Type IIP Restriction Endonuclease Research Articles

Crystal structure of restriction endonuclease Kpn2I of CCGG-family

BackgroundRestriction endonucleases belong to prokaryotic restriction-modification systems, that protect host cells from invading DNA. Type II restriction endonucleases recognize short 4–8 bp sequences in the target DNA and cut both DNA strands producing double strand breaks. Type II restriction endonuclease Kpn2I cleaves 5′-T/CCGGA DNA sequence (“/” marks the cleavage position). Analysis of protein sequences suggested that Kpn2I belongs to the CCGG-family, which contains ten enzymes that recognize diverse nucleotides outside the conserved 5′-CCGG core and share similar motifs for the 5′-CCGG recognition and cleavage. MethodsWe solved a crystal structure of Kpn2I in a DNA-free form at 2.88 Å resolution. From the crystal structure we predicted active center and DNA recognition residues and tested them by mutational analysis. We estimated oligomeric state of Kpn2I by SEC-MALS and performed plasmid DNA cleavage assay to elucidate DNA cleavage mechanism. ResultsStructure comparison confirmed that Kpn2I shares a conserved active site and structural determinants for the 5′-CCGG tetranucleotide recognition with other restriction endonucleases of the CCGG-family. Guided by structural similarity between Kpn2I and the CCGG-family restriction endonucleases PfoI and AgeI, Kpn2I residues involved in the outer base pair recognition were proposed. ConclusionsKpn2I is an orthodox Type IIP restriction endonuclease, which acts as a dimer. Kpn2I shares structural similarity to the CCGG-family restriction endonucleases PfoI, AgeI and PspGI. General significanceThe Kpn2I structure concluded the studies of the CCGG-family, covering detailed structural and biochemical characterization of eleven restriction enzymes and their complexes with DNA.

Single-Molecule Dwell-Time Analysis of Restriction Endonuclease-Mediated DNA Cleavage.

This novel total internal reflection fluorescence microscopy-based assay facilitates the simultaneous measurement of the length of the catalytic cycle for hundreds of individual restriction endonuclease (REase) molecules in one experiment. This assay does not require protein labeling and can be carried out with a single imaging channel. In addition, the results of multiple individual experiments can be pooled to generate well-populated dwell-time distributions. Analysis of the resulting dwell-time distributions can help elucidate the DNA cleavage mechanism by revealing the presence of kinetic steps that cannot be directly observed. Example data collected using this assay with the well-studied REase, EcoRV - a dimeric Type IIP restriction endonuclease that cleaves the palindromic sequence GAT↓ATC (where ↓ is the cut site) - are in agreement with prior studies. These results suggest that there are at least three steps in the pathway to DNA cleavage that is initiated by introducing magnesium after EcoRV binds DNA in its absence, with an average rate of 0.17 s-1 for each step.

Protein NCRII-18: the role of gene fusion in the molecular evolution of restriction endonucleases.

This work first constructed the fusion protein NCRII-18 by fusing the restriction endonuclease Ecl18kI gene and part of the gene coding for the N-terminal domain of the endonuclease EcoRII. The fusion of the EcoRII N-terminal domain leads to a change in the properties of the recombinant protein. Unlike Ecl18kI, which made the basis of NCRII-18, the fusion protein predominantly recognizes the CCWGG sites, having lost the capability of interacting with the CCSGG sites. Experimental data support the hypothesis of a close evolutionary relationship between type IIE and IIP restriction endonucleases via a recombination between domains with active site structure and elements for recognition with domains responsible for recognition of DNA sequences.

TfoI produced by Tepidimonas fonticaldi PL17, a moderate thermophilic bacterium, is an isoschizomer of MseI.

A moderately thermophilic Gram-negative bacterium isolated from the Polok hot spring, Sikkim, India, was identified as a strain (PL17) of Tepidimonas fonticaldi by 16S rDNA sequencing. T. fonticaldi PL17 produces a Type IIP restriction endonuclease; named TfoI. Restriction mapping, run-off sequencing of TfoI-digests of dsDNA fragments, and end compatibility of TfoI with NdeI confirmed that the enzyme recognizes and cleaves the sequence 5'-T^TAA-3', and is thus an isoschizomer of MseI. The TfoI restriction-modification genes in the T. fonticaldi PL17 genome were identified, and the annotated TfoI protein encodes a protein of 181 amino acid residues that shares 47.2% sequence identity with MseI. The native enzyme was purified using a four-column chromatography protocol, and its functional homogeneity was confirmed by standard quality control tests. The ESI-MS measured molecular weight of purified TfoI (20.696kDa) is in agreement with that of the calculated monomeric molecular weight of the predicted TfoI protein sequence (20.694kDa). TfoI exhibits optimal activity in the temperature range of 55-70 °C with Mg+2 or Co+2 as cofactor. Similar to its isoschizomers, TfoI can be used as the frequent cutter for genome analysis.

