Defining amino acid residues involved in DNA-protein interactions and revelation of 3'-exonuclease activity in endonuclease V

Endonuclease V is an enzyme that initiates a conserved DNA repair pathway by making an endonucleolytic incision at the 3' side one nucleotide from a deaminated base lesion. Site-directed mutagenesis analysis was conducted at seven conserved motifs of the thermostable Thermotoga maritima endonuclease V to probe for residues that affect DNA-protein interactions. Y80, G83, and L85 in motif III, H116 and G121 in motif IV, A138 in motif V, and S182 in motif VI affect binding of both the double-stranded inosine-containing DNA substrate and the nicked double-stranded inosine-containing DNA product, resulting in multiple enzymatic turnovers. The substantially reduced DNA cleavage activity observed in G113 in motif IV and G136 in motif V can be partly attributed to their defect in metal cofactor coordination. Alanine substitution at amino acid 118 primarily reduces the level of binding to the nicked product, suggesting that R118 plays a significant role in postcleavage DNA-protein interaction. Binding and cleavage analyses of multiple mutants at positions Y80 and H116 underscore the role these residues play in protein-DNA interaction and implicate their potential involvement as a hydrogen bond donor in recognition of deaminated DNA bases. DNA cleavage analysis using mutants defective in DNA binding reveals a novel 3'-exonuclease activity in endonuclease V. An alternative model is proposed that entails lesion specific cleavage and endonuclease to 3'-exonuclease mode switch by endonuclease V for removal of deaminated base lesions during endonuclease V-mediated repair.     

Amino acid residues in the GIY-YIG endonuclease II of phage T4 affecting sequence recognition and binding as well as catalysis

Phage T4 endonuclease II (EndoII), a GIY-YIG endonuclease lacking a carboxy-terminal DNA-binding domain, was subjected to site-directed mutagenesis to investigate roles of individual amino acids in substrate recognition, binding, and catalysis. The structure of EndoII was modeled on that of UvrC. We found catalytic roles for residues in the putative catalytic surface (G49, R57, E118, and N130) similar to those described for I-TevI and UvrC; in addition, these residues were found to be important for substrate recognition and binding. The conserved glycine (G49) and arginine (R57) were essential for normal sequence recognition. Our results are in agreement with a role for these residues in forming the DNA-binding surface and exposing the substrate scissile bond at the active site. The conserved asparagine (N130) and an adjacent proline (P127) likely contribute to positioning the catalytic domain correctly. Enzymes in the EndoII subfamily of GIY-YIG endonucleases share a strongly conserved middle region (MR, residues 72 to 93, likely helical and possibly substituting for heterologous helices in I-TevI and UvrC) and a less strongly conserved N-terminal region (residues 12 to 24). Most of the conserved residues in these two regions appeared to contribute to binding strength without affecting the mode of substrate binding at the catalytic surface. EndoII K76, part of a conserved NUMOD3 DNA-binding motif of homing endonucleases found to overlap the MR, affected both sequence recognition and catalysis, suggesting a more direct involvement in positioning the substrate. Our data thus suggest roles for the MR and residues conserved in GIY-YIG enzymes in recognizing and binding the substrate.     

Implications for switching restriction enzyme specificities from the structure of BstYI bound to a BglII DNA sequence

The type II restriction endonuclease BstYI recognizes the degenerate sequence 5'-RGATCY-3' (where R = A/G and Y = C/T), which overlaps with both BamHI (GGATCC) and BglII (AGATCT), and thus raises the question of whether BstYI DNA recognition will be more BamHI-like or BglII-like. We present here the structure of BstYI bound to a cognate DNA sequence (AGATCT). We find the complex to be more BglII-like with similarities mapping to DNA conformation, domain organization, and residues involved in catalysis. However, BstYI is unique in containing an extended arm subdomain, and the mechanism of DNA capture has both BglII-like and BamHI-like elements. Further, DNA recognition is more minimal than BglII and BamHI, where only two residues mediate recognition of the entire core sequence. Taken together, the structure reveals a mechanism of degenerate DNA recognition and offers insights into the possibilities and limitations in altering specificities of closely related restriction enzymes.     

