We propose to combine the best proven aspects of SBS with streamlined methods for DNA amplification and high-speed fluorescence imaging to develop and implement a platform for rapid and inexpensive genome resequencing and de novo sequencing. Our platform is called """"""""Natural Sequencing by Synthesis"""""""" (nSBS). Amplified DNA molecular clones will be sequenced in massive parallel by cyclic sequencing by synthesis using DNA polymerases and mostly natural nucleotides. The key is to use a small percentage of a cleavable fluorescently-labeled nucleotide along with the natural nucleotide in the cyclic base-by-base DNA sequencing by synthesis process for sequence detection. Not only will the fluorescently-labeled nucleotide incorporation be sparse but the fluorescent moiety will also be cleaved off after each imaging step. This will minimize the modification of the natural structure of the extending DNA template and ensure that DNA synthesis will not be significantly affected. With this strategy, homopolymer tracts can be sequenced and very long read lengths can be achieved. We present a concept for a new breakthrough technology called natural DNA sequencing by synthesis (nSBS). We also present several other breakthrough innovations: 1) In situ massive parallel amplification of single DNA molecules with micro fabricated arrays and rapid assembly of DNA templates. 2) The usage of an automaton to validate and optimize the new nSBS chemistry for cyclic sequencing by synthesis using DNA polymerases and commercially available nucleotides and nucleotides we will design and synthesize for efficient incorporation; 3) The decoupling of the reaction from detection to make the system scalable to very high-density arrays for whole genome sequencing. Since much higher density arrays can be used and only one enzyme (DNA polymerase) will be used, much less reagent will be needed. This will result in dramatic improvement of throughput and reduction in reagent cost. 4) The implementation of a double barrel paired-end strategy and new algorithms for de novo sequence assembly. In the long run this technology will have a great potential to enable very accurate re-sequencing and de novo sequencing of genomes at high speed and much lower cost for biomedical research and personalized medicine. PROJECT

Public Health Relevance

We propose to develop a breakthrough DNA sequencing technology called DNA sequencing by natural DNA synthesis (nSBS). We will combine streamlined methods for genome-scale DNA amplification with the new sequencing chemistry to engineer a sequencing platform for ultra-fast and low-cost human genome sequencing so that routine sequencing of individual human genomes can be performed for biomedical applications and personalized medicine. ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Human Genome Research Institute (NHGRI)
Type
Research Project (R01)
Project #
1R01HG004804-01
Application #
7533414
Study Section
Special Emphasis Panel (ZHG1-HGR-N (M1))
Program Officer
Schloss, Jeffery
Project Start
2008-08-19
Project End
2012-05-31
Budget Start
2008-08-19
Budget End
2009-05-31
Support Year
1
Fiscal Year
2008
Total Cost
$599,063
Indirect Cost
Name
University of California San Diego
Department
Engineering (All Types)
Type
Schools of Arts and Sciences
DUNS #
804355790
City
La Jolla
State
CA
Country
United States
Zip Code
92093
Walsh, Matthew T; Hsiao, Alexander P; Lee, Ho Suk et al. (2015) Capture and enumeration of mRNA transcripts from single cells using a microfluidic device. Lab Chip 15:2968-80
Walsh, Matthew T; Roller, Eric E; Ko, Kwang-Seuk et al. (2015) Measurement of DNA Polymerase Incorporation Kinetics of Dye-Labeled Nucleotides Using Total Internal Reflection Fluorescence Microscopy. Biochemistry 54:4019-21
Lee, Ho Suk; Chu, Wai Keung; Zhang, Kun et al. (2013) Microfluidic devices with permeable polymer barriers for capture and transport of biomolecules and cells. Lab Chip 13:3389-97
Barbee, Kristopher D; Chandrangsu, Matt; Huang, Xiaohua (2011) Fabrication of DNA polymer brush arrays by destructive micropatterning and rolling-circle amplification. Macromol Biosci 11:607-17
Theilacker, Nora; Roller, Eric E; Barbee, Kristopher D et al. (2011) Multiplexed protein analysis using encoded antibody-conjugated microbeads. J R Soc Interface 8:1104-13
Joneja, Aric; Huang, Xiaohua (2011) Linear nicking endonuclease-mediated strand-displacement DNA amplification. Anal Biochem 414:58-69
Barbee, Kristopher D; Hsiao, Alexander P; Roller, Eric E et al. (2010) Multiplexed protein detection using antibody-conjugated microbead arrays in a microfabricated electrophoretic device. Lab Chip 10:3084-93
Hsiao, Alexander P; Barbee, Kristopher D; Huang, Xiaohua (2010) Microfluidic Device for Capture and Isolation of Single Cells. Proc SPIE Int Soc Opt Eng 7759:
Barbee, Kristopher D; Hsiao, Alexander P; Heller, Michael J et al. (2009) Electric field directed assembly of high-density microbead arrays. Lab Chip 9:3268-74