Separation of genomic DNA from plasmid DNA by selective renaturation with immobilized metal affinity capture

In contrast to proteins, many nucleic acids can undergo reversible modification of their conformations, and this flexibility can be used to facilitate purification. Selective renaturation with capture is a novel method of removing contaminating genomic DNA from plasmid samples. Plasmid DNA quickly renatures after thermal denaturation and cooling (or alkaline denaturation followed by neutralization), whereas genomic DNA remains locally denatured after rapid cooling in mismatch-stabilizing high ionic strength buffer. Partially denatured genomic DNA can be selectively bound to a metal chelate affinity adsorbent through exposed purine bases, while double-stranded renatured plasmid DNA is not bound. Using this method we have readily achieved 1,000,000-fold clearance of 71 wt % contaminating E. coli genomic DNA from plasmid samples.     

Direct cloning of specific genomic DNA sequences in plasmid libraries following fragment enrichment.

We describe a simple method to directly clone any DNA fragment for which a flanking restriction enzyme map is known. Genomic DNA is digested with multiple enzymes cutting outside the fragment to be cloned, selected by electroelution from an agarose gel, and cloned directly into a plasmid vector. It is only necessary to screen 10-1000 colonies and recombinant DNA is ready for immediate molecular analysis without further subcloning. The use of this technique is demonstrated for the cloning of a sequence from within the human alpha-globin complex that was previously shown to be "unclonable" in bacteriophage and cosmid vectors and which is a multiallelic general genetic marker, as well as both beta-globin alleles from an individual with beta-thalassaemia.     

Reversible capture of genomic DNA by a Nafion-coated electrode

A method in which an electrode itself is used as the sample preparation microchip is described. The gold electrode was coated with an ion-permeable polymer, Nafion, to prevent the permanent adsorption and destruction of DNA. The modified electrode was able to capture as much DNA as the bare gold electrode and to release the captured DNA effectively, whereas the bare gold electrode could not release bound DNA. The elution efficiency was greater than 70% for the Nafion-coated electrode, whereas it was less than 10% for the bare electrode. The DNA obtained was undamaged and could be amplified by polymerase chain reaction.     

BayMeth: improved DNA methylation quantification for affinity capture sequencing data using a flexible Bayesian approach

Affinity capture of DNA methylation combined with high-throughput sequencing strikes a good balance between the high cost of whole genome bisulfite sequencing and the low coverage of methylation arrays. We present BayMeth, an empirical Bayes approach that uses a fully methylated control sample to transform observed read counts into regional methylation levels. In our model, inefficient capture can readily be distinguished from low methylation levels. BayMeth improves on existing methods, allows explicit modeling of copy number variation, and offers computationally efficient analytical mean and variance estimators. BayMeth is available in the Repitools Bioconductor package.     

A systematic approach for detecting high-frequency restriction fragment length polymorphisms using large genomic probes.

Thirteen phage clones containing low-copy sequences were isolated from a human DNA library and tested for their ability to detect restriction fragment length polymorphisms (RFLPs). Reported are the RFLPs revealed with each clone, all found in frequencies useful for linkage studies. Cytological data are available for five of the 13 clones, with regional assignments made for three of the markers by in situ hybridization. It is concluded that phage clones containing large unique DNA inserts detect multiple RFLPs with high efficiency. An analysis of the relative efficiency of 20 restriction enzymes for detecting single nucleotide changes is discussed by comparing the observed data to those expected on the basis of recognition and potential site frequencies, as computed from the dinucleotide distribution. Finally, in an effort to facilitate linkage studies using polymorphic DNA sequences, experiments were made with pools of probes from various sources.     

Physical and genetic mapping of the Rhodobacter sphaeroides 2.4.1 genome: genome size, fragment identification, and gene localization.

Four restriction endonucleases, AseI (5'-ATTAAT), SpeI (5'-ACTAGT), DraI (5'-TTTAAA), and SnaBI (5'-TACGTA), generated DNA fragments of suitable size distributions for mapping the genome of Rhodobacter sphaeroides by transverse alternating field electrophoresis. AseI produced 17 fragments, ranging in size from 3 to 1,105 kilobases (kb), SpeI yielded 16 fragments (12 to 1,645 kb), DraI yielded at least 25 fragments (6 to 800 kb), and SnaBI generated 10 fragments (12 to 1,225 kb). A total genome size of approximately 4,400 +/- 112 kb was determined by summing the fragment lengths in each of the digests generated by using the different restriction endonucleases. The total genomic DNA consisted of chromosomal DNA (3,960 +/- 112 kb) and the five endogenous plasmids (approximately 450 kb total) whose cognate DNA fragments have been unambiguously identified. A number of genes have been physically mapped to the AseI-generated restriction endonuclease fragments of total genomic DNA by Southern hybridization analysis with either homologous or heterologous specific gene probes or, in the case of several auxotrophic and pigment-biosynthetic mutants apparently generated by Tn5, a Tn5-specific probe. Other genes have been mapped by a comparison with wild-type patterns of the electrophoretic banding patterns of the AseI-digested genomic DNA derived from mutants generated by the insertion of either kanamycin or spectinomycin-streptomycin resistance cartridges. The relative orientations, distance, and location of the pufBALMX, puhA, cycA, and pucBA operons have also been determined, as have been the relative orientations between prkB and hemT and between prkA and the fbc operon.     

