Direct sequencing of baculovirus genomic DNA: sequence determination of the engineered respiratory syncytial virus chimeric FG gene.

Primer-directed enzymatic sequencing has proven to be an efficient and effective method for sequencing various size double-stranded DNA templates. We previously developed a primer-directed sequencing procedure for using double-stranded cosmid (50 kb) DNAs as template. We are interested in using this method to directly sequence larger DNA templates. Towards this goal we applied this method to directly sequence an engineered gene that had been transferred and integrated into the 130-kb baculovirus genome. Both crudely prepared and CsCl gradient-banded baculovirus DNAs were tested and reasonable sequencing ladders were obtained for both types of DNA templates. As little as 3 micrograms of gradient-banded baculovirus DNA were found to be sufficient to obtain film exposure times similar to those observed for cosmid size templates, 24 to 48 h. Effectiveness of the described method was demonstrated by obtaining the complete sequence of the engineered respiratory syncytial virus chimeric FG gene (2.5 kb in length) directly from the recombinant baculovirus "Baculo-FG" genome. Thus, our results demonstrate first, that double-stranded DNA templates as large as 130 kb can be sequenced directly and second, that the nucleotide sequence of engineered genes integrated within the baculovirus genome can be determined without the use of any intermediate steps of procedures.     

Rolling circle amplification of genomic templates for inverse PCR (RCA–GIP): a method for 5′- and 3′-genome walking without anchoring

We have devised an improved method of genome walking, named rolling circle amplification of genomic templates for Inverse PCR (RCA–GIP). The method is based on the generation of circular genomic DNA fragments, followed by rolling circle amplification of the circular genomic DNA using ϕ29 DNA polymerase without need for attachment of anchor sequences. In this way from the circular genomic DNA fragments, after RCA amplification, a large amount of linear concatemers is generated suitable for Inverse PCR template that can be amplified, sequenced or cloned allowing the isolation of the 3′- and 5′- of unknown ends of genomic sequences. To prove the concept of the proposed methodology, we used this procedure to isolate the promoter regions from different species. Herein as an example we present the isolation of four promoter regions from Crocus sativus, a crop cultivated for saffron production.     

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.     

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.     

DNA sequencing using rolling circle amplification and precision glass syringes in a high-throughput liquid handling system

An automated high-throughput method that employs rolling circle amplification (RCA) to generate template for large-scale DNA sequencing has been developed using liquid handling systems equipped with precision glass syringes. A protocol was designed to perform the sequencing analysis from template preparation to thermal cycle sequencing within the same vessel, thus minimizing the amount of liquid handling and transfer. The amplified DNA was directly used for cycle sequencing with no need for any purification procedures. Total RCA reaction volumes as low as 500 nL generated sufficient templates for successful sequencing. Reducing the RCA total reaction volumes by a 40-fold factor, from a total of 20 microL to 500 nL, resulted in a significant reduction in cost, from $1.25/reaction to less than $0.04/reaction. Additionally, the volume of the sequencing reactions was reduced from a total of 20 to 10 microL, thus generating a further cost advantage. This high-throughput DNA sequencing protocol maximizes the speed and precision of processing while significantly reducing the cost of amplification.     

Evaluating Bias of Illumina-Based Bacterial 16S rRNA Gene Profiles

Massively parallel sequencing of 16S rRNA genes enables the comparison of terrestrial, aquatic, and host-associated microbial communities with sufficient sequencing depth for robust assessments of both alpha and beta diversity. Establishing standardized protocols for the analysis of microbial communities is dependent on increasing the reproducibility of PCR-based molecular surveys by minimizing sources of methodological bias. In this study, we tested the effects of template concentration, pooling of PCR amplicons, and sample preparation/interlane sequencing on the reproducibility associated with paired-end Illumina sequencing of bacterial 16S rRNA genes. Using DNA extracts from soil and fecal samples as templates, we sequenced pooled amplicons and individual reactions for both high (5- to 10-ng) and low (0.1-ng) template concentrations. In addition, all experimental manipulations were repeated on two separate days and sequenced on two different Illumina MiSeq lanes. Although within-sample sequence profiles were highly consistent, template concentration had a significant impact on sample profile variability for most samples. Pooling of multiple PCR amplicons, sample preparation, and interlane variability did not influence sample sequence data significantly. This systematic analysis underlines the importance of optimizing template concentration in order to minimize variability in microbial-community surveys and indicates that the practice of pooling multiple PCR amplicons prior to sequencing contributes proportionally less to reducing bias in 16S rRNA gene surveys with next-generation sequencing.     

