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.     

High-speed plasmid isolation using 96-well, size-exclusion filter plates

The accelerating pace of genomics analysis has necessitated the abbreviation of DNA sample preparation protocols. We have developed a size-exclusion-based system for the rapid isolation ofplasmid DNA in a 96-well microplate format. This high-speed protocol employs a modified alkaline lysis methodfor the preparation of the bacterial lysate, followed by three short vacuum filtration steps. Unlike traditional bind/wash/elute methods, there is no need to use chaotropic salts or ethanol. The samples are recovered from the top side of the MultiScreen96 PLASMID plates. Starting with bacterial cell pellets, the entire prycedure for purifying the plasmid DNA can be performed in 30 min with a multichannel pipettor. The high yields, reproducibility, and quality of the plasmids make this system a good choice for any cloning or DNA sequencing operation.     

Magnetic, microplate-format plasmid isolation protocol for high-yield, sequencing-grade DNA

We have developed a rapid, microplate-format plasmid isolation procedure to purify sequencing-grade DNA templates for high-throughput DNA sequencing operations. A modified lysozyme/boiling method is used to produce a plasmid-containing supernatant that is then purified by iron bead capture. After binding, the beads are pelleted in a magnetic field, washed and the DNA eluted in water. The method yields up to 10 micrograms plasmid DNA from a 1-mL overnight culture in a deep-well microplate. The procedure is suitable for large-scale experiments, amenable to automation and does not require expensive reagents or equipment. The entire protocol can be completed in as little as 2 h, and one technician with a 96-well pipetting station can process up to 48 plates per day. This protocol is ideal for any high-throughput operation in which template quantity, quality and reproducibility are of primary importance.     

An efficient, automatable template preparation for high throughput sequencing

We have developed a 96-well format for DNA template isolation that can be readily automatable. The template isolation protocol involves simple alkaline lysis chemistry and reversible capture on a silica solid phase. After the cells are lysed, no centrifugation is necessary, as lysate purification, DNA binding, washing, and release occur in 96-well filter plates. Large numbers of templates prepared using the silica purification method have been sequenced and analyzed. The quality of sequence resulting from our method has been compared with that generated from several commercial plasmid preparation protocols. We found sequence quality of the silica bead preparations to be equivalent to or, in some cases, better than those prepared by other methods. This method offers many advantages over other protocols we have used. First, the silica purifications have allowed us to more than double overall laboratory throughput while decreasing our template isolation materials cost at least five-fold. Second, because we have eliminated all centrifugation steps in the protocol, automation has been much simpler. The protocol has also been adapted to purify PCR products for use as templates in subsequent sequencing reactions.     

Automated high-throughput probe production for DNA microarray analysis

DNA microarrays have become an established tool for gene expression profiling. Construction of these microarrays using immobilized cDNAs is a common experimental strategy. However, this is extremely laborious, requiring the preparation of hundreds or thousands of cDNA probes. To minimize this initial bottleneck, we developed a comprehensive high-throughput robotic system to prepare DNA probes suitable for microarray analysis with minimal user intervention. We describe an automated system using the MultiPROBE Nucleic Acid Purification Workstation to provide the liquid handling and other functions needed to optimize this process. We were able to carry out fully automated plasmid cDNA isolation, PCR assay setup, and PCR purification and also to direct the characterization and tracking of DNA probes during processing. Protocols began with the initial preparation of a plasmid DNA archive of bacterial stocks in parallel 96-well plates (192 samples/run) and continued through to the dilution and reformatting of chip-ready DNA probes in 384-well format. These and other probe production procedures and additional instrument systems were used to process fully a set of mouse cDNA clones that were then validated by differential gene expression analysis.     

一种简便的适用于酵母双杂交系统的酵母质粒提取方法

目的:建立一种适用于酵母双杂交系统的简便快捷的酵母质粒提取方法。方法:以酿酒酵母为供试材料,用玻璃珠振荡法破除酵母细胞壁,提取酵母总DNA,最后通过电转化大肠杆菌DH10B获得目的质粒。结果:粗提得到的质粒可直接转化DH10B,作为模板用于PCR分析及酵母双杂交后续的序列分析等,大大降低了工作量。结论:该方法简便快捷,经济实用,降低了成本,提高了效率,可以作为一种实验室酵母质粒提取方法。     

Magnetic bead purification of M13 DNA sequencing templates.

