An integrated system for DNA sequencing by synthesis using novel nucleotide analogues

Jia Guo, Lin Yu, Nicholas J. Turro, Jingyue Ju

Research output: Contribution to journalArticle

41 Citations (Scopus)

Abstract

The Human Genome Project has concluded, but its successful completion has increased, rather than decreased, the need for high-throughput DNA sequencing technologies. The possibility of clinically screening a full genome for an individual's mutations offers tremendous benefits, both for pursuing personalized medicine and for uncovering the genomic contributions to diseases. The Sanger sequencing method, although enormously productive for more than 30 years, requires an electrophoretic separation step that, unfortunately, remains a key technical obstacle for achieving economically acceptable full-genome results. Alternative sequencing approaches thus focus on innovations that can reduce costs. The DNA sequencing by synthesis (SBS) approach has shown great promise as a new sequencing platform, with particular progress reported recently. The general fluorescent SBS approach involves (i) incorporation of nucleotide analogs bearing fluorescent reporters, (ii) identification of the incorporated nucleotide by its fluorescent emissions, and (iii) cleavage of the fluorophore, along with the reinitiation of the polymerase reaction for continuing sequence determination. In this Account, we review the construction of a DNA-immobilized chip and the development of novel nucleotide reporters for the SBS sequencing platform. Click chemistry, with its high selectivity and coupling efficiency, was explored for surface immobilization of DNA. The first generation (G-1) modified nucleotides for SBS feature a small chemical moiety capping the 3′-OH and a fluorophore tethered to the base through a chemically cleavable linker; the design ensures that the nucleotide reporters are good substrates for the polymerase. The 3'-capping moiety and the fluorophore on the DNA extension products, generated by the incorporation of the G-1 modified nucleotides, are cleaved simultaneously to reinitiate the polymerase reaction. The sequence of a DNA template immobilized on a surface via click chemistry is unambiguously identified with this chip-SBS system. The second generation (G-2) SBS system was developed based on the concept that the closer the structures of the added nucleotide and the primer are to their natural counterparts, the more faithfully the polymerase would incorporate the nucleotide. In this approach, the polymerase reaction is performed with the combination of 3′-capped nucleotide reversible terminators (NRTs) and cleavable fluorescent dideoxynucleotides (ddNTPs). By sacrifice of a small amount of the primers permanently terminated by ddNTPs, the majority of the primers extended by the reversible terminators are reverted to the natural ones after each sequencing cycle. We have also developed the 3′-capped nucleotide reversible terminators to solve the problem of deciphering the homopolymeric regions of the template in conventional pyrosequencing. The 3′-capping moiety on the DNA extension product temporarily terminates the polymerase reaction, which allows only one nucleotide to be incorporated during each sequencing cycle. Thus, the number of nucleotides in the homopolymeric regions are unambiguously determined using the 3′-capped NRTs. It has been established that millions of DNA templates can be immobilized on a chip surface through a variety of approaches. Therefore, the integration of these high-density DNA chips with the molecular-level SBS approaches described in this Account is expected to generate a high-throughput and accurate DNA sequencing system with wide applications in biological research and health care.

Original languageEnglish (US)
Pages (from-to)551-563
Number of pages13
JournalAccounts of Chemical Research
Volume43
Issue number4
DOIs
StatePublished - Apr 20 2010
Externally publishedYes

Fingerprint

Nucleotides
DNA
Dideoxynucleotides
Fluorophores
Genes
Bearings (structural)
Throughput
Immobilized Nucleic Acids
Health care
Medicine
Screening
Innovation
Substrates

ASJC Scopus subject areas

  • Chemistry(all)

Cite this

An integrated system for DNA sequencing by synthesis using novel nucleotide analogues. / Guo, Jia; Yu, Lin; Turro, Nicholas J.; Ju, Jingyue.

In: Accounts of Chemical Research, Vol. 43, No. 4, 20.04.2010, p. 551-563.

