Increased SFHR gene correction efficiency with sense single-stranded DNA

BACKGROUND: The correction of a mutated gene by the small fragment homologous replacement (SFHR) method is a highly attractive approach for gene therapy. However, the current SFHR method with a heat-denatured double-stranded PCR fragment yielded a low correction efficiency. METHODS: Single-stranded (ss) DNA fragments were prepared from ss phagemid DNA and tested in a gene correction assay with an inactivated Hyg-EGFP fusion gene, as a model target. RESULTS: A 606-nt sense, ss DNA fragment dramatically (12-fold) improved the gene correction efficiency, although the antisense strand showed only minimal correction efficiency. CONCLUSIONS: These results suggest that the use of a sense, single-stranded DNA fragment is useful in the SFHR method for the correction of mutated genes.     

Effects of target sequence and sense versus anti-sense strands on gene correction with single-stranded DNA fragments

The correction of an inactivated hygromycin resistance and enhanced green fluorescent protein (Hyg-EGFP) fusion gene by a several hundred-base single-stranded (ss) DNA fragment has been reported. In this study, the effectiveness of this type of gene correction was examined for various positions in the rpsL gene. Sense and anti-sense ssDNA fragments were prepared, and the gene correction efficiencies were determined by co-introduction of the target plasmid containing the gene with the ssDNA fragments. The gene correction efficiency varied (0.8-9.3%), depending on target positions and sense/anti-sense strands. Sense ssDNA fragments corrected the target gene with equal or higher efficiencies as compared to their anti-sense counterparts. The target positions corrected with high efficiency by the sense fragments also tended to be corrected efficiently by the anti-sense fragments. These results suggest that the sense ssDNA fragments are useful for the correction of mutated genes. The variation in the correction efficiency may depend on the sequence of the target position in double-stranded DNA.     

Stimulation of Oligonucleotide-Directed Gene Correction by Redβ Expression and MSH2 Depletion in Human HT1080 Cells

The correction of disease-causing mutations by single-strand oligonucleotide-templated DNA repair (ssOR) is an attractive approach to gene therapy, but major improvements in ssOR efficiency and consistency are needed. The mechanism of ssOR is poorly understood but may involve annealing of oligonucleotides to transiently exposed single-stranded regions in the target duplex. In bacteria and yeast it has been shown that ssOR is promoted by expression of Redβ, a single-strand DNA annealing protein from bacteriophage lambda. Here we show that Redβ expression is well tolerated in a human cell line where it consistently promotes ssOR. By use of short interfering RNA, we also show that ssOR is stimulated by the transient depletion of the endogenous DNA mismatch repair protein MSH2. Furthermore, we find that the effects of Redβ expression and MSH2 depletion on ssOR can be combined with a degree of cooperativity. These results suggest that oligonucleotide annealing and mismatch recognition are distinct but interdependent events in ssOR that can be usefully modulated in gene correction strategies.     

Purification and characterization of the PcrA helicase of Bacillus anthracis

PcrA is an essential helicase in gram-positive bacteria, and a gene encoding this helicase has been identified in all such organisms whose genomes have been sequenced so far. The precise role of PcrA that makes it essential for cell growth is not known; however, PcrA does not appear to be necessary for chromosome replication. The pcrA gene was identified in the genome of Bacillus anthracis on the basis of its sequence homology to the corresponding genes of Bacillus subtilis and Staphylococcus aureus, with which it shares 76 and 72% similarity, respectively. The pcrA gene of B. anthracis was isolated by PCR amplification and cloning into Escherichia coli. The PcrA protein was overexpressed with a His6 fusion at its amino-terminal end. The purified His-PcrA protein showed ATPase activity that was stimulated in the presence of single-stranded (ss) DNA (ssDNA). Interestingly, PcrA showed robust 3'-->5' as well as 5'-->3' helicase activities, with substrates containing a duplex region and a 3' or 5' ss poly(dT) tail. PcrA also efficiently unwound oligonucleotides containing a duplex region and a 5' or 3' ss tail with the potential to form a secondary structure. DNA binding experiments showed that PcrA bound much more efficiently to oligonucleotides containing a duplex region and a 5' or 3' ss tail with a potential to form a secondary structure than to those with ssDNAs or duplex DNAs with ss poly(dT) tails. Our results suggest that specialized DNA structures and/or sequences represent natural substrates of PcrA in biochemical processes that are essential for the growth and survival of gram-positive organisms, including B. anthracis.     

