Glass bead purification of plasmid template DNA for high throughput sequencing of mammalian genomes

To meet the new challenge of generating the draft sequences of mammalian genomes, we describe the development of a novel high throughput 96-well method for the purification of plasmid DNA template using size-fractionated, acid-washed glass beads. Unlike most previously described approaches, the current method has been designed and optimized to facilitate the direct binding of alcohol-precipitated plasmid DNA to glass beads from alkaline lysed bacterial cells containing the insoluble cellular aggregate material. Eliminating the tedious step of separating the cleared lysate significantly simplifies the method and improves throughput and reliability. During a 4 month period of 96-capillary DNA sequencing of the Rattus norvegicus genome at the Baylor College of Medicine Human Genome Sequencing Center, the average success rate and read length derived from >1 800 000 plasmid DNA templates prepared by the direct lysis/glass bead method were 82.2% and 516 bases, respectively. The cost of this direct lysis/glass bead method in September 2001 was ~10 cents per clone, which is a significant cost saving in high throughput genomic sequencing efforts.     

Chemical sequencing of restriction fragments 3′-end-labeled with [S]dATPαS

Although the phosphorous radioisotope 32P is routinely used in Maxam-Gilbert sequencing, it presents disadvantages that adversely affect safety and ease of use, resolution, and DNA degradation rates. Here, we introduce a new protocol utilizing the alternative isotope 35S for 3'-end-labeling DNA restriction fragments. In our method, plasmid DNA is labeled with [35S]dATPalphaS and 7 Sequenase Version 2.0. We have shown that bands on Maxam-Gilbert sequencing gels are sharp with extremely low background. In addition, a single labeling reaction produces DNA sufficient for 80 sequencing lanes, and the labeled DNA can be utilized for prolonged periods of time without significant degradation. We have further demonstrated the utility of our 35S-end-labeling procedure by successfully mapping the sequence-specificity of DNA damage induced by photoexcited riboflavin. Overall, we have shown that 35S can be used as a safe and practical alternative to 32P in the 3'-end-labeling of DNA restriction fragments.     

Resuspension of DNA sequencing reaction products in agarose increases sequence quality on an automated sequencer

We are investigating approaches to increase DNA sequencing quality. Since a majorfactor in sequence generation is the cost of reagents and sample preparations, we have developed and optimized methods to sequence directly plasmid DNA isolated from alkaline lysis preparations. These methods remove the costly PCR and post-sequencing purification steps but can result in low sequence quality when using standard resuspension protocols on some sequencing platforms. This work outlines a simple, robust, and inexpensive resuspension protocol for DNA sequencing to correct this shortcoming. Resuspending the sequenced products in agarose before electrophoresis results in a substantial and reproducible increase in sequence quality and read length over resuspension in deionized water and has allowed us to use the aforementioned sample preparation methods to cut considerably the overall sequencing costs without sacrificing sequence quality. We demonstrate that resuspension of unpurified sequence products generated from template DNA isolated by a modified alkaline lysis technique in low concentrations of agarose yields a 384% improvement in sequence quality compared to resuspension in deionized water. Utilizing this protocol, we have produced more than 74,000 high-quality, long-read-length sequences from plasmid DNA template on the MegaBACET 1000 platform.     

双磁珠法质粒DNA提取技术及应用

质粒是基因合成与测序领域中使用最为频繁的基因运载工具,然而传统的质粒DNA提取方法面临提取通量低、生产成本高等问题,无法满足日益增长的需求。本研究基于质粒提取原理,开发了双磁珠法(double-magnetic-bead method, DMBM)质粒提取技术,探究了磁珠投入量、质粒DNA片段大小、菌液投入量等因素对质粒提取的影响,并且对比了本技术与商业化质粒DNA提取试剂盒提取DNA质量、提取通量及提取成本。结果表明,双磁珠法质粒DNA提取技术可满足不同细胞密度、不同片段长度的质粒DNA提取。此外,该技术搭载96通道全自动核酸提取仪,提取的质粒DNA纯度更高、提取时间缩短80%、提取成本缩减57.1%,从而实现了质粒DNA提取的高通量、低成本,有效助力基因合成与测序。     

Construction of Templates for Sequencing Extended DNA Fragments

A rapid and convenient method was proposed for constructing insertional mutants in the sequencing of extended DNA fragments. The gist is insertion of an antibiotic resistance gene in plasmid DNA digested with DNase I. DNase I provides for a uniform distribution of insertion sites along the plasmid, and the background is low owing to antibiotic-based selection. The method requires neither high quality nor large amounts of plasmid DNA (which is especially important with low-copied plasmids), yields the results independent of the plasmid nucleotide sequence, and allows highly accurate analysis and ordering of the insertional mutants.     