Rolling-circle amplification under topological constraints

We have performed rolling-circle amplification (RCA) reactions on three DNA templates that differ distinctly in their topology: an unlinked DNA circle, a linked DNA circle within a pseudorotaxane-type structure and a linked DNA circle within a catenane. In the linked templates, the single-stranded circle (dubbed earring probe) is threaded, with the aid of two peptide nucleic acid openers, between the two strands of double-stranded DNA (dsDNA). We have found that the RCA efficiency of amplification was essentially unaffected when the linked templates were employed. By showing that the DNA catenane remains intact after RCA reactions, we prove that certain DNA polymerases can carry out the replicative synthesis under topological constraints allowing detection of several hundred copies of a dsDNA marker without DNA denaturation. Our finding may have practical implications in the area of DNA diagnostics.     

A rapid single-stranded cloning strategy for producing a sequential series of overlapping clones for use in DNA sequencing: application to sequencing the corn mitochondrial 18 S rDNA

A simple new procedure was described for producing a sequential series of overlapping clones for use in DNA sequencing. The technique used single-stranded M13 DNA and complementary DNA oligomers to form specific cleavage and ligation substrates. It was, therefore, independent of the sequence of the DNA cloned into the vector. Deletions of varying sizes were generated from one end of the insert through the 3' to 5' exonuclease activity of T4 DNA polymerase. The approximate size of the deletion and therefore the starting point for DNA sequencing could be estimated by electrophoresis of the subcloned phage DNA on a agarose gel. This greatly reduced the number of templates that must be sequenced to obtain a complete sequence. The entire procedure could be carried out in one tube in less than a day. The procedure was used to subclone and sequence the maize mitochondrial 18 S rDNA and 5' flanking region (2622 bases) in less than a week. Other applications of oligomers and single-stranded DNA in the construction of insertions, deletions, and cDNAs are discussed.     

Kilo-sequencing: an ordered strategy for rapid DNA sequence data acquisition

A strategy for rapid DNA sequence acquisition in an ordered, nonrandom manner, while retaining all of the conveniences of the dideoxy method with M13 transducing phage DNA template, is described. Target DNA 3 to 14 kb in size can be stably carried by our M13 vectors. Suitable targets are stretches of DNA which lack an enzyme recognition site which is unique on our cloning vectors and adjacent to the sequencing primer; current sites that are so useful when lacking are Pst, Xba, HindIII, BglII, EcoRI. By an in vitro procedure, we cut RF DNA once randomly and once specifically, to create thousands of deletions which start at the unique restriction site adjacent to the dideoxy sequencing primer and extend various distances across the target DNA. Phage carrying a desired size of deletions, whose DNA as template will give rise to DNA sequence data in a desired location along the target DNA, may be purified by electrophoresis alive on agarose gels. Phage running in the same location on the agarose gel thus conveniently give rise to nucleotide sequence data from the same kilobase of target DNA.     

