Resonance Raman spectroscopy of 4-thiothymidine and oligodeoxynucleotides containing this base both free in solution and bound to the restriction endonuclease EcoRV.

The resonance Raman spectra of 4-thiothymidine [4ST] have been recorded (a) in the free deoxynucleoside form, (b) when incorporated into the single stranded oligodeoxynucleotide d(AG[4ST]-TC), and (c) within the double-stranded self-complementary dodecamer d(GACGA[4ST]ATCGTC). Vibrational mode assignments of almost all the major Raman bands observed in each spectra have been made, mainly by comparison with the published assignments of related nucleosides and nucleotides. Differences between the spectra were observed, particularly when [4ST] and d(AG[4ST]TC) were compared to d(GACGA[4ST]ATCGTC). This is explained in terms of the variations in structure between single-and double-stranded DNA. Good quality spectra were obtained at nucleotide/oligonucleotide concentrations of between 100 and 500 microM and this coupled with an apparatus that uses small volumes (100 microL) allowed measurement of the spectrum of d(GACGA[4ST]ATCGTC) bound to the EcoRV endonuclease. This well characterised nuclease, for which crystal structures are available, recognizes d(GATAT) sequences. When this is replaced with d(GA[4ST]ATC), a poor substrate results but turnover can be prevented during data accumulation by omission of the essential cation Mg2+. Large shifts in several of the Raman bands were observed, and these have been related to the environment of the [4ST] base in the protein-bound oligonucleotide as deduced from the crystal structure. The wavenumber for the C = S stretch vibration in free d(GACGA[4ST]ATCGTC) has been used to calculate the strength of the Watson-Crick hydrogen bond between the sulphur atom in [4ST] and the 6-NH2 group on its partner dA. On binding to the enzyme, the shift in the wavenumber of the C = S stretch indicates this Watson-Crick hydrogen bond is weakened, in good agreement with X-ray structures. The advantage of using [4ST] as a resonance Raman probe is that it absorbs at 340 nm, a wavelength where other nucleic acid and protein absorbance is minimal. Thus the spectra obtained are very simple and consist of signals that arise predominantly from the thiobase alone, and this facilitates data interpretation.

Influence of the phosphate backbone on the recognition and hydrolysis of DNA by the EcoRV restriction endonuclease. A study using oligodeoxynucleotide phosphorothioates.

A set of phosphorothioate-containing oligonucleotides based on pGACGATATCGTC, a self-complementary dodecamer that contains the EcoRV recognition sequence (GATATC), has been prepared. The phosphorothioate group has been individually introduced at the central nine phosphate positions and the two diastereomers produced at each site separated and purified. The Km and Vmax values found for each of these modified DNA molecules with the EcoRV restriction endonuclease have been determined and compared with those seen for the unmodified all-phosphate-containing dodecamer. This has enabled an evaluation of the roles that both of the non-esterified oxygen atoms in the individual phosphates play in DNA binding and hydrolysis by the endonuclease. The results have also been compared with crystal structures of the EcoRV endonuclease, complexed with an oligodeoxynucleotide, to allow further definition of phosphate group function during substrate binding and turnover. For further study, see the related article "Probing the Indirect Readout of the Restriction Enzyme EcoRV: Mutational Analysis of Contacts to the DNA Backbone" (Wenz, A., Jeltsch, A., and Pingoud, A. (1996) J. Biol. Chem. 271, 5565-5573).

DNA binding specificity of the EcoRV restriction endonuclease is increased by Mg2+ binding to a metal ion binding site distinct from the catalytic center of the enzyme.

In contrast to many other type II restriction endonucleases, EcoRV binds specifically to DNA only in the presence Mg2+. According to the co-crystal structure of an EcoRV-DNA complex, Mg2+ ion(s) bind to the active site of EcoRV liganded by Glu45, Asp74, and Asp90. Here we present experimental evidence suggesting that the EcoRV-DNA complex also interacts with Mg2+ ions at other sites: (i) We have prepared an EcoRV triple mutant, in which all acidic amino acids in the catalytic center are replaced by alanine. This mutant is catalytically inactive. It binds nonspecifically to DNA in the absence of Mg2+, whereas it binds specifically to DNA in the presence of Mg2+. This means that Mg2+ induces specific DNA binding in this mutant, although all Mg2+ ligands in the catalytic center are removed. Therefore, additional interactions between Mg2+ and the EcoRV-DNA complex probably occur at sites distinct from the catalytic center. (ii) We have measured the specific and nonspecific DNA binding constants of EcoRV and of the triple mutant in the presence and absence of Mg2+. Mg2+ reduces nonspecific binding by 3-4 orders of magnitude, presumably because Mg2+ ions bound to the DNA have to be released upon complex formation. In contrast, the specific binding of the wild-type enzyme and the triple mutant is increased in the presence of Mg2+. This result can only be explained if a Mg2+ ion binds to the specific EcoRV-DNA complex probably at a site distinct from the catalytic center.(ABSTRACT TRUNCATED AT 250 WORDS)