The site-specific cleavage of synthetic Holliday junction analogs and related branched DNA structures by bacteriophage T7 endonuclease I

Various branched DNA structures were created from synthetic, partly complementary oligonucleotides combined under annealing conditions. Appropriate mixtures of oligonucleotides generated three specific branched duplex DNA molecules: (i) a Holliday junction analog having a fixed (immobile) crossover bounded by four duplex DNA branches, (ii) a similar Holliday junction analog which is capable of limited branch migration and, (iii) a Y-junction, with three duplex branches and fixed branch point. Each of these novel structures was specifically cleaved by bacteriophage T7 gene 3 product, endonuclease I. The cleavage reaction "resolved" the two Holliday structure analogs into pairs of duplex DNA products half the size of the original molecules. The point of cleavage in the fixed-junction molecules was predominantly one nucleotide removed to the 5' side of the expected crossover position. Multiple cleavage positions were mapped on the Holliday junction with the mobile, or variable, branch point, to sites consistent with the unrestricted movement of the phosphodiester crossover within the region of limited dyad symmetry which characterizes this molecule. Based on the cleavage pattern observed with this latter substrate, the enzyme displayed a modest degree of sequence specificity, preferring a pyrimidine on the 3' side of the cleavage site. Branched molecules that were partial duplexes (lower order complexes which possessed single-stranded as well as duplex DNA branches) were also substrates for the enzyme. In these molecules, the cleaved phosphodiester bonds were in duplex regions only and predominantly one nucleotide to the 5' side of the branch point. The phosphodiester positions 5' of the branch point in single-stranded arms were not cleaved. Under identical reaction conditions, individually treated oligonucleotides were completely refractory. Thus, cleavage by T7 endonuclease I displays great structural specificity with an efficiency that can vary slightly according to the DNA sequence.     

Viral SPP1 DNA is infectious in naturally competent Bacillus subtilis cells: inter- and intramolecular recombination pathways

A proteolyzed bacteriophage (phage) might release its DNA into the environment. Here, we define the recombination functions required to resurrect an infective lytic phage from inactive environmental viral DNA in naturally competent Bacillus subtilis cells. Using phage SPP1 DNA, a model that accounts for the obtained data is proposed (i) the DNA uptake apparatus takes up environmental SPP1 DNA, fragments it, and incorporates into the cytosol different linear single-stranded (ss) DNA molecules shorter than genome-length; (ii) the SsbA-DprA mediator loads RecA onto any fragmented linear SPP1 ssDNA, but negative modulators (RecX and RecU) promote a net RecA disassembly from these ssDNAs not homologous to the host genome; (iii) single strand annealing (SSA) proteins, DprA and RecO, anneal the SsbA- or SsbB-coated complementary strands, yielding tailed SPP1 duplex intermediates; (iv) RecA polymerized on these tailed intermediates invades a homologous region in another incomplete molecule, and in concert with RecD2 helicase, reconstitutes a complete linear phage genome with redundant regions at the ends of the molecule; and (v) DprA, RecO or viral G35P SSA, may catalyze the annealing of these terminally redundant regions, alone or with the help of an exonuclease, to produce a circular unit-length duplex viral genome ready to initiate replication.     

Translocation of Escherichia coli recA protein from a single-stranded tail to contiguous duplex DNA

Duplex DNA with a contiguous single-stranded tail was nearly as effective as single-stranded DNA in acting as a cofactor for the ATPase activity of recA protein at neutral pH and concentrations of MgCl2 that support homologous pairing. The ATP hydrolysis reached a steady state rate that was proportional to the length of the duplex DNA attached to a short 5' single-stranded tail after a lag. Separation of the single-stranded tail from most of the duplex portion of the molecule by restriction enzyme cleavage led to a gradual decline in ATP hydrolysis. Measurement of the rate of hydrolysis as a function of DNA concentration for both tailed duplex DNA and single-stranded DNA cofactors indicated that the binding site size of recA protein on a duplex DNA lattice, about 4 base pairs, is similar to that on a single-stranded DNA lattice, about four nucleotides. The length of the lag phase preceding steady state hydrolysis depended on the DNA concentration, length of the duplex region, and the polarity of the single-stranded tail, but was comparatively independent of tail length for tails over 70 nucleotides in length. The lag was 5-10 times longer for 3' than for 5' single-stranded tailed duplex DNA molecules, whereas the steady state rates of hydrolysis were lower. These observations show that, after nucleation of a recA protein complex on the single-stranded tail, the protein samples the entire duplex region via an interaction that is labile and not strongly polarized.     

