The data reveal potentially important and apparently additive effects of Dbh genotype and disulfiram administration on PFC catecholamine metabolism. These effects may have implications for genetic control of DBH activity in humans and for understanding therapeutic effects of disulfiram.
The thermodynamics governing the denaturation of RNA duplexes containing 8 bp and a central tandem mismatch or 10 bp were evaluated using UV absorbance melting curves. Each of the eight tandem mismatches that were examined had one U-U pair adjacent to another noncanonical base pair. They were examined in two different RNA duplex environments, one with the tandem mismatch closed by G.C base pairs and the other with G.C and A.U closing base pairs. The free energy increments (Delta Gdegrees(loop)) of the 2 x 2 loops were positive, and showed relatively small differences between the two closing base pair environments. Assuming temperature-independent enthalpy changes for the transitions, (Delta Gdegrees(loop)) for the 2 x 2 loops varied from 0.9 to 1.9 kcal/mol in 1 M Na(+) at 37 degrees C. Most values were within 0.8 kcal/mol of previously estimated values; however, a few sequences differed by 1.2-2.0 kcal/mol. Single strands employed to form the RNA duplexes exhibited small noncooperative absorbance increases with temperature or transitions indicative of partial self-complementary duplexes. One strand formed a partial self-complementary duplex that was more stable than the tandem mismatch duplexes it formed. Transitions of the RNA duplexes were analyzed using equations that included the coupled equilibrium of self-complementary duplex and non-self-complementary duplex denaturation. The average heat capacity change (DeltaC(p)) associated with the transitions of two RNA duplexes was estimated by plotting DeltaH degrees and DeltaS degrees evaluated at different strand concentrations as a function of T(m) and ln T(m), respectively. The average DeltaC(p) was 70 +/- 5 cal K(-)(1) (mol of base pairs)(-)(1). Consideration of this heat capacity change reduced the free energy of formation at 37 degrees C of the 10 bp control RNA duplexes by 0.3-0.6 kcal/mol, which may increase Delta Gdegrees(loop) values by similar amounts.
RNase H degradation of two 15 nt RNA target sites was examined in the presence of hairpin DNAs with a 5 nt loop and a 10 bp stem or single-stranded 15 nt DNAs. One target site was a segment of a 79 nt RNA, and the other was part of a 53 nt RNA. Secondary structure predictions indicate that the 53 nt RNA target site is entirely single stranded, while a portion of the 79 nt RNA target site forms an intramolecular duplex. Less RNase H and DNA were needed to cleave the 53 nt RNA target site than the less accessible 79 nt RNA site. The hairpin DNAs had their 5 nt loop and 3' side of the stem fully complementary to the target sites or had sequence changes that produced one to nine mismatched pairs. T(m) values ranged from 57 to 80 degrees C. The stability of the hairpin DNAs relative to the stability of their corresponding RNA-DNA hybrids influenced the extent of RNase H degradation at 37 degrees C. Under the assay conditions employed, the amount of degradation directed by the hairpin DNAs was correlated with their predicted DeltaG(o) (37) of binding to the RNA targets. A DNA hairpin with one mismatch to the target site of the 79 nt RNA did not induce degradation under conditions where fully complementary DNA hairpins produced 50-80% degradation. The in vitro results indicate that DNA hairpins can enhance the stringency of RNase H targeted degradation of the RNA sites.
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