A method for the preparation of multiple M13 DNA sequencing templates is described. No phenol extraction is required and the procedure can be carried out in Eppendorf tubes or 96-well microtiter plates. Starting with a phage supernatant, the entire procedure is carried out in the same reaction vessel and all separation steps are based on a novel application of magnetic bead separation. The design of a 96-well magnetic separator is presented and the application of the method for large-scale sequencing is discussed.     

Rapid method for DNA isolation from a tough cell wall green alga <Emphasis Type="Italic">Tetraspora</Emphasis> sp. CU2551

Genetic studies are important to understand the complex biological system of various organisms. Some eukaryotic green organisms have tough cell wall which precludes the efficient extraction of the genetic materials. Here, we developed the method for simple and rapid isolation of high quality DNA from a green alga Tetraspora sp. CU2551. The cell homogenization procedures were combined with physical force plus heat treatment to disrupt the cell envelope of Tetraspora sp. CU2551. Without protease treatment, vortexing with glass bead for 30–105 s at 70 °C led to the isolation of a high purity DNA which was suitable for downstream process. The improved method was successfully developed and could be applied for the rapid isolation of DNA from other unicellular and filamentous green microalgal strains.     

The performance of a glass bead shaking technique for the disruption of Escherichia coli cells

The efficacy of a simple laboratory method for cell disruption based on the shaking of glass beads on a rotary shaker was assessed in this study, via measurements of the release of total protein and interferon-α2b from E. coli. The optimum conditions for cell disruption were detected after 30 min of shaking in Tris-HCl buffer (pH 8) at 300 rpm with 1.5 g of glass beads (diameter: 0.5 mm) per mL of cell suspension volume. Three test runs were conducted under the above conditions and the maximum average protein release values were determined as 3.048, 3.564, and 3.015 mg/mL, respectively. The amount of protein release was comparable to the amount of protein release in ultrasonica-tion and glass bead vortexing procedures. The amount of interferon-α2b release in the ultrasonication, glass bead vortexing, and glass bead shaking trials were 240, 172, and 201 ng/mL, respectively. This method was shown to process between 1 and 10 mL of sample volume in a 50 mL Falcon tube without a great deal of deviation, and was able to handle in excess of 60 samples simultaneously.     

Rapid, high-throughput extraction of bacterial genomic DNA from selective-enrichment culture media

AIMS: To create a fast, sensitive and inexpensive high-throughput method for the extraction of bacterial genomic DNA from selective-enrichment culture media. METHODS AND RESULTS: Lysis of bacteria was achieved using guanidinium isothiocyanate, and DNA was extracted using 96-well glass microfibre filtration plates. Extraction-PCR detected the presence of 1 cfu Yersinia ruckeri and 16 cfu Lactococcus garvieae 200 microl(-1) sample of selective-enrichment medium. CONCLUSION: An efficient method for high-throughput extraction of bacterial genomic DNA from selective-enrichment culture media was achieved. SIGNIFICANCE AND IMPACT OF THE STUDY: This method enables detection of covert bacterial infections in fish. The simultaneous extraction of large numbers of samples allows for its use in bacterial monitoring programmes and quarantine.     

High Throughput BAC DNA Isolation for Physical Map Construction of Sorghum (Sorghum bicolor)

With the aim of constructing a physical map of sorghum, we developed a rapid, high throughput approach for isolating BAC DNA suitable for restriction endonuclease digestion fingerprinting, PCR- based STS-content mapping, and BAC-end sequencing. The system utilizes a programmable 96 channel liquid handling system and associated accessories that permit bacterial cultivation and DNA isolation in 96-well plate format. This protocol details culture conditions that optimize bacterial growth in deep-well plates and criteria for BAC DNA isolation to obtain high yields of quality BAC DNA. The system is robust, accurate, and relatively cost-effective. The BAC DNA isolation system has been tested during efforts to construct a physical map of sorghum.     

Simple and rapid preparation of plasmid template by a filtration method using microtiter filter plates.

We developed a new simple high-throughput plasmid DNA extraction procedure, based on a modified alkaline lysis method, using only one 96-well microtiter glassfilter plate. In this method, cell harvesting, lysis by alkaline and plasmid purification are performed on only one microtiter glassfilter plate. After washing out RNAs or other contaminants, plasmid DNA is eluted by low-ion strength solution, although precipitated chromosomal DNA is not eluted. The plasmid prepared by this method can be applied to sequencing reactions or restriction enzyme cleavage.     

