Development of artificial restriction DNA cutter composed of Ce(Iv)/EDTA and PNA

An artificial restriction enzyme, which we developed recently by combining Ce(IV)/EDTA and peptide nucleic acids, was used for PCR-free construction of a fusion protein. The fusion protein was successfully expressed in mammalian cells. This artificial DNA cutter can be also applied to site-selective scission of huge DNAs. Promising features of this novel tool were concretely evidenced.     

Hydrolysis of DNA by Ce(IV)/EDTA complexes--the mechanism of DNA cleavage and design of artificial restriction enzymes.

Homogeneous Ce(IV) complex of EDTA promptly hydrolyzes oligonucleotides under physiological conditions. Moreover, the activity of Ce(IV)/EDTA for DNA hydrolysis is promoted by the addition of amines. When [Ce(IV)/EDTA] = 5 mumol dm3 and [ethylenediamine] = 100 mmol dm3, the catalytic activity is about 50 times as large as that of Ce(IV)/EDTA. The combination of Ce(IV)/EDTA and amines is eminent tools for the future molecular biology and biotechnology.     

Artificial restriction DNA cutter for site-selective scission of double-stranded DNA with tunable scission site and specificity

The artificial restriction DNA cutter (ARCUT) method to cut double-stranded DNA at designated sites has been developed. The strategy at the base of this approach, which does not rely on restriction enzymes, is comprised of two stages: (i) two strands of pseudo-complementary peptide nucleic acid (pcPNA) anneal with DNA to form 'hot spots' for scission, and (ii) the Ce(IV)/EDTA complex acts as catalytic molecular scissors. The scission fragments, obtained by hydrolyzing target phosphodiester linkages, can be connected with foreign DNA using DNA ligase. The location of the scission site and the site-specificity are almost freely tunable, and there is no limitation to the size of DNA substrate. This protocol, which does not include the synthesis of pcPNA strands, takes approximately 10 d to complete. The synthesis and purification of the pcPNA, which are covered by a related protocol by the same authors, takes an additional 7 d, but pcPNA can also be ordered from custom synthesis companies if necessary.     

Crystal structure of Ce(IV)/dipicolinate complex as catalyst for DNA hydrolysis

The structures of Ce⁴⁺ complexes that are active for DNA hydrolysis were determined for the first time by X-ray crystallography. The crystals were prepared from a 1:2 mixture of Ce(NH₄)₂(NO₃)₆ and dipicolinic acid (2,6-pyridinedicarboxylic acid). Depending on the recrystallization conditions, three types of crystals were obtained. Some of the Ce⁴⁺ ions in these complexes have enough coordinated water molecules that can directly and indirectly participate in the catalysis. The distances between the Ce⁴⁺ and the dipicolinate ligand are considerably shorter than those in the corresponding La³⁺ and Ce³⁺ complexes. On the other hand, the distances between the Ce⁴⁺ and its coordinated water are similar to those for the La³⁺ and Ce³⁺ complexes. In a proposed mechanism of DNA hydrolysis, the scissile phosphodiester linkage is notably activated by coordination to Ce⁴⁺ and attacked by the Ce⁴⁺-bound hydroxide. The process is further assisted by acid catalysis of Ce⁴⁺-bound water. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Oligoamine-acridine conjugates for promotion of gap-selective DNA hydrolysis by Ce(IV)/EDTA complex

Oligoamines (spermidine, dipropylenetriamine and propylenediamine) were covalently attached to acridine via a hexamethylene linker. These oligoamine–acridine conjugates were efficiently bound to gap sites in substrate DNA, and promoted the DNA hydrolysis by a homogeneous Ce(IV)/ethylenediamine-N,N,N′,N′-tetraacetate (EDTA) complex at these sites. In contrast, the hydrolysis of the double-stranded portion in the DNA was little affected by these conjugates, although they were strongly bound thereto by the intercalation of their acridine moieties. As a result, the gap site was selectively and efficiently hydrolyzed by combining the Ce(IV)/EDTA complex with the oligoamine– acridine conjugate. Either the oligoamine or the acridine was only poorly active for the purpose, substantiating the essential role of cooperation between them. The promotion of gap-selective DNA hydrolysis by the conjugates has been ascribed to electrostatic stabilization of a negatively charged transition state by their positive charges.     

