Cross-Site Evaluation of Commercial Sanger Sequencing Chemistries.

Sanger sequencing remains an essential tool utilized by researchers. Despite competition from commercial sequencing providers, many academic sequencing core facilities continue to offer these services based on a model of competitive pricing, knowledgeable technical support, and rapid turnaround time. In-house Sanger sequencing remains a viable core service and, until recently, Applied Biosystems BigDye Terminator chemistry was the only commercially available solution for Sanger DNA sequencing on Applied Biosystems (ABI) instruments; however, several new products employing novel dye chemistries and reaction configurations have entered the market. As a result, there is a need to benchmark the performance of these new chemistries on various DNA templates, including difficult-to-sequence templates, and their amenability to commonly employed cost-saving measures, such as dye dilution and reaction miniaturization. To evaluate these new reagents, a study was designed to compare the quality of Sanger sequencing data produced by ABI BigDye and commercially available kits from 2 other vendors using both control and difficult-to-sequence DNA templates under various reaction conditions. This study will serve as a valuable resource to core facilities conducting Sanger sequencing that wish to evaluate the use of an alternative chemistry in their sequencing core.

Sequencing of the Dutch elm disease fungus genome using the Roche/454 GS-FLX Titanium System in a comparison of multiple genomics core facilities.

As part of the DNA Sequencing Research Group of the Association of Biomolecular Resource Facilities, we have tested the reproducibility of the Roche/454 GS-FLX Titanium System at five core facilities. Experience with the Roche/454 system ranged from <10 to >340 sequencing runs performed. All participating sites were supplied with an aliquot of a common DNA preparation and were requested to conduct sequencing at a common loading condition. The evaluation of sequencing yield and accuracy metrics was assessed at a single site. The study was conducted using a laboratory strain of the Dutch elm disease fungus Ophiostoma novo-ulmi strain H327, an ascomycete, vegetatively haploid fungus with an estimated genome size of 30-50 Mb. We show that the Titanium System is reproducible, with some variation detected in loading conditions, sequencing yield, and homopolymer length accuracy. We demonstrate that reads shorter than the theoretical minimum length are of lower overall quality and not simply truncated reads. The O. novo-ulmi H327 genome assembly is 31.8 Mb and is comprised of eight chromosome-length linear scaffolds, a circular mitochondrial conti of 66.4 kb, and a putative 4.2-kb linear plasmid. We estimate that the nuclear genome encodes 8613 protein coding genes, and the mitochondrion encodes 15 genes and 26 tRNAs.

Overview of DNA sequencing strategies.

Efficient and cost-effective DNA sequencing technologies are critical to the progress of molecular biology. This overview of DNA sequencing strategies provides a high-level review of seven distinct approaches to DNA sequencing: (a) dideoxy sequencing; (b) solid phase sequencing; (c) sequencing-by-hybridization; (d) mass spectrometry; (e) cyclic array sequencing; (f) microelectrophoresis; and (g) nanopore sequencing. Other platforms currently in development are also briefly described. The primary focus here is on Sanger dideoxy sequencing, which has been the dominant technology since 1977, and on cyclic array strategies, for which several competitive implementations have been developed since 2005. Because the field of DNA sequencing is changing rapidly, this unit represents a snapshot as of September, 2011.

"First generation" automated DNA sequencing technology.

Beginning in the 1980s, automation of DNA sequencing has greatly increased throughput, reduced costs, and enabled large projects to be completed more easily. The development of automation technology paralleled the development of other aspects of DNA sequencing: better enzymes and chemistry, separation and imaging technology, sequencing protocols, robotics, and computational advancements (including base-calling algorithms with quality scores, database developments, and sequence analysis programs). Despite the emergence of high-throughput sequencing platforms, automated Sanger sequencing technology remains useful for many applications. This unit provides background and a description of the "First-Generation" automated DNA sequencing technology. It also includes protocols for using the current Applied Biosystems (ABI) automated DNA sequencing machines.

Optimization of protocol for sequencing of difficult templates.

