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Studies on the hydrophobic effect and its contribution to the stability, crystallization, and helix packing of Z-DNA

The studies presented here use the B- to Z-DNA transition and Z-DNA
crystallization as model systems to determine the contribution of solvent interactions to
macromolecular structures. The substituent groups of naturally occurring and modified
nucleotide bases affect the hydration and thus the stability of right-handed B-DNA and
left-handed Z-DNA. The free energy for alternating pyrimidine-purine sequences in the
B- and Z-conformations are quantitated as solvent free energies (SFE) from their solvent-accessible
surfaces. The effect of methylation of the C5 carbon of pyrimidine bases on
the stability of Z-DNA was analyzed in comparisons of d(TA) versus d(UA)
dinucleotides. In the minor groove, the N2 amino group of purine bases was examined
by comparing the stability of d(CG) versus d(CI), and d(TA) versus d(TA') dinucleotides
as Z-DNA. These comparisons correctly accounted for the observed effects of the major
and minor groove substituent groups on the relative stability of Z-DNA. These
predictions were confirmed by comparing the amount of salt required to crystallize
various hexanucleotides as Z-DNA.
The relative contribution of solvent and steric interactions in DNA assembly were
studied crystallographically using an asymmetric hexanucleotide which assumes two
discrete and discernible orientations in the crystal lattice. How this sequence orients in
the lattice is a direct measure of the DNA-DNA interactions at the surface of the crystal.
These interaction free energies were directly correlated with differences in solvation for 5
sequences where there was effectively no differences in steric interactions for the two orientations. In the singular case where a large steric clash was expected, the orientation was in fact determined by this interaction. The comparisons indicate that both solvent and van der Waals interactions are significant in DNA assembly with van der Waa ls interactions dominating in situations with large steric interactions.
The analyses of the B- to Z-DNA transition and Z-DNA crystallization based on SFEs support the significance of solvent interactions in determining the structure and assembly of macromolecules. / Graduation date: 1995

Identiferoai:union.ndltd.org:ORGSU/oai:ir.library.oregonstate.edu:1957/35299
Date01 December 1994
CreatorsKagawa, Todd F.
ContributorsHo, Pui Shing
Source SetsOregon State University
Languageen_US
Detected LanguageEnglish
TypeThesis/Dissertation

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