M. A. Scheerhagen scite author profile

Bokma²,

Vlaanderen³

et al. 1986

Biopolymers

SynopsisThe CD and absorption (OD) spectra of single-stranded nucleic acids in complex with the helix-destabilizing protein of either bacteriophage T4 (GP32) or bacteriophage fd (GP5) show similar and unusual features for all polynucleotides investigated. The change in the CD spectra between 310 and 240 nm is in all cases characterized by a considerable decrease in the positive band, while the negative band (if present) remains relatively intense. These changes are different from those due to temperature or solvent denaturation and, moreover, cannot be induced by the binding of simple oligopeptides. Absorption measurements show that all polynucleotides remain hypochromic in the complex. Both CD and OD spectra point to a specific and probably similar conformation in complex for all polynucleotides with substantial interactions between the bases. The spectral properties are almost temperature independent (0-40°C). Therefore, we conclude that the conformation must be regular and rigid. To investigate the relation between these optical properties and the specific polynucleotide structure, CD and OD spectra were calculated for an adenine hexamer over a wide range of the conformational parameters. It appears that the calculated CD intensity is not very sensitive to an increase in the axial increment and that many different conformations can give rise to more or less similar CD spectra. However, simulation of the very nonconservative experimental CD spectrum of the poly(rA)-GP32 complex requires that the conformation satisfies two criteria: (1) a considerable tilt of the bases (< -10") in combination with (2) a small rotation per base (=ZOO) andor a position of the bases close to the helix axis (dx = 0 A). Such conformations can also explain the observed hyperchromism upon binding of GP32 to poly(rA)/(dA). Very similar structural characteristics also account for the optical properties of the complexes with GP5. These are discussed as an alternative to the structure suggested by Alma-Zeestraten for poly(dA) in the complex [N. C. M. Alma-Zeestraten (1982) Doctoral thesis Catholic University, Nijmegen, The Netherlands]. The secondary structure proposed in this work can be reconciled with the overall dimensions of the complex, assuming that the polynucleotide helix is further organized in a superhelix.

Hydrodynamic studies of a DNA‐protein complex

Amerongen²,

Grondelle³

et al. 1985

FEBS Letters

Short DNA and RNA fragments complexed with the helix destabilizing protein of bacteriophage T4, GP32, have been studied in solution by electric birefringence and circular dichroism. The birefringence of the complexes is positive and the magnitude indicates that the DNA and RNA fragments become linear and rigid upon protein binding. The field free decay is biphasic. On the basis of a rigid rod approximation the slow relaxation time leads to a base-base distance along the helix axis in the complex from 4.3 to 5.6 A, an elongation of at least 50% compared to single-stranded DNA.

Journal of Biomolecular Structure and Dynamics

A Model for the Complex Between the Helix Destabilizing Protein GP32 of Bacteriophage T4 and Single-Stranded DNA

Scheerhagen

Kuil

Amerongen

et al. 1989

A model for the structure of the complex between the helix-destabilizing protein of bacteriophage T4, GP32, and single-stranded DNA is proposed. In this model the bases are arranged in a helix, that is characterized by a relatively large distance between successive bases, a substantial base tilt, in combination with a small rotation per base. This helix is further organized into a tertiary structure, possibly a superhelix, of which the corresponding protein shell corresponds to the relatively rigid and rod-like structure that is observed in hydrodynamic experiments. It is proposed that similar structural features apply to other single-stranded DNA binding proteins in complex with polynucleotides.

Hydrodynamic studies of a DNA‐protein complex

Kuil²,

Grondelle³

et al. 1985

FEBS Letters

The transiationai diffusion coefficient of the saturated complex of single-stranded 145 base DNA and the helix-destabilizing protein of phage T4, GP32, can be measured at equilibrium by means of quasi-elastic light scattering. If the complex is considered as a rigid rod one can estimate its dimensions by combining the translational diffusion coefficient with earlier data on rotational diffusion. It was found that the average base-base distance of the 145 base DNA in the complex is between 4.3 and 4.7 A, while the diameter of the complex is between 44 and 68 A. This suggests that the conformation of the complex must be such that a large amount of water is trapped.

Binding Stoichiometry of the Gene 32 Protein of Phage T4 in the Complex with Single Stranded DNA Deduced from Boundary Sedimentation

Journal of Biomolecular Structure and Dynamics

Vlaanderen²,

Blök³

et al. 1986

Short 145 base DNA fragments in complex with the helix destabilizing protein of bacteriophage T4, GP32, have been studied with boundary sedimentation. The sedimentation coefficient was determined as a function of concentration, protein-nucleic acid ratio, temperature and salt concentration. It can be concluded that the measured values reflect the properties of the saturated DNA-GP32 complex. A combination of the earlier obtained translational diffusion coefficient of the complex with the sedimentation coefficient yields its anhydrous molecular weight (Mw = 5.4.10(5) D), which corresponds to a size of the binding site of 10 nucleotides per protein. This procedure is not sensitive to the presence of non-binding protein molecules and to the assumed protein concentration, and therefore, it seems more reliable than a determination from titration experiments. Similar sedimentation measurements were performed with tRNA-complexes containing 76 nucleotides. The translational diffusion coefficient can be calculated from the measured rotational diffusion coefficient and assuming the same hydrodynamic diameter for this complex as obtained for the 145 b DNA complex. The molecular weight derived from the data then also leads to a binding site size of about 10 nucleotides. This suggests that also the short tRNA-complex forms an open, strongly solvated structure, as was proposed for the 145 b DNA-GP32 complex.