Rapid shotgun cloning utilizing the two base recognition endonuclease CviJI.

A new approach has been developed for the rapid fragmentation and fractionation of DNA into a size suitable for shotgun cloning and sequencing. The restriction endonuclease CviJI normally cleaves the recognition sequence PuGCPy between the G and C to leave blunt ends. Atypical reaction conditions which alter the specificity of this enzyme (CviJI**) yield a quasi-random distribution of DNA fragments from the small molecule pUC19 (2686 base pairs). To quantitatively evaluate the randomness of this fragmentation strategy, a CviJI** digest of pUC19 was size fractionated by a rapid gel filtration method and directly ligated, without end repair, to a lacZ minus M13 cloning vector. Sequence analysis of 76 clones showed that CviJI** restricts PyGCPy and PuGCPu, in addition to PuGCPy sites, and that new sequence data is accumulated at a rate consistent with random fragmentation. Advantages of this approach compared to sonication and agarose gel fractionation include: smaller amounts of DNA are required (0.2-0.5 micrograms instead of 2-5 micrograms), fewer steps are involved (no preligation, end repair, chemical extraction, or agarose gel electrophoresis and elution are needed), and higher cloning efficiencies are obtained (CviJI** digested and column fractionated DNA transforms 3-16 times more efficiently than sonicated, end-repaired, and agarose fractionated DNA).     

Chemically-induced affinity star restriction specificity: a novel TspGWI/sinefungin endonuclease with theoretical 3-bp cleavage frequency

The type IIS/IIC restriction endonuclease TspGWI recognizes the sequence 5'-ACGGA-3', cleaving DNA 11/9 nucleotides downstream. Here we show that sinefungin, a cofactor analog of S-adenosyl methionine, induces a unique type of relaxation in DNA recognition specificity. In the presence of sinefungin, TspGWI recognizes and cleaves at least 12 degenerate variants of the original recognition sequence that vary by single base pair changes from the original 5-bp restriction site with only a single degeneracy per variant appearing to be allowed. In addition, sinefungin was found to have a stimulatory effect on cleavage at these nondegenerate TspGWI recognition sites, irrespective of their number or the DNA topology. Interestingly, no fixed "core" could be identified among the new recognition sequences. Theoretically, TspGWI cleaves DNA every 1024 bp, while sinefungin-induced activity cleaves every 78.8 bp, corresponding to a putative 3-bp long recognition site. Thus, the combination of sinefungin and TspGWI represents a novel frequent cutter, next only to CviJI/CviJI*, that should prove useful in DNA cloning methodologies.     

Restriction generated oligonucleotides utilizing the two base recognition endonuclease CviJI*.

The conversion of an anonymous DNA sample into numerous oligonucleotides is enzymatically feasible using an unusual restriction endonuclease, CviJI. Depending on reaction conditions, CviJI is capable of digesting DNA at a two or three base recognition sequence. CviJI normally cleaves RGCY sites between the G and C to leave blunt ends. Under 'relaxed' conditions CviJI* cleaves RGCY, and RGCR/YGCY, but not YGCR sites. In theory, CviJI* restriction of pUC19 (2686 bp) should produce 157 fragments, 75% of which are smaller than 20 bp. Instead, 96% of the CviJI* fragments were 18-56 bp long and none of the fragments were smaller than 18 bp. Thermal denaturation of these fragments generates sequence specific oligonucleotides homologous for the cognate template. The enzymatic conversion of anonymous DNA into sequence specific oligomers has implications for several conventional and novel molecular biology procedures.     

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.     

Molecular cloning of the three base restriction endonuclease R.CviJI from eukaryotic Chlorella virus IL-3A.

R.CviJI is unique among site-specific restriction endonucleases in that its activity can be modulated to recognize either a two or three base sequence. Normally R.CviJI cleaves RGCY sites between the G and C to leave blunt ends. In the presence of ATP R.CviJI* cleaves RGCN and YGCY sites, but not YGCR sites. The gene encoding R.CviJI was cloned from the eukaryotic Chlorella virus IL-3A and expressed in Escherichia coli. The primary E.coli cviJIR gene product is a 278 amino acid protein initiated from a GTG codon, rather than the expected 358 amino acid protein initiated from an in-frame upstream ATG codon. Interestingly, the 278 amino acid protein displays the normal restriction activity but not the R.CviJI* activity of the native enzyme. Nine restriction and modification proteins which recognize a central GC or CG sequence share short regions of identity with R.CviJI amino acids 144-235, suggesting that this region is the recognition and/or catalytic domain.     

