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The 15-Minute Genome 2009 Industrial Physics Forum features faster, cheaper genome sequencing
July 28, 2009In the race for faster, cheaper ways to read human genomes, Pacific Biosciences is hoping to set a new benchmark with technology that watches DNA being copied in real time. The device is being developed to sequence DNA at speeds 20,000 times faster than second-generation sequencers currently on the market and will ultimately have a price tag of $100 per genome.
Chief Technology Officer Stephen Turner of Pacific Biosciences will discuss Single Molecule Real-Time (SMRT) sequencing, due to be released commercially in 2010, at the 2009 Industrial Physics Forum, a component of the 51st Annual Meeting of American Association of Physicists in Medicine, which takes place from July 26 - 30 in Anaheim, California
A decade ago, it took Celera Genomics and the Human Genome Project years to sequence complete human genomes. In 2008, James Watson's entire genetic code was read by a new generation of technology in months. SMRT sequencing aims to eventually accomplish the same feat in minutes.
The method used in the Human Genome Project, Sanger sequencing, taps into the cell's natural machinery for replicating DNA. The enzyme DNA polymerase is used to copy strands of DNA, creating billions of fragments of varying length. Each fragment -- a chain of building blocks called nucleotides -- ends with a tiny fluorescent molecule that identifies only the last nucleotide in the chain. By lining these fragments up according to length, their glowing tips can be read off like letters on a page.
Instead of inspecting DNA copies after polymerase has done its work, SMRT sequencing watches the enzyme in real time as it races along and copies an individual strand stuck to the bottom of a tiny well. Every nucleotide used to make the copy is attached to its own fluorescent molecule that lights up when the nucleotide is incorporated. This light is spotted by a detector that identifies the color and the nucleotide -- A, C, G, or T.
By repeating this process simultaneously in many wells, the technology hopes to bring about a substantial boost in sequencing speed. "When we reach a million separate molecules that we're able to sequence at once - we'll be able to sequence the entire human genome in less than 15 minutes," said Turner.
The speed of the reaction is currently limited by the ability of the detector to keep up with the polymerase. The first commercial instrument will operate at three to five bases per second, and Turner reports that lab tests have achieved 10 bases per second. The polymerase has the potential to go much faster, up to hundreds of bases per second. "To push past 50 bases per second, we will need brighter fluorescent reporters or more sensitive detection," says Turner.
The device also has the potential to reduce the number of errors made in DNA sequencing. Current technologies achieve an accuracy of 99.9999 percent (three thousand errors in a genome of three billion base pairs). "For cancer, you need to be able to spot a single mutation in the genome," said Turner. Because the errors made by SMRT sequencing are random -- not systematically occurring at the same spot -- they are more likely to disappear as the procedure is repeated.
The talk, "Single Molecule Real-Time DNA Sequencers," will be given at 4:00 p.m. PDT on Monday, July 27.
American Institute of Physics
The method used in the Human Genome Project, Sanger sequencing, taps into the cell's natural machinery for replicating DNA. The enzyme DNA polymerase is used to copy strands of DNA, creating billions of fragments of varying length. Each fragment -- a chain of building blocks called nucleotides -- ends with a tiny fluorescent molecule that identifies only the last nucleotide in the chain. By lining these fragments up according to length, their glowing tips can be read off like letters on a page.
Instead of inspecting DNA copies after polymerase has done its work, SMRT sequencing watches the enzyme in real time as it races along and copies an individual strand stuck to the bottom of a tiny well. Every nucleotide used to make the copy is attached to its own fluorescent molecule that lights up when the nucleotide is incorporated. This light is spotted by a detector that identifies the color and the nucleotide -- A, C, G, or T.
By repeating this process simultaneously in many wells, the technology hopes to bring about a substantial boost in sequencing speed. "When we reach a million separate molecules that we're able to sequence at once - we'll be able to sequence the entire human genome in less than 15 minutes," said Turner.
The speed of the reaction is currently limited by the ability of the detector to keep up with the polymerase. The first commercial instrument will operate at three to five bases per second, and Turner reports that lab tests have achieved 10 bases per second. The polymerase has the potential to go much faster, up to hundreds of bases per second. "To push past 50 bases per second, we will need brighter fluorescent reporters or more sensitive detection," says Turner.
The device also has the potential to reduce the number of errors made in DNA sequencing. Current technologies achieve an accuracy of 99.9999 percent (three thousand errors in a genome of three billion base pairs). "For cancer, you need to be able to spot a single mutation in the genome," said Turner. Because the errors made by SMRT sequencing are random -- not systematically occurring at the same spot -- they are more likely to disappear as the procedure is repeated.
The talk, "Single Molecule Real-Time DNA Sequencers," will be given at 4:00 p.m. PDT on Monday, July 27.
American Institute of Physics
Genome Sequencing Current Events and Genome Sequencing News RSSScientists at UA, collaborating institutions decode maize genome
Scientists from the University of Arizona led by Arizona Genomics Institute director Rod A. Wing and from collaborating institutions have deciphered the complete genetic code of the maize plant for the first time.
UCSD discovery allows scientists for the first time to experimentally annotate genomes
Over the last 20 years, the sequencing of the human genome, along with related organisms, has represented one of the largest scientific endeavors in the history of mankind.
Standards for a new genomic era
A team of geneticists at Los Alamos National Laboratory, together with a consortium of international researchers, has recently proposed a set of standards designed to elucidate the quality of publicly available genetic sequencing information.
Establishing standard definitions for genome sequences
In 1996, researchers from major genome sequencing centers around the world convened on the island of Bermuda and defined a finished genome as a gapless sequence with a nucleotide error rate of one or less in 10,000 bases.
Draft potato genome based on unique potato variety
The Potato Genome Sequencing Consortium (PGSC), an international team of scientists from industry and academia in 14 countries, has released a draft sequence of the potato genome with the help of a Virginia Tech researcher.
MSU scientist helps map potato genome; move will improve crop yield
It's been cultivated for at least 7,000 years and spread from South America to grow on every continent except Antarctica. Now the humble potato has had its genome sequenced.
Study of huge numbers of genetic mutations point to oxidative stress as underlying cause
A study that tracked genetic mutations through the human equivalent of about 5,000 years has demonstrated for the first time that oxidative DNA damage is a primary cause of the process of mutation - the fuel for evolution but also a leading cause of aging, cancer and other diseases.
Faster, cheaper way to find disease genes in human genome passes initial test
University of Washington (UW) researchers have successfully developed a novel genome-analysis strategy for more rapid, lower cost discovery of possible gene-disease links.
CSHL scientists harness logic of 'Sudoku' math puzzle to vastly enhance genome-sequencing capability
A math-based game that has taken the world by storm with its ability to delight and puzzle may now be poised to revolutionize the fast-changing world of genome sequencing and the field of medical genetics.
Aluminum-oxide nanopore beats other materials for DNA analysis
Fast and affordable genome sequencing has moved a step closer with a new solid-state nanopore sensor being developed by researchers at the University of Illinois.
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