The method of template construction for sequencing extended DNA fragments

A rapid and convenient method was proposed for constructing insertional mutants in the sequencing of extended DNA fragments. The gist is insertion of an antibiotic resistance gene in plasmid DNA digested with DNase I. DNase I provides for a uniform distribution of insertion sites along the plasmid, and the background is low owing to antibiotic-based selection. The method requires neither high quality nor large amounts of plasmid DNA (which is especially important with low-copied plasmids), yields the results independent of the plasmid nucleotide sequence, and allows highly accurate analysis and ordering of the insertional mutants.     

An extended boiling method for small-scale preparation of plasmid DNA tailored to long-range automated sequencing

Automated fluorescence sequencing depends on high-quality plasmid DNA, which is conveniently prepared by minipreparation procedures. While those procedures are effective for high-copy number plasmids, purity and yields of low-copy number plasmids are often not sufficient to achieve reasonable sequencing results. Here, we describe a reproducible and cheap procedure for the small-scale preparation of plasmid DNA, which is based on the original Holmes and Quigley protocol, comprising a boiling and two selective precipitation steps. Besides various other modifications, this procedure utilizes polyethylene glycol (PEG) precipitation as a key step to further purify plasmid DNA tailored to automated fluorescence sequencing. Independent of the plasmid size and copy number, the modified procedure yields plasmid DNA, which gives average reading lengths of 800 and more bases with a standard fluorescence cycle sequencing protocol. To demonstrate the efficiency and reproducibility of the method, sequencing data of various human interleukin-6 gene variants cloned in different vectors are presented. This procedure offers an economical alternative to commercial miniprep kits, utilizing silica resins or anion-exchanger matrices and, moreover, is more reliable and consistent with respect to reading lengths and accuracy in automated fluorescence sequencing.     

Dideoxy sequencing method using denatured plasmid templates

The dideoxy sequencing method in which denatured plasmid DNA is used as a template was improved. The method is simple and rapid: the recombinant plasmid DNA is extracted and purified by rapid alkaline lysis followed by ribonuclease treatment. The plasmid DNA is then immediately denatured with alkali and subjected to a sequencing reaction utilizing synthetic oligonucleotide primers. It takes only several hours from the start of the plasmid extraction to the end of the sequencing reaction. We examined each step of the procedure, and several points were found to be crucial for making the method reproducible and powerful: (i) the plasmid DNA should be free from RNA and open circular (or linear) DNA; (ii) a heptadecamer rather than a pentadecamer is recommended as a primer; and (iii) the sequencing reaction should be done at 37 degrees C or higher rather than at room temperature. The method enabled us to determine the sequence of more than a thousand nucleotides from a single template DNA.     

A one-step miniprep for the isolation of plasmid DNA and lambda phage particles

Plasmid DNA minipreps are fundamental techniques in molecular biology. Current plasmid DNA minipreps use alkali and the anionic detergent SDS in a three-solution format. In addition, alkali minipreps usually require additional column-based purification steps and cannot isolate other extra-chromosomal elements, such as bacteriophages. Non-ionic detergents (NIDs) have been used occasionally as components of multiple-solution plasmid DNA minipreps, but a one-step approach has not been developed. Here, we have established a one-tube, one-solution NID plasmid DNA miniprep, and we show that this approach also isolates bacteriophage lambda particles. NID minipreps are more time-efficient than alkali minipreps, and NID plasmid DNA performs better than alkali DNA in many downstream applications. In fact, NID crude lysate DNA is sufficiently pure to be used in digestion and sequencing reactions. Microscopic analysis showed that the NID procedure fragments E. coli cells into small protoplast-like components, which may, at least in part, explain the effectiveness of this approach. This work demonstrates that one-step NID minipreps are a robust method to generate high quality plasmid DNA, and NID approaches can also isolate bacteriophage lambda particles, outperforming current standard alkali-based minipreps.     

