T4 endonuclease V catalyzes the DNA strand cleavage in the vicinity of a thymine dimer. In order to obtain insight into the specific recognition mechanism of this enzyme with a thymine photodimer within DNA, the conformations of five different DNA duplexes, [sequence: see text] with which the enzyme can interact, were studied by 1H NMR. DNA I, DNA IV, and DNA V do not contain the TT sequence or a thymine dimer and hence, are expected to bind the enzyme only in a nonspecific manner. DNA II includes a single TT sequence which does not form a thymine dimer. Only DNA III is expected to bind specifically to the enzyme through a thymine photodimer. The NMR spectra of these five DNA duplexes in the absence of the enzyme clearly show that the formation of a thymine dimer within the DNA induces only a minor distortion in the structure and that the overall structure of B-type DNA is retained. The photodimer formation is found to cause a large change in chemical shifts at the GC7 base pair, which is located at the 3'-side of the thymine dimer, accompanied by the major conformational change at the thymine dimer site. The effects of T4 endonuclease V binding on these DNA duplexes were also investigated by 1H NMR. The binding of this enzyme to DNA I, DNA IV, and DNA V causes no alteration in chemical shift values of the imino proton resonances, but the binding to DNA II induces a small downfield shift in the imino proton resonance of GC7.(ABSTRACT TRUNCATED AT 250 WORDS)