Mutational analysis of endonuclease V from Thermotoga maritima

Endonuclease V nicks damaged DNA at the second phosphodiester bond 3' to inosine, uracil, mismatched bases, or abasic (AP) sites. Alanine scanning mutagenesis was performed in nine conserved positions of Thermotoga maritima endonuclease V to identify amino acid residues involved in recognition or endonucleolytic cleavage of these diverse substrates. Alanine substitution at D43, E89, and D110 either abolishes or substantially reduces inosine cleavage activity. These three mutants gain binding affinity for binding to double-stranded or single-stranded inosine substrates in the absence of a metal ion, suggesting that these residues may be involved in coordinating catalytic metal ion(s). Y80A, H116A, and, to a lesser extent, R88A demonstrate reduced affinities for double-stranded or single-stranded inosine substrates or nicked products. The lack of tight binding to a nicked inosine product accounts for the increased rate of turnover of inosine substrate since the product release is less rate-limiting. Y80A, R88A, and H116A fail to cleave AP site substrates. Their activities toward uracil substrates are in the following order: H116A > R88A > Y80A. These residues may play a role in substrate recognition. K139A maintains wild-type binding affinity for binding to double-stranded and single-stranded inosine substrate, but fails to cleave AP site and uracil substrate efficiently, suggesting that K139 may play a role in facilitating non-inosine substrate cleavage.     

Functional expression of a sequence-specific endonuclease encoded by the retrotransposon R2Bm

A fraction of the 28S ribosomal genes in certain insect species is interrupted by the insertion elements R1 and R2. These two elements from the silkworm Bombyx mori (R1Bm and R2Bm) are retrotransposons capable of transposing in a highly sequence-specific manner. We report here the functional expression in E. coli of the entire single open reading frame of R2Bm and show that it encodes a double-stranded endo-nuclease (integrase) that can specifically cleave the 28S gene at the R2 insertion site. The resulting cleavage is a 4 bp staggered 5' overhang. Deletion analysis of the 28S gene revealed that the DNA sequence required for specific cleavage is asymmetric with respect to the actual insertion (cleavage) site, with fewer than 10 bp required at one side and at least 24 bp at the other side of the site. A model is proposed based on these and previous data to account for the sequence-specific integration of the R2 retrotransposon.     

Related sites in human and herpesvirus DNA recognized by methylated DNA-binding protein from human placenta.

Methylated DNA-binding protein (MDBP) from mammalian cells binds specifically to six pBR322 and M13mp8 DNA sequences but only when they are methylated at their CpG dinucleotide pairs. We cloned three high-affinity MDBP recognition sites from the human genome on the basis of their binding to MDBP. These showed much homology to the previously characterized prokaryotic sites. However, the human sites exhibited methylation-independent binding apparently because of the replacement of m5C residues with T residues. We also identified three other MDBP sites in the herpes simplex virus type 1 genome, two of which require in vitro CpG methylation for binding and are in the upstream regions of viral genes. A comparison of MDBP sites leads to the following partially symmetrical consensus sequence for MDBP recognition sites: 5'-R T m5Y R Y Y A m5Y R G m5Y R A Y-3'; m5Y (m5C or T), R (A or G), Y (C or T). This consensus sequence displays an unusually high degree of degeneracy. Also, interesting deviations from this consensus sequence, including a one base-pair deletion in the middle, are sometimes observed in high-affinity MDBP sites.     