A strategy for recovering high quality genomic DNA from a large number of Phytophthora isolates

We present a strategy to recover high molecular weight genomic DNA from large numbers of isolates of Phytophthora. Included are steps for generating mycelial mass in 24-well reuseable deep well plates, efficient lyophilization and disruption of the mycelium and genomic DNA extraction with 96-well glass fiber filter plates. The resulting DNA is consistently high molecular weight and is suitable for applications that require high quality DNA such as AFLP analysis and TILLING. A single operator easily can manage mycelium preparation and/or DNA extraction from 384 isolates in a single day and this approach might be useful for other fungi or fungi-like organisms that can be grown in liquid media.     

A Method for Preparing DNA Sequencing Templates Using a DNA-Binding Microplate

A DNA-binding matrix was immobilized on the surface of a 96-well microplate and used for plasmid DNA preparation for DNA sequencing. The same DNA-binding plate was used for bacterial growth, cell lysis, DNA purification, and storage. In a single step using one buffer, bacterial cells were lysed by enzymes, and released DNA was captured on the plate simultaneously. After two wash steps, DNA was eluted and stored in the same plate. Inclusion of phosphates in the culture medium was found to enhance the yield of plasmid significantly. Purified DNA samples were used successfully in DNA sequencing with high consistency and reproducibility. Eleven vectors and nine libraries were tested using this method. In 10 μl sequencing reactions using 3 μl sample and 0.25 μl BigDye Terminator v3.1, the results from a 3730xl sequencer gave a success rate of 90–95% and read-lengths of 700 bases or more. The method is fully automatable and convenient for manual operation as well. It enables reproducible, high-throughput, rapid production of DNA with purity and yields sufficient for high-quality DNA sequencing at a substantially reduced cost.     

Time-Resolved Fluorescence Energy Transfer DNA Helicase Assays for High Throughput Screening

DNA helicases are responsible for the unwinding of double-stranded DNA, facilitated by the binding and hydrolysis of 5'-nucleoside triphosphates. These enzymes represent an important class of targets for the development of novel anti-infective agents particularly because opportunity exists for synergy with existing therapies targeted at other enzymes involved in DNA replication. Unwinding reactions are conventionally monitored by low throughput, gel-based radiochemical assays; to overcome the limitations of low throughput to achieve comprehensive characterization of adenosine triphosphate (ATP)-dependent unwinding by viral and bacterial helicases and the screening for unwinding inhibitors, we have developed and validated homogeneous time-resolved fluorescence energy transfer (TRET) assays. Rapid characterization and screening of DNA helicase has been performed in 96- and 384-well plate densities, and the ability to assay in 1536-well format also demonstrated. We have successfully validated and are running full high throughput runs using 384-well TRET helicase assays, culminating in the identification of a range of chemically diverse inhibitors of viral and bacterial helicases. For screening in mixtures, we used a combination of quench correction routines and confirmatory scintillation proximity (SP) assays to eliminate false-positives due to the relatively high levels of compound quenching (unlike other Ln(3+)-based assays). This strategy was successful yet emphasised the need for further improvements in helicase assays.     

Increasing PCR fragment stability and protein yields in a cell-free system with genetically modified Escherichia coli extracts

Escherichia coli cell-free protein synthesis is a highly productive system that can be applied to high throughput expression from polymerase chain reaction (PCR) products in 96-well plates for proteomic studies as well as protein evolution. However, linear DNA instability appears to be a major limitation of the system. We modified the genome of the E. coli strain A19 by removing the endA gene encoding the endonuclease I and replacing the recCBD operon (in which recD encodes the exonuclease V) by the lambda phage recombination system. Using the cell extract from this new strain increased the stability of PCR products amplified from a plasmid containing the cat gene. This resulted in CAT (chloramphenicol acetyltransferase) production from PCR products comparable to that from plasmids (500-600 microg/ml) in a batch reaction. We show that cell-free protein synthesis reactions using PCR products amplified from genomic DNA and extended with the T7 promoter and the T7 terminator give the same high yields of proteins (550 microg/ml) in 96-well plates. With this system, it was possible to rapidly express a range of cytoplasmic and periplasmic proteins.     

