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.     

Single-stranded regions in transforming deoxyribonucleic acid after uptake by competent Haemophilus influenzae.

About 15% of donor deoxyribonucleic acid (DNA) is single stranded immediately after uptake into competent Haemophilus influenzae wild-type cells, as judged by its sensitivity to S1 endonuclease. This amount decreases to 4 to 5% by 30 min after uptake. Mutants which are defective in the covalent association of recipient and donor DNA form little or no S1 endonuclease-sensitive donor. At 17 C donor DNA taken up by the wild type contains single-stranded regions although there is no observable association, either covalent or noncovalent. The single-stranded regions are at the ends of donor DNA molecules, as judged by the unchanged sedimentation velocity after S1 endonuclease digestion. The amount of single-stranded donor remains constant at 17 C for more than 60 min after uptake, suggesting that the decrease observed at 37 C is the result of association of single-stranded ends with single-stranded regions of recipient cell DNA. Three sequential steps necessary for the integration of donor DNA into recipient DNA are proposed: the synthesis of single-stranded regions in recipient DNA, the interaction of donor DNA with recipient DNA resulting in the production of single-stranded ends on donor DNA, and the stable pairing of homologous single-stranded regions.     

Real-time single-molecule observations of T7 Exonuclease activity in a microflow channel

T7 Exonuclease (T7 Exo) DNA digestion reactions were studied using direct single-molecule observations in microflow channels. DNA digestion reactions were directly observed by staining template DNA double-stranded regions with SYTOX Orange and staining single-stranded (digested) regions with a fluorescently labeled ssDNA-recognizing peptide (ssBP-488). Sequentially acquired photographs demonstrated that a double-stranded region monotonously shortened as a single-stranded region monotonously increased from the free end during a DNA digestion reaction. Furthermore, DNA digestion reactions were directly observed both under pulse-chase conditions and under continuous buffer flow conditions with T7 Exo. Under pulse-chase conditions, the double-stranded regions of λDNA monotonously shortened by a DNA digestion reaction with a single T7 Exo molecule, with an estimated average DNA digestion rate of 5.7 bases/s and a processivity of 6692 bases. Under continuous buffer flow conditions with T7 Exo, some pauses were observed during a DNA digestion reaction and double-stranded regions shortened linearly except during these pauses. The average DNA digestion rate was estimated to be 5.3 bases/s with a processivity of 5072 bases. Thus, the use of our direct single-molecule observations using a fluorescently labeled ssDNA-recognizing peptide (ssBP-488) was an effective analytic method for investigating DNA metabolic processes.     

Single-strand-specific degradation of DNA during isolation of rat liver nuclei

We have investigated structural change in rat liver DNA produced by different isolation procedures and specifically compared the integrity of DNA derived by phenol extraction from isolated and purified nuclei with preparations extracted immediately from a crude liver homogenate containing intact nuclei. As indicated by stepwise elution from benzoylated DEAE-cellulose, most structural change in DNA was evident following nuclei isolation. Damage principally involved generation of single-stranded regions in otherwise double-stranded DNA fragments; totally single-stranded DNA was not detected by hydroxylapatite chromatography. Caffeine gradient elution suggested formation of single-stranded regions extending for up to several kilobases. In neutral sucrose gradients, differences in sedimentation rates of respective DNA samples consequent upon S1 nuclease digestion could be detected after isolation of nuclei, though not in other circumstances. The observed single-strand-specific nuclease digestion of DNA could apparently be reduced if steps were taken to reduce autodigestion during nuclei isolation by reduction of temperature and covalent cation concentration. The results are discussed in terms of the use of exogenous and endogenous nucleases in chromatin fractionation studies involving isolated nuclei and possible artifactual findings that may be generated by single-strand-specific autodigestion.     