Isolation of BamHI variants with reduced cleavage activities

Derivation of the bamhIR sequence (Brooks, J. E., Nathan, P.D., Landry, D., Sznyter, L.A., Waite-Rees, P., Ives, C. C., Mazzola, L. M., Slatko, B. E., and Benner, J. S. (1991) Nucleic Acids Res., in press), the gene coding for BamHI endonuclease, has facilitated construction of an Escherichia coli strain that overproduces BamHI endonuclease (W. E. Jack, L. Greenough, L. F. Dorner, S. Y. Xu, T. Strezelecka, A. K. Aggarwal, and I. Schildkraut, submitted for publication). As expected, low-level constitutive expression of the bamhIR gene in E. coli from the Ptac promotor construct is lethal to the host unless the bamHIM gene, which encodes the BamHI methylase, is also expressed within the cell. We identified four classes of BamHI endonuclease variants deficient in catalysis by selecting for survival of a host deficient for bamHIM gene, transformed with mutagenized copies of the bamhIR gene, and then screening the surviving cell extracts for DNA cleavage and binding activities. Class I variants (G56S, G91S/T153I, T114I, G130R, E135K, T153I, T157I, G194D) displayed 0.1-1% of the wild-type cleavage activity; class II variant (D94N) lacked cleavage activity but retained wild-type DNA binding specificity; class III variants (E77K, E113K) lacked cleavage activity but bound DNA more tightly; class IV variants (G56D, G90D, G91S, R122H, R155H) lacked both binding and cleavage activities. Variants with residual cleavage activities induced the E. coli SOS response and thus are presumed to cleave chromosomal DNA in vivo. We conclude that Glu77, Asp94, and Glu113 residues are essential for BamHI catalytic function.     

Mapping of a DNA binding region of the PI-sceI homing endonuclease by affinity cleavage and alanine-scanning mutagenesis.

The PI-SceI protein is a member of the LAGLIDADG family of homing endonucleases that is generated by a protein splicing reaction. PI-SceI has a bipartite domain structure, and the protein splicing and endonucleolytic reactions are catalyzed by residues in domains I and II, respectively. Structural and mutational evidence indicates that both domains mediate DNA binding. Treatment of the protein with trypsin breaks a peptide bond within a disordered region of the endonuclease domain situated between residues Val-270 and Leu-280 and interferes with the ability of this domain to bind DNA. To identify specific residues in this region that are involved in DNA binding and/or catalysis, alanine-scanning mutagenesis was used to create a set of PI-SceI mutant proteins that were assayed for activity. One of these mutants, N281A, was >300-fold less active than wild-type PI-SceI, and two other proteins, R277A and N284A, were completely inactive. These decreases in cleavage activity parallel similar decreases in substrate binding by the endonuclease domains of these mutant proteins. We mapped the approximate position of the disordered region to one of the ends of the 31 base pair PI-SceI recognition sequence using mutant proteins that were substituted with cysteine at residues Asn-274 and Glu-283 and tethered to the chemical nuclease FeBABE. These mutational and affinity cleavage data strongly support a model of PI-SceI docked to its DNA substrate that suggests that one or more residues identified here are responsible for contacting base pair A/T(-)(9), which is essential for substrate binding.     

Evidence for mutations that break communication between the Endo and Topo domains in NaeI endonuclease/topoisomerase

NaeI is a type IIe endonuclease that interacts with two DNA recognition sequences to cleave DNA. One DNA sequence serves as a substrate and the other serves to activate cleavage. NaeI is divided into two domains whose structures parallel the two functionalities recognized in NaeI, endonuclease and topoisomerase. In this study, we report evidence for mutations that break interdomain functional communication in a NaeI-DNA complex. Deletion of the initial 124 amino acids of the N-terminal domain of NaeI converted NaeI to a monomer, consistent with self-association being mediated by the Endo domain. Deletions within a small region of the C-terminal DNA binding domain of NaeI (amino acids 182-192) altered the recognition by NaeI of sequences flanking the NaeI recognition sequence. Substituting Ala for Arg182 within this region had no apparent effect on DNA binding but greatly reduced the extent of DNA cleavage even though it is not part of the catalytic Endo domain. Substituting Ala for Ile185 reduced the extent of DNA binding about 1000-fold. Substituting Ala for Lys189 altered flanking sequence recognition. Residues 182-192 are away from the Endo domain responsible for cleavage and also face away from the modeled DNA binding faces of the apoprotein crystal structure. We propose that residues 182-192 are part of a web that mediates the flow of information between the NaeI Endo and Topo domains.     

Mutagenesis of the DNA binding residues in bovine pancreatic DNase 1: an investigation into the mechanism of sequence discrimination by a sequence selective nuclease.

The sequence selectivity of DNase 1 cleavage has been investigated by site-directed mutagenesis of a chemically synthesised gene. Two key DNA binding residues have been conservatively altered (Y76F and R41K) or have had their side-chains truncated (Y76A and R41A) and the effect on the cleavage of tyr T promoter DNA has been noted. It would appear from these studies that DNase 1 is not sensitive to minor groove width via these DNA-contacting residues, and it is suggested that DNA helical stiffness is a controlling parameter in determining DNase 1 sequence selectivity.     

