N. Puri et J. Chattopadhyaya, Physico-chemical properties of 5 '-polyarene tethered DNA-conjugates, and their duplexes with complementary RNA, NUCLEOS NUC, 18(11-12), 1999, pp. 2785-2818
Fluorophores 1-13 when covalently linked to the 5'-terminus of 9-mer ssDNA
(as in ssDNA-conjugates 16-28) enhance the stablity of the duplexes with bo
th RNA (29) and DNA (30) targets compared to the natural counterparts, whic
h, for the first time, demonstrated the effect of the bulk and the x-electr
on density of various 5'-tethered fluorophores on the heteroduplex stabilit
y. It has been found that decreasing the pi-electron density of the fluorop
hore induces a more favourable pi-pi interaction with the adjacent nucleoba
se, leading to higher duplex stability. Increasing the surface-area of 5'-s
tacked fluorophore only increases the thermal stability of the duplex, if i
t leads to an increase in the area of pi-overlap with the adjacent nucleoba
se. The fluorescence characteristics show that the tethered-fluorophores st
ack to the exterior of the terminal nucleobase pair, except for 5'-tethered
-alpha-Napthalene (10), which shows dramatic enhancement in fluorescence as
normally observed for the minor groove binders. CD data shows that tetheri
ng the DNA with different fluorophores at the 5'-end did not make any gross
changes in the helical structure of the duplexes of DNA-conjugates with RN
A and DNA targets compared to the natural counterparts. It has emerged that
the 5'-tethered fluorophores assist in pre-organising the ssDNA-conjugates
into a helical conformation more effectively by a stronger fluorophore-nuc
leobase stacking than in the native ssDNA. All DNA-conjugates tested assist
ed in cleavage of the complementary RNA strand by RNase H. The RNase H acti
vation by 5'-conjugated DNA-RNA duplex decreased with the decrease of their
thermal stabilities, and as they deviated from the structure of the corres
ponding native DNA-RNA duplex. It has been also found that both native and
conjugated DNA-DNA duplexes can indeed block the RNase H activity, thereby
reducing the effect of a potential antisense agent. This implies that the p
alindromic as well hairpin-forming sequences of antisense DNA should be avo
ided.