Purification of mitochondrial and plastid DNA

The size, structure and conformation of mitochondrial and plastid genomes differ dramatically among eukaryotes. Similarly, the yield and purity of extracted organelle DNA also vary, and are crucial factors for the success of restriction mapping and sequencing experiments. We describe here procedures for the purification of organelle DNA from a broad range of eukaryotes. By emphasizing the underlying principles, these procedures will facilitate the development of new species-specific protocols. The presented purification schemes involve either isolation of organelles and subsequent extraction of DNA from this subcellular fraction, or processing of whole-cell lysates followed by CsCl gradient centrifugation to separate nuclear and organelle DNAs according to their A + T content. We have successfully used the described procedures for organelle genome sequencing from diverse eukaryotes, including non-axenic protists. Procedures can be completed in 3-5 days, typically yielding a few micrograms of DNA-ample for sequencing complete genomes.     

Rapid isolation and sequencing of purified plasmid DNA from Bacillus subtilis.

We report two methods for isolation of plasmid DNA from the gram-positive bacterium Bacillus subtilis. The protoplast alkaline lysis procedure was developed for general use, and the protoplast alkaline lysis magic procedure was developed for isolation of DNA for sequencing. Both procedures yielded large amounts of high-quality DNA in less than 1 h, while current protocols require 4 to 7 h to perform and give lower yields and quality. Plasmid DNA was obtained from strains containing either high- or low-copy-number plasmids. In addition, the procedures were easily adapted to yield large amounts of plasmid DNA suitable for sequencing from another gram-positive organism, Staphylococcus aureus. Further, we demonstrated that neither chloramphenicol, used for plasmid selection, nor the mutation recE4 reduced plasmid DNA yield from the strains we examined.     

A simple system of cloning in phage M13 and DNA sequencing with terminators

A compilation of techniques for DNA cloning in filamentous phage M13 based vectors for a novice in cloning is presented. It does not require either specialized microbiological facilities, or any specific knowledge in Escherichia coli genetics. The cloning strategy uses only blunt-end ligation into a vector that has been prepared once for several hundred experiments. The first part describes the isolation, preparation and checking of a blunt-ended M13 vector (with M13 mp series vectors as an example), and also the isolation of clonable fragments, transformation of competent cells and preliminary analysis of recombinants. The second part describes procedures and equipment, which enable to sequence recombinant M13 clones by the chain termination procedure of Sanger et al. It includes simplified procedures for the preparation of sequencing gels, and the rules of interpretation of the sequencing ladders. Reference material is added, which includes trouble-shooting guide, E. coli K12 strain list and polylinker sequences for use of mp-series vectors as well as a fully documented cloning and sequencing experiment.     

A method for determining DNA sequence by labeling the end of the molecule and cleaving at the base. Isolation of DNA fragments, end-labeling, cleavage, electrophoresis in polyacrylamide gel and analysis of results

We elaborate basic chemical principles and current laboratory procedures for sequencing end-labeled DNA by partial cleavage and gel electrophoresis (A. M. Maxam and W. Gilbert, Proc. Natl. Acad. Sci. USA, 1977, v. 74, p. 560-564). We provide step-by-step protocols for 32P-labeling DNA ends, segregating the labeled ends by cutting with a second restriction enzyme or separating strands, partially cleaving the DNA at specific bases with reagents, electrophoresing the labeled products of cleavage on sequencing gels, and interpreting sequencing band patterns. Many of these procedures have been condensed, to make them faster and easier, and some are new. We also discuss sequencing strategies, and suggest a technique which will reduce plasmid or viral DNA to a collection of singly-end-labeled fragments in one day, for efficient sequencing of these chromosomes in 250-nucleotide blocks.     

