Gel shift analysis reveals [Lagunavicius, A., & Siksnys, V. (1997) Biochemistry 36 (preceding paper in this issue)] that at pH 8.3 in the absence of Mg2+, MunI restriction endonuclease exhibits little DNA binding specificity, as compared with the D83A and E98A mutants of MunI. This suggests that charged carboxylate residue(s) influence the DNA binding specificity of MunI. In our efforts to establish the determinants of MunI binding specificity, we investigated the possible role of the ionic milieu, and we found that lowering pH or elevating Ca2+ levels per se induces specific DNA recognition by WT MunI. In contrast to the binding experiments at pH 8.3, gel shift analysis at pH 6.5 indicated tight sequence-specific binding of WT MunI in the absence of Mg2+, suggesting that protonation of active site carboxylate residue(s) which manifest anomalously high pKa value(s) control binding specificity. Interestingly, Ca2+ ion concentrations, which did not support DNA cleavage by MunI also induced DNA binding specificity in WT MunI at pH 8.3. To explore possible structural changes upon DNA binding, we then used a limited proteolysis technique. Trypsin cleavage of MunI-DNA complexes indicated that in the presence of cognate DNA the MunI restriction endonuclease became resistant to proteolytic cleavage, suggesting that binding of specific DNA induced a structural change. CD measurements confirmed this observation, suggesting minor secondary structural differences between complexes of MunI with cognate and noncognate DNA. These results therefore suggest that binding of MunI to its recognition sequence triggers a conformational transition that correctly juxtaposes active site carboxylate residues, which then chelate Mg2+ ions. In the absence of Mg2+ ions, at pH 8.3, conditions in which carboxylate groups would be expected to be completely ionized, electrostatic repulsion between charged carboxylates and phosphate oxygens is enhanced such as to interfere with specific DNA binding. Elimination of such repulsive constraints by replacement of carboxylate residues, by lowering pH, or by metal ion binding, then promotes MunI binding specificity.
The type IIs restriction enzyme BfiI recognizes the non-palindromic nucleotide sequence 5-ACTGGG-3 and cleaves complementary DNA strands 5/4 nucleotides downstream of the recognition sequence. The genes coding for the BfiI restriction-modification (R-M) system were cloned/sequenced and biochemical characterization of BfiI restriction enzyme was performed. The BfiI R-M system contained three proteins: two N4-methylcytosine methyltransferases and a restriction enzyme. Sequencing of bisulfite-treated methylated DNA indicated that each methyltransferase modifies cytosines on opposite strands of the recognition sequence. The N-terminal part of the BfiI restriction enzyme amino acid sequence revealed intriguing similarities to an EDTA-resistant nuclease of Salmonella typhimurium. Biochemical analyses demonstrated that BfiI, like the nuclease of S. typhimurium, cleaves DNA in the absence of Mg 2؉ ions and hydrolyzes an artificial substrate bis(p-nitrophenyl) phosphate. However, unlike the nonspecific S. typhimurium nuclease, BfiI restriction enzyme cleaves DNA specifically. We propose that the DNA-binding specificity of BfiI stems from the C-terminal part of the protein. The catalytic N-terminal subdomain of BfiI radically differs from that of type II restriction enzymes and is presumably similar to the EDTA-resistant nonspecific nuclease of S. typhimurium; therefore, BfiI did not require metal ions for catalysis. We suggest that BfiI represents a novel subclass of type IIs restriction enzymes that differs from the archetypal FokI endonuclease by the fold of its cleavage domain, the domain location, and reaction mechanism.Type IIs restriction enzymes recognize short non-palindromic DNA sequences and, in the presence of Mg 2ϩ ions, cleave both DNA strands a short distance outside the recognition sequence (1). Currently, our knowledge of the structure and mechanisms of catalysis used by type IIs restriction enzymes is limited to the FokI restriction enzyme that recognizes asymmetric nucleotide sequence 5Ј-GGATG and cleaves both DNA strands 9/13 nucleotides away from the recognition sequence (2). According to proteolytic cleavage and deletion analysis data (3, 4), further confirmed by structural studies (5), FokI contains two functional domains, one responsible for DNA recognition (N-terminal domain) and the other for cleavage (C-terminal domain). Interestingly, the structural architecture of the FokI cleavage domain displays a striking similarity to the monomer of BamHI (6), demonstrating that both enzymes share similar catalytic machinery despite the fact that they interact with nucleic acids differently. Protein sequence comparisons suggest that the StsI restriction enzyme, which recognizes the same nucleotide sequence as FokI but cleaves DNA 10/14 nucleotides away, possesses a similar modular organization (7, 8). However, we still lack evidence to indicate if other type IIs restriction enzymes share a similar structural architecture.The BfiI, isolated from Bacillus firmus S8120 strain, is a member of the type IIs rest...
Mapping of the conserved sequence regions in the restriction endonucleases MunI (C/AATTG) and EcoRI (G/AATTC) to the known X-ray structure of EcoRI allowed us to identify the sequence motif 82PDX14EXK as the putative catalytic/Mg2+ ion binding site of MunI [Siksnys, V., Zareckaja, N., Vaisvila, R., Timinskas, A., Stakenas, P., Butkus, V., & Janulaitis, A. Gene (1994) 142, 1-8]. Site-directed mutagenesis was then used to test whether amino acids P82, D83, E98, and K100 were important for the catalytic activity of MunI. Mutation P82A generated only a marginal effect on the cleavage properties of the enzyme. Investigation of the cleavage properties of the D83, E98, and K100 substitution mutants, however, in vivo and in vitro, revealed either an absence of catalytic activity or markedly reduced catalytic activity. Interestingly, the deleterious effect of the E98Q replacement in vitro was partially overcome by replacement of the metal cofactor used. Though the catalytic activity of the E98Q mutant was only 0.4% of WT under standard conditions (in the presence of Mg2+ ions), the mutant exhibited 40% of WT catalytic activity in buffer supplemented with Mn2+ ions. Further, the DNA binding properties of these substitution mutants were analyzed using the gel shift assay technique. In the absence of Mg2+ ions, WT MunI bound both cognate DNA and noncognate sequences with similar low affinities. The D83A and E98A mutants, in contrast, in the absence of Mg2+ ions, exhibited significant specificity of binding to cognate DNA, suggesting that the substitutions made can simulate the effect of the Mg2+ ion in conferring specificity to the MunI restriction enzyme.
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