龙眼SCoT-PCR反应体系的优化

目标起始密码子多态(start condon tardeted polymorphism,SCoT)分子标记结合了ISSR标记和RAPD标记的优点,具有操作简单、成本低廉、多态性丰富、重复性好、引物设计简单且通用性良好等诸多优点.本实验以石硖龙眼的新鲜叶片为试材,采用单因素试验的方法分别研究模版、引物、rTaqDNA聚合酶、dNTPs、缓冲液(Mg~(2+))及退火温度共6因素各8个水平对龙眼SCoT-PCR扩增结果的影响.结果表明:龙眼SCoT标记的20μL优化反应体系为:10×Buffer Ⅱ(含Mg~(2+))2.0μL、DNA模板30 ng、引物浓度为30 μmol/L、rTaqDNA聚合酶用量为0.45 U、dNTP浓度为4.0 mmol/L.适宜的扩增程序为:94℃预变性4 min;95℃变性50 s,49.5℃退火40 s,72℃复性2 min,36个循环;最后72℃延伸10 min.利用24个龙眼品种验证该反应体系,1.5%琼脂糖电泳检测结果显示,扩增产物在400～2 200 bp之间,不同品种间DNA谱带具有多态性,反应体系具有良好的稳定性和可重复性.     

A multiple-template approach to protein threading

Most threading methods predict the structure of a protein using only a single template. Due to the increasing number of solved structures, a protein without solved structure is very likely to have more than one similar template structures. Therefore, a natural question to ask is if we can improve modeling accuracy using multiple templates. This article describes a new multiple-template threading method to answer this question. At the heart of this multiple-template threading method is a novel probabilistic-consistency algorithm that can accurately align a single protein sequence simultaneously to multiple templates. Experimental results indicate that our multiple-template method can improve pairwise sequence-template alignment accuracy and generate models with better quality than single-template models even if they are built from the best single templates (P-value <10(-6)) while many popular multiple sequence/structure alignment tools fail to do so. The underlying reason is that our probabilistic-consistency algorithm can generate accurate multiple sequence/template alignments. In another word, without an accurate multiple sequence/template alignment, the modeling accuracy cannot be improved by simply using multiple templates to increase alignment coverage. Blindly tested on the CASP9 targets with more than one good template structures, our method outperforms all other CASP9 servers except two (Zhang-Server and QUARK of the same group). Our probabilistic-consistency algorithm can possibly be extended to align multiple protein/RNA sequences and structures.     

Formation of Template-Switching Artifacts by Linear Amplification

Linear amplification is a method of synthesizing single-stranded DNA from either a single-stranded DNA or one strand of a double-stranded DNA. In this protocol, molecules of a single primer DNA are extended by multiple rounds of DNA synthesis at high temperature using thermostable DNA polymerases. Although linear amplification generates the intended full-length single-stranded product, it is more efficient over single-stranded templates than double-stranded templates. We analyzed linear amplification over single- or double-stranded mouse H-ras DNA (exon 1–2 region). The single-stranded H-ras template yielded only the intended product. However, when the double-stranded template was used, additional artifact products were observed. Increasing the concentration of the double-stranded template produced relatively higher amounts of these artifact products. One of the artifact DNA bands could be mapped and analyzed by sequencing. It contained three template-switching products. These DNAs were formed by incomplete DNA strand extension over the template strand, followed by switching to the complementary strand at a specific Ade nucleotide within a putative hairpin sequence, from which DNA synthesis continued over the complementary strand.     

Primer extension mutagenesis powered by selective rolling circle amplification

Primer extension mutagenesis is a popular tool to create libraries for in vitro evolution experiments. Here we describe a further improvement of the method described by T.A. Kunkel using uracil-containing single-stranded DNA as the template for the primer extension by additional uracil-DNA glycosylase treatment and rolling circle amplification (RCA) steps. It is shown that removal of uracil bases from the template leads to selective amplification of the nascently synthesized circular DNA strand carrying the desired mutations by phi29 DNA polymerase. Selective RCA (sRCA) of the DNA heteroduplex formed in Kunkel's mutagenesis increases the mutagenesis efficiency from 50% close to 100% and the number of transformants 300-fold without notable diversity bias. We also observed that both the mutated and the wild-type DNA were present in at least one third of the cells transformed directly with Kunkel's heteroduplex. In contrast, the cells transformed with sRCA product contained only mutated DNA. In sRCA, the complex cell-based selection for the mutant strand is replaced with the more controllable enzyme-based selection and less DNA is needed for library creation. Construction of a gene library of ten billion members is demonstrated with the described method with 240 nanograms of DNA as starting material.     

