Restriction enzyme BsoBI-DNA complex: a tunnel for recognition of degenerate DNA sequences and potential histidine catalysis.

BACKGROUND: Restriction endonucleases form a diverse family of proteins with substantial variation in sequence, structure, and interaction with recognition site DNA. BsoBI is a thermophilic restriction endonuclease that exhibits both base-specific and degenerate recognition within the sequence CPyCGPuG. RESULTS: The structure of BsoBI complexed to cognate DNA has been determined to 1.7 A resolution, revealing several unprecedented features. Each BsoBI monomer is formed by inserting a helical domain into an expanded EcoRI-type catalytic domain. DNA is completely encircled by a BsoBI dimer. Recognition sequence DNA lies within a 20 A long tunnel of protein that excludes bulk solvent. Interactions with the specific bases are made in both grooves through direct and water-mediated hydrogen bonding. Interaction with the degenerate position is mediated by a purine-specific hydrogen bond to N7, ensuring specificity, and water-mediated H bonding to the purine N6/O6 and pyrimidine N4/O4, allowing degeneracy. In addition to the conserved active site residues of the DX(n)(E/D)ZK restriction enzyme motif, His253 is positioned to act as a general base. CONCLUSIONS: A catalytic mechanism employing His253 and two metal ions is proposed. If confirmed, this would be the first example of histidine-mediated catalysis in a restriction endonuclease. The structure also provides two novel examples of the role of water in protein-DNA interaction. Degenerate recognition may be mediated by employing water as a hydrogen bond donor or acceptor. The structure of DNA in the tunnel may also be influenced by the absence of bulk solvent.

Single-column purification of free recombinant proteins using a self-cleavable affinity tag derived from a protein splicing element.

A novel protein purification system has been developed which enables purification of free recombinant proteins in a single chromatographic step. The system utilizes a modified protein splicing element (intein) from Saccharomyces cerevisiae (Sce VMA intein) in conjunction with a chitin-binding domain (CBD) from Bacillus circulans as an affinity tag. The concept is based on the observation that the modified Sce VMA intein can be induced to undergo a self-cleavage reaction at its N-terminal peptide linkage by 1,4-dithiothreitol (DTT), beta-mercaptoethanol (beta-ME) or cysteine at low temperatures and over a broad pH range. A target protein is cloned in-frame with the N-terminus of the intein-CBD fusion, and the stable fusion protein is purified by adsorption onto a chitin column. The immobilized fusion protein is then induced to undergo self-cleavage under mild conditions, resulting in the release of the target protein while the intein-CBD fusion remains bound to the column. No exogenous proteolytic cleavage is needed. Furthermore, using this procedure, the purified free target protein can be specifically labeled at its C-terminus.

Overexpression of BsoBI restriction endonuclease in E. coli, purification of the recombinant BsoBI, and identification of catalytic residues of BsoBI by random mutagenesis.

BsoBI is a type II restriction enzyme found in Bacillus stearothermophilus JN209 that recognizes the symmetric sequence 5'-CYCGRG-3' (Y=C or T; R=A or G) and cleaves between the first and second base to generate a four-base 5' extension. The cloning and sequencing of BsoBI restriction-modification system has been described by Ruan et al. [Mol. Gen. Genet. 252 (1996) 695-699]. Here we report the overexpression of BsoBI restriction endonuclease gene in E. coli by insertion of the endonuclease gene into an expression vector pRRS. The recombinant BsoBI was purified to homogeneity and its N-terminus sequence was determined. It has the same N-terminal aa sequence as the native enzyme. The constitutive expression of BsoBI from pRRS is lethal to E. coli in the absence of the cognate methylase. The bsoBIR gene was mutagenized with either hydroxylamine or by error-prone polymerase chain reaction in vitro and transferred into E. coli via plasmid vectors in the absence of the cognate methylase. Surviving transformants were selected that carry BsoBI variants which lost endonuclease activity. DNA sequencing of the mutant alleles revealed that G123, D124, D212, D246, E252 and H253 are important residues for enzymatic activity. An electrophoretic mobility shift assay was used to identify binding-proficient and cleavage-deficient variants. Seven variants I95M&D124Y, G123R, D212N, K207R&D212V, D246N, D246G and E252K can still bind DNA despite the loss of cleavage activity. Thus, residues D124, D212, D246 and E252 may be located near or within the catalytic center, and are likely involved in metal ion binding.

Cloning and sequence comparison of AvaI and BsoBI restriction-modification systems.

AvaI and BsoBI restriction endonucleases are isoschizomers which recognize the symmetric sequence 5'CYCGRG3' and cleave between the first C and second Y to generate a four-base 5' extension. The AvaI restriction endonuclease gene (avaIR) and methylase gene (avaIM) were cloned into Escherichia coli by the methylase selection method. The BsoBI restriction endonuclease gene (bsoBIR) and part of the BsoBI methylase gene (bsoBIM) were cloned by the "endo-blue" method (SOS induction assay), and the remainder of bsoBIM was cloned by inverse PCR. The nucleotide sequences of the two restriction-modification (RM) systems were determined. Comparisons of the predicted amino acid sequences indicated that AvaI and BsoBI endonucleases share 55% identity, whereas the two methylases share 41% identity. Although the two systems show similarity in protein sequence, their gene organization differs. The avaIM gene precedes avaIR in the AvaI RM system, while the bsoBI R gene is located upstream of bsoBI M in the BsoBI RM system. Both AvaI and BsoBI methylases contain motifs conserved among the N4 cytosine methylases.

Thermostable Bst DNA polymerase I lacks a 3'-->5' proofreading exonuclease activity.

A thermostable DNA polymerase, the Bst DNA polymerase I, from Bacillus stearothermophilus N3468 was prepared to near-homogeneity. The dominant species of the Bst DNA polymerase I preparation sized about 97 kDa when analyzed on SDS polyacrylamide gels. The Bst polA gene that codes for Bst polymerase I was cloned and sequenced. Comparative sequence analysis showed that all three conserved 3'-->5' exonuclease motifs found in E. coli DNA polymerase I were missing in Bst DNA polymerase I. This cast doubt on the existence of a 3'-->5' exonuclease function in that enzyme. Four biochemical assays were used to measure exonuclease activities of Bst DNA polymerase I, testing both full-length Bst polymerase I and the Bst large fragment which lacks the N-terminal 5'-->3' exonuclease domain. These exonuclease assays demonstrated that Bst DNA polymerase I only contained a double-strand dependent 5'-->3' exonuclease activity but lacked any detectable 3'-->5' proofreading exonuclease activity. The lack of 3'-->5' exonuclease function in a variety of thermostable repair DNA polymerases may reflect enhancement of thermostability at the expense of proofreading activity.