Differences between EcoRI nonspecific and "star" sequence complexes revealed by osmotic stress

The binding of the restriction endonuclease EcoRI to DNA is exceptionally specific. Even a single basepair change ("star" sequence) from the recognition sequence, GAATTC, decreases the binding free energy of EcoRI to values nearly indistinguishable from nonspecific binding. The difference in the number of waters sequestered by the protein-DNA complexes of the "star" sequences TAATTC and CAATTC and by the specific sequence complex determined from the dependence of binding free energy on water activity is also practically indistinguishable at low osmotic pressures from the 110 water molecules sequestered by nonspecific sequence complexes. Novel measurements of the dissociation rates of noncognate sequence complexes and competition equilibrium show that sequestered water can be removed from "star" sequence complexes by high osmotic pressure, but not from a nonspecific complex. By 5 Osm, the TAATTC "star" sequence complex has lost almost 90 of the approximately 110 waters initially present. It is more difficult to remove water from the CAATTC "star" sequence complex. The sequence dependence of water loss correlates with the known sequence dependence of "star" cleavage activity.     

A single amino acid change restores DNA cytosine methyltransferase activity in a cloned chlorella virus pseudogene.

The chlorella virus PBCV-1 contains an open reading frame, named P17-ORF4, which differs by eight amino acids from a DNA cytosine methyltransferase, M.CviJI, encoded by a different chlorella virus IL-3A. Whereas IL-3A expresses M.CviJI, which methylates the central cytosine in (A/G)GC(T/C/G) sequences, P17-ORF4 is non-functional. Gene fusions between P17-ORF4 and M.CviJI and site-directed point mutations revealed that changing Gln188 to Lys188 abolishes M.CviJI methyltransferase activity. Conversely, changing Lys188 in P17-ORF4 to Gln188 results in M.CviJI activity. The other altered seven amino acids do not appear to affect M.CviJI activity.     

Massively parallel characterization of restriction endonucleases

Restriction endonucleases are highly specific in recognizing the particular DNA sequence they act on. However, their activity is affected by sequence context, enzyme concentration and buffer composition. Changes in these factors may lead to either ineffective cleavage at the cognate restriction site or relaxed specificity allowing cleavage of degenerate ‘star’ sites. Additionally, uncharacterized restriction endonucleases and engineered variants present novel activities. Traditionally, restriction endonuclease activity is assayed on simple substrates such as plasmids and synthesized oligonucleotides. We present and use high-throughput Illumina sequencing-based strategies to assay the sequence specificity and flanking sequence preference of restriction endonucleases. The techniques use fragmented DNA from sequenced genomes to quantify restriction endonuclease cleavage on a complex genomic DNA substrate in a single reaction. By mapping millions of restriction site–flanking reads back to the Escherichia coli and Drosophila melanogaster genomes we were able to quantitatively characterize the cognate and star site activity of EcoRI and MfeI and demonstrate genome-wide decreases in star activity with engineered high-fidelity variants EcoRI-HF and MfeI-HF, as well as quantify the influence on MfeI cleavage conferred by flanking nucleotides. The methods presented are readily applicable to all type II restriction endonucleases that cleave both strands of double-stranded DNA.     

Nmel, a restriction endonuclease from Neisseria meningitidis

A restriction endonuclease, Nmel, present in Neisseria meningitidis was partially purified by passing through a blue 2-cross linked agarose column; no contaminating nucleases remained detectable. This enzyme cleaved phage lambda, adenovirus type 2 and phi x 174 DNA but did not cleave SV40 DNA. It had an absolute requirement for Mg2+ for its activity and was inhibited by high concentrations of NaCl or MgCl2. Nmel activity was completely abolished after 1 h of incubation at 65 degrees C. S-adenosyl-L-methionine and ATP had no effect on its activity suggesting that Nmel is a type II restriction endonuclease enzyme. It is the first report of a restriction enzyme present in N. meningitidis.     