A screening system for artificial small RNAs that inhibit the growth of Escherichia coli

We have developed a screening system for artificial small RNAs (sRNAs) that inhibit the growth of Escherichia coli. In this system, we used a plasmid library to express artificial sRNAs (approximately 200 bases long) containing 60 bases of random nucleotide sequence. The induced expression of the known rydB sRNA in the system reduced the amount of its possible target mRNA, rpoS, supporting the reliability of the method. To isolate clones of sRNAs that inhibited the growth of E. coli, we used two successive screening steps: (i) colony size selection on plates and (ii) monitoring E. coli growth in a 96-well plate format. As a result, 83 artificial sRNAs were identified that showed a range of inhibitory effects on bacterial growth. We also introduced nucleotide replacements into one of the highly inhibitory sRNA clones, H12, which partially abolished the inhibition of bacterial growth, suggesting that bacterial growth was inhibited in a sequence-specific manner.     

Evaluation of 96-well high-throughput DNA extraction methods for 16S rRNA gene metabarcoding

Gaining meaningful insights into bacterial communities associated with animal hosts requires the provision of high-quality nucleic acids. Although many studies have compared DNA extraction methods for samples with low bacterial biomass (e.g. water) or specific PCR inhibitors (e.g. plants), DNA extraction bias in samples without inherent technical constraint (e.g. animal samples) has received little attention. Furthermore, there is an urgent need to identify a DNA extraction methods in a high-throughput format that decreases the cost and time for processing large numbers of samples. We here evaluated five DNA extraction protocols, using silica membrane-based spin columns and a 96-well microplate format and based on either mechanical or enzymatic lysis or a combination of both, using three bacterial mock communities and Illumina sequencing of the V4 region of the 16SrRNA gene. Our results showed that none of the DNA extraction methods fully eliminated bias associated with unequal lysis efficiencies. However, we identified a DNA extraction method with a lower bias for each mock community standard. Of these methods, those including an enzymatic lysis showed biases specific to some bacteria. Altogether, these results again demonstrate the importance of DNA extraction standardization to be able to compare the microbiome results of different samples. In this attempt, we advise for the use of the 96-well DNeasy Blood and Tissue kit (Qiagen) with a zirconia bead-beating procedure, which optimizes altogether the cost, handling time and bacteria-specific effects associated with enzymatic lysis.     

High-throughput method for isolating plasmid DNA with reduced lipopolysaccharide content

Isolating plasmid DNA from bacteria is a fundamental step in molecular biology. It is often accomplished by an alkaline lysis of bacteria and the subsequent adsorption of nucleic acids to silica oxide in the presence of chaotropic substances. Here we show that the addition of such chaotropic reagents is not required for the efficient DNA isolation with silica oxide. This surprising finding allowed us to purify plasmid DNA with significantly less lipopolysaccharides (LPS), which is otherwise a common bacterial contaminant of silica oxide-isolated DNA and inhibits subsequent applications. In addition, we have implemented a precipitation step that altogether leads to a reduction of the LPS content by a factor of 900 relative to published methods. Our novel protocol facilitates an inexpensive high-throughput analysis of pure plasmids in a 96-well format without the addition of hazardous reagents.     

Evaluation of DNA extraction methods from mouse stomachs for the quantification of H. pylori by real-time PCR

Real-time PCR methods have recently been developed for the quantification of Helicobacter pylori from infected mouse stomachs. However, the extent to which results is affected by the efficiency of different methods of DNA extraction and the degree of inhibition of the subsequent PCR have largely been ignored. In this study, mouse stomachs were processed using two homogenisation methods: complete disruption using a blender and homogenisation by vortexing with glass beads. Each procedure was followed by DNA purification by three different protocols-two commercially available kits-Qiagen DNA Mini Tissue kit and Qiagen Stool Kit and a phenol-chloroform extraction method. PCR inhibition was assessed by screening for mouse DNA and for H. pylori DNA after spiking stomach extracts with H. pylori 16S rDNA. PCR inhibition was found to be lower in DNA samples prepared by vortexing and processed by column kits. Validation of procedures was performed by quantification of H. pylori DNA and mouse DNA in infected mouse stomachs. Homogenisation with glass beads followed by the Qiagen Tissue kit was found to be the most suitable protocol combining high extraction and detection efficiency of 16S rDNA in the presence of a mouse DNA background.