Primer-independent RNA sequencing with bacteriophage phi6 RNA polymerase and chain terminators

Here we propose a new general method for directly determining RNA sequence based on the use of the RNA-dependent RNA polymerase from bacteriophage phi6 and the chain terminators (RdRP sequencing). The following properties of the polymerase render it appropriate for this application: (1) the phi6 polymerase can replicate a number of single-stranded RNA templates in vitro. (2) In contrast to the primer-dependent DNA polymerases utilized in the sequencing procedure by Sanger et al. (Proc Natl Acad Sci USA, 1977, 74:5463-5467), it initiates nascent strand synthesis without a primer, starting the polymerization on the very 3'-terminus of the template. (3) The polymerase can incorporate chain-terminating nucleotide analogs into the nascent RNA chain to produce a set of base-specific termination products. Consequently, 3' proximal or even complete sequence of many target RNA molecules can be rapidly deduced without prior sequence information. The new technique proved useful for sequencing several synthetic ssRNA templates. Furthermore, using genomic segments of the bluetongue virus we show that RdRP sequencing can also be applied to naturally occurring dsRNA templates. This suggests possible uses of the method in the RNA virus research and diagnostics.     

Sensitive detection of proteins using assembled cascade fluorescent DNA nanotags based on rolling circle amplification

A novel cascade fluorescence signal amplification strategy based on the rolling circle amplification (RCA)-aided assembly of fluorescent DNA nanotags as fluorescent labels and multiplex binding of the biotin-streptavidin system was proposed for detection of protein target at ultralow concentration. In the strategy, fluorescent DNA nanotags are prepared relying on intercalating dye arrays assembled on nanostructured DNA templates by intercalation between base pairs. The RCA product containing tandem-repeat sequences could serve as an excellent template for periodic assembly of fluorescent DNA nanotags, which were presented per protein recognition event to numerous fluorescent DNA nanotags for assay readout. Both the RCA and the multiplex binding system showed remarkable amplification efficiency, very little nonspecific adsorption, and low background signal. Using human IgG as a model protein, the designed strategy was successfully demonstrated for the ultrasensitive detection of protein target. The results revealed that the strategy exhibited a dynamic response to human IgG over a three-decade concentration range from 1.0 pM to 1.0 fM with a limit of detection as low as 0.9 fM. By comparison with the assay of multiple labeling antibodies with the dye/DNA conjugate, the limit of detection was improved by 4 orders. The designed signal amplification strategy would hold great promise as a powerful tool to be applied for the ultrasensitive detection of target protein in immunoassay.     

The ligation amplification reaction (LAR)--amplification of specific DNA sequences using sequential rounds of template-dependent ligation

A novel DNA sequence detection method that utilizes the ligation of oligonucleotide pairs that are complementary to adjacent sites on appropriate DNA templates is described. The product is increased by either linear or exponential amplification using sequential rounds of template-dependent ligation. In the case of linear amplification, a single pair of oligonucleotides is ligated, the reaction is heated to dissociate the ligation product, and an additional round of ligation is performed. After n rounds there is a (1 + x) X n-fold amplification of product, where x is the efficiency of the ligation reaction. Exponential amplification utilizes two pairs of oligonucleotides, one complementary to the upper strand and one to the lower strand of a target sequence. The products of the ligation reaction serve as templates for subsequent rounds of ligation. In this case there is (1 + x)(n-1)-fold amplification of product after n rounds. A single base-pair mismatch between the annealed oligonucleotides and the template prevents ligation, thus allowing the distinction of single base-pair differences between DNA templates. At high template concentrations, the ligation reaction has an efficiency approaching 100%. In this report, we demonstrate the use of the ligation amplification reaction (LAR) to distinguish the normal from the sickle cell allele of the human beta-globin gene. We also report the use of LAR as a detection system for polymerase chain reaction-enriched DNA sequences.