An automated sample preparation system for large-scale DNA sequencing

Recent advances in DNA sequencing technologies, both in the form of high lane-density gels and automated capillary systems, will lead to an increased requirement for sample preparation systems that operate at low cost and high throughput. As part of the development of a fully automated sequencing system, we have developed an automated subsystem capable of producing 10,000 sequence-ready ssDNA templates per day from libraries of M13 plaques at a cost of $0.29 per sample. This Front End has been in high throughput operation since June, 1997 and has produced > 400,000 high-quality DNA templates.

DNA microarray technology: the anticipated impact on the study of human disease

One can imagine that, one day, there will be a general requirement that relevant array data be deposited, at the time of publication of manuscripts in which they are described, into a single site made available for the storage and analysis of array data (modeled after the GenBank submission requirements for DNA sequence information). With this system in place, one can anticipate a time when data from thousands of gene expression experiments will be available for meta-analysis, which has the potential to balance out artifacts from many individual studies, thus leading to more robust results and subtle conclusions. This will require that data adhere to some type of uniform structure and format that would ideally be independent of the particular expression technology used to generate it. The pros and cons of various publication modalities for these large electronic data sets have been discussed elsewhere [12], but, practical difficulties aside, general depositing must occur for this technology to reach the broadest range of investigators. Finally, as mentioned at the beginning of this review, it is unfortunate that this important research tool remains largely restricted to a few laboratories that have developed expertise in this area and to a growing number of commercial interests. Ultimately the real value of microarray technology will only be realized when this approach is generally available. It is hoped that issues including platforms, instrumentation, clone availability, and patents [20] will be resolved shortly, making this technology accessible to the broadest range of scientists at the earliest possible moment.

High throughput direct end sequencing of BAC clones

Libraries constructed in bacterial artificial chromosome (BAC) vectors have become the choice for clone sets in high throughput genomic sequencing projects primarily because of their high stability. BAC libraries have been proposed as a source for minimally over-lapping clones for sequencing large genomic regions, and the use of BAC end sequences (i.e. sequences adjoining the insert sites) has been proposed as a primary means for selecting minimally overlapping clones for sequencing large genomic regions. For this strategy to be effective, high throughput methods for BAC end sequencing of all the clones in deep coverage BAC libraries needed to be developed. Here we describe a low cost, efficient, 96 well procedure for BAC end sequencing. These methods allow us to generate BAC end sequences from human and Arabidoposis libraries with an average read length of >450 bases and with a single pass sequencing average accuracy of >98%. Application of BAC end sequences in genomic sequen-cing is discussed.

System for preparing microhybridization arrays on glass slides

We describe the construction and operation of an arrayer system to produce patterns of DNA sequences for analytical uses such as microarrays of oligonucleotide on microchips. Detailed documentation on construction is provided, as well as added electronic circuitry and the software for the instrument, including programs to machine its own working surface as well as those to operate it as an arrayer. Its cost is modest, and with a single droplet tip it can deposit 96 spots per slide on 32 slides in about 200 min (readily upgraded to higher speeds). As currently operated, it can place 400 spots in 1 cm2, and this density, too, can be increased easily. We discuss design features and performance to demonstrate utility and flexibility.

New goals for the U.S. Human Genome Project: 1998-2003

The Human Genome Project has successfully completed all the major goals in its current 5-year plan, covering the period 1993-98. A new plan, for 1998-2003, is presented, in which human DNA sequencing will be the major emphasis. An ambitious schedule has been set to complete the full sequence by the end of 2003, 2 years ahead of previous projections. In the course of completing the sequence, a "working draft" of the human sequence will be produced by the end of 2001. The plan also includes goals for sequencing technology development; for studying human genome sequence variation; for developing technology for functional genomics; for completing the sequence of Caenorhabditis elegans and Drosophila melanogaster and starting the mouse genome; for studying the ethical, legal, and social implications of genome research; for bioinformatics and computational studies; and for training of genome scientists.

Optimization of restriction fragment DNA mapping

Consider a mapping project in which overlap of clonal segments is inferred from complete multiple restriction digests. The fragment sizes of the clones are measured with some error, potentially leading to a map with erroneous links. The number of errors in the map depends on the number and types of enzymes used to characterize the clones. The most critical parameter is the decision rule k, or the criterion for declaring clone overlap. Small changes in k may cause an order of magnitude change in the amount of work it takes to build a map of given completion. We observe that the cost of an optimal mapping strategy is approximately proportional to the target size. While this finding is encouraging, considerable effort is nonetheless required: for large-scale sequencing projects with up-front mapping, mapping will be a non-negligible fraction of the total sequencing cost.