Genome-wide high throughput analysis of DNA methylation in eukaryotes

Cytosine methylation is the quintessential epigenetic mark. Two well-established methods, bisulfite sequencing and methyl-DNA immunoprecipitation (MeDIP) lend themselves to the genome-wide analysis of DNA methylation by high throughput sequencing. Here we provide an overview and brief review of these methods. We summarize our experience with MeDIP followed by high throughput Illumina/Solexa sequencing, exemplified by the analysis of the methylated fraction of the Neurospora crassa genome ("methylome"). We provide detailed methods for DNA isolation, processing and the generation of in vitro libraries for Illumina/Solexa sequencing. We discuss potential problems in the generation of sequencing libraries. Finally, we provide an overview of software that is appropriate for the analysis of high throughput sequencing data generated by Illumina/Solexa-type sequencing by synthesis, with a special emphasis on approaches and applications that can generate more accurate depictions of sequence reads that fall in repeated regions of a chosen reference genome.     

Specific-primer-directed DNA sequencing using automated fluorescence detection.

Automated fluorescence-based DNA sequence analysis offers the possibility to undertake very large scale sequencing projects. Directed strategies, such as the specific-primer-directed sequencing approach ('gene walking'), should prove useful in such projects. Described herein is a study involving the use of this approach in conjunction with automated fluorescence detection on a commercial instrument (ABI 370A DNA sequencer). This includes procedures for the rapid chemical synthesis and purification of labeled primers, the design of primer sequences that are compatible with the commercial analysis software, and automated DNA sequence analysis using such primers. A set of four fluorophore-labeled primers can be reliably synthesized in a twenty-four hour period, and greater than 300 nucleotides of analyzed new sequence obtained using this set in an additional twenty-four hours. Scale-up of these procedures to take advantage of the full capabilities of the sequencer is, at present, too slow and costly to be suitable for routine sequencing, and therefore the use of specific-primers is best suited to the closure of gaps in extended sequence produced using random cloning and sequencing strategies.     

Rapid and reliable fluorescent cycle sequencing of double-stranded templates.

Automated DNA sequencing is an extremely valuable technique which requires very high quality DNA templates to be carried out successfully. While it has been possible to readily produce large numbers of such templates from M13 or other single-stranded vectors for several years, the sequencing of double-stranded DNA templates using the ABI 373 DNA Sequencer has had a considerably lower success rate. We describe how the combination of a new fluorescent, dideoxy sequencing method, called cycle-sequencing, coupled with modifications to template isolation procedures based on Qiagen columns, makes fluorescent sequencing of double-stranded templates a reliable procedure. From a single five milliliter culture enough DNA can be isolated (up to 20 micrograms) to do 4-8 sequencing reactions, each of which yields 400-500 bases of high quality sequence data. These procedures make the routine use of double-stranded DNA templates a viable strategy in automated DNA sequencing projects.     

DNA sequence analysis by MALDI mass spectrometry.

Conventional DNA sequencing is based on gel electrophoretic separation of the sequencing products. Gel casting and electrophoresis are the time limiting steps, and the gel separation is occasionally imperfect due to aberrant mobility of certain fragments, leading to erroneous sequence determination. Furthermore, illegitimately terminated products frequently cannot be distinguished from correctly terminated ones, a phenomenon that also obscures data interpretation. In the present work the use of MALDI mass spectrometry for sequencing of DNA amplified from clinical samples is implemented. The unambiguous and fast identification of deletions and substitutions in DNA amplified from heterozygous carriers realistically suggest MALDI mass spectrometry as a future alternative to conventional sequencing procedures for high throughput screening for mutations. Unique features of the method are demonstrated by sequencing a DNA fragment that could not be sequenced conventionally because of gel electrophoretic band compression and the presence of multiple non-specific termination products. Taking advantage of the accurate mass information provided by MALDI mass spectrometry, the sequence was deduced, and the nature of the non-specific termination could be determined. The method described here increases the fidelity in DNA sequencing, is fast, compatible with standard DNA sequencing procedures, and amenable to automation.     

The construction and analysis of M13 libraries prepared from YAC DNA.

Yeast artificial chromosomes (YACs) provide a powerful way to isolate and map large regions of genomic DNA and their use in genome analysis is now extensive. We modified a series of procedures to produce high quality shotgun libraries from small amounts of YAC DNA. Clones from several different libraries have been sequenced and analyzed for distribution, sequence integrity and degree of contamination from yeast DNA. We describe these procedures and analyses and show that sequencing at about 1-fold coverage, followed by database comparison (survey sequencing) offers a relatively quick method to determine the nature of previously uncharacterized cosmid or YAC clones.     