Stimulation of D-loop formation by polypurine/polypyrimidine sequences

Most of the approaches used to correct gene mutations in mammalian cells involve the targeting of short nucleotide molecules to homologous chromosomal sequences and the replacement of resident sequences via homologous recombination and mismatch repair. The limited efficiency and inconsistent reproducibility of these techniques are major constraints to their use in gene therapy. One of the main problems is that it is impossible to obtain reproducible results when the targeted gene loci differ. We investigated the effects of flanking sequences on homologous recombination by means of an in vitro assay of the efficiency of oligonucleotide targeting to its homologous sequence on a large duplex molecule in a reaction catalysed by the Escherichia coli RecA protein. We demonstrated that polypurine·polypyrimidine tracts (PPTs) in duplex DNA strongly stimulate the formation of D-loops with short oligodeoxynucleotides. This result was reproduced with various PPT sequences and oligonucleotides. The stimulatory effect was observed at loci as far as 4000 bp from the PPT. The formation of complexes between the oligonucleotide and the duplex molecule depended on the extent of sequence similarity between the two DNAs and the presence of the RecA protein. The stimulatory effect was inhibited by excess RecA and restored by adding heterologous DNA. We suggest that PPT sequences induce conformational changes in duplex DNA, leading to the aggregation of molecules, facilitating homology searches. We com pared, in vivo, the efficiency of the oligonucleotide-mediated correction of a URA3 chromosomal mutation for sequences with and without a PPT sequence in the vicinity. Consistent with our in vitro results, the efficiency of correction was eight times higher in the presence of the PPT sequence.     

A tolerance of DNA heterology in the mammalian targeted gene repair reaction

Targeted gene repair consists of at least two major steps, the pairing of an oligonucleotide to a site bearing DNA sequence complementarity followed by a nucleotide exchange reaction directed by the oligonucleotide. In this study, oligonucleotides with different structures were designed to target a stably integrated (mutant) enhanced green fluorescent protein (EGFP) gene and used to direct the repair of a single base mutation. We show that the efficiency of correction is influenced by the degree of DNA sequence homology existing between the oligonucleotide and target gene. Correction is reduced when a heterologous stretch of DNA sequence is placed in the center of the oligonucleotide and the mismatched base pair is then formed near the terminus. The negative impact of heterology is dependent on the type of DNA sequence inserted and on the size of the heterologous region. If the heterologous sequence is palindromic and adopts a secondary structure, the negative impact on the correction frequency is removed, and wild-type levels of repair are restored. Although differences in the efficiency of correction are observed in various cell types, the effect of structural changes on gene repair is consistent. These results reveal the existence of a directional-specific repair pathway that relies on the pairing stability of a bilateral complex and emphasize the importance of sequence homology between pairing partners for efficient catalysis of gene repair.     

Reconstitution of the strand invasion step of double-strand break repair using human Rad51 Rad52 and RPA proteins

The human Rad51 recombinase is essential for the repair of double-strand breaks in DNA that occur in somatic cells after exposure to ionising irradiation, or in germ line cells undergoing meiotic recombination. The initiation of double-strand break repair is thought to involve resection of the double-strand break to produce 3'-ended single-stranded (ss) tails that invade homologous duplex DNA. Here, we have used purified proteins to set up a defined in vitro system for the initial strand invasion step of double-strand break repair. We show that (i) hRad51 binds to the ssDNA of tailed duplex DNA molecules, and (ii) hRad51 catalyses the invasion of tailed duplex DNA into homologous covalently closed DNA. Invasion is stimulated by the single-strand DNA binding protein RPA, and by the hRad52 protein. Strikingly, hRad51 forms terminal nucleoprotein filaments on either 3' or 5'-ssDNA tails and promotes strand invasion without regard for the polarity of the tail. Taken together, these results show that hRad51 is recruited to regions of ssDNA occurring at resected double-strand breaks, and that hRad51 shows no intrinsic polarity preference at the strand invasion step that initiates double-strand break repair.     

The antitumor agent CC-1065 inhibits helicase-catalyzed unwinding of duplex DNA.