Targeted enrichment of genomic DNA regions for next-generation sequencing

In this review, we discuss the latest targeted enrichment methods and aspects of their utilization along with second-generation sequencing for complex genome analysis. In doing so, we provide an overview of issues involved in detecting genetic variation, for which targeted enrichment has become a powerful tool. We explain how targeted enrichment for next-generation sequencing has made great progress in terms of methodology, ease of use and applicability, but emphasize the remaining challenges such as the lack of even coverage across targeted regions. Costs are also considered versus the alternative of whole-genome sequencing which is becoming ever more affordable. We conclude that targeted enrichment is likely to be the most economical option for many years to come in a range of settings.     

Functional genomic mapping of an early-activated centromeric mammalian origin of DNA replication.

Ors12, a mammalian autonomously replicating sequence (812 bp), was previously isolated by extrusion of African green monkey (CV-1 cells) nascent DNA from active replication bubbles. It contains a region of alpha-satellite extending 168-bp from the 5'-end, and a nonrepetitive portion extending from nucleotide position 169 to nucleotide 812 that is present in less than nine copies per haploid genome. Ors12 is capable of transient autonomous DNA replication in vivo and in vitro, associates with the nuclear matrix in a cell cycle-dependent manner, and hybridizes at the centromeric region of six CV-1 cell chromosomes as well as a marker chromosome. To demonstrate that DNA replication initiates at ors12 at a native chromosomal locus, a 14.2 kb African green monkey genomic clone was isolated and sequence information was obtained that allowed us to generate eight sets of PCR primers spanning a region of 8 kb containing ors12. One set of primers occurred inside ors12. These primers were used to amplify nascent DNA strands from asynchronously growing CV-1 and African green monkey kidney (AGMK) cells, using noncompetitive and competitive PCR-based mapping methodologies. Both assays showed that DNA replication in vivo initiates preferentially in a 2.3 kb region containing ors12, as well as at a second site located 1.7 kb upstream of ors12. This study provides the first demonstration of genomic function for a centromeric mammalian origin of DNA replication, originally isolated by nascent strand extrusion.     

Plant genome studies: restriction fragment length polymorphism and chromosome mapping information.

The detection of sequence variation with restriction fragment length polymorphisms is advancing our knowledge of plant genetics on several fronts. In the past year, there has been progress in genetic map construction, phylogeny studies, and the dissection of multigenic traits. In addition, new methods that are independent of restriction sites are being developed for polymorphism detection.     

Happy mapping: a proposal for linkage mapping the human genome.

A theoretical approach for linkage mapping the genome of any higher eukaryote is described. It uses the polymerase chain reaction, oligonucleotides of random sequence and single haploid cells. Markers are defined and then the DNA of a single sperm is broken at random (eg by gamma-rays) and physically split into 3 aliquots. Each aliquot is screened for the presence of each marker. Closely-linked markers are more likely to be found in the same aliquot than unlinked markers. The entire process is repeated with further sperm and the frequency that any two markers co-segregate determined. Closely-linked markers co-segregate from most cells; unlinked markers do so rarely. A map can then be constructed from these co-segregation frequencies. A specific application for determining the order and distance between sets of closely-linked and previously-defined markers is also described.     

Rapid isolation of cosmid insert DNA by triple-helix-mediated affinity capture

A simple and rapid method for the isolation of cosmid insert DNA was developed based on triple-helix-mediated affinity capture (TAC). A modified cosmid was constructed from the SuperCos 1 cosmid vector by flanking the cloning site with two homopurine-homopyrimidine triple-helix-forming sequences. The cosmid DNA is digested with NotI restriction enzyme to release the insert DNA. The NotI-digested cosmid DNA is then combined with a biotinylated homopyrimidine oligonucleotide in an acidic buffer solution to form a triple-helix complex. The triple-helix complex is captured with streptavidin-coated magnetic beads. Insert DNA is eluted by adding a pH 9 buffered solution to the captured complex, The purified insert DNA is recovered with a yield of up to 95% and a purity of at least 95%. The isolated insert DNA was directly digested with CviJI restriction endonuclease to generate random fragments for shotgun sequencing.     

Methylase-limited partial NotI cleavage for physical mapping of genomic DNA.