Chemical and biological approaches to improve the efficiency of homologous recombination in human cells mediated by artificial restriction DNA cutter

A chemistry-based artificial restriction DNA cutter (ARCUT) was recently prepared from Ce(IV)/EDTA complex and a pair of pseudo-complementary peptide nucleic acids. This cutter has freely tunable scission-site and site specificity. In this article, homologous recombination (HR) in human cells was promoted by cutting a substrate DNA with ARCUT, and the efficiency of this bioprocess was optimized by various chemical and biological approaches. Of two kinds of terminal structure formed by ARCUT, 3'-overhang termini provided by 1.7-fold higher efficiency than 5'-overhang termini. A longer homology length (e.g. 698 bp) was about 2-fold more favorable than shorter one (e.g. 100 bp). When the cell cycle was synchronized to G2/M phase with nocodazole, the HR was promoted by about 2-fold. Repression of the NHEJ-relevant proteins Ku70 and Ku80 by siRNA increased the efficiency by 2- to 3-fold. It was indicated that appropriate combination of all these chemical and biological approaches should be very effective to promote ARCUT-mediated HR in human cells.     

Preferential hydrolysis of gap and bulge sites in DNA by Ce(IV)/EDTA complex

A new strategy for site-selective DNA hydrolysis, which takes advantage of the difference in reactivity between the phosphodiester linkages at the target site and the others, is presented. As the molecular scissors, homogeneous Ce(IV)/ethylenediamine-N,N,N′,N′-tetraacetate (EDTA) complex is used without being bound to any sequence-recognizing moiety. When a gap structure is formed at the target site by using two short oligonucleotides and the composite is treated with the Ce(IV)/EDTA complex at pH 7.0 and 37°C, the gap site in the substrate DNA is preferentially hydrolyzed over the double-stranded portion of the DNA. Site-selective DNA scission is also achieved by forming a bulge structure at the target site with the use of the appropriate oligonucleotide. These site-selective scissions are based on the following two factors: (i) the phosphodiester linkages in a single-stranded DNA are far more susceptible to the hydrolysis by the Ce(IV) complex than are the linkages in double-stranded DNA, and (ii) the phosphodiester linkages in the bulge sites are still more reactive than those in single-stranded DNA. In both cases, the addition of spermine significantly accelerates the scission.     

Kinetic studies on Ce(IV)-induced hydrolysis of single-stranded and double-stranded oligonucleotides

The Ce(IV)-induced hydrolyses of DNA are kinetically investigated. The formation constants of the Ce(IV)-DNA complexes are in the following order: the single-stranded DNA > the double-stranded DNA > the dinucleotide. On the other hand, the catalytic rate constants for the single-stranded DNA and the double-stranded DNA are comparable with each other, but both of them are much smaller than the value for the dinucleotide hydrolysis.     

A versatile non-radioactive technique for restriction analysis of recombinant DNA

Restriction analysis of recombinant DNA is most frequently performed according to Smith and Birnstiel by labeling 5'-termini with 32P, followed by partial digestion, separation, and autoradiographic detection of labeled fragments. We describe a rapid, non-radioactive technique for restriction analysis of recombinant DNA which combines Southern blotting of partial restriction digests and hybridization with a vector-specific probe labeled with the steroid-hapten Digoxigenin for immunological detection. This technique has several advantages compared to conventional methods. Labeling with 32P is not necessary and as the labeled DNA-fragment used as probe is vector-specific, it can be applied for numerous constructs using the particular cloning vector (e.g.pBR322). Furthermore, the probe can be stored for several months and can be reused many times.     

A rapid and versatile site-directed method of mutagenesis for double-stranded plasmid DNA

This paper describes a new method for site-directed mutagenesis which allows mutations by deletion, insertion or substitution of large fragments of DNA with more than 50% efficiency and does not require subcloning in a single-stranded (ss) DNA vehicle. The site of mutagenesis is removed from a linearized plasmid DNA by BAL 31 digestion, ss DNA regions are generated by limited exonuclease treatment and the mutated target site is reconstituted by annealing of the plasmid DNA to a 35-70 nucleotide long mutated ss oligodeoxynucleotide containing the desired mutation. The circularized plasmid is finally used to transform directly Escherichia coli competent cells.     