Toward Direct Observation of the DNA Binding Dynamics of Monomeric Type IIP Restriction Endonucleases

Restriction endonucleases (REases) are enzymes that cleave duplex DNA at a recognition site specified by a particular nucleotide sequence. These enzymes are found in a wide range of bacterial species, and serve as a defense against infection by phage. Type IIP REases are typically antiparallel homodimers that recognize a palindromic DNA sequence and cleave within or close to the recognition site. However, some Type IIP REases cleave pseudopalindromic sequences, and some of these may be active as monomers. It is hypothesized that these monomeric REases sequentially cleave the two complementary strands of duplex DNA during a single DNA binding event. Since the two strands of DNA are antiparallel, after cleaving one strand, a monomeric REase would be required to rotate about the axis perpendicular to the DNA to be properly oriented to cleave the second strand. This type of reorientation is known a “flipping”. Although only a small number of proteins have been observed reorienting in this way, protein flipping may play an important role in binding to a specific DNA sequence. Direct observation of flipping during DNA cleavage will greatly improve our understanding of how monomeric REases mediate double strand breaks. We are currently using total internal reflection fluorescence (TIRF) microscopy to observe REase-mediated cleavage of quantum dot-labeled DNA at the single-molecule level. In our highly multiplexed assay, the disappearance of a quantum dot indicates cleavage of the DNA that tethers it to a functionalized glass coverslip. We plan to utilize single-molecule Forster resonance energy transfer (smFRET) to trace individual monomeric REases in real time through the entire process of DNA cleavage from substrate binding to product release. Our observations should provide significant insight into the mechanism by which these enzymes cleave duplex DNA.

Restriction endonuclease AgeI is a monomer which dimerizes to cleave DNA.

Although all Type II restriction endonucleases catalyze phosphodiester bond hydrolysis within or close to their DNA target sites, they form different oligomeric assemblies ranging from monomers, dimers, tetramers to higher order oligomers to generate a double strand break in DNA. Type IIP restriction endonuclease AgeI recognizes a palindromic sequence 5΄-A/CCGGT-3΄ and cuts it (‘/’ denotes the cleavage site) producing staggered DNA ends. Here, we present crystal structures of AgeI in apo and DNA-bound forms. The structure of AgeI is similar to the restriction enzymes that share in their target sites a conserved CCGG tetranucleotide and a cleavage pattern. Structure analysis and biochemical data indicate, that AgeI is a monomer in the apo-form both in the crystal and in solution, however, it binds and cleaves the palindromic target site as a dimer. DNA cleavage mechanism of AgeI is novel among Type IIP restriction endonucleases.

DNA recognition by the SwaI restriction endonuclease involves unusual distortion of an 8 base pair A:T-rich target.

R.SwaI, a Type IIP restriction endonuclease, recognizes a palindromic eight base pair (bp) symmetric sequence, 5΄-ATTTAAAT-3΄, and cleaves that target at its center to generate blunt-ended DNA fragments. Here, we report three crystal structures of SwaI: unbound enzyme, a DNA-bound complex with calcium ions; and a DNA-bound, fully cleaved complex with magnesium ions. We compare these structures to two structurally similar ‘PD-D/ExK’ restriction endonucleases (EcoRV and HincII) that also generate blunt-ended products, and to a structurally distinct enzyme (the HNH endonuclease PacI) that also recognizes an 8-bp target site consisting solely of A:T base pairs. Binding by SwaI induces an extreme bend in the target sequence accompanied by un-pairing and re-ordering of its central A:T base pairs. This result is reminiscent of a more dramatic target deformation previously described for PacI, implying that long A:T-rich target sites might display structural or dynamic behaviors that play a significant role in endonuclease recognition and cleavage.

Elimination of inter-domain interactions increases the cleavage fidelity of the restriction endonuclease DraIII.