Partial cleavage of DNA with the restriction endonuclease NotI (5'...GC/GGCCGC...3') is an important technique for genomic mapping. However, partial genomic cleavage with this enzyme is impaired by the agarose matrix in which the DNA must be suspended. To solve this problem we have purified the blocking methylase M. BspRI (5'...GGmCC...3') for competition digests with NotI. The resulting methylase-limited partial DNA cleavage is shown to be superior to standard techniques on bacterial genomic DNA. Abbreviations: bp, base-pair; kb, one thousand base-pairs; Mb, one million base-pairs; Tris, Tris(hydroxy-methyl)aminomethane; EDTA, (ethylenedinitrilo)tetraacetic; beta-ME, beta-mercaptoethanol; PMSF, phenyl methyl-sulfonyl fluoride; PEG, polyethyleneglycol (MW = 8000); 3H, tritium; SAM, S-adenosylmethionine; KGB, potassium glutamate buffer; DTT, dithiothreitol; IPTG, isopropyl-beta-D-thiogalactopyranoside; BSA, bovine serum albumin.     

Mapping DNA by stochastic relaxation: a new approach to fragment sizes

Instead of the traditional manipulations with given fixed fragmentlengths in the restriction map construction a method of varyingthe lengths is proposed and realized under the simulated annealingalgorithm scheme. The described approach has no upper limiton the number of fragments mapped with even ordinary hardware.A program has been derived from the algorithm combined withthe least–squares refinement procedure for both linearand circular maps. The algorithm's abilily to pick up missedmaps is illustrated and the problem of reducing the number ofsolutions is discussed. Received on January 8, 1990; accepted on January 9, 1990     

Association mapping of disease loci, by use of a pooled DNA genomic screen.

Genomic screening to map disease loci by association requires automation, pooling of DNA samples, and 3,000-6,000 highly polymorphic, evenly spaced microsatellite markers. Case-control samples can be used in an initial screen, followed by family-based data to confirm marker associations. Association mapping is relevant to genetic studies of complex diseases in which linkage analysis may be less effective and to cases in which multigenerational data are difficult to obtain, including rare or late-onset conditions and infectious diseases. The method can also be used effectively to follow up and confirm regions identified in linkage studies or to investigate candidate disease loci. Study designs can incorporate disease heterogeneity and interaction effects by appropriate subdivision of samples before screening. Here we report use of pooled DNA amplifications-the accurate determination of marker-disease associations for both case-control and nuclear family-based data-including application of correction methods for stutter artifact and preferential amplification. These issues, combined with a discussion of both statistical power and experimental design to define the necessary requirements for detecting of disease loci while virtually eliminating false positives, suggest the feasibility and efficiency of association mapping using pooled DNA screening.     

Specificity of randomly generated genomic DNA fragment probes on a DNA array

The use of randomly generated DNA fragment sequences as probes on DNA arrays offers a unique potential for exploring unsequenced microorganisms. In this study, the detection specificity was evaluated with respect to probe-target sequence similarity using genomic DNAs of four Pseudomonas strains. Genome fragments averaging 2000?bp were found to be specific enough to discriminate 85-90% similarity under highly stringent hybridization conditions. Such stringent conditions compromised signal intensities; however, specific signals remained detectable at the highest stringency (at 75?°C hybridization) with negligible false negatives. These results suggest that, without any probe design or selection, genomic fragments can provide a reasonable specificity for microbial diagnostics or species delineation by DNA-DNA similarities.     

AtMap1: a DNA microarray for genomic deletion mapping in Arabidopsis thaliana

We have designed a novel tiling array, AtMap1, for genomic deletion mapping. AtMap1 is a 60-mer oligonucleotide microarray consisting of 42 497 data probes designed from the genomic sequence of Arabidopsis thaliana Col-0. The average probe interval is 2.8 kb. The performance of the AtMap1 array was assessed using the deletion mutants mag2-2, rot3-1 and zig-2. Eight of the probes showed threefold lower signals in mag2-2 than Col-0. Seven of these probes were located in one region on chromosome 3. We considered these adjacent probes to represent one deletion. This deletion was consistent with a reported deleted region. The other probe was located near the end of chromosome 4. A newly identified deletion around the probe was confirmed by PCR. We also detected the responsible deletions for rot3-1 and zig-2. Thus we concluded that the AtMap1 array was sufficiently sensitive to identify a deletion without any a priori knowledge of the deletion. An analysis of the result of hybridization of Ler and previously reported polymorphism data revealed that the signal decrease tended to depend on the overlap size of sequence polymorphisms. Mutation mapping is time-consuming, laborious and costly. The AtMap1 array removes these limitations.     

High affinity binding of the large T protein of polyoma virus to a genomic mouse DNA sequence

We purified a fragment of mouse DNA to which the large T protein of polyoma virus was bound in chromatin prepared from transformed mouse cells. This sequence, which is not repeated to a measurable extent within the mouse genome, does not show any significant homology to the viral ori region, except in a short region, which comprises a sequence related to the consensus for recognition by large T proteins ((A,T)GPuGGC). This region of pCG4 was confirmed by in vitro binding assays to be essential for T antigen binding.