Adaptation of a Silica Membrane-based Kit for Purification of Sequencing-ready BAC DNA

We describe a modification of a protocol for the isolation of BAC DNA using a silica membrane-based kit designed for the isolation of plasmid DNA. The major advantages of this protocol are the expediency of the procedure, the high yield and purity, and the high quality of the BAC DNA that is suitable for direct sequencing.     

PCR-Free Enrichment of Mitochondrial DNA from Human Blood and Cell Lines for High Quality Next-Generation DNA Sequencing

Recent advances in sequencing technology allow for accurate detection of mitochondrial sequence variants, even those in low abundance at heteroplasmic sites. Considerable sequencing cost savings can be achieved by enriching samples for mitochondrial (relative to nuclear) DNA. Reduction in nuclear DNA (nDNA) content can also help to avoid false positive variants resulting from nuclear mitochondrial sequences (numts). We isolate intact mitochondrial organelles from both human cell lines and blood components using two separate methods: a magnetic bead binding protocol and differential centrifugation. DNA is extracted and further enriched for mitochondrial DNA (mtDNA) by an enzyme digest. Only 1 ng of the purified DNA is necessary for library preparation and next generation sequence (NGS) analysis. Enrichment methods are assessed and compared using mtDNA (versus nDNA) content as a metric, measured by using real-time quantitative PCR and NGS read analysis. Among the various strategies examined, the optimal is differential centrifugation isolation followed by exonuclease digest. This strategy yields >35% mtDNA reads in blood and cell lines, which corresponds to hundreds-fold enrichment over baseline. The strategy also avoids false variant calls that, as we show, can be induced by the long-range PCR approaches that are the current standard in enrichment procedures. This optimization procedure allows mtDNA enrichment for efficient and accurate massively parallel sequencing, enabling NGS from samples with small amounts of starting material. This will decrease costs by increasing the number of samples that may be multiplexed, ultimately facilitating efforts to better understand mitochondria-related diseases.     

CircumVent thermal cycle sequencing and alternative manual and automated DNA sequencing protocols using the highly thermostable VentR (exo-) DNA polymerase.

CircumVent thermal cycle and standard DNA sequencing protocols utilizing the cloned and highly thermostable VentR (exo-) DNA polymerase are described. The thermal cycle sequencing procedures are advantageous because they allow fast and simple semiautomation of the sequencing reaction; make possible the direct DNA sequencing of PCR products, bacterial colonies and phage plaques; require only femtomoles of template DNA; eliminate the requirement of an independent primer annealing step; remove the requirement of denatured plasmids for sequencing double-stranded templates; and use a highly thermostable DNA polymerase for sequencing through potential recalcitrant secondary structure domains and large linear double-stranded DNA templates such as lambda derivatives. More standard methods of DNA sequencing (i.e., a one-step protocol and a labeling-termination protocol) are also presented. For each protocol, alternatives for choice of label and method of labeling are presented, including the use of 5' biotinylated primers for chemiluminescent DNA sequencing and fluorinated primers for automated sequencing using the BaseStation Automated DNA Sequencer.     

A method for isolation and purification of peanut genomic DNA suitable for analytical applications

Numerous methods are available for isolation of plant genomic DNA, but in practice these procedures are empirical due to variability in plant tissue composition. Consistent isolation of quality DNA from peanut (Arachis hypogaea L.) is particularly problematic due to the presence of phenolic compounds and polysaccharides. Inconsistencies in extraction results can be attributed to the age and growth stage of the plant material analyzed. Mature leaves have higher quantities of polyphenols, tannins, and polysaccharides that can contaminate DNA during isolation. We show that four published protocols could not be used to isolate peanut DNA of sufficient quality for PCR amplification or Southern hybridization. We have devised a new protocol that uses DEAE-cellulose purification to isolate peanut DNA useful for downstream applications.     

