Characterization of the specific DNA nicking activity of restriction endonuclease N.BstNBI

Cloning of CviPII nicking and modification system from chlorella virus NYs-1 and application of Nt.CviPII in random DNA amplification

The cloning and expression of the CviPII DNA nicking and modification system encoded by chlorella virus NYs-1 is described. The system consists of a co-linear MTase encoding gene (cviPIIM) and a nicking endonuclease encoding gene (cviPIINt) separated by 12 nt. M.CviPII possesses eight conserved amino acid motifs (I to VIII) typical of C5 MTases, but, like another chlorella virus MTase M.CviJI, lacks conserved motifs IX and X. In addition to modification of the first cytosine in CCD (D = A, G or T) sequences, M.CviPII modifies both the first two cytosines in CCAA and CCCG sites as well. Nt.CviPII has significant amino acid sequence similarity to Type II restriction endonuclease CviJI that recognizes an overlapping sequence (RG--CY). Nt.CviPII was expressed in Escherichia coli with or without a His-tag in a host pre-modified by M.CviPII. Recombinant Nt.CviPII recognizes the DNA sequence CCD and cleaves the phosphodiester bond 5' of the first cytosine while the other strand of DNA at this site is not affected. Nt.CviPII displays site preferences with CCR (R = A or G) sites preferred over CCT sites. Nt.CviPII is active from 16 to 65 degrees C with a temperature optimum of 30-45 degrees C. Nt.CviPII can be used to generate single-stranded DNAs (ssDNAs) for isothermal strand-displacement amplification. Nt.CviPII was used in combination with Bst DNA polymerase I large fragment to rapidly amplify anonymous DNA from genomic DNA or from a single bacterial colony.

Asymmetric activation of Xer site-specific recombination by FtsK

Chromosome dimers, which frequently form in Escherichia coli, are resolved by the combined action of two tyrosine recombinases, XerC and XerD, acting at a specific site on the chromosome, dif, together with the cell division protein FtsK. The C-terminal domain of FtsK (FtsK(C)) is a DNA translocase implicated in helping synapsis of the dif sites and in locally promoting XerD strand exchanges after synapse formation. Here we show that FtsK(C) ATPase activity is directly involved in the local activation of Xer recombination at dif, by using an intermolecular recombination assay that prevents significant DNA translocation, and we confirm that FtsK acts before Holliday junction formation. We show that activation only occurs with a DNA segment adjacent to the XerD-binding site of dif. Only one such DNA extension is required. Taken together, our data suggest that FtsK needs to contact the XerD recombinase to switch its activity on using ATP hydrolysis.

The isolation of strand-specific nicking endonucleases from a randomized SapI expression library

The Type IIS restriction endonuclease SapI recognizes the DNA sequence 5'-GCTCTTC-3' (top strand by convention) and cleaves downstream (N1/N4) indicating top- and bottom-strand spacing, respectively. The asymmetric nature of DNA recognition presented the possibility that one, if not two, nicking variants might be created from SapI. To explore this possibility, two parallel selection procedures were designed to isolate either top-strand nicking or bottom-strand nicking variants from a randomly mutated SapI expression library. These procedures take advantage of a SapI substrate site designed into the expression plasmid, which allows for in vitro selection of plasmid clones possessing a site-specific and strand-specific nick. A procedure designed to isolate bottom-strand nicking enzymes yielded Nb.SapI-1 containing a critical R420I substitution near the end of the protein. The top-strand procedure yielded several SapI variants with a distinct preference for top-strand cleavage. Mutations present within the selected clones were segregated to confirm a top-strand nicking phenotype for single variants Q240R, E250K, G271R or K273R. The nature of the amino acid substitutions found in the selected variants provides evidence that SapI may possess two active sites per monomer. This work presents a framework for establishing the mechanism of SapI DNA cleavage.