Crystal structure of BstYI at 1.85A resolution: a thermophilic restriction endonuclease with overlapping specificities to BamHI and BglII

We report here the structure of BstYI, an "intermediate" type II restriction endonuclease with overlapping sequence specificities to BamHI and BglII. BstYI, a thermophilic endonuclease, recognizes and cleaves the degenerate hexanucleotide sequence 5'-RGATCY-3' (where R=A or G and Y=C or T), cleaving DNA after the 5'-R on each strand to produce four-base (5') staggered ends. The crystal structure of free BstYI was solved at 1.85A resolution by multi-wavelength anomalous dispersion (MAD) phasing. Comparison with BamHI and BglII reveals a strong structural consensus between all three enzymes mapping to the alpha/beta core domain and residues involved in catalysis. Unexpectedly, BstYI also contains an additional "arm" substructure outside of the core protein, which enables the enzyme to adopt a more compact, intertwined dimer structure compared with BamHI and BglII. This arm substructure may underlie the thermostability of BstYI. We identify putative DNA recognition residues and speculate as to how this enzyme achieves a "relaxed" DNA specificity.     

Structural analysis of cysteine-free Nt.BspD6 nicking endonuclease and its functional features

Nicking endonuclease Nt.BspD6I (Nt.BspD6I) is the large subunit of the heterodimeric restriction endonuclease R.BspD6I. It recognizes the short specific DNA sequence 5´′- GAGTC and cleaves only the top strand in dsDNA at a distance of four nucleotides downstream the recognition site toward the 3´′-terminus. A mechanism of interaction of this protein with DNA is still unknown. Here we report the crystal structure of Cysteine-free Nt.BspD6I, with four cysteine residues (11, 160, 508, 578) substituted by serine, which was determined with a resolution of 1.93 Å. A comparative structural analysis showed that the substitution of cysteine residues induced marked conformational changes in the N-terminal recognition and the C-terminal cleavage domains. As a result of this changes were formed three new hydrogen bonds and the electrostatic field in these regions changed compared with wild type Nt.BspD6I. The substitution of cysteine residues did not alter the nicking function of Cysteine-free Nt.BspD6I but caused change in the activity of Cysteine-free heterodimeric restriction endonuclease R.BspD6I due to a change in the interaction between its large and small subunits. The results obtained contribute to the identification of factors influencing the interactions of subunits in the heterodimeric restriction enzyme R.BspD6I.     

The restriction endonuclease R.NmeDI from Neisseria meningitidis that recognizes a palindromic sequence and cuts the DNA on both sides of the recognition sequence

The restriction endonuclease Type II R.NmeDI from Neisseria meningitidis 2120 (serogroup C, ST-11 complex) was characterized. The cloned nmeDIR gene was expressed in Escherichia coli cells, and the endonucleolytic and restriction activities of R.NmeDI were then observed in vitro and in vivo. The nmeDIR gene consists of 1056 bp coding 351 aa protein with a calculated molecular weight of M_(r) = 39 000 ± 1000 Da. The R.NmeDI enzyme was purified to apparent homogeneity following overexpression, using metal affinity chromatography. This enzyme recognizes a palindrome sequence and cleaves double-stranded DNA upstream and downstream of its recognition sequence (12/7) RCCGGY (7/12) (R = A/G, Y = C/T) cutting out a 25-bp fragment. R.NmeDI cleaves in two steps. The enzyme cleaves the first strand randomly on either side of the recognition sequence generating an intermediate, and the second cleavage occurs more slowly and results in the production of a final reaction product. The R.NmeDI endonuclease requires two recognition sequences for effective cleavage. The tetramer is an active form of the R.NmeDI enzyme.     

