DNA Interstrand Crosslink Formation by Mechlorethamine at a Cytosine–Cytosine Mismatch Pair: Kinetics and Sequence Dependence

Expansion of the triplet repeat DNA sequence d[CGG]n · d[CCG]n is a characteristic of Fragile X syndrome, a human neurodegenerative disease. Stable intrastrand conformations formed by both d[CGG]n and d[CCG]n, and involving G–G and C–C mismatch pairs, respectively, are believed to be of importance i...

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Bibliographic Details
Published inArchives of biochemistry and biophysics Vol. 386; no. 2; pp. 143 - 153
Main Authors Romero, Rebecca M., Rojsitthisak, Pornchai, Haworth, Ian S.
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 15.02.2001
Subjects
Alkylating Agents - chemistry
Alkylating Agents - metabolism
Base Composition
Base Pair Mismatch - genetics
Base Pairing
Base Sequence
Computer Simulation
Cross-Linking Reagents - chemistry
Cross-Linking Reagents - metabolism
crosslink
cytosine
Cytosine - metabolism
DNA
DNA - chemistry
DNA - genetics
DNA - metabolism
DNA Adducts - chemistry
DNA Adducts - genetics
DNA Adducts - metabolism
Electrophoresis, Polyacrylamide Gel
Fragile X
Fragile X Syndrome - genetics
GC Rich Sequence - genetics
Humans
Kinetics
mechlorethamine
Mechlorethamine - chemistry
Mechlorethamine - metabolism
mismatch
Models, Molecular
Molecular Probes - chemistry
Molecular Probes - metabolism
Nucleic Acid Denaturation
stability
Substrate Specificity
Temperature
cytosine
mechlorethamine
DNA
mismatch
kinetics
stability
Fragile X
crosslink
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Summary:Expansion of the triplet repeat DNA sequence d[CGG]n · d[CCG]n is a characteristic of Fragile X syndrome, a human neurodegenerative disease. Stable intrastrand conformations formed by both d[CGG]n and d[CCG]n, and involving G–G and C–C mismatch pairs, respectively, are believed to be of importance in the development of the disease. We have shown previously that C–C mismatch pairs can be crosslinked covalently by mechlorethamine, a nitrogen mustard alkylating agent, and hence this reaction may be of value as a probe for conformers of d[CCG]n. To characterize the mechlorethamine C–C crosslink reaction further, here we report the kinetics and sequence dependence of formation of the crosslink species, using a series of model duplexes. The rate of reaction depends on the base sequence proximal to the C–C mismatch pair. Hence, in 19mer duplexes containing a central d[M4M3M2M1Cn1n2n3n4] · d[N4N3N2N1Cm1m2m3m4] sequence, where M–m and N–n are complementary base pairs, the amount of crosslink increased with increasing G–C content of the eight base pairs neighboring the C–C mismatch and with the proximity of the G–C pairs to the C–C mismatch. Molecular dynamics simulations of the solvated duplexes provided an explanation of these data. Hence, for a C–C pair flanked by G–C base pairs the mismatched cytosine bases remain stacked within the duplex, but for a C–C pair flanked by A–T base pairs, the simulations suggested local opening of the duplex around the C–C pair, making it a less effective target for mechlorethamine.
ISSN:0003-9861
1096-0384
DOI:10.1006/abbi.2000.2198