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Biophys J, October 2000, p. 2095-2104, Vol. 79, No. 4
Department of Chemistry, Tennessee State University, Nashville, Tennessee 37209-1561 USA
Earlier calorimetric studies had indicated that despite
the absence of a GpC sequence, the self-complementary octamer
d(CGTCGACG) binds strongly to actinomycin D (ACTD) with high
cooperativity and a 2:1 drug/duplex ratio. A subsequent optical
spectral study with related oligomers led us to suggest that ACTD may
likely stack at the G · C basepairs of the duplex termini. New
findings are reported herein to indicate that despite the lack of
complete self-complementarity, oligomers of d(CGXCGXCG) [X = A or
T] motif exhibit unusually strong ACTD affinities with binding
constants of roughly 2 × 107 M
1 and
binding densities of 1 drug molecule per strand. The ACTD binding
affinity for the corresponding heteroduplex obtained by annealing these
two oligomers is, however, considerably reduced. Although spectroscopic
results with related oligomers obtained by removing, replacing, or
appending bases at the termini appear to be consistent with the
end-stacking model, capillary electrophoretic (CE) evidence provides
additional insights into the binding mode. CE experiments with the
self-complementary oligomers d(CGAGCTCG) and d(CGTCGACG) revealed
contrasting migration patterns in the presence of ACTD, with mobility
retardation and acceleration exhibited by the GpC- and
non-GpC-containing octamers, respectively, whereas the X/X-mismatched
d(CGXCGXCG) experienced retardation. These results, along with those of
related oligomers, suggest that ACTD may in fact stack at the duplex
stem end of a monomeric hairpin or at the 3'-end of dG as a single
strand. The seemingly cooperative ACTD binding and the curved Scatchard
plot for the self-complementary d(CGTCGACG) may thus be attributed to
the drug-induced duplex denaturation resulting from strong binding to
single strands of d(CGXCGYCG) motif. Detailed structural information on
the ACTD-DNA complexes, however, must await further NMR investigations.
Biophys J, October 2000, p. 2095-2104, Vol. 79, No. 4
© 2000 by the Biophysical Society 0006-3495/00/10/2095/10 $2.00
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