Evolution of I-SceI homing endonucleases with increased DNA recognition site specificity

Elucidating how homing endonucleases undergo changes in recognition site specificity will facilitate efforts to engineer proteins for gene therapy applications. I-SceI is a monomeric homing endonuclease that recognizes and cleaves within an 18-bp target. It tolerates limited degeneracy in its target sequence, including substitution of a C:G₊₄ base pair for the wild-type A:T₊₄ base pair. Libraries encoding randomized amino acids at I-SceI residue positions that contact or are proximal to A:T₊₄ were used in conjunction with a bacterial one-hybrid system to select I-SceI derivatives that bind to recognition sites containing either the A:T₊₄ or the C:G₊₄ base pairs. As expected, isolates encoding wild-type residues at the randomized positions were selected using either target sequence. All I-SceI proteins isolated using the C:G₊₄ recognition site included small side-chain substitutions at G100 and either contained (K86R/G100T, K86R/G100S and K86R/G100C) or lacked (G100A, G100T) a K86R substitution. Interestingly, the binding affinities of the selected variants for the wild-type A:T₊₄ target are 4- to 11-fold lower than that of wild-type I-SceI, whereas those for the C:G₊₄ target are similar. The increased specificity of the mutant proteins is also evident in binding experiments in vivo. These differences in binding affinities account for the observed ∼36-fold difference in target preference between the K86R/G100T and wild-type proteins in DNA cleavage assays. An X-ray crystal structure of the K86R/G100T mutant protein bound to a DNA duplex containing the C:G₊₄ substitution suggests how sequence specificity of a homing enzyme can increase. This biochemical and structural analysis defines one pathway by which site specificity is augmented for a homing endonuclease.     

Characterization of BseMII, a new type IV restriction-modification system, which recognizes the pentanucleotide sequence 5'-CTCAG(N)(10/8)/

We report the properties of the new BseMII restriction and modification enzymes from Bacillus stearothermophilus Isl 15-111, which recognize the 5'-CTCAG sequence, and the nucleotide sequence of the genes encoding them. The restriction endonuclease R.BseMII makes a staggered cut at the tenth base pair downstream of the recognition sequence on the upper strand, producing a two base 3'-protruding end. Magnesium ions and S:-adenosyl-L-methionine (AdoMet) are required for cleavage. S:-adenosylhomocysteine and sinefungin can replace AdoMet in the cleavage reaction. The BseMII methyltransferase modifies unique adenine residues in both strands of the target sequence 5'-CTCAG-3'/5'-CTGAG-3'. Monomeric R.BseMII in addition to endonucleolytic activity also possesses methyltransferase activity that modifies the A base only within the 5'-CTCAG strand of the target duplex. The deduced amino acid sequence of the restriction endonuclease contains conserved motifs of DNA N6-adenine methylases involved in S-adenosyl-L-methionine binding and catalysis. According to its structure and enzymatic properties, R.BseMII may be regarded as a representative of the type IV restriction endonucleases.     

Mutational Analysis of Highly Conserved Residues in the Phage PhiC31 Integrase Reveals Key Amino Acids Necessary for the DNA Recombination

Background

Amino acid sequence alignment of phage phiC31 integrase with the serine recombinases family revealed highly conserved regions outside the catalytic domain. Until now, no system mutational or biochemical studies have been carried out to assess the roles of these conserved residues in the recombinaton of phiC31 integrase.

Methodology/Principal Findings

To determine the functional roles of these conserved residues, a series of conserved residues were targeted by site-directed mutagenesis. Out of the 17 mutants, 11 mutants showed impaired or no recombination ability, as analyzed by recombination assay both in vivo and in vitro. Results of DNA binding activity assays showed that mutants (R18A, I141A, L143A,E153A, I432A and V571A) exhibited a great decrease in DNA binding affinity, and mutants (G182A/F183A, C374A, C376A/G377A, Y393A and V566A) had completely lost their ability to bind to the specific target DNA attB as compared with wild-type protein. Further analysis of mutants (R18A, I141A, L143A and E153A) synapse and cleavage showed that these mutants were blocked in recombination at the stage of strand cleavage.

Conclusions/Significance

This data reveals that some of the highly conserved residues both in the N-terminus and C-terminus region of phiC31 integrase, play vital roles in the substrate binding and cleavage. The cysteine-rich motif and the C-tail val-rich region of phiC31 integrase may represent the major DNA binding domains of phiC31 integrase.