Application of a novel chemiluminescence-based DNA detection method to single-vector and multiplex DNA sequencing

A chemiluminescent DNA detection method is described and its application shown for both single-vector and multiplex DNA sequencing using the standard dideoxy chain-termination process. This recently developed detection method, which utilizes the light emitted by an enzyme-catalyzed dioxetane reaction, is highly sensitive and affords significant advantages in safety and speed over the traditional radioactive labeling method. When adapted to a multiplex strategy, this chemiluminescent detection method constitutes a safe, simple and rapid method for increasing the throughput of DNA sequencing procedures.     

Production of single-stranded DNA for sequencing: an alternative approach.

We describe a simple procedure for the direct sequencing of single-stranded, PCR-amplified, target regions of human genomic DNA. At variance with previously reported procedures, purification of the desired double-stranded DNA was introduced. This additional step allowed the single-stranded amplification and sequencing of the target gene. This step is required for direct sequencing of some amplified regions of human genomic DNA. However, no individual technique seems suitable to generate and sequence all single-stranded DNA.     

New rapid methods for DNA sequencing based in exonuclease III digestion followed by repair synthesis.

We describe improve enzymatic methods for sequencing method for sequencing DNA. They are based on partial digestion of duplex DNA with exonuclease III to produce DNA molecules with 3' ends shortened to varying lengths, followed by repair synthesis to extend and label the 3' ends. After asymmetrical cleavage of the DNA with a restriction enzyme, the labeled products are separated by gel electrophoresis and the sequence read from the autoradiogram. The entire procedures, beginning with unrestricted DNA and followed through gel electrophoresis, takes only one day for sequencing both strands of the DNA molecule. These methods are especially suitable for sequencing DNA cloned in plasmid vectors, and they greatly extend the usefulness of the dideoxynucleotide chain termination method of Sanger et al. (Proc. Natl. Acad. Sci. USA 74, 5463, 1977). Using these methods we have determined the sequence of a 410 base pair fragment which includes the yeast SUP3 tyrosine tRNA gene.     

Metagenomics: DNA sequencing of environmental samples

Although genomics has classically focused on pure, easy-to-obtain samples, such as microbes that grow readily in culture or large animals and plants, these organisms represent only a fraction of the living or once-living organisms of interest. Many species are difficult to study in isolation because they fail to grow in laboratory culture, depend on other organisms for critical processes, or have become extinct. Methods that are based on DNA sequencing circumvent these obstacles, as DNA can be isolated directly from living or dead cells in various contexts. Such methods have led to the emergence of a new field, which is referred to as metagenomics.     

Sequential DEXAS: a method for obtaining DNA sequences from genomic DNA and blood in one reaction

Sequential DEXAS (direct exponential amplification and sequencing), a one step amplification and sequencing procedure that allows accurate, inexpensive and rapid DNA sequence determination directly from genomic DNA, is described. This method relies on the simultaneous use of two DNA polymerases that differ both in their ability to incorporate dideoxynucleotides and in the time at which they are activated during the reaction. One enzyme, which incorporates deoxynucleotides and performs amplification of the target DNA sequence, is supplied in an active state whereas the other enzyme, which incorporates dideoxynucleotides and performs the sequencing reaction, is supplied in an inactive state but becomes activated by a temperature step during the thermocycling. Thus, in the initial stage of the reaction, target amplification occurs, while in the second stage the sequencing reaction takes place. We show that Sequential DEXAS yields high quality sequencing results directly from genomic DNA as well as directly from human blood without any prior isolation or purification of DNA.     

蚜虫基因组DNA提取方法的改进

蚜虫基因组DNA的提取是蚜虫分子生物学研究中的难点。参照动物基因组DNA的提取方法,根据蚜虫体型微小,体表有外骨骼的特点,对SDS法作了改进。改进的方法无需用组织捣碎棒破碎虫体,操作简便。与现在常用的提取方法相比,改进的SDS法能快速、有效地提取单头蚜虫的基因组DNA,适用于RAPD随机引物和测序引物的PCR扩增。     

Rapid isolation of DNA from Staphylococcus aureus

We describe a Staphylococcus aureus bulk DNA isolation procedure which uses detergent and guanidine hydrochloride to free the nucleic acid from contaminants. The procedure is rapid and yields high-molecular-weight DNA suitable for molecular biological procedures.