DNA guanine-guanine crosslinking sequence specificity of isophosphoramide mustard, the alkylating metabolite of the clinical antitumor agent ifosfamide.

PURPOSE: The purpose of this investigation was to determine the base sequence specificity of isophosphoramide mustard (IPM), the alkylating metabolite of ifosfamide, by crosslinking of designed DNA oligomers in comparison with the clinical alkylating agents mechlorethamine (ME) (nitrogen mustard) and phosphoramide mustard (PM), the alkylating metabolite of cyclophosphamide. METHODS: IPM, as well as PM and ME were each reacted with three dodecameric duplexes, which were designed to detect interstrand crosslinking between guanines in 5'-GC-3' (I), 5'-GNC-3' (II) or 5'-GNNC-3' (III) sequences (N = A or T). RESULTS: All three agents preferentially react with 5'-GNC-3' target sequences. The 5'-GNNC-3' target sequence is less reactive by a factor of approximately 2.5- to 10-fold, while 5'-GC-3' is of even lower reactivity. CONCLUSION: These results indicate that all three agents show approximately equal preference for reaction with a 5'-GNC-3' target sequence in spite of the fact that IPM yields a 7-atom crosslink, while the other two agents yield 5-atom crosslinks.

Electrophoretic and chromatographic separation methods used to reveal interstrand crosslinking of nucleic acids.

Several electrophoretic and chromatographic techniques, many of which have only been developed recently, provide sensitive methods for the detection and separation of DNA containing interstrand crosslinks such as those produced by many cancer chemotherapeutic drugs and photoactive psoralen derivatives. Most of the methods rely on the fact that the presence of such crosslinks prevent the complete denaturation of the two complimentary DNA strands by heat or alkali. A simple and highly sensitive neutral agarose gel electrophoresis method is particularly applicable to detailed time-course experiments of both total crosslink formation, and the "second-arm" of the crosslink reaction. This method separates denatured single-stranded from double-stranded DNA which has reannealed as a result of an interstrand crosslink. Polyacrylamide gel-based assays using denaturing gels are more suited to the separation of smaller crosslinked DNA fragments and, in particular, small oligonucleotides on high-percentage gels. In addition, they provide methods for the determination of the exact base position and sequence selectivity of crosslink formation. Sephadex chromatography and high-performance liquid chromatography can separate small crosslinked oligonucleotides from non-crosslinked duplexes, and the hydroxyapatite column chromatographic separation of single- and double-stranded cellular DNA can be used to quantitate the level of interstrand crosslinking present in the bulk of the genome. Finally, the analysis of damage by crosslinking agents, and its repair, at the level of specific genes can be achieved by hybridization with specific probes following membrane transfer from neutral agarose gels used to fractionate restricted and fully denatured genomic DNA from drug-treated cells.

Two structurally related diaziridinylbenzoquinones preferentially cross-link DNA at different sites upon reduction with DT-diaphorase.

The nucleotide sequence preferences for the formation of interstrand cross-links induced in DNA by 2,5-diaziridinyl-1,4-benzoquinone (DZQ) and 3,6-dimethyl-2,5-diaziridinyl-1,4-benzoquinone (MeDZQ) were studied using synthetic duplex oligonucleotides and denaturing polyacrylamide gel electrophoresis (PAGE). Reaction of these bifunctional alkylating agents with a DNA duplex containing several potential cross-linking sites resulted in the formation of cross-linked DNAs with different electrophoretic mobilities. Analysis of the principal cross-linked products by piperidine fragmentation revealed that the preferential site of cross-linking was altered from a 5'-GNC to a 5'-GC sequence upon reduction of DZQ to the hydroquinone form by the enzyme DT-diaphorase. In contrast, the reduced form of MeDZQ was found to preferentially cross-link at 5'-GNC sites within the same sequence. These preferences were confirmed in duplex oligonucleotides containing single potential cross-linking sites. Additional minor cross-linked products were characterized and revealed that DZQ and MeDZQ are both capable of cross-linking across four base pairs in a 5'-GNNC sequence.

Alteration in DNA cross-linking and sequence selectivity of a series of aziridinylbenzoquinones after enzymatic reduction by DT-diaphorase.

