Dielectric study on hydration of B‐, A‐, and Z‐DNA

Abstract Dielectric relaxation peak due to bound water was found around 100 MHz in poly(dG‐dC) · poly(dG‐dC) and calf thymus DNA in water–ethanol mixtures with NaCl buffer. Relaxation time and strength show a transition for poly(dG‐dC) · poly(dG‐dC) at anethanol composition C w = 0.45 (w/w) where the structural transition from B‐ to Z‐DNA takes place. It has been suggested that the transition is caused by removal of the bound water molecules preferentially from the phosphate groups. If the bound water molecules are removed equally from the phosphate groups and the grooves, the structural transition from B to A takes place. By analogy with hydration of tropocollagen, it was found that 19 water molecules per one nucleotide are at least necessary to keep B‐DNA. Thirteen molecules are bound to A‐DNA and 9 molecules to Z‐DNA. Stringlike multimers are proposed as available structures of the bound water.