Environmentally induced conformational changes in B-type DNA: comparison of the conformation of the oligonucleotide d(TCGCGAATTCGCG) in solution and in its crystalline complex with the restriction nuclease EcoRI.

Raman spectroscopic analysis of the secondary structure of the crystalline restriction endonuclease EcoRI, the oligonucleotide d(TCGCGAATTCGCG) in solution, and the corresponding crystalline EcoRI-oligonucleotide complex reveals structural differences between the complexed and uncomplexed protein and oligonucleotide components that appear to be linked to complex formation. Structural differences that are spectroscopically identified include (1) an increase in the population of furanose rings adopting the C3'-endo conformation and (2) spectroscopically observed changes in base stacking which are probably associated with the crystallographically observed distortion of the phosphate backbone about positions C(3)-G(4) and C(9)-G(10) and unwinding between the symmetry-related segments GAA-TTC which make up the central recognition core (McClarin et al., 1986). Changes in base stacking due to distortions and unwinding along the oligonucleotide result in differences in the base vibrational region between the spectra of the complex and the oligonucleotide in solution. The spectroscopic analysis indicates that the C2'-endo population is similar for the oligonucleotide in solution and in the complex. The additional C3'-endo population in the complex appears to arise from the conversion of rings adopting alternative conformations such as C1'-exo and O1'-endo. Analysis of the vibrational bands derived from guanine indicates that the population of guanine residues associated with furanose rings in a C2'-endo conformation is similar for the oligonucleotide in solution and in the crystalline complex. This implies that the increase in C3'-endo population is not associated with guanine residues. Large conformational distortions such as those observed in the crystal distortions are not observed in either the crystal or the solution of the oligomer d(CGCGAATTCGCG).(ABSTRACT TRUNCATED AT 250 WORDS)

Structure of the DNA-Eco RI endonuclease recognition complex at 3 A resolution.

The crystal structure of the complex between Eco RI endonuclease and the cognate oligonucleotide TCGCGAATTCGCG provides a detailed example of the structural basis of sequence-specific DNA-protein interactions. The structure was determined, to 3 A resolution, by the ISIR (iterative single isomorphous replacement) method with a platinum isomorphous derivative. The complex has twofold symmetry. Each subunit of the endonuclease is organized into an alpha/beta domain consisting a five-stranded beta sheet, alpha helices, and an extension, called the "arm," which wraps around the DNA. The large beta sheet consists of antiparallel and parallel motifs that form the foundations for the loops and alpha helices responsible for DNA strand scission and sequence-specific recognition, respectively. The DNA cleavage site is located in a cleft that binds the DNA backbone in the vicinity of the scissile bond. Sequence specificity is mediated by 12 hydrogen bonds originating from alpha helical recognition modules. Arg200 forms two hydrogen bonds with guanine while Glu144 and Arg145 form four hydrogen bonds to adjacent adenine residues. These interactions discriminate the Eco RI hexanucleotide GAATTC from all other hexanucleotides because any base substitution would require rupture of at least one of these hydrogen bonds.

Kinked DNA in crystalline complex with EcoRI endonuclease.

The 3 A electron density map of a co-crystalline recognition complex between EcoRI endonuclease and the oligonucleotide TCGCGAATTCGCG reveals that a tight, complementary interface between the enzyme and the major groove of the DNA is the major determinant of sequence specificity. The DNA contains a torsional kink and other departures from the B conformation which unwind the DNA and thereby widen the major groove in the recognition site.

Two-fold symmetry of crystalline DNA-EcoRI endonuclease recognition complexes.

Recognition complexes between EcoRI endonuclease and either of two synthetic oligonucleotides (sequences CGCGAATTCGCG and TCGCGAATTCGCG) crystallize in Space Group P321 with unit cell parameters a = 128 and c = 47 A and a = 118.4 and c = 49.7 A, respectively. Native diffraction data to 3 A resolution have been collected from the form containing the tridecameric sequence. Electrophoretic analyses of dissolved crystals demonstrate that this form contains DNA and protein in a ratio of one double helix per enzyme dimer. The most likely asymmetric unit contents are one 31,000 dalton enzyme subunit and one strand of DNA, yielding VM values of 3.1 A3/dal and 2.8 A3/dal for the forms containing dodecameric and tridecameric DNA, respectively. This implies that the DNA-protein complex possesses two-fold rotational symmetry, which has been incorporated in the crystalline lattice.

Coordinate ion pair formation between EcoRI endonuclease and DNA.

The free energy of the binding reaction between EcoRI restriction endonuclease and a specific cognate dodecadeoxynucleotide (d(CGCGAATTCGCG)) has contributions from both electrostatic and nonelectrostatic components. These contributions were dissected by measuring the effects of varying salt concentration on the equilibrium binding constant and applying the thermodynamic analyses of Record et al. (Record, M. T., Jr., Lohman, T. M., and deHaseth, P. L. (1976) J. Mol. Biol. 107, 145-158). Endonuclease mutation S187 (Arg 187 to Ser) (Greene, P. J., Gupta, M., Boyer, H. W., Brown, W. E., and Rosenberg, J. M. (1981) J. Biol. Chem. 256, 2143-2153) did not significantly affect the nonelectrostatic component but did perturb the electrostatic contribution to the binding energy (we are numbering the amino acid residues according to the DNA sequence). The former was determined by extrapolating the linear portion of the salt dependence curve (0.125 to 0.25 M KCl) to 1 M ionic strength, with the same result for both wild type and S187 endonucleases at both pH 6.0 and 7.4 (-8.5 +/- 1.5 kcal/mol or greater than 50% of the total binding free energy). The slopes of these same curves yield estimates of eight ionic interactions between wild type endonuclease and the DNA at both pH values. By contrast, binding of EcoRI-S187 to dodecanucleotide involves six charge-charge interactions at pH 6.0. Only two ionic interactions are observed at pH 7.4. This was unexpected since gel permeation chromatography demonstrated that the recognition complex for both wild type and S187 proteins contains an enzyme dimer and a DNA duplex. EcoRI-S187 endonuclease retains wild type DNA sequence specificity, and the rate of the phosphodiester hydrolysis step is also unchanged. Thus, electrostatic interactions are functionally separable from sequence recognition and strand cleavage. Our results also establish that arginine 187 plays a key role in the electrostatic function and suggest that it might be located at the DNA-protein interface. The disproportionate loss of ion pairs at pH 7.4 can be rationalized by a model which suggests that six conformationally mobile ionic groups on the protein act in a coordinated manner during the interaction with DNA.