DraIII is a type IIP restriction endonucleases (REases) that recognizes and creates a double strand break within the gapped palindromic sequence CAC↑NNN↓GTG of double-stranded DNA (↑ indicates nicking on the bottom strand; ↓ indicates nicking on the top strand). However, wild type DraIII shows significant star activity. In this study, it was found that the prominent star site is CAT↑GTT↓GTG, consisting of a star 5′ half (CAT) and a canonical 3′ half (GTG). DraIII nicks the 3′ canonical half site at a faster rate than the 5′ star half site, in contrast to the similar rate with the canonical full site. The crystal structure of the DraIII protein was solved. It indicated, as supported by mutagenesis, that DraIII possesses a ββα-metal HNH active site. The structure revealed extensive intra-molecular interactions between the N-terminal domain and the C-terminal domain containing the HNH active site. Disruptions of these interactions through site-directed mutagenesis drastically increased cleavage fidelity. The understanding of fidelity mechanisms will enable generation of high fidelity REases.Electronic supplementary materialThe online version of this article (doi:10.1007/s13238-014-0038-z) contains supplementary material, which is available to authorized users.

BspRI restriction endonuclease: cloning, expression in Escherichia coli and sequential cleavage mechanism

The GGCC-specific restriction endonuclease BspRI is one of the few Type IIP restriction endonucleases, which were suggested to be a monomer. Amino acid sequence information obtained by Edman sequencing and mass spectrometry analysis was used to clone the gene encoding BspRI. The bspRIR gene is located adjacently to the gene of the cognate modification methyltransferase and encodes a 304 aa protein. Expression of the bspRIR gene in Escherichia coli was dependent on the replacement of the native TTG initiation codon with an ATG codon, explaining previous failures in cloning the gene using functional selection. A plasmid containing a single BspRI recognition site was used to analyze kinetically nicking and second-strand cleavage under steady-state conditions. Cleavage of the supercoiled plasmid went through a relaxed intermediate indicating sequential hydrolysis of the two strands. Results of the kinetic analysis of the first- and second-strand cleavage are consistent with cutting the double-stranded substrate site in two independent binding events. A database search identified eight putative restriction-modification systems in which the predicted endonucleases as well as the methyltransferases share high sequence similarity with the corresponding protein of the BspRI system. BspRI and the related putative restriction endonucleases belong to the PD-(D/E)XK nuclease superfamily.

Selection of enzymes for terminal restriction fragment length polymorphism analysis of fungal internally transcribed spacer sequences.

Terminal restriction fragment length polymorphism (TRFLP) profiling of the internally transcribed spacer (ITS) ribosomal DNA of unknown fungal communities is currently unsupported by a broad-range enzyme-choosing rationale. An in silico study of terminal fragment size distribution was therefore performed following virtual digestion (by use of a set of commercially available 135 type IIP restriction endonucleases) of all published fungal ITS sequences putatively annealing to primers ITS1 and ITS4. Different diversity measurements were used to rank primer-enzyme pairs according to the richness and evenness that they showed. Top-performing pairs were hierarchically clustered to test for data dependency. The enzyme set composed of MaeII, BfaI, and BstNI returned much better results than randomly chosen enzyme sets in computer simulations and is therefore recommended for in vitro TRFLP profiling of fungal ITSs.

Unexpected domain architecture of Type IIP restriction endonuclease SdaI

Unexpected domain architecture of Type IIP restriction endonuclease SdaI

Kinetic analyses of divalent cation-dependent EcoRV digestions on a DNA-immobilized quartz crystal microbalance

Enzymatic digestion with a type IIP restriction endonuclease EcoRV was investigated on a DNA-immobilized 27-MHz quartz crystal microbalance (QCM). Real-time observations of both the enzyme binding process and the DNA cleavage process of EcoRV were followed by frequency (mass) changes on the QCM, which were dependent on divalent cations such as Ca 2+ or Mg 2+. In the presence of Ca 2+, the site-specific binding of EcoRV to DNA could be observed, without the catalytic process. On the other hand, in the presence of Mg 2+, both the binding of the enzyme to the specific DNA (mass increase) and the site-specific cleavage reaction (mass decrease) could be observed continuously from QCM frequency changes. From time courses of frequency (mass) changes, each kinetic parameter, namely binding rate constants ( k on), dissociation rate constants ( k off), dissociation constants ( K d) of EcoRV to DNA, and catalytic rate constant ( k cat) of the cleavage reaction, could be determined. The binding kinetic parameters of EcoRV in the presence of Ca 2+ were consistent with those of the binding process followed by the cleavage process in the presence of Mg 2+. The k cat value obtained by the QCM method was also consistent with that obtained by other methods. This study is the first to simultaneously determine k on, k off, and k cat for a type IIP restriction endonuclease on one device.