Research output: Contribution to journalArticle

Guo, Jia ; Yu, Lin ; Turro, Nicholas J. ; Ju, Jingyue. / An integrated system for DNA sequencing by synthesis using novel nucleotide analogues. In: Accounts of Chemical Research. 2010 ; Vol. 43, No. 4. pp. 551-563.
@article{605e306830a74f4ea1ea1e5c7a2afa8f,
title = "An integrated system for DNA sequencing by synthesis using novel nucleotide analogues",
abstract = "The Human Genome Project has concluded, but its successful completion has increased, rather than decreased, the need for high-throughput DNA sequencing technologies. The possibility of clinically screening a full genome for an individual's mutations offers tremendous benefits, both for pursuing personalized medicine and for uncovering the genomic contributions to diseases. The Sanger sequencing method, although enormously productive for more than 30 years, requires an electrophoretic separation step that, unfortunately, remains a key technical obstacle for achieving economically acceptable full-genome results. Alternative sequencing approaches thus focus on innovations that can reduce costs. The DNA sequencing by synthesis (SBS) approach has shown great promise as a new sequencing platform, with particular progress reported recently. The general fluorescent SBS approach involves (i) incorporation of nucleotide analogs bearing fluorescent reporters, (ii) identification of the incorporated nucleotide by its fluorescent emissions, and (iii) cleavage of the fluorophore, along with the reinitiation of the polymerase reaction for continuing sequence determination. In this Account, we review the construction of a DNA-immobilized chip and the development of novel nucleotide reporters for the SBS sequencing platform. Click chemistry, with its high selectivity and coupling efficiency, was explored for surface immobilization of DNA. The first generation (G-1) modified nucleotides for SBS feature a small chemical moiety capping the 3′-OH and a fluorophore tethered to the base through a chemically cleavable linker; the design ensures that the nucleotide reporters are good substrates for the polymerase. The 3'-capping moiety and the fluorophore on the DNA extension products, generated by the incorporation of the G-1 modified nucleotides, are cleaved simultaneously to reinitiate the polymerase reaction. The sequence of a DNA template immobilized on a surface via click chemistry is unambiguously identified with this chip-SBS system. The second generation (G-2) SBS system was developed based on the concept that the closer the structures of the added nucleotide and the primer are to their natural counterparts, the more faithfully the polymerase would incorporate the nucleotide. In this approach, the polymerase reaction is performed with the combination of 3′-capped nucleotide reversible terminators (NRTs) and cleavable fluorescent dideoxynucleotides (ddNTPs). By sacrifice of a small amount of the primers permanently terminated by ddNTPs, the majority of the primers extended by the reversible terminators are reverted to the natural ones after each sequencing cycle. We have also developed the 3′-capped nucleotide reversible terminators to solve the problem of deciphering the homopolymeric regions of the template in conventional pyrosequencing. The 3′-capping moiety on the DNA extension product temporarily terminates the polymerase reaction, which allows only one nucleotide to be incorporated during each sequencing cycle. Thus, the number of nucleotides in the homopolymeric regions are unambiguously determined using the 3′-capped NRTs. It has been established that millions of DNA templates can be immobilized on a chip surface through a variety of approaches. Therefore, the integration of these high-density DNA chips with the molecular-level SBS approaches described in this Account is expected to generate a high-throughput and accurate DNA sequencing system with wide applications in biological research and health care.",
author = "Jia Guo and Lin Yu and Turro, {Nicholas J.} and Jingyue Ju",
year = "2010",
month = "4",
day = "20",
doi = "10.1021/ar900255c",
language = "English (US)",
volume = "43",
pages = "551--563",
journal = "Accounts of Chemical Research",
issn = "0001-4842",
publisher = "American Chemical Society",
number = "4",

}

TY - JOUR

T1 - An integrated system for DNA sequencing by synthesis using novel nucleotide analogues

AU - Guo, Jia

AU - Yu, Lin

AU - Turro, Nicholas J.