Seamless gene engineering using RNA- and DNA-overhang cloning

Here we describe two methods for generating DNA fragments with single-stranded overhangs, like those generated by the activity of many restriction enzymes, by simple methods that do not involve DNA digestion. The methods, RNA-overhang cloning (ROC) and DNA-overhang cloning (DOC), generate polymerase chain reaction (PCR) products composed of double-stranded (ds) DNA flanked by single-stranded (ss) RNA or DNA overhangs. The overhangs can be used to recombine DNA fragments at any sequence location, creating "perfect" chimeric genes composed of DNA fragments that have been joined without the insertion, deletion, or alteration of even a single base pair. The ROC method entails using PCR primers that contain regions of RNA sequence that cannot be copied by certain thermostable DNA polymerases. Using such a chimeric primer in PCR would yield a product with a 5' overhang identical to the sequence of the RNA component of the primer, which can be used for directional ligation of the amplified product to other preselected DNA molecules. This method provides complete control over both the length and sequence of the overhangs, and eliminates the need for restriction enzymes as tools for gene engineering.     

Properties of the 3' to 5' exonuclease associated with calf DNA polymerase delta

The 3' to 5' exonuclease of calf thymus DNA polymerase delta has properties expected of a proofreading nuclease. It digests either single-stranded DNA or the single-stranded nucleotides of a mismatched primer on a DNA template by a nonprocessive mechanism. The distribution of oligonucleotide products suggests that a significant portion of the enzyme dissociates after the removal of one nucleotide. This mechanism is expected if the substrate in vivo is an incorrect nucleotide added by the polymerase. Digestion of single-stranded DNA does not proceed to completion, producing final products six to seven nucleotides long. Digestion of a long mismatched terminus accelerates when the mismatched region is reduced to less than six nucleotides. At the point of complementation, the digestion rate is greatly reduced. These results suggest that short mismatched regions are a preferred substrate. The use of a mismatched primer-template analogue, lacking the template single strand, greatly lowers digestion efficiency at the single-stranded 3'-terminus, suggesting that the template strand is important for substrate recognition. When oligonucleotides were examined for effectiveness as exonuclease inhibitors, (dG)8 was found to be the most potent inhibitor of single-stranded DNA digestion. (dG)8 was less effective at inhibiting digestion of mismatched primer termini, again suggesting that this DNA is a preferred substrate. Overall, these results indicate that the exonuclease of DNA polymerase delta efficiently removes short mismatched DNA, a structure formed from misincorporation during DNA synthesis.     

Improved gene correction efficiency with a tailed duplex DNA fragment

A 606-base single-stranded (ss) DNA fragment, prepared by restriction enzyme digestion of ss phagemid DNA, corrects a hygromycin resistance and enhanced green fluorescent protein (Hyg-EGFP) fusion gene more efficiently than a PCR fragment, which is the conventional type of DNA fragment used in gene correction. Here, a tailed duplex, obtained by annealing an oligonucleotide to the ss DNA fragment, was used in the correction. The tailed duplex may be a good substrate for the RAD51 protein, an important enzyme in homologous recombination, which could be the gene correction pathway. The annealing of the oligonucleotides enhanced the correction efficiency of the Hyg-EGFP gene, especially when annealed in the 3'-region of the ss DNA fragment. Both the length and backbone structure of the oligonucleotides affected the gene correction efficiency. This type of gene correction device was also effective for another target gene, the rpsL gene. The results obtained in this study indicate that tailed duplex DNA fragments are effective nucleic acids for gene correction.     

Functional cloning vectors for use in directional cDNA cloning using cohesive ends produced with T4 DNA polymerase.

This paper describes the construction of 'Prime' cloning vectors, which include phage lambda and plasmid vectors useful for functional cloning in oocytes, yeast, and mammalian cells, and their use in a 'Prime' cloning system. The system takes advantage of the very active and precise 3' exonuclease activity of T4 DNA polymerase to produce single-stranded (ss) ends (cut-back) of vector and insert DNA. This results in the highly efficient directional cloning of cDNA and PCR-amplified DNA. The system obviates the need to digest insert DNA with a restriction endonuclease to unveil cloning sites, and thus eliminates the chance of internal digestion of the insert DNA. The cloning of PCR-amplified DNA, which is sometimes difficult, is made routine with this system. The 'Prime' sequence is included in vector cloning sites and cDNA and PCR primers. The 'Prime' sequence was chosen so that the ss sticky ends are nonpalindromic and will hybridize only to the appropriate partners. This makes cloning with the 'Prime' system very efficient, because neither the vector nor insert DNA is lost to unproductive self-hybridization.     

A general method to cleave a known DNA sequence at any site.

We describe a new method for obtaining DNA fragments starting at a desired point where there is no recognition sequence for any known restriction endonuclease. A single-stranded DNA containing the fragment of interest is annealed to a synthetic oligonucleotide hybridizing at the 5' end of the required fragment. Then, a partially double-stranded DNA is synthesized using the Klenow fragment of DNA polymerase I in the presence of the four deoxynucleoside triphosphates. The remaining single-stranded regions are removed by digestion with a single-strand nuclease, and the resulting 5' blunt-ended fragment is finally released by digestion with a restriction endonuclease at any site downstream its 3' end. The usefulness of the method was exemplified here by insertion of an epidermal growth factor-like African swine fever virus gene immediately downstream of the ribosome binding site of an expression vector.     

A sizing artifact of DNA restriction fragments with unusually long single-stranded termini.

The restriction endonucleases (ENases) BstNI (CCATGG) and EcoRII (CCATGG) both cleave DNA at the same time sequences, but only EcoRII produces 5-nucleotide (nt) cohesive ends and is inhibited by 5-methylation of the inner cytosine. The low-Mr fragments in digests of mouse DNA made with these two ENases exhibit different mobilities during agarose-gel electrophoresis. The difference in the mobilities of the BstNI and EcoRII fragments from mouse DNA was not due to closely spaced, differentially methylated sites, or to alternate mechanisms such as circularization of the long cohesive ends of the EcoRII fragments, or to residual bound protein. Rather, it was due to the unusually long 5-nt single-stranded (ss) ends of fragments produced by EcoRII digestion, since the slower mobility of the EcoRII fragments was abolished by treatment with ss-specific nuclease. Similar mobility differences between BstNI and EcoRII fragments which could be removed by ss nuclease were also observed in digests of simian virus 40 DNA.     

Cloning a defined region of DNA using a limited action of DNA polymerase: application to dissection of hepatitis B virus surface antigen gene

Using dodecadeoxynucleotides as primers for DNA synthesis and 3'-o-chlorophenyl-phosphorylated dodecadeoxynucleotides as "stoppers" for chain elongation, pre-defined regions of a gene previously cloned in M13 single-stranded (ss) DNA phage were converted into double-stranded (ds) DNA utilizing the action of the Klenow fragment of Escherichia coli DNA polymerase I (PolIk). The resulting ds DNA was freed from the ss region by S1 nuclease treatment. This method can be used to obtain DNA fragments of any size with pre-defined 5' and 3' ends. About 15% of the input ss DNA template molecules are converted into ds DNA fragments. This technique was used to synthesize several DNA fragments from different portions of the hepatitis B virus surface antigen (HBsAg) gene. The products were then ligated into a yeast plasmid vector that carries the E. coli lacZ gene which is located downstream from the yeast acid-phosphatase promotor. Using this system, several fragments of HBsAg were produced in the form of beta-galactosidase fused protein.     

Enzymatic production of single-stranded DNA as a target for fluorescence in situ hybridization

This study demonstrates that Exonuclease III (Exo III) can be used to produce sufficient single-stranded (ss)DNA in chromosomes and cells to allow in situ hybridization. In this study, all of the probes were modified with biotin and the probe binding was visualized with fluorescein-labeled avidin. Exo III digestion starting at naturally occurring breaks in methanol-acetic acid preparations produced enough ssDNA for strong hybridization when human genomic DNA was used to probe human chromosomes. Pretreatment with the endonucleases EcoRI, Hind III and BamHI was used to produce more sites for initiation of Exo III digestion when using a chromosome-specific repetitive probe specific to a small chromosomal subregion near the telomere of human chromosome 1(1p36). The fluorescence intensity following hybridization to Exo Ill-treated targets was roughly equal to that following hybridization to thermally denatured targets, but background fluorescence was lower.     