Fast-scanning atomic force microscopy reveals the molecular mechanism of DNA cleavage by ApaI endonuclease

Newly developed fast-scanning atomic force microscopy (AFM) allows the dissection of molecular events such as DNA-enzyme reactions at the single-molecule level. With this novel technology, a model is proposed of the DNA cleavage reaction by a type IIP restriction endonuclease ApaI. Detailed analyses revealed that ApaI bound to DNA as a dimer and slid along DNA in a one-dimensional diffusion manner. When it encountered a specific DNA sequence, the enzyme halted for a moment to digest the DNA. Immediately after digestion, the ApaI dimer separated into two monomers, each of which remained on the DNA end and then dissociated from the DNA end. Thus, fast-scanning AFM is a powerful tool to aid the understanding of protein structures and dynamics in biological reactions at the single-molecule level in sub-seconds.

Two crystal forms of the restriction enzyme MspI–DNA complex show the same novel structure

The crystal structure of the Type IIP restriction endonuclease MspI bound to DNA containing its cognate recognition sequence has been determined in both monoclinic and orthorhombic space groups. Significantly, these two independent crystal forms present an identical structure of a novel monomer-DNA complex, suggesting a functional role for this novel enzyme-DNA complex. In both crystals, MspI interacts with the CCGG DNA recognition sequence as a monomer, using an asymmetric mode of recognition by two different structural motifs in a single polypeptide. In the crystallographic asymmetric unit, the two DNA molecules in the two MspI-DNA complexes appear to stack with each other forming an end-to-end pseudo-continuous 19-mer duplex. They are primarily B-form and no major bends or kinks are observed. For DNA recognition, most of the specific contacts between the enzyme and the DNA are preserved in the orthorhombic structure compared with the monoclinic structure. A cation is observed near the catalytic center in the monoclinic structure at a position homologous to the 74/45 metal site of EcoRV, and the orthorhombic structure also shows signs of this same cation. However, the coordination ligands of the metal are somewhat different from those of the 74/45 metal site of EcoRV. Combined with structural information from other solved structures of Type II restriction enzymes, the possible relationship between the structures of the enzymes and their cleavage behaviors is discussed.

Conversion of the Tetrameric Restriction Endonuclease Bse634I into a Dimer: Oligomeric Structure–Stability–Function Correlations

The Bse634I restriction endonuclease is a tetramer and belongs to the type IIF subtype of restriction enzymes. It requires two recognition sites for its optimal activity and cleaves plasmid DNA with two sites much faster than a single-site DNA. We show that disruption of the tetramerisation interface of Bse634I by site-directed mutagenesis converts the tetrameric enzyme into a dimer. Dimeric W228A mutant cleaves plasmid DNA containing one or two sites with the same efficiency as the tetramer cleaves the two-site plasmid. Hence, the catalytic activity of the Bse634I tetramer on a single-site DNA is down-regulated due to the cross-talking interactions between the individual dimers. The autoinhibition within the Bse634I tetramer is relieved by bridging two DNA copies into the synaptic complex that promotes fast and concerted cleavage at both sites. Cleavage analysis of the oligonucleotide attached to the solid support revealed that Bse634I is able to form catalytically competent synaptic complexes by bridging two molecules of the cognate DNA, cognate DNA-miscognate DNA and cognate DNA-product DNA. Taken together, our data demonstrate that a single W228A mutation converts a tetrameric type IIF restriction enzyme Bse634I into the orthodox dimeric type IIP restriction endonuclease. However, the stability of the dimer towards chemical denaturants, thermal inactivation and proteolytic degradation are compromised.

Diversity of type II restriction endonucleases that require two DNA recognition sites.

Orthodox Type IIP restriction endonucleases, which are commonly used in molecular biological work, recognize a single palindromic DNA recognition sequence and cleave within or near this sequence. Several new studies have reported on structural and biochemical peculiarities of restriction endonucleases that differ from the orthodox in that they require two copies of a particular DNA recognition sequence to cleave the DNA. These two sites requiring restriction endonucleases belong to different subtypes of Type II restriction endonucleases, namely Types IIE, IIF and IIS. We compare enzymes of these three types with regard to their DNA recognition and cleavage properties. The simultaneous recognition of two identical DNA sites by these restriction endonucleases ensures that single unmethylated recognition sites do not lead to chromosomal DNA cleavage, and might reflect evolutionary connections to other DNA processing proteins that specifically function with two sites.