The antitumor drug CC-1065 is thought to exert its effects by covalent bonding to N3 of adenine in DNA and interfering with some aspect of DNA metabolism. Therefore, it is of interest to determine what effect this drug has on enzymes involved in various aspects of DNA metabolism. In this report, we examine the ability of two DNA helicases, the dda protein of phage T4 and helicase II of Escherichia coli, to unwind CC-1065-adducted, tailed, oligonucleotides. It is shown that the presence of the drug on DNA strongly inhibits unwinding catalyzed by the T4 and E. coli proteins. A significant difference between the results obtained with the two helicases is that DNAs containing drug on either the tailed or the completely duplex strands are poor substrates for helicase II but dda protein-mediated unwinding is inhibited only when the drug is on the tailed strand. The drug-modified, helicase-released, strands migrate abnormally through a native gel, suggesting that the drug traps an unusual secondary structure generated in the course of protein-mediated unwinding. A kinetic analysis of the drug-inhibited reactions reveals that the helicases are trapped by the DNA-drug complex. This is evidenced by a decrease in the rate of helicase exchange between drug-bound substrate and drug-free duplex. The implications of these results with respect to the mechanism of action of CC-1065 in vivo are discussed.     

RecA protein promotes strand exchange with DNA substrates containing isoguanine and 5-methyl isocytosine

The Escherichia coli RecA protein pairs homologous DNA molecules and promotes DNA strand exchange in vitro. We have examined DNA strand exchange between a 70 nucleotide ssDNA fragment and a 40 bp duplex, in which all G and C residues (at 18 positions distributed throughout the 40 bp exchanged region) were replaced with the nonstandard nucleosides 2'-deoxyisoguanosine (iG) and 2'-deoxy-5-methylisocytidine (MiC), respectively. We demonstrate that the nonstandard oligonucleotides are substrates for the RecA protein, permitting DNA strand exchange in vitro at a rate and efficiency comparable to exchange with normal DNA substrates. This observation provides an expanded experimental basis for discussions of potential roles for iG and MiC in a genetic code. Experiments of this type also provide another avenue for exploring RecA-facilitated DNA pairing mechanisms.     

The herpes simplex virus type 1 DNA polymerase processivity factor, UL42, does not alter the catalytic activity of the UL9 origin-binding protein but facilitates its loading onto DNA

The herpes simplex virus type 1 UL42 DNA polymerase processivity factor interacts physically with UL9 and enhances its ability to unwind short, partially duplex DNA. In this report, ATP hydrolysis during translocation of UL9 on single-stranded (ss) or partially duplex DNA was examined in the presence and absence of UL42 to determine the effect of UL42 on the catalytic function of UL9. Our studies reveal that a homodimer of UL9 is sufficient for DNA translocation coupled to ATP hydrolysis, and the steady-state ATPase catalytic rate was greater on partially duplex DNA than on ss DNA in the presence or absence of UL42. Although UL42 protein increased the steady-state rate for ATP hydrolysis by UL9 during translocation on either partially duplex or ss DNA, UL42 had no significant effect on the intrinsic ATPase activity of UL9. UL42 also had no effect on the catalytic rate of ATP hydrolysis when UL9 was not limiting but enhanced the steady-state ATPase rate at only subsaturating UL9 concentrations. At subsaturating UL9 to DNA ratios, stoichiometric concentrations of UL42 were shown to increase the amount of UL9 bound to ss DNA at equilibrium. These data support a model whereby UL42 increases the ability of UL9 to load onto DNA, thus increasing its ability to assemble into a functional complex capable of unwinding duplex DNA.     

Cloning, expression and characterisation of a recombinant triosephosphate isomerase from Taenia solium

We isolated and characterised the cDNA that encodes the glycolytic enzyme, triosephosphate isomerase from Taenia solium. A 450 bp DNA fragment was obtained by the polymerase chain reaction using a cDNA from larval stage as template and degenerate oligonucleotides designed from conserved polypeptide sequences from TPIs of several organisms. The fragment was used to screen a T. solium larval stage cDNA library. The isolated cDNA, encoding a protein of 250 amino acids shares 44.8-59.6% positional identity with other known TPIs, in which the catalytic enzyme residues were conserved. The complete coding sequence of the T. solium TPI cDNA was cloned into the expression vector pRSET and expressed as a fusion protein with an N-terminal tail of six histidine residues. The catalytic activity of the purified protein was similar to other TPI enzymes. Northern and Southern blot analysis suggest that in T. solium, single gene exists for triosephosphate isomerase and that the gene is expressed in all stages of the parasite.     