An efficient cost-effective protocol for automated fluorescent-DNA sequencing

A simple and cost-effective method is described to sequence double-stranded DNA (< 100 ng) using a very small amount of fluorescent sequencing mix (one-tenth of manufacturer-recommended amount). The modification has significant advantages over conventional protocols and can be used to sequence, using a single sequencing kit, at least ten times the number of samples. This modified method also removes the post-reaction cleaning protocol and can be used for direct loading of samples on gels after completion of sequencing reactions. The accuracy of DNA sequencing data from analysis of 700 to 750 nucleotides is greater than 98.5%.

A cost effective base-matching assay with low backgrounds

Base-matching or so-called mini-sequencing is a powerful technique for genotyping and mutation identification. However, its application is often hampered by high background and high cost. We have decreased the background by approximately 5-fold by incorporating an end-blocking step and using only 1/10 of the usual nucleotide concentrations.

Towards inexpensive DNA diagnostics

Methodologies to obtain DNA sequence information efficiently and accurately will provide the basis for a broad spectrum of economical products and applications to a variety of industrial sectors, in addition to healthcare. Such technologies will build upon the evolving molecular biology and instrumentation base that is serving a specific research market. This will require the efficient integration of technical advances in microchemistry, micromachining, separation technologies, detection systems, microelectronics and information technology, and will involve the expertise of engineers, physicists, chemists, mathematicians, computer scientists and molecular biologists. The biotechnology, microelectronics, software, instrumentation, pharmaceutical and fine chemical industries will be vital to this development.

A new strategy for genome sequencing

Existing approaches to sequencing the human genome are based on the assumption that each region to be sequenced must first be mapped. But there is a simpler strategy in which any number of laboratories can cooperate.

Two-dimensional DNA typing: A cost-effective way of analyzing complex mixtures of DNA fragments for sequence variations

By two-dimensional (2D) DNA typing, multiple DNA fragments can be analyzed in parallel for all possible sequence variations. The method involves electrophoretic separation in polyacrylamide gels, first by size and subsequently on the basis of basepair sequence in a denaturing gradient. The system has been automated partly and a dedicated image analysis system for rapid interpretation of the often complex spot patterns was developed. In this review, the basic principles of 2D DNA typing, its methodology, and some major applications in genetic studies of animals, plants, and microorganisms will be discussed, with the emphasis on human genetics.

Patenting genes. J. Craig Venter and the Human Genome Project

He often begins to answer before you have finished asking your question, but his replies are to the point. He speaks with emotion about the people he hopes to help, particularly children with fatal genetic diseases. 'I prefer to do something: the outcome of doing nothing is perfectly clear', he says. He began sequencing human genes while others were discussing how and when to do so. His methods have been called inelegant, redundant, wasteful, and too 'industrial'. Will his method fail to detect some infrequently transcribed genes? That's all right with him. He is not concerned with finding all the human genes, but rather with the fastest possible route to a useful catalog of most human genes.

Analysis of errors in finished DNA sequences: the surfactin operon of Bacillus subtilis as an example

Increased productivity in DNA sequencing would not be valid without a straightforward detection and estimation of errors in finished sequences. The sequence of the surfactin operon from Bacillus subtilis was obtained by two different groups and by chance we were also working on the same chromosome region. Taking advantage of this situation we report in this paper, the number and nature of errors found in the overlapping part of the DNA sequences obtained by the three laboratories. The coincidence of some of the errors with compression in sequence ladders and with secondary DNA structures as well as the detection of frameshift errors using computer programs, are demonstrated. Finally we discuss the definition of a new sequencing strategy that might minimize both the error rate and the cost of sequencing.

DNA sequence confidence estimation

A significant bottleneck in the current DNA sequencing process is the manual editing of trace data generated by automated DNA sequencers. This step is used to correct base calls and to associate to each base call a confidence level. The confidence levels are used in the assembly process to determine overlaps and to resolve discrepancies in determining the consensus sequence. This single step may cost as much as 4 to 8 cents per finished base. We report an approach to automated trace editing using classification trees to detect and exploit context-based patterns in trace peak heights. Local base composition and nearby peak heights account for 80% of the variations in peak heights. Classification algorithms were developed to identify 37% of automated base calls that differ from the consensus sequence. With these algorithms, 12% of the base calls had confidence levels less than 90%.

DNA sequencing using ultra small amounts of reagents and template

One of the key points in the genome project is finding ways to reduce the running cost in DNA sequencing. One way is to use a highly-sensitive fluorescent DNA sequencer, where only trace amounts of template DNA and reagents are needed. An experimental protocol optimized for the trace amounts of DNA analysis was established by using the hybridization reaction rate coefficient of primers on template DNA, which was estimated to be 7.5 x 10(5) M-1sec-1 at 37 degrees C. One femtomole of template DNA with 0.001 unit of modified T7 DNA polymerase (Sequenase Ver. 2.0) and also 0.45 fmol of M13 template DNA with 0.01 unit of Taq DNA polymerase were enough to sequence DNA of up to 400 bases.