Abstract
XPA is involved in the damage recognition step of nucleotide excision repair (NER). XPA binds to other repair factors, and acts as a key element in NER complex formation. The central domain of human repair factor XPA (residues Met98 to Phe219) is responsible for the preferential binding to damaged DNA and to replication protein A (RPA). The domain consists of a zinc-containing subdomain with a compact globular structure and a C-terminal subdomain with a positively charged cleft in a novel α/β structure. The resonance assignments and backbone dynamics of the central domain of human XPA were studied by multidimensional heteronuclear NMR methods. 15N relaxation data were obtained at two static magnetic fields, and analyzed by means of the model-free formalism under the assumption of isotropic or anisotropic rotational diffusion. In addition, exchange contributions were estimated by analysis of the spectral density function at zero frequency. The results show that the domain exhibits a rotational diffusion anisotropy (D_??_/D_??_) of 1.38, and that most of the flexible regions exist on the DNA binding surface in the cleft in the C-terminal subdomain. This flexibility may be involved in the interactions of XPA with various kinds of damaged DNA.