Site-selective and hydrolytic two-strand scission of double-stranded DNA using Ce(IV)/EDTA and pseudo-complementary PNA

By combining Ce(IV)/EDTA with two pseudo-complementary peptide nucleic acids (pcPNAs), both strands in double-stranded DNA were site-selectively hydrolyzed at the target site. Either plasmid DNA (4361 bp) or its linearized form was used as the substrate. When two pcPNAs invaded into the double-stranded DNA, only the designated portion in each of the two strands was free from Watson–Crick base pairing with the counterpart DNA or the pcPNA. Upon the treatment of this invasion complex with Ce(IV)/EDTA at 37°C and pH 7.0, both of these single-stranded portions were selectively hydrolyzed at the designated site, resulting in the site-selective two-strand scission of the double-stranded DNA. Furthermore, the hydrolytic scission products were successfully connected with foreign double-stranded DNA by using ligase. The potential of these artificial systems for manipulation of huge DNA has been indicated.     

Cerium(IV)/Lanthanide(III)/Dextran Ternary Solutions for Efficient and Homogeneous DNA Hydrolysis

Abstract

Homogeneous and neutral solutions are prepared by mixing Ce(NH₄)₂(NO₃)₆ and dextrans at pH 7. These homogeneous solutions are active for DNA hydrolysis. Still more importantly, the activities of the binary solutions are greatly promoted by the addition of various lanthanide(III) ions.     

Efficient manipulation of nanoparticle-bound DNA via restriction endonuclease

As a programmable biopolymer, DNA has shown great potential in the fabrication and construction of nanometer-scale assemblies and devices. In this report, we described a strategy for efficient manipulation of gold nanoparticle-bound DNA using restriction endonuclease. The digestion efficiency of this restriction enzyme was studied by varying the surface coverage of stabilizer, the size of nanoparticles, as well as the distance between the nanoparticle surface and the enzyme-cutting site of particle-bound DNA. We found that the surface coverage of stabilizer is crucial for achieving high digestion efficiency. In addition, this stabilizer surface coverage can be tailored by varying the ion strength of the system. Based on the results of polyacrylamide gel electrophoresis and fluorescent study, a high digestion efficiency of 90+% for particle-bound DNA was achieved for the first time. This restriction enzyme manipulation can be considered as an additional level of control of the particle-bound DNA and is expected to be applied to manipulate more complicated nanostructures assembled by DNA.     

Two-step red-mediated recombination for versatile high-efficiency markerless DNA manipulation in Escherichia coli

Red recombination using PCR-amplified selectable markers is a well-established technique for mutagenesis of large DNA molecules in Escherichia coli. The system has limited efficacy and versatility, however, for markerless modifications including point mutations, deletions, and particularly insertions of longer sequences. Here we describe a procedure that combines Red recombination and cleavage with the homing endonuclease I-SceI to allow highly efficient, PCR-based DNA engineering without retention of unwanted foreign sequences. We applied the method to modification of bacterial artificial chromosome (BAC) constructs harboring an infectious herpesvirus clone to demonstrate the potential of the mutagenesis technique, which was used for the insertion of long sequences such as coding regions or promoters, introduction of point mutations, scarless deletions, and insertion of short sequences such as an epitope tag. The system proved to be highly reliable and efficient and can be adapted for a variety of different modifications of BAC clones, which are fundamental tools for applications as diverse as the generation of transgenic animals and the construction of gene therapy or vaccine vectors.     

Sequence-specific chemical modification of double-stranded DNA with alkylating oligodeoxyribonucleotide derivatives

Chemical modification of double-stranded (ds) DNA with alkylating oligodeoxynucleotide (oligo) derivatives, 5'-p(N-2-chloroethyl-N-methylamino) benzylamides of oligos, has been investigated. In contrast to relaxed plasmid DNAs, the superhelical molecules interact with the oligo derivatives and specific alkylation of the DNAs occurs at the regions complementary to the oligo reagents. Alkylating derivatives of oligocytidylates and pT(pCpT)6 react with corresponding homopyrimidine-homopurine tracts within ds DNA fragments due to triple helix formation.     