Isolation of specific ribosome binding sites from single-stranded DNA.

The ability of Escherichia coli ribosomes to protect small specific regions of single-stranded bacteriophage DNA from digestion by pancreatic DNAase has been investigated. A procedure is described by which ribosome-protected fragments can be isolated from the DNA of bacteriophage f1 and φX174. Size determination by polyacrylamide gel electrophoresis or thin layer homochromatography together with fingerprinting analysis following chemical depurination or digestion with E. coli endonuclease IV were employed to show that these fragments represent a small specific portion of these DNAs. The protection reaction is largely dependent upon components necessary for ribosome binding to mRNA, including GTP, formylmethionyl-tRNA, and initiation factors. Thus, ribosomal binding to DNA mimics the ribosome-mRNA interaction. Furthermore, the regions in f1 and φX174 DNA which are protected differ in sequence from each other.When E. coli endonuclease IV is substituted for pancreatic DNAase in the ribosome protection reaction, a fragment of φX174 DNA is obtained about 150 bases in length which contains all of the pyrimidine tracts in the shorter 50-base fragment obtained with pancreatic DNAase, and a number of additional polypyrimidines.Double-stranded DNAs such as φX174 replicative form do not bind at all to ribosomes in their native state. Heat denaturation of such double-stranded DNAs allows ribosome binding. Protection of the same specific regions as those protected in single-stranded φX174 DNA was observed. A similar specific protection was observed following heat denaturation and ribosome binding with DNA from polyoma virus.     

High content,size and distribution of single-stranded DNA in the mitochondria of Chenopodium album (L.)

Mitochondrial (mt) DNA of higher plants is unique in its large size and complexity. We report here a hitherto unknownfeature, the presence of large quantities of single-stranded (ss) DNA. About 2.0-8.5% of the chromosomal mtDNA from a suspension culture (depending on the growth stage) and 6.5% of the chromosomal mtDNA from whole plants of Chenopodium album were found to be in ss form by dot-blot hybridization after neutral transfer. Similar amounts of ss mtDNA were observed by binding of the single-strand binding (SSB) protein of Escherichia coli under the electron microscope. Significantly less ssDNA was found in plastids of C. album and in E. coli cells. We observed ss regions between 100 and 22 800 bases distributed in the mt genome spaced from 0.5-100 kb apart. After pulsed-field gel electrophoresis (PFGE), the well-bound fraction of mtDNA (found to consist of circular, sigma-shaped and rosette-like molecules), contained the major part of ssDNA as opposed to the migrating linear molecules. Digestion of mtDNA by ss-specific nucleases followed by PFGE mobilized all well-bound DNA and correspondingly increased the quantity of migrating linear DNA molecules. The implications of ssDNA for the structural organization on plant mt genomes are discussed.     

Exoquence DNA sequencing.

We have developed a strategy for DNA sequencing based on exonuclease III digestion followed by double strand specific endonuclease digestion and direct dideoxynucleotide sequencing reaction. This strategy eliminates the need for subcloning, oligonucleotide primers, and prior knowledge of the DNA to be sequenced. All template and primer duplexes needed for sequencing a complete insert can be prepared in one day from uncharacterized starting DNA. Sequence information can be obtained from different regions of the DNA simultaneously. The method uses double-stranded DNA to generate single-stranded template and primer, and thus produces high quality sequence results. Commercially available dideoxy-sequencing kits are well suited for this method. The strategy should be applicable for both automatic and routine laboratory DNA sequencing.     

RNA-Dependent DNA Polymerase Activity of RNA Tumor Viruses I. Directing Influence of DNA in the Reaction

The template requirements and deoxyribonucleic acid (DNA) products of the DNA polymerases isolated from Rauscher leukemia and avian myeloblastosis viruses have been examined. All DNA preparations or synthetic polydeoxynucleotides which are active as primers possess a duplex structure containing single-stranded regions with a 3'-hydroxyl terminus. Native DNA and fully single-stranded DNA are inactive; moreover, their activity is not enhanced by sonic oscillation or treatment with micrococcal nuclease, Neurospora nuclease, or low levels of deoxyribonuclease I. Poor DNA templates are activated by treatment with exonuclease III, large amounts of deoxyribonuclease I, or an endonuclease isolated from Rauscher viral preparations. In reactions primed with deoxyadenylate-deoxythymidylate copolymer, the product formed is covalently attached to primer strands, indicating that no new strands are initiated. DNA polymerase products formed with exonuclease III- or deoxyribonuclase I-treated DNA are duplex structures. Short single-stranded regions are completely filled in, whereas long single-stranded regions are only partly repaired. DNA preparations containing extensive single-stranded regions are poorly utilized as templates.     

Coordinated Interactions of Multiple POT1-TPP1 Proteins with Telomere DNA

Telomeres are macromolecular nucleoprotein complexes that protect the ends of eukaryotic chromosomes from degradation, end-to-end fusion events, and from engaging the DNA damage response. However, the assembly of this essential DNA-protein complex is poorly understood. Telomere DNA consists of the repeated double-stranded sequence 5′-TTAGGG-3′ in vertebrates, followed by a single-stranded DNA overhang with the same sequence. Both double- and single-stranded regions are coated with high specificity by telomere end-binding proteins, including POT1 and TPP1, that bind as a heterodimer to single-stranded telomeric DNA. Multiple POT1-TPP1 proteins must fully coat the single-stranded telomere DNA to form a functional telomere. To better understand the mechanism of multiple binding, we mutated or deleted the two guanosine nucleotides residing between adjacent POT1-TPP1 recognition sites in single-stranded telomere DNA that are not required for multiple POT1-TPP1 binding events. Circular dichroism demonstrated that spectra from the native telomere sequence are characteristic of a G-quadruplex secondary structure, whereas the altered telomere sequences were devoid of these signatures. The altered telomere strands, however, facilitated more cooperative loading of multiple POT1-TPP1 proteins compared with the wild-type telomere sequence. Finally, we show that a 48-nucleotide DNA with a telomere sequence is more susceptible to nuclease digestion when coated with POT1-TPP1 proteins than when it is left uncoated. Together, these data suggest that POT1-TPP1 binds telomeric DNA in a coordinated manner to facilitate assembly of the nucleoprotein complexes into a state that is more accessible to enzymatic activity.     

A nuclear factor that binds purine-rich, single-stranded oligonucleotides derived from S1-sensitive elements upstream of the CFTR gene and the MUC1 gene.

We have identified two regions of non-random purine/pyrimidine strand asymmetry that were nearly identical in sequence in the 5' flanking (promoter) regions of the human cystic fibrosis transmembrane conductance regulator (CFTR) gene and the human MUC1 gene. These regions contain perfect mirror repeat elements, a sequence motif previously found to be associated with the formation of H-DNA conformations. In this report we demonstrate that a single-stranded non-B DNA conformation exists at low pH in supercoiled plasmids containing the similar mirror repeat elements, and that S1 nuclease digestion maps the single-stranded region to the position of the mirror repeats. In addition, we identify a nuclear protein of approximately 27 kD that binds to single-stranded oligonucleotides corresponding to the purine-rich strand of this region, but not to the pyrimidine-rich strands or to double-stranded oligonucleotides with corresponding purine/pyrimidine strand asymmetry.     

Single-stranded regions in DNA from pre- and postmenopausal human ovaries.

No differences were noted between the percent (2–4%) of single-stranded regions in DNA isolated from pre- and postmenopausal human ovaries as determined by nuclease S₁ digestion.