In this paper, we have fine-tuned a DNA sequencing protocol suitable for a wide range of difficult templates. The primary goal was to evaluate a number of parameters--such as various dye terminator mixes in the presence or absence of additives, the amount of DNA or primer, and cycling protocols--about the effectiveness of reading through complex regions. We showed that the modification of a published protocol leads to significant (75%) cost reduction without forfeiting quality of the data. In the recommended protocol, we used betaine as a standard additive, but better results can be obtained when betaine and Reagent A are mixed in an equivalent ratio.

Identification of optimal protocols for sequencing difficult templates: results of the 2008 ABRF DNA Sequencing Research Group difficult template study 2008.

The 2008 ABRF DNA Sequencing Research Group (DSRG) difficult template sequencing study was designed to identify a general set of guidelines that would constitute the best approaches for sequencing difficult templates. This was a continuation of previous DSRG difficult template studies performed in 1996, 1997, and 2003. The distinguishing factors in the present study were the number of DNA templates used, the number of different types of difficult regions tested, and the inclusion of a follow-up phase of the study to identify optimal protocols for each type of difficult template. DNA templates with associated sequencing primers were distributed to participating laboratories and each laboratory returned their sequencing results along with descriptions of the experimental conditions used. The data were analyzed and the best protocols were identified for each difficult template. This information was subsequently distributed to the participating laboratories for a second round of sequencing to evaluate the general applicability of the optimized protocols. The average improvements in sequencing results were 11% overall, with a range of -25% to +43% using the optimized protocols. The full results from this study are presented here and they demonstrate that general experimental protocols and common additives can be used to improve the sequencing success for many difficult templates.

Effect of primer proximity to a difficult-to-sequence region on read length and sequence quality.

Anecdotal and not well-established evidence implies that there could be some effect of primer proximity in relation to a difficult region on read length and sequence quality. In this paper we sequenced many different categories of difficult regions where primers were located at various distances in relation to such regions and we found that there is only weak, if any, correlation between primer proximity and read length or sequence quality. The occasional improvements observed in some studies could be related instead to more optimal primers or better quality DNA. We suggest that instead of trying to design primers at varying distances to a difficult region, sequence finishers concentrate on applying modified chemistries appropriate to a given difficult region.

DNA sequencing research group: 2006 general survey of DNA sequencing facilities.

Over the past few years, technological advances in automated DNA sequencing have had a profound effect on the nature of DNA sequencing laboratories. To characterize the changes occurring within DNA sequencing facilities, the DNA Sequencing Research Group conducted three previous studies, in 1998, 2000, and 2003. A new general survey has been designed and conducted by the DSRG to capture the current status of DNA sequencing facilities in all sectors. Included were questions regarding facility administration, pricing, instrumentation, technology, protocols, and operation. The results of the survey are presented here, accompanied by comparisons to the previous surveys. These comparisons formed a basis for the discussion of trends within the facilities in response to the dynamics of a changing technology.

Fundamentals of sequencing of difficult templates--an overview.

Despite enormous progress, the DNA sequencing of difficult regions, whether they are part of complex genomes or individual constructs, still presents a significant challenge and may require many trials, brute-force, or the intervention of a very experienced sequencer (and sometimes all of the above). Very early on, it was realized that sequencing of various types of difficult templates requires distinct treatments. To sequence through GC-rich regions, the addition of DMSO, NP-40/Tween-20 detergents, or the mix (4:1) of BD3.0:dGTP3.0 was sometimes helpful. To get through long poly-A/T tails, sometimes one would be successful using tailored poly- A/T (V/B) N primers or primers that spanned part of pre-tail and tail regions. A few years ago invitrogen introduced a set of sequencing additives that proved to be useful for many different types of difficult templates.

Simple modifications of the standard DNA sequencing protocol allow for sequencing through siRNA hairpins and other repeats.