AU - Ju, Jingyue

PY - 2010/4/20

Y1 - 2010/4/20

N2 - The Human Genome Project has concluded, but its successful completion has increased, rather than decreased, the need for high-throughput DNA sequencing technologies. The possibility of clinically screening a full genome for an individual's mutations offers tremendous benefits, both for pursuing personalized medicine and for uncovering the genomic contributions to diseases. The Sanger sequencing method, although enormously productive for more than 30 years, requires an electrophoretic separation step that, unfortunately, remains a key technical obstacle for achieving economically acceptable full-genome results. Alternative sequencing approaches thus focus on innovations that can reduce costs. The DNA sequencing by synthesis (SBS) approach has shown great promise as a new sequencing platform, with particular progress reported recently. The general fluorescent SBS approach involves (i) incorporation of nucleotide analogs bearing fluorescent reporters, (ii) identification of the incorporated nucleotide by its fluorescent emissions, and (iii) cleavage of the fluorophore, along with the reinitiation of the polymerase reaction for continuing sequence determination. In this Account, we review the construction of a DNA-immobilized chip and the development of novel nucleotide reporters for the SBS sequencing platform. Click chemistry, with its high selectivity and coupling efficiency, was explored for surface immobilization of DNA. The first generation (G-1) modified nucleotides for SBS feature a small chemical moiety capping the 3′-OH and a fluorophore tethered to the base through a chemically cleavable linker; the design ensures that the nucleotide reporters are good substrates for the polymerase. The 3'-capping moiety and the fluorophore on the DNA extension products, generated by the incorporation of the G-1 modified nucleotides, are cleaved simultaneously to reinitiate the polymerase reaction. The sequence of a DNA template immobilized on a surface via click chemistry is unambiguously identified with this chip-SBS system. The second generation (G-2) SBS system was developed based on the concept that the closer the structures of the added nucleotide and the primer are to their natural counterparts, the more faithfully the polymerase would incorporate the nucleotide. In this approach, the polymerase reaction is performed with the combination of 3′-capped nucleotide reversible terminators (NRTs) and cleavable fluorescent dideoxynucleotides (ddNTPs). By sacrifice of a small amount of the primers permanently terminated by ddNTPs, the majority of the primers extended by the reversible terminators are reverted to the natural ones after each sequencing cycle. We have also developed the 3′-capped nucleotide reversible terminators to solve the problem of deciphering the homopolymeric regions of the template in conventional pyrosequencing. The 3′-capping moiety on the DNA extension product temporarily terminates the polymerase reaction, which allows only one nucleotide to be incorporated during each sequencing cycle. Thus, the number of nucleotides in the homopolymeric regions are unambiguously determined using the 3′-capped NRTs. It has been established that millions of DNA templates can be immobilized on a chip surface through a variety of approaches. Therefore, the integration of these high-density DNA chips with the molecular-level SBS approaches described in this Account is expected to generate a high-throughput and accurate DNA sequencing system with wide applications in biological research and health care.

AB - The Human Genome Project has concluded, but its successful completion has increased, rather than decreased, the need for high-throughput DNA sequencing technologies. The possibility of clinically screening a full genome for an individual's mutations offers tremendous benefits, both for pursuing personalized medicine and for uncovering the genomic contributions to diseases. The Sanger sequencing method, although enormously productive for more than 30 years, requires an electrophoretic separation step that, unfortunately, remains a key technical obstacle for achieving economically acceptable full-genome results. Alternative sequencing approaches thus focus on innovations that can reduce costs. The DNA sequencing by synthesis (SBS) approach has shown great promise as a new sequencing platform, with particular progress reported recently. The general fluorescent SBS approach involves (i) incorporation of nucleotide analogs bearing fluorescent reporters, (ii) identification of the incorporated nucleotide by its fluorescent emissions, and (iii) cleavage of the fluorophore, along with the reinitiation of the polymerase reaction for continuing sequence determination. In this Account, we review the construction of a DNA-immobilized chip and the development of novel nucleotide reporters for the SBS sequencing platform. Click chemistry, with its high selectivity and coupling efficiency, was explored for surface immobilization of DNA. The first generation (G-1) modified nucleotides for SBS feature a small chemical moiety capping the 3′-OH and a fluorophore tethered to the base through a chemically cleavable linker; the design ensures that the nucleotide reporters are good substrates for the polymerase. The 3'-capping moiety and the fluorophore on the DNA extension products, generated by the incorporation of the G-1 modified nucleotides, are cleaved simultaneously to reinitiate the polymerase reaction. The sequence of a DNA template immobilized on a surface via click chemistry is unambiguously identified with this chip-SBS system. The second generation (G-2) SBS system was developed based on the concept that the closer the structures of the added nucleotide and the primer are to their natural counterparts, the more faithfully the polymerase would incorporate the nucleotide. In this approach, the polymerase reaction is performed with the combination of 3′-capped nucleotide reversible terminators (NRTs) and cleavable fluorescent dideoxynucleotides (ddNTPs). By sacrifice of a small amount of the primers permanently terminated by ddNTPs, the majority of the primers extended by the reversible terminators are reverted to the natural ones after each sