1 EB), which is highly sensitive to changes in nucleic acid conformation.

2 chaperones, which drive the rearrangement of nucleic acid conformation.

3 ions were chiefly associated with changes in nucleic acid conformation.

4 h the SCs appear to relate to differences in nucleic acid conformation.

5 y are apparently sensitive to differences in nucleic acid conformation and could conceivably be devel

6 study of time-resolved structural changes of nucleic acid conformation and protein-nucleic acid compl

7 nd virus detection and analysis, and probing nucleic acid conformations and binding interactions.

8 rized tethering points to extend analysis of nucleic acid conformation, and its modulation by protein

9 protein facilitates the formation of compact nucleic acid conformations by acting as a flexible macro

10 d tools exist that are capable of monitoring nucleic acid conformations, fluctuations, and distributi

11 ures and existing biochemical data suggest a nucleic acid conformation-induced mechanism for guiding

12                      The full description of nucleic acid conformation involves eight torsion angles

13                        Calculations on other nucleic acid conformations predict that the variation in

14                 BBR3464 binding to different nucleic acid conformations raises the possibility that t

15 of the poly(rA/dT) tract of the PPT with the nucleic acid conformation that is required for RNase H c

16 ctor, but it differs in that DnaA promotes a nucleic acid conformation that prevents pairing of a com

17 The reaction of BBR3464 with three different nucleic acid conformations was assessed by gel electroph