Engineering TaqII bifunctional endonuclease DNA recognition fidelity: the effect of a single amino acid substitution within the methyltransferase catalytic site

The aim of this study was to improve a useful molecular tool—TaqII restriction endonuclease-methyltransferase—by rational protein engineering, as well as to show an application of our novel method of restriction endonuclease activity modulation through a single amino acid change in the NPPY motif of methyltransferase. An amino acid change was introduced using site-directed mutagenesis into the taqIIRM gene. The mutated gene was expressed in Escherichia coli. The protein variant was purified and characterized. Previously, we described a TspGWI variant with an amino acid change in the methyltransferase motif IV. Here, we investigate a complex, pleiotropic effect of an analogous amino acid change on its homologue—TaqII. The methyltransferase activity is reduced, but not abolished, while TaqII restriction endonuclease can be reactivated by sinefungin, with an increased DNA recognition fidelity. The general method for engineering of the IIS/IIC/IIG restriction endonuclease activity/fidelity is developed along with the generation of an improved TaqII enzyme for biotechnological applications. A successful application of our novel strategy for restriction endonuclease activity/fidelity alteration, based on bioinformatics analyses, mutagenesis and the use of cofactor-analogue activity modulation, is presented.     

Modulating restriction endonuclease activities and specificities using neutral detergents

It is well known that type II restriction enzyme activities and specificities can be modulated by altering solution conditions. The addition of co-solvents such as dimethyl sulfoxide (DMSO), alcohols and polyols can promote star activity, which is the cleavage of non-cognate sequences. While neutral detergents are often used to control protein aggregation, little is known about the effect of neutral detergents on restriction enzyme activities and specificities. We report here that BamHI, BglI, BglII, EcoRI, EcoRV, HindIII, MluI, PvuII, SalI and XhoI restriction endonucleases are remarkably tolerant of high concentrations of neutral detergents Triton X-100, CHAPS and octyl glucoside. In most cases, lambda DNA cleavage rates were comparable to those observed in the absence of detergent. Indeed, the specific activities of SalI and XhoI were appreciably increased in the presence of Triton X-100. For all enzymes active in the presence of detergents, sequence specificity toward lambda DNA was not compromised. Assays of star cleavage of pUC18 by EcoRI, PvuII and BamHI endonucleases in equimolar concentrations of Triton X-100 and sucrose revealed reduced star activity in the detergent relative to the sucrose co-solvent. Interestingly, under star activity-promoting conditions, PvuII endonuclease displayed greater fidelity in Triton X-100 than in conventional buffer. Taken altogether, these results suggest that in some cases, neutral detergents can be used to manipulate restriction endonuclease reaction rates and specificities.     

Restriction endonuclease activity induced by NC-1A virus infection of a Chlorella-like green alga.

A type II restriction endonuclease, CviBI, was isolated from a eukaryotic, Chlorella-like green alga infected with the dsDNA containing virus NC-1A. The enzyme recognizes the sequence GANTC and cleaves DNA between the G and A. Methylation of deoxyadenosine in the GANTC sequence probably inhibits enzyme activity. In vitro CviBI cleaves host nuclear DNA but not viral DNA. A survey of 18 other viruses which infect the same Chlorella sp. revealed that infection with 5 of these viruses also induced a restriction endonuclease which cleaves DNA into the same size fragments as CviBI.     

Isolation and characterisation of DraI, a type II restriction endonuclease recognising a sequence containing only A:T basepairs, and inhibition of its activity by uv irradiation of substrate DNA

A type II restriction endonuclease, DraI, isolated from Deinococcus radiophilus ATCC 27603 recognises the palindromic hexanucleotide sequence (formula; see text) and cleaves it, as indicated by the arrows, to produce blunt-ended fragments. The yield of enzyme is 100 to 1000 times that of the only other known type II restriction endonuclease that recognises a sequence composed solely of A:T basepairs, the isoschizomer AhaIII (1). Ultraviolet irradiation of the DNA substrate at relatively low doses inhibits the activity of DraI by "protecting" the recognition sequence and this may be exploited to give control of partial digestion of DNA by DraI.     

Restriction endonuclease activity induced by PBCV-1 virus infection of a Chlorella-like green alga.

