/V139L/P140K, and G160R gave levels of protection from the chloroethylating agent BCNU equivalent to that of wild-type AGT. This indicates that a 10-fold reduction in rate constant did not prevent their ability to repair chloroethylated DNA in the cell. AGT activity was readily lost when CHO cells expressing wild-type AGT were exposed to BG or its 8-oxo metabolite (O6-benzyl-8-oxoguanine), but cells expressing mutants P140A or G160R required 30-fold higher concentrations and cells expressing mutants P140K or P138M/V139L/P140K were totally resistant. When cells were treated with 80 microM BCNU plus BG or 8-oxo-BG, those expressing wild-type AGT were killed when inhibitor concentrations of up to 500 microM were used, whereas cells expressing P140K or P138M/V139L/P140K showed no effect, and cells expressing P140A or G160R showed an intermediate resistance. These results suggest that: (i) appearance of BG-resistant mutant AGTs may be a problem during therapy, and (ii) the P140K mutant AGT is an excellent candidate for gene therapy approaches where expression of a BG-resistant AGT in hematopoietic cells is used to reduce toxicity.     

Evaluation of the role of isocyanates in the action of therapeutic nitrosoureas

The half-lives of chloroethyl and cyclohexyl isocyanate have been determined in tissue culture medium, and the isocyanate concentration produced during the breakdown of 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) and 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU) has been calculated. L1210 or HeLa cells exposed either to the parent nitrosourea or to an equivalent constant isocyanate concentration show no deficiency in the repair of gamma-irradiation damage as measured by DNA strand separation in alkali. Viability studies indicate that the isocyanates play a minor role in the overall cytotoxicity of the nitrosoureas.     

Inactivation of O(6)-alkylguanine-DNA alkyltransferase by folate esters of O(6)-benzyl-2'-deoxyguanosine and of O(6)-[4-(hydroxymethyl)benzyl]guanine

O6-Alkylguanine-DNA alkyltransferase (alkyltransferase) provides an important source of resistance to some cancer chemotherapeutic alkylating agents. Folate ester derivatives of O6-benzyl-2'-deoxyguanosine and of O6-[4-(hydroxymethyl)benzyl]guanine were synthesized and tested for their ability to inactivate human alkyltransferase. Inactivation of alkyltransferase by the gamma-folate ester of O6-[4-(hydroxymethyl)benzyl]guanine was similar to that of the parent base. The gamma-folate esters of O6-benzyl-2'-deoxyguanosine were more potent alkyltransferase inactivators than the parent nucleoside. The 3'-ester was considerably more potent than the 5'-ester and was more than an order of magnitude more active than O6-benzylguanine, which is currently in clinical trials to enhance therapy with alkylating agents. They were also able to sensitize human tumor cells to killing by 1,3-bis(2-chloroethyl)-1-nitrosourea, with O6-benzyl-3'-O-(gamma-folyl)-2'-deoxyguanosine being most active. These compounds provide a new class of highly water-soluble alkyltransferase inactivators and form the basis to construct more tumor-specific and potent compounds targeting this DNA repair protein.     

Nitrosourea-induced DNA single-strand breaks.

Reaction of DNA with nitrosoureas in vitro results in extensive formation of alkali labile sites. Two types of single-strand scission (SSS) processes may be distinguished by their different rates: (1) type I SSS which occurs relatively fast at high pH, and (2) type II SSS which is a much slower process. Neither of these processes is affected by free radical traps. Dimethyl sulfate, which is known to alkylate DNA bases but not phosphate residues, shows no type I SSS but does show extensive type II SSS. That the latter process involves alkylation of bases followed by the formation of apurinic sites was confirmed by using endonuclease VI, an enzyme specific for apurinic positions. Reactions of chloroethylnitrosoureas with DNA produces both type I and type II SSS. Aliphatic amines produced in the decomposition of alkyl nitrosoureas do not contribute significantly to the scission of apurinic sites via Schiff base formation. However, this process may be significant for aryl nitrosoureas. Ethyl nitrosourea (ENU), 1, 3-bis(2-chloroethyl)nitrosourea (BCNU), and 3-cyclohexyl-1-(2-hydroxyethyl)-1-nitrosourea (CHNU) readily degrade poly A by phosphate alkylation, with rates that parallel their relative rates of decomposition. The relative rates of hydrolysis of triethylphosphate and β-hydroxyethyl diethyl phosphate parallel the type I SSS observed for ENU and CHNU with DNA. The type I SSS of DNA by these compounds appears to involve a similar phosphotriester formation and hydrolysis. The type I SSS is in accord with the observed extreme liability of β-hydroxyethyl diethyl phosphate which is attributed to participation of the OH group, and by the fact that methylation of the OH completely inhibits the type I SSS process.