Engineering strand-specific DNA nicking enzymes from the type IIS restriction endonucleases BsaI, BsmBI, and BsmAI

More than 80 type IIA/IIS restriction endonucleases with different recognition specificities are now known. In contrast, only a limited number of strand-specific nicking endonucleases are currently available. To overcome this limitation, a novel genetic screening method was devised to convert type IIS restriction endonucleases into strand-specific nicking endonucleases. The genetic screen consisted of four steps: (1) random mutagenesis to create a plasmid library, each bearing an inactivated endonuclease gene; (2) restriction digestion of plasmids containing the wild-type and the mutagenized endonuclease gene; (3) back-crosses with the wild-type gene by ligation to the wild-type N-terminal or C-terminal fragment; (4) transformation of the ligated DNA into a pre-modified host and screening for nicking endonuclease activity in total cell culture or cell extracts of the transformants. Nt.BsaI and Nb.BsaI nicking endonucleases were isolated from BsaI using this genetic screen. In addition, site-directed mutagenesis was carried out to isolate BsaI nicking variants with minimal double-stranded DNA cleavage activity. The equivalent amino acid substitutions were introduced into BsmBI and BsmAI restriction endonucleases with similar recognition sequence and significant amino acid sequence identity and their nicking variants were successfully isolated. This work provides strong evidence that some type IIS restriction endonucleases carry two separate active sites. When one of the active sites is inactivated, the type IIS restriction endonuclease may nick only one strand.

How the BfiI restriction enzyme uses one active site to cut two DNA strands

Unlike other restriction enzymes, BfiI functions without metal ions. It recognizes an asymmetric DNA sequence, 5'-ACTGGG-3', and cuts top and bottom strands at fixed positions downstream of this sequence. Many restriction enzymes are dimers of identical subunits, with one active site for each DNA strand. Others, like FokI, dimerize transiently during catalysis. BfiI is also a dimer but it has only one active site, at the dimer interface. We show here that BfiI remains a dimer as it makes double-strand breaks in DNA and that its single active site acts sequentially, first on the bottom and then the top strand. Hence, after cutting the bottom strand, a rearrangement of either the protein and/or the DNA in the BfiI-DNA complex must switch the active site to the top strand. Low pH values selectively block top-strand cleavage, converting BfiI into a nicking enzyme that cleaves only the bottom strand. The switch to the top strand may depend on the ionization of the cleaved 5' phosphate in the bottom strand. BfiI thus uses a mechanism for making double-strand breaks that is novel among restriction enzymes.

Isothermal reactions for the amplification of oligonucleotides

We have devised a class of isothermal reactions for amplifying DNA. These homogeneous reactions rapidly synthesize short oligonucleotides (8-16 bases) specified by the sequence of an amplification template. Versions of the reactions can proceed in either a linear or an exponential amplification mode. Both of these reactions require simple, constant conditions, and the rate of amplification depends entirely on the molecular parameters governing the interactions of the molecules in the reaction. The exponential version of the reaction is a molecular chain reaction that uses the oligonucleotide products of each linear reaction to create producers of more of the same oligonucleotide. It is a highly sensitive chain reaction that can be specifically triggered by given DNA sequences and can achieve amplifications of >10(6)-fold. Several similar reactions in this class are described here. The robustness, speed, and sensitivity of the exponential reaction suggest it will be useful in rapidly detecting the presence of small amounts of a specific DNA sequence in a sample, and a range of other applications, including many currently making use of the PCR.

Paranemic cohesion of topologically-closed DNA molecules

Specific cohesion of DNA molecules is key to the success of work in biotechnology, DNA nanotechnology and DNA-based computation. The most common form of intermolecular cohesion between double helices is by sticky ends, but sticky ends generated by naturally occurring restriction enzymes may often be too short to bind large constructs together. An alternative form of binding is available through the paranemic crossover (PX) motif. Each of the two components of a PX motif can be a DNA dumbbell or other topologically closed species. Alternate half-turns of the dumbbell are paired intramolecularly. The intervening half-turns are paired with those of the opposite component. We demonstrate the efficacy of PX cohesion by showing that it can result in the 1:1 binding of two triangle motifs, each containing nearly 500 nucleotides. The cohesion goes to completion, demonstrating an alternative to binding nucleic acid molecules through sticky ends.