An enzyme was isolated from a eucaryotic, Chlorella-like green alga infected with the virus PBCV-1 which exhibits type II restriction endonuclease activity. The enzyme recognized the sequence GATC and cleaved DNA 5' to the G. Methylation of deoxyadenosine in the GATC sequence inhibited enzyme activity. In vitro the enzyme cleaved host Chlorella nuclear DNA but not viral DNA because host DNA contains GATC and PBCV-1 DNA contains GmATC sequences. PBCV-1 DNA is probably methylated in vivo by the PBCV-1-induced methyltransferase described elsewhere (Y. Xia and J. L. Van Etten, Mol. Cell. Biol. 6:1440-1445). Restriction endonuclease activity was first detected 30 to 60 min after viral infection; the appearance of enzyme activity required de novo protein synthesis, and the enzyme is probably virus encoded. Appearance of enzyme activity coincided with the onset of host DNA degradation after PBCV-1 infection. We propose that the PBCV-1-induced restriction endonuclease participates in host DNA degradation and is part of a virus-induced restriction and modification system in PBCV-1-infected Chlorella cells.     

The proteolytic control of restriction activity in Escherichia coli K-12

The endonuclease activity of EcoKI is regulated by the ClpXP-dependent degradation of the subunit that is essential for restriction, but not modification. We monitored proteolysis in mutants blocked at different steps in the restriction pathway. Mutations that prevent DNA translocation render EcoKI refractory to proteolysis, whereas those that permit DNA translocation, but block endonuclease activity, do not. Although proteolysis alleviates restriction in a mutant that lacks modification activity, some restriction activity remains; our evidence indicates residual EcoKI associated with the membrane fraction. ClpXP protects the bacterial chromosome, but little effect was detected on unmodified foreign DNA within the cytoplasm of a restriction-proficient cell. The molecular basis for the distinction between unmodified resident and foreign DNA remains to be determined.     

DNA methyltransferase induced by PBCV-1 virus infection of a Chlorella-like green alga.

A DNA methyltransferase was isolated from a eucaryotic, Chlorella-like green alga infected with the virus PBCV-1. The enzyme recognized the sequence GATC and methylated deoxyadenosine solely in GATC sequences. Host DNA, which contains GATC sequences, but not PBCV-1 DNA, which contains GmATC sequences, was a good substrate for the enzyme in vitro. The DNA methyltransferase activity was first detected about 1 h after viral infection; PBCV-1 DNA synthesis and host DNA degradation also began at about this time. The appearance of the DNA methyltransferase activity required de novo protein synthesis, and the enzyme was probably virus encoded. Methylation of DNAs with the PBCV-1-induced methyltransferase conferred resistance of the DNAs to a PBCV-1-induced restriction endonuclease enzyme described previously (Y. Xia, D. E. Burbank, L. Uher, D. Rabussay, and J. L. Van Etten, Mol. Cell. Biol. 6:1430-1439). We propose that the PBCV-1-induced methyltransferase protects viral DNA from the PBCV-1-induced restriction endonuclease and is part of a virus-induced restriction and modification system in PBCV-1-infected Chlorella cells.     

Characterization of a highly repeated satellite DNA from the cyprinid fish Notropis lutrensis

1. A highly repeated, satellite DNA family from the North American cyprinid fish, Notropis lutrensis, was identified as a fragment band following restriction endonuclease enzyme digestion and agarose gel electrophoresis of genomic DNA; evidence of a tandem arrangement of the satellite in the genome was demonstrated by the formation of "ladders" in partial restriction endonuclease digests. 2. The satellite family was estimated densitometrically to comprise 7-8% of the N. lutrensis genome; mapping experiments using isolated and purified monomer repeat units of the satellite uncovered nine sites for seven different restriction enzymes. 3. A monomeric repeat unit of the satellite was cloned and sequenced, and found to be 174 base pairs in length and to have a base composition of 47% G + C (guanine + cytosine); computer analysis of the sequence revealed 13 new restriction sites for 12 additional enzymes. 4. Computer analysis also revealed that a large degree of internal redundancy in the monomer unit exists in the form of both direct and inverted repeating units, and that the entire sequence, starting with one base in either orientation, constitutes an open reading frame. In all but the last characteristic, the N. lutrensis satellite DNA is very similar to satellite DNAs in other eukaryotes.     