Enzymatic collapse of artificial polymer composite material containing double-stranded DNA

Large amounts of DNA-enriched biomaterials, such as salmon milts and shellfish gonads, are discarded as industrial waste around the world. Therefore, the utilizations of DNA with the specific function are important for the biomaterial science and the curce technology. We could convert the discarded DNA to an enzymatic collapsible material by the addition of DNA to the artificial polymer material, such as nylon. Although these DNA-artificial polymer composite materials were stable in water, these materials indicated the collapsibility at the DNA-hydrolyzed enzyme, such as Micrococcal nuclease, condition. Additionally, these collapsibilities under enzyme condition were controlled by the number of imino groups in the components of the artificial polymer. Furthermore, these composite materials could create the fiber form with a highly ordered molecular orientation by the reaction at the liquid/liquid interface. The DNA-artificial polymer composite materials may have the potential utility as a novel bio-, medical-, and environmental materials with the enzymatic collapsibility and degradability.     

DNA modification by oxovanadium(IV) complexes of salen derivatives

Oxovanadium(IV) complexes of hydroxysalen derivatives have been prepared and tested as DNA reactive agents. The nuclease activity has been investigated under oxidative or reducing conditions, on the basis of the various oxidation states of vanadium: V^III, V^IV and V^V. In the absence of an activating agent, none of the compounds tested was able to induce cleavage of DNA, whereas in the presence of mercaptopropionic acid (MPA) or Oxone the four complexes induced DNA modifications. Under both conditions, the para-hydroxy complex was found to be the most active compound. Reaction of these salen complexes with DNA occurs essentially at guanine residues and is more efficient in the presence of Oxone than under reducing conditions. The extent of Oxone-mediated DNA oxidation by the four vanadyl complexes was clearly superior to VOSO₄ and was observed without piperidine treatment. EPR studies provided information on the reactive metal-oxo species involved under each conditions and a mechanism of reaction with DNA is discussed.Electronic Supplementary Material Supplementary material is available in the online version of this article at http://dx.doi.org/10.1007/s00775-004-0529-0Abbreviations BPE buffer bis-phosphate EDTA buffer - DMPO 5,5-dimethylpyrroline N-oxide - DMS dimethyl sulfate - HFS hyperfine structure - Lin linear - MPA 3-mercaptopropionic acid - Nck nicked - salen (salicylidene)ethylenediamine - Sc supercoiled - TBE buffer tris-borate EDTA buffer - Tris tris(hydroxymethyl)aminomethane     

Active species for Ce(IV)-induced hydrolysis of phosphodiester linkage in cAMP and DNA

The hydrolysis of cyclic adenosine 3',5'-monophosphate and 2'-deoxythymidylyl(3'-5')2'-deoxythymidine by Ce(NH4)2(NO3)6 was kinetically studied. The rate of hydrolysis was fairly proportional to the concentration of [Ce2(IV) (OH)4]4+ , showing that this is the catalytically active species. According to quantum-chemical calculation, the two Ce(IV) ions in this [Ce2(IV) (OH)4]4+ cluster are bridged by two OH residues. Upon the complex formation with H2 PO4- (a model compound for the phosphodiesters), these two Ce(IV) ions bind the two oxygen atoms of the substrate and enhance the electrophilicity of the phosphorus atom. The catalytic mechanism of Ce(IV)-induced hydrolysis of phosphodiesters has been proposed on the basis these results.     

Active Species for Ce(IV)-Induced Hydrolysis of Phosphodiester Linkage in cAMP AND DNA

The hydrolysis of cyclic adenosine 3′,5′-monophosphate and 2′-deoxythymidylyl(3′-5′)2′-deoxythymidine by Ce(NH₄)₂(NO₃)₆ was kinetically studied. The rate of hydrolysis was fairly proportional to the concentration of [Ce ^IV ₂ (OH)₄]⁴⁺, showing that this is the catalytically active species. According to quantum-chemical calculation, the two Ce(IV) ions in this [Ce^IV ₂(OH)₄]⁴⁺ cluster are bridged by two OH residues. Upon the complex formation with H₂ PO₄ ^? (a model compound for the phosphodiesters), these two Ce(IV) ions bind the two oxygen atoms of the substrate and enhance the electrophilicity of the phosphorus atom. The catalytic mechanism of Ce(IV)-induced hydrolysis of phosphodiesters has been proposed on the basis these results.