Physical Properties of Human Polynucleotide Kinase: Hydrodynamic and Spectroscopic Studies

Abstract

Human polynucleotide kinase (hPNK) is a putative DNA repair enzyme in the base excision repair pathway required for processing and rejoining strand-break termini. This study represents the first systematic examination of the physical properties of this enzyme. The protein was produced in Escherichia coli as a His-tagged protein, and the purified recombinant protein exhibited both the kinase and the phosphatase activities. The predicted relative molecular mass (M_r) of the 521 amino acid polypeptide encoded by the sequenced cDNA for PNK and the additional 21 amino acids of the His tag is 59 538. The M_r determined by low-speed sedimentation equilibrium under nondenaturing conditions was 59 600 ± 1000, indicating that the protein exists as a monomer, in contrast to T4 phage PNK, which exists as a homotetramer. The size and shape of hPNK in solution were determined by analytical ultracentrifugation studies. The protein was found to have an intrinsic sedimentation coefficient, s⁰_20,w, of 3.54 S and a Stokes radius, R_s, of 37.5 Å. These hydrodynamic data, together with the M_r of 59 600, suggest that hPNK is a moderately asymmetric protein with an axial ratio of 5.51. Analysis of the secondary structure of hPNK on the basis of circular dichroism spectra, which revealed the presence of two negative dichroic bands located at 218 and 209 nm, with ellipticity values of −7200 ± 300 and −7800 ± 300 deg·cm²·dmol^-1, respectively, indicated the presence of approximately 50% β-structure and 25% α-helix. Binding of ATP to the protein induced an increase in β-structure and perturbed tryptophan, tyrosine, and phenylalanine signals observed by aromatic CD and UV difference spectroscopy.