Creation of a type IIS restriction endonuclease with a long recognition sequence

Type IIS restriction endonucleases cleave DNA outside their recognition sequences, and are therefore particularly useful in the assembly of DNA from smaller fragments. A limitation of type IIS restriction endonucleases in assembly of long DNA sequences is the relative abundance of their target sites. To facilitate ligation-based assembly of extremely long pieces of DNA, we have engineered a new type IIS restriction endonuclease that combines the specificity of the homing endonuclease I-SceI with the type IIS cleavage pattern of FokI. We linked a non-cleaving mutant of I-SceI, which conveys to the chimeric enzyme its specificity for an 18-bp DNA sequence, to the catalytic domain of FokI, which cuts DNA at a defined site outside the target site. Whereas previously described chimeric endonucleases do not produce type IIS-like precise DNA overhangs suitable for ligation, our chimeric endonuclease cleaves double-stranded DNA exactly 2 and 6nt from the target site to generate homogeneous, 5′, four-base overhangs, which can be ligated with 90% fidelity. We anticipate that these enzymes will be particularly useful in manipulation of DNA fragments larger than a thousand bases, which are very likely to contain target sites for all natural type IIS restriction endonucleases.     

Role of "anti-restriction" motif in functional activity of anti-restriction protein ArdA pKM101 (incN)

A number of mutant forms of the antirestriction protein ArdA encoded by the ardA gene located in a transmissive IncN plasmid pKM101 have been constructed. Proteins belonging to the Ard family are specific inhibitors of type I restriction--modification enzymes. Single mutational substitutions of negatively charged amino acid residues located in the "antirestriction motif" with hydrophobic alanine, E134A, E137A, D144A, or a double substitution E134A, E137A do not affect the antirestriction activity (Ard) of ArdA but almost completely abolish the antimodification activity (Amd). Mutational substitutions F107D and A110D in the assumed interface ArdA, which determines contact between monomers in the active dimer (Ard)2, cause an approximately 100-fold decrease in the antirestriction protein activity. It is hypothesized that the ArdA protein forms two complexes with the type I restriction--modification enzyme (R2M2S): (1) with a specific region in the S subunit involved in contact with the sK site in DNA; and (2) with a nonspecific region in the R subunit involved in DNA translocation and degradation by restriction endonucleases. The association of ArdA with the specific region inhibits restriction endonuclease and methyltransferase activities simultaneously, whereas the association of ArdA with a nonspecific region inhibits only restriction endonuclease activity of the R2M2S enzyme.     

Tsp49I (ACGT/), a thermostable neoschizomer of the Type II restriction endonuclease MaeII (A/CGT), discovered in isolates of the genus Thermus from the Azores, Iceland and New Zealand.

One hundred and forty eight isolates of the genus Thermus, from neutral and alkaline hot water springs on four continents, have been screened for the presence of restriction endonuclease activity. An isolate (SM49) from the island of Sao Miguel, in the Azores, showed a high level of restriction endonuclease activity when a cell-free extract was incubated with lambda phage DNA at 65 degrees C. A Type II restriction endonuclease (Tsp49I) has been partially purified from this isolate and the recognition and cleavage site determined. Tsp49I recognizes the four base sequence ACGT, which is the same as the recognition sequence of the mesophilic Type II restriction endonuclease MaeII. However, unlike MaeII, which cleaves DNA between the first and second bass of the recognition sequence (A/CGT), Tsp49I hydrolyses the phosphodiester bond in both strands of the substrate after the last base of the recognition sequence 5'-ACGT/-3', producing four base 3'-OH overhangs (sticky ends). The enzyme has a pH optimum of 9.0, requires 2 mM MgCl2 for maximum activity and retains full enzyme activity following incubation for 10 min at temperatures up to 8O degrees C. Two further examples of the same restriction endonuclease specificity as Tsp491 were detected in Thermus isolates from Iceland (TspIDSI) and New Zealand (TspWAM8AI). The three MaeII neoschizomers, Tsp49I, TspIDSI and TspWAM8AI, exhibit similar pH optima, heat stabilities and MgCl2 requirements, but differ in their requirements for NaCl and KCl.