RNAi is a relatively new but powerful technology used for monitoring gene silencing in many species. The RNA corresponding to the gene of interest can be delivered into cells using various protocols, but the approach where both sense and antisense strands are located in the same transcript seems to be the most promising. However, the DNA sequencing step is a challenge due to the formation of a strong hairpin structure. In this work we present a very simple modification to the standard DNA sequencing protocol that allows sequencing through such difficult regions. The modification does not require any additional enzymatic or chemical manipulations. It simply adds a 5-min heat-denaturation step at 98 degrees C, prior to addition of a Taq mix. The inclusion of this step is very effective in sequencing through many different categories of difficult templates. Other examples of the implementation of this step have been described previously and more detailed information on heat-denaturation of plasmid DNAs has been presented.

The pea mitochondrial atp6: RNA editing and similarity of presequences in the Vicieae tribe.

The atp6 gene has been identified as a single-copy sequence in the mitochondrial genome of the pea. An unexpected finding concerns the atp6 5' extension which is known to be poorly conserved at the sequence level, even between closely related plant species. We have shown that the presequences of ATP6 from the pea and other species belonging to the Vicieae tribe of Fabaceae (broad bean, hairy vetch) share a sequence similarity which extends to long 5' untranslated transcript termini. The reason for the observed conservation is not clear but may simply reflect the close phylogenetic relationship of species from the Vicieae tribe. The result of editing analysis indicates the occurrence of fully and partially edited transcripts of atp6 in the pea mitochondria. The majority of the editing sites are targeted to the last transmembrane domain of the pea ATP6, important in proton translocation and interactions with other subunits of ATP synthase.

Duplication of primate and rodent B7-H3 immunoglobulin V- and C-like domains: divergent history of functional redundancy and exon loss.

B7-H3 is a novel protein structurally related to the B7 family of ligands by the presence of a single set of immunoglobulin-V-like and immunoglobulin-C-like (VC) domains. By multiplex PCR, the dominantly expressed form of human B7-H3 was found to be a splice variant containing tandemly duplicated VC domains (VCVC). In contrast, mouse B7-H3 cDNA contained only one single VC form due to an exon structure corresponding to V-(pseudoexon C)-(pseudoexon V)-C. Comparisons of human, monkey, mouse, and hamster genomic B7-H3 reveal that primates, but not rodents, exhibited a higher degree of intramolecular sequence similarity between VC duplications than between molecules. Both VC and VCVC forms of human B7-H3 inhibited CD4(+) T cell proliferation and downregulated cytokine production upon TCR activation. These results suggest independent, but convergent, paths of B7-H3 active domain duplication followed by divergent histories of exon degeneration in rodents and exon maintenance by humans.

A higher plant mitochondrial homologue of the yeast m-AAA protease. Molecular cloning, localization, and putative function.

Mitochondrial AAA metalloproteases play a fundamental role in mitochondrial biogenesis and function. They have been identified in yeast and animals but not yet in plants. This work describes the isolation and sequence analysis of the full-length cDNA from the pea (Pisum sativum) with significant homology to the yeast matrix AAA (m-AAA) protease. The product of this clone was imported into isolated pea mitochondria where it was processed to its mature form (PsFtsH). We have shown that the central region of PsFtsH containing the chaperone domain is exposed to the matrix space. Furthermore, we have demonstrated that the pea protease can complement respiration deficiency in the yta10 and/or yta12 null yeast mutants, indicating that the plant protein can compensate for the loss of at least some of the important m-AAA functions in yeast. Based on biochemical experiments using isolated pea mitochondria, we propose that PsFtsH-like m-AAA is involved in the accumulation of the subunit 9 of the ATP synthase in the mitochondrial membrane.

Complete nucleotide sequence and likely recombinatorial origin of bacteriophage T3.

We report the complete genome sequence (38,208 bp) of bacteriophage T3 and provide a bioinformatic comparative analysis with other completely sequenced members of the T7 group of phages. This comparison suggests that T3 has evolved from a recombinant between a T7-like coliphage and a yersiniophage. To assess this, recombination between T7 and the Yersinia enterocolitica serotype O:3 phage phiYeO3-12 was accomplished in vivo; coliphage progeny from this cross were selected that had many biological properties of T3. This represents the first experimentally observed recombination between lytic phages whose normal hosts are different bacterial genera.