DT-diaphorase (DTD) mediated reduction of a series of 2,5-bis-substituted-3,6-diaziridinyl-1,4-benzoquinones was found to increase the level of DNA interstrand cross-linking (ISC) formed at neutral pH with an enhancement observed as the pH was decreased to 5.8. The analogues used were symmetrically alkyl-substituted carbamoyl ester analogues of AZQ (D1-D7), 3,6-diaziridinyl-1,4-benzoquinone (DZQ), the 2,5-dimethyl derivative (MeDZQ), and a 2,5-bis[(2-hydroxyethyl)amino] analogue (BZQ). At pH 5.8, the level of DNA ISC induced by enzymatic reduction was as follows: DZQ greater than MeDZQ much greater than D1 (methyl) greater than D3 (n-propyl) greater than D2 (AZQ; ethyl) greater than D5 (n-butyl) greater than D7 (sec-butyl) greater than D4 (isopropyl) D6 greater than (isobutyl). A similar trend was observed at pH 7.2. The level of DNA ISC induced by BZQ, which is not a substrate for DTD, was not increased by enzymatic reduction. Dicumarol, a known inhibitor of DTD, was capable of inhibiting the DNA ISC induced by these quinones upon enzymatic reduction. MeDZQ and DZQ reacted with guanines, as measured by Maxam and Gilbert sequencing, with a sequence selectivity similar to that of the nitrogen mustard class of antitumor agents. Enzymatic reduction of DZQ and MeDZQ by DTD was found to alter their sequence-selective alkylation. Reduced DZQ showed enhanced guanine alkylation in 5'-GC-3' sequences and new sites of adenine alkylation in 5'-(A/T)AA-3' sequences. Reduced MeDZQ only showed new sites of adenine alkylation at 5'-(A/T)AA-3' sequences but no enhancement of guanine alkylation. The new sites of adenine alkylation were found to be inhibited in the presence of magnesium and rapidly converted into apurinic sites.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure activity analysis of the formation of DNA damage induced in human tumor cells by the cyclodisone class of anti-tumor agent.

1,5,2,4-dioxadithiocane-2,2,4,4-tetraoxide (compound II) and 1,5,2,4-dioxadithionane-2,2,4,4-tetraoxide (compound III) are two structural analogues of the anticancer agent cyclodisone. Compound III was found to be more toxic to human colon carcinoma cells of the Mer- phenotype (BE) than the Mer+ phenotype (HT-29). In contrast, compound II showed little preferential toxicity with both cell lines being equally sensitive to this agent. DNA interstrand crosslinks were induced in the sensitive cell line by compound III but only at concentrations which were extremely cytotoxic. No DNA interstrand crosslinks were detected in the resistant cell line by compound III nor in either cell line by compound II. Total crosslinks which reflects both DNA interstrand and DNA-protein crosslinks, were observed in both cell lines after exposure to each agent although the kinetics of formation and repair of these lesions differed between both the compounds and each cell line. DNA strand breaks were also induced in both cell lines by each compound and were found to be totally 'protein associated' with compound III and to a lesser extend with compound II. The mechanism of action of this class of compound is thus different from other bifunctional alkylating agents and has still to be identified.

An agarose gel method for the determination of DNA interstrand crosslinking applicable to the measurement of the rate of total and "second-arm" crosslink reactions.

A simple agarose gel electrophoresis method for the determination of DNA interstrand crosslinks is described. Following complete denaturation of 32P-end-labeled DNA the presence of an interstrand crosslink results in renaturation to double-stranded DNA. The single- and double-stranded bands separated on an agarose gel can be accurately quantitated by densitometry of the autoradiograph produced from the dried gel. The technique is particularly applicable to detailed time-course experiments of both total crosslink formation and, following removal of free drug, the "second-arm" of the crosslink reaction. The method is illustrated for a number of nitrogen mustard antitumor agents, showing how the moiety attached to a bifunctional reactive group can influence the extent and rate of crosslink formation and, in particular, the conversion of monoadducts to crosslinks. It is sensitive enough to follow the formation of crosslinks by slow and inefficient cross-linking agents such as busulfan which have not previously been measured by physical procedures.