Interaction of the Escherichia coli replication terminator protein (Tus) with DNA: a model derived from DNA-binding studies of mutant proteins by surface plasmon resonance.

The Escherichia coli replication terminator protein (Tus) binds tightly and specifically to termination sites such as TerB in order to halt DNA replication. To better understand the process of Tus-TerB interaction, an assay based on surface plasmon resonance was developed to allow the determination of the equilibrium dissociation constant of the complex (K(D)) and association and dissocation rate constants for the interaction between Tus and various DNA sequences, including TerB, single-stranded DNA, and two nonspecific sequences that had no relationship to TerB. The effects of factors such as the KCl concentration, the orientation and length of the DNA, and the presence of a single-stranded tail on the binding were also examined. The K(D) measured for the binding of wild type and His(6)-Tus to TerB was 0.5 nM in 250 mM KCl. Four variants of Tus containing single-residue mutations were assayed for binding to TerB and the nonspecific sequences. Three of these substitutions (K89A, R198A, and Q250A) increased K(D) by 200-300-fold, whereas the A173T substitution increased K(D) by 4000-fold. Only the R198A substitution had a significant effect on binding to the nonspecific sequences. The kinetic and thermodynamic data suggest a model for Tus binding to TerB which involves an ordered series of events that include structural changes in the protein.

Reorganization of terminator DNA upon binding replication terminator protein: implications for the functional replication fork arrest complex.

Termination of DNA replication in Bacillus subtilis involves the polar arrest of replication forks by a specific complex formed between the replication terminator protein (RTP) and DNA terminator sites. While determination of the crystal structure of RTP has facilitated our understanding of how a single RTP dimer interacts with terminator DNA, additional information is required in order to understand the assembly of a functional fork arrest complex, which requires an interaction between two RTP dimers and the terminator site. In this study, we show that the conformation of the major B.subtilis DNA terminator,TerI, becomes considerably distorted upon binding RTP. Binding of the first dimer of RTP to the B site of TerI causes the DNA to become slightly unwound and bent by approximately 40 degrees. Binding of a second dimer of RTP to the A site causes the bend angle to increase to approximately 60 degrees . We have used this new data to construct two plausible models that might explain how the ternary terminator complex can block DNA replication in a polar manner. In the first model, polarity of action is a consequence of the two RTP-DNA half-sites having different conformations. These different conformations result from different RTP-DNA contacts at each half-site (due to the intrinsic asymmetry of the terminator DNA), as well as interactions (direct or indirect) between the RTP dimers on the DNA. In the second model, polar fork arrest activity is a consequence of the different affinities of RTP for the A and B sites of the terminator DNA, modulated significantly by direct or indirect interactions between the RTP dimers.

Symmetry and secondary structure of the replication terminator protein of Bacillus subtilis: sedimentation equilibrium and circular dichroic, infrared, and NMR spectroscopic studies.

We have used analytical ultracentrifugation in combination with a number of spectroscopic techniques to analyze the symmetry and secondary structure of the DNA-binding replication terminator protein (RTP) of Bacillus subtilis. Sedimentation equilibrium studies confirm that RTP is a dimer in solution under the conditions used for spectroscopic analysis, whereas the number of cross peaks displayed in 1H-15N HSQC NMR spectra of uniformly 15N-labeled RTP are consistent with the primary structure of the monomer. These two results in combination lead to the conclusion that RTP is a symmetric dimer in solution. Circular dichroic and Fourier-transform infrared spectra reveal, in contrast to the results obtained from a number of commonly used secondary structure prediction algorithms, that RTP contains 20-30% alpha-helical and 40-50% beta-sheet/beta-turn secondary structure and that the conformation of the protein remains unchanged over the pH range 5-8. It is proposed on the basis of protein folding-class prediction algorithms, in combination with various physical properties of RTP, that it belongs to the alpha + beta protein-folding class.

Determination of the solution structure of a platelet-adhesion peptide of von Willebrand factor.

Two-dimensional nuclear magnetic resonance (NMR) spectroscopy in combination with distance geometry (DG) and dynamical simulated annealing (DSA) calculations have been used to determine the tertiary solution structure of a synthetic 29-residue fragment of von Willebrand factor (vWF). This fragment (D514-E542) represents an adhesion site on vWF for its platelet receptor, the glycoprotein Ib-IX complex (GP Ib-IX). The NMR data yielded 109 interproton distance measurements and two chi 1 dihedral angle constraints for use in DG and DSA calculations. Most prominent in the calculated family of solution structures was an amphipathic, right-handed alpha-helix in the C-terminal segment of the peptide. We propose that this highly structured region may be important for the specific molecular interaction of vWF with the GP Ib-IX complex.