'Sequence capture' technology enables fast and accurate enrichment of thousands of selected genomic regions, either contiguous or dispersed, such as segments of chromosomes or all genes or exons
Researchers at Baylor College of Medicine and Roche NimbleGen have published details of a highly efficient and cost-effective method for capturing targeted regions of the genome via NimbleChip microarrays in preparation for high-throughput 454 Sequencing.
The study, entitled 'Direct selection of human genomic loci by microarray hybridization', appears online (ahead of print) in the journal Nature Methods.
In light of the success of the current sequence capture technology, Baylor's Human Genome Sequencing Center (HGSC) has signed on as an early access customer to Roche NimbleGen's sequence capture technology.
As presented on 10 October 2007, at the Venter Institute's Genomes, Medicine, and the Environment (GME) conference, Roche NimbleGen and 454 Life Sciences, working with Richard Gibbs, professor and director of the HGSC, will create a whole-genome human exome (all exons) microarray, with the goal of resequencing the entire human exome.
Resequencing of genes or other genomic regions of interest is a key step in detecting mutations associated with various complex human diseases, such as cancer, asthma and heart disease.
The predominant method for selection of specific genomic regions for resequencing has primarily relied on PCR (polymerase chain reaction) to enrich for specific DNA fragments.
However, PCR is limited in the length of sequence it can amplify, is difficult to scale or multiplex for the enrichment of thousands of fragments, and has limited performance in the repetitive regions typical of complex genomes, such as human.
The sequence capture microarray technology bridges the gap between next-generation DNA sequencing technology and current sample preparation methods by providing an adaptable, massively parallel method for selective enrichment of genomic regions of interest.
Roche NimbleGen's sequence capture technology enables high-performance targeting of thousands of specific genes or loci using a single microarray hybridisation-based enrichment process.
The Baylor study used Roche's Genome Sequencer FLX to quickly and affordably sequence the enriched genomic regions for downstream analysis.
454 Sequencing technology is ideal for this targeted sequencing approach because of its long read lengths and highly accurate reads.
"This new technology will replace polymerase chain reaction (PCR) for many purposes," said Gibbs.
"If the aim is to sequence a whole genome for everybody, this is a huge step in that direction".
The Nature Methods paper published by Baylor demonstrates that the sequence capture process is simpler, more accurate, more efficient and more cost-effective than the multiplex PCR that was previously used to prepare genomic samples for sequencing.
In one experiment, more than 6700 exons (the part of the genetic code that together form genes), were enriched and analyzed, as well as contiguous genomic regions of up to five million bases.
Using the old technology this would have taken at least six months.
"We're delighted to have an opportunity to collaborate with scientists at Baylor HGSC on the development of this breakthrough technology," said Stan Rose, president of Roche NimbleGen.
"The combination of these two Roche technologies - NimbleGen and 454 - has the potential to transform the market for DNA sequence analysis."