Monitoring of single nicks in duplex DNA by gel electrophoretic mobility-shift assay

We demonstrate that the gel electrophoretic mobility-shift assay (EMSA) can be used for site-selective and quantitative monitoring of nicks in linear double-stranded DNA (dsDNA) thus allowing to expediently follow the nicking activity of enzymes or other agents targeted to a designated dsDNA site. At elevated temperature and/or in the presence of urea, DNA fragments carrying a single nick produced by the nicking enzyme N.BstNBI exhibit a well-detectable gel retardation effect. On the basis of permutation analysis, the decreased electrophoretic mobility of nicked dsDNA fragments is attributed to a bend (or hinge) in the DNA double helix sequence-specifically generated by a nick. Since nick-induced DNA bending depends on interaction between base pairs adjacent to a nick, the change in mobility is different for nicked DNA sites with different sequences. Therefore, EMSA monitoring of differential mobility change caused by nicks within various DNA sequences could be useful for studying the differential base stacking and nearest-neighbor energetics.

Engineering a nicking endonuclease N.AlwI by domain swapping

Changing enzymatic function through genetic engineering still presents a challenge to molecular biologists. Here we present an example in which changing the oligomerization state of an enzyme changes its function. Type IIs restriction endonucleases such as AlwI usually fold into two separate domains: a DNA-binding domain and a catalytic/dimerization domain. We have swapped the putative dimerization domain of AlwI with a nonfunctional dimerization domain from a nicking enzyme, N.BstNBI. The resulting chimeric enzyme, N.AlwI, no longer forms a dimer. Interestingly, the monomeric N.AlwI still recognizes the same sequence as AlwI but only cleaves the DNA strand containing the sequence 5'-GGATC-3' (top strand). In contrast, the wild-type AlwI exists as a dimer in solution and cleaves two DNA strands; the top strand is cleaved by an enzyme binding to that sequence, and its complementary bottom strand is cleaved by the second enzyme dimerized with the first enzyme. N.AlwI is unable to form a dimer and therefore nicks DNA as a monomer. In addition, the engineered nicking enzyme is at least as active as the wild-type AlwI and is thus a useful enzyme. To our knowledge, this is the first report of creating a nicking enzyme by domain swapping.

Converting MlyI endonuclease into a nicking enzyme by changing its oligomerization state

N.BstNBI is a nicking endonuclease that recognizes the sequence GAGTC and nicks one DNA strand specifically. The Type IIs endonuclease, MlyI, also recognizes GAGTC, but cleaves both DNA strands. Sequence comparisons revealed significant similarities between N.BstNBI and MlyI. Previous studies showed that MlyI dimerizes in the presence of a cognate DNA, whereas N.BstNBI remains a monomer. This suggests that dimerization may be required for double-stranded cleavage. To test this hypothesis, we used a multiple alignment to design mutations to disrupt the dimerization function of MlyI. When Tyr491 and Lys494 were both changed to alanine, the mutated endonuclease, N.MlyI, no longer formed a dimer and cleaved only one DNA strand specifically. Thus, we have shown that changing the oligomerization state of an enzyme changes its enzymatic function. This experiment also established a protocol that could be applied to other Type IIs endonucleases in order to generate more novel nicking endonucleases.

The nicking endonuclease N.BstNBI is closely related to type IIs restriction endonucleases MlyI and PleI

N.BstNBI is a nicking endonuclease that recognizes the sequence GAGTC and nicks the top strand preferentially. The Type IIs restriction endonucleases PleI and MlyI also recognize GAGTC, but cleave both DNA strands. Cloning and sequencing the genes encoding each of these three endonucleases discloses significant sequence similarities. Mutagenesis studies reveal a conserved set of catalytic residues among the three endonucleases, suggesting that they are closely related to each other. Furthermore, PleI and MlyI contain a single active site for DNA cleavage. The results from cleavage assays show that the reactions catalyzed by PleI and MlyI are sequential two step processes. The double-stranded DNA is first nicked on one DNA strand and then further cleaved on the second strand to form linear DNA. Gel filtration analysis shows that MlyI dimerizes in the presence of a cognate DNA and Ca(2+) whereas N.BstNBI remains a monomer, implicating dimerization as a requisite for the second strand cleavage. We suggest that N.BstNBI, MlyI and PleI diverged from a common ancestor and propose that N.BstNBI differs from MlyI and PleI in having an extremely limited second strand cleavage activity, resulting in a site-specific nicking endonuclease.