Construction of a synthetic Holliday junction analog and characterization of its interaction with a Saccharomyces cerevisiae endonuclease that cleaves Holliday junctions

We describe the construction and characterization of an oligonucleotide Holliday junction analog and characterize its interaction with a Saccharomyces cerevisiae endonuclease that cleaves Holliday junctions. A Holliday junction analog containing four duplex arms and 54 base pairs was constructed by annealing four unique synthetic oligonucleotides. Mixing curve analysis showed that the complex contained a 1:1:1:1 mol ratio of the four unique sequence strands. In addition, a linear duplex with a sequence identical to two of the junction arms was also constructed for use as a control fragment. High resolution gel exclusion chromatography was used to purify and characterize the synthetic junction. The synthetic Holliday junction was found to be a specific inhibitor of a S. cerevisiae enzyme that catalyzes the cleavage of Holliday junctions. Under standard cleavage conditions, 50% inhibition was observed at a synthetic Holliday junction to substrate ratio of 7/1, whereas no inhibition by linear duplex was observed at molar ratios in excess of 150/1. Kinetic analysis showed that Holliday junction was a competitive inhibitor of the reaction and had an apparent Ki = 2.5 nM, although the mode of inhibition was complex. The synthetic Holliday junction was not a substrate for the enzyme, but was found to form a specific complex with the enzyme as evidenced by polyacrylamide gel electrophoresis DNA binding assays.     

Parallel DNA: generation of a duplex between two Drosophila sequences in vitro

We have observed the existence of a parallel complementary region between two Drosophila DNA sequences, fragments of the suffix [(1986) EMBO J, 5, 2341-2347] and a 5'-non-coding sequence of the alcohol dehydrogenase gene [(1983) Cell 33, 125-133]. The region includes approximately 40 bp, 76% of which are complementary in the same polarity. Synthetic complementary 16 bp oligonucleotides corresponding to this region which were bound by the 5'-ends through a 1.6-hexanediol bridge form a duplex which displays both melting and annealing as judged by UV absorbance. Anti parallel complementary 16 bp long oligonucleotides bound by the 5'-3' ends through the same bridge and a single-strand sequence were used as controls. The Hoechst 33,258 drug binds to this parallel duplex of DNA; however, the properties of such a complex testify against the B-form of the duplex.     

Domain structure and DNA binding regions of beta protein from bacteriophage lambda

beta protein from bacteriophage lambda promotes a single-strand annealing reaction that is central to Red-mediated recombination at double-strand DNA breaks and chromosomal ends. beta protein binds most tightly to an intermediate of annealing formed by the sequential addition of two complementary oligonucleotides. Here we have characterized the domain structure of beta protein in the presence and absence of DNA using limited proteolysis. Residues 1-130 form an N-terminal "core" domain that is resistant to proteases in the absence of DNA, residues 131-177 form a central region with enhanced resistance to proteases upon DNA complex formation, and the C-terminal residues 178-261 of beta protein are sensitive to proteases in both the presence and absence of DNA. We probed the DNA binding regions of beta protein further using biotinylation of lysine residues and mass spectrometry. Several lysine residues within the first 177 residues of beta protein are protected from biotinylation in the DNA complex, whereas none of the lysine residues in the C-terminal portion are protected. The results lead to a model for the domain structure and DNA binding of beta protein in which a stable N-terminal core and a more flexible central domain come together to bind DNA, whereas a C-terminal tail remains disordered. A fragment consisting of residues 1-177 of beta protein maintains normal binding to sequentially added complementary oligonucleotides and has significantly enhanced binding to single-strand DNA.     

Insertion and Deletion Mismatches Distant from the Target Position Improve Gene Correction with a Tailed Duplex

A 5′-tailed duplex (TD) DNA corrects a base-substitution mutation. In this study, the effects of insertion and deletion (indel) mismatches distant from the target position on the gene correction were examined. Three target plasmid DNAs with and without indel mismatches ～330 bases distant from the correction target position were prepared, and introduced into HeLa cells together with the TD. The indel mismatches improved the gene correction efficiency and specificity without sequence conversions at the indel mismatch site. These results suggested that the gene correction efficiency and specificity are increased when an appropriate second mismatch is introduced into the TD fragment.