An improved filamentous helper phage for generating single-stranded plasmid DNA

Gene cloning in plasmid vectors that contain a filamentous phage intergenic region presents several advantages. However, technical difficulties have been a problem, primarily low yields of packaged single stranded (ss) plasmid DNA from the rapid, small scale procedures usually employed, and ambiguities in sequencing reactions attributed to the contamination by helper phage ss DNA. We report here the construction and some properties of a new f1 helper phage. Using this phage, R408, plasmid ss DNA is packaged and exported preferentially over phage ss DNA, and the absolute yield of plasmid ss DNA is usually increased.     

A QuikChange-like method to realize efficient blunt-ended DNA directional cloning and site-directed mutagenesis simultaneously

Here we present a QuikChange-like method to efficiently realize blunt-ended DNA cloning and conveniently introduce a site-directed mutation to recombinant plasmid at the same time. After blunt-ended DNA ligation and transformation, the plasmid DNA mixture is extracted from pooled transformants and directly used as template for PCR amplification with a pair of complementary mutagenic primers. With this method, sam1 gene was inserted into pUC19 vector by blunt-end ligation, and a unique restriction site Spe I was introduced to the recombinant plasmid at the same time. The randomly selected transformants were analyzed by DNA sequencing, and most of the clones were found to have correct sequences. However, no correct construct was found from randomly selected transformants after traditional blunt-ended DNA ligation and transformation.     

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.     

Large scale sequencing projects using rapidly prepared double-stranded plasmid DNA.

We have developed a simple rapid plasmid DNA mini-preparation method which yields DNA of sufficient quality to be used in large scale sequencing projects. The method, which is a modification of the alkaline method of Birnboim and Doly (1979), requires less than two hours. We have eliminated the use of organic extractions, RNase digestion and alkaline denaturation of the DNA for annealing of the primer. The proportion of supercoiled plasmid DNA obtained is close to 100%. Greater than 80% of the clones yield at least 500 bp of sequence information per primer. The sequencing reactions from these double-stranded templates can be done on both strands using the universal and reverse sequence primers with the usual two reactions per primer, one to read close to the primer and one to read far from it. Thus, each clone yields at least 1 kb of sequence information. The preparation of the templates and the sequencing reactions can be done in less than three hours so that the sequencing gel can be run the same day.     

Quantifying Population Genetic Differentiation from Next-Generation Sequencing Data

Over the past few years, new high-throughput DNA sequencing technologies have dramatically increased speed and reduced sequencing costs. However, the use of these sequencing technologies is often challenged by errors and biases associated with the bioinformatical methods used for analyzing the data. In particular, the use of naïve methods to identify polymorphic sites and infer genotypes can inflate downstream analyses. Recently, explicit modeling of genotype probability distributions has been proposed as a method for taking genotype call uncertainty into account. Based on this idea, we propose a novel method for quantifying population genetic differentiation from next-generation sequencing data. In addition, we present a strategy for investigating population structure via principal components analysis. Through extensive simulations, we compare the new method herein proposed to approaches based on genotype calling and demonstrate a marked improvement in estimation accuracy for a wide range of conditions. We apply the method to a large-scale genomic data set of domesticated and wild silkworms sequenced at low coverage. We find that we can infer the fine-scale genetic structure of the sampled individuals, suggesting that employing this new method is useful for investigating the genetic relationships of populations sampled at low coverage.     

A cost-effective plasmid purification protocol suitable for fluorescent automated DNA sequencing

A cost-effective, reliable, and reproducible method has been developed to produce good-quality, double-stranded plasmid DNA for automated sequence analysis. The method incorporates modifications to a previously described plasmid-purification protocol used in manual sequencing. The quality of the DNA produced from the present protocol is suitable for automated fluorescent sequencing. Using a dye-terminator sequencing protocol, most runs using plasmid DNA prepared using this protocol produced over 700 bases with greater than 99% base-calling accuracy.     

Whole-genome long-read TAPS deciphers DNA methylation patterns at base resolution using PacBio SMRT sequencing technology

Long-read sequencing provides valuable information on difficult-to-map genomic regions, which can complement short-read sequencing to improve genome assembly, yet limited methods are available to accurately detect DNA methylation over long distances at a whole-genome scale. By combining our recently developed TET-assisted pyridine borane sequencing (TAPS) method, which enables direct detection of 5-methylcytosine and 5-hydroxymethylcytosine, with PacBio single-molecule real-time sequencing, we present here whole-genome long-read TAPS (wglrTAPS). To evaluate the performance of wglrTAPS, we applied it to mouse embryonic stem cells as a proof of concept, and an N50 read length of 3.5 kb is achieved. By sequencing wglrTAPS to 8.2× depth, we discovered a significant proportion of CpG sites that were not covered in previous 27.5× short-read TAPS. Our results demonstrate that wglrTAPS facilitates methylation profiling on problematic genomic regions with repetitive elements or structural variations, and also in an allelic manner, all of which are extremely difficult for short-read sequencing methods to resolve. This method therefore enhances applications of third-generation sequencing technologies for DNA epigenetics.     

A method for sequencing polymerase chain reaction products can be used to sequence Bacillus subtilis "miniprep" plasmid DNA

Several methods for sequencing double-stranded plasmid DNA isolated from E. coli have been described. These methods are usually not effective when used to sequence plasmid DNA isolated from Bacillus subtilis. In the course of developing a simplified version of a previously published protocol for polymerase chain reaction product sequencing, it was found that this protocol could be used for sequencing plasmid DNA isolated from Bacillus subtilis.     

Efficient integration of artificial transposons into plasmid targets in vitro: a useful tool for DNA mapping, sequencing and genetic analysis.

We have developed efficient methods for creating artificial transposons and inserting these transposons into plasmid targets in vitro, primarily for the purpose of DNA mapping and sequencing. A novel plasmid has been engineered to convert virtually any DNA sequence, or combination of sequences, into an artificial transposon; hence, custom transposons containing any desired feature can be easily designed and constructed. Such transposons are then efficiently inserted into plasmid targets, in vitro, using the integrase activity present in yeast Ty1 virus-like particles. A single in vitro integration reaction, which resembles a simple restriction digestion in the complexity of the reaction, gives rise to thousands of recoverable insertion events within DNA target molecules; this frequency approaches one insertion per phosphodiester bond in typical plasmids. Importantly, transposon insertions are recovered from all regions of DNA inserts carried on plasmid targets, indicating that integration is a random or nearly-random process. Because of its versatility, this technology offers a generalized method of generating recombinant DNA molecules of a desired structure. We have adapted this system for DNA sequencing by developing a customized artificial transposon to insert new primer binding sites into internal regions of DNA inserts carried on cloning vectors. Transposon insertions have been generated throughout several different yeast and human DNA inserts carried on plasmids, allowing the efficient recovery of sequence information from these inserts. Our results demonstrate the overall utility of this method for both small and large-scale DNA sequencing, as well as general DNA restructuring, and indicate that it could be adapted for use with a number of additional applications including functional genetic analysis.     

一种快速有效纯化DNA序列分析模板的方法

介绍一种ＤＮＡ序列分析模板的快速、有效的纯化方法。该法对ＤＮＡ模板的回收率可达９５％以上。多次测序结果表明,此法与其他常规纯化方法相比,具有简便、快速、有效、可靠等优点,其测序结果电泳带清晰,无模糊带及“鬼带”出现,重复性及稳定性较好。     

Rapid construction of sequencing templates by random insertion of antibiotic resistance genes

We describe a novel and handy method for generating a population of templates for sequencing. The method is based on the random insertion of antibiotic resistance gene in plasmid DNA digested by DNase I. The advantages of this approach are the small quantity of DNA necessary for mutagenesis and the complete independence from the restriction map of the plasmid. DNase I digestion provides a random distribution of the insertions, while antibiotic selection provides low background. We also present a convenient PCR-based procedure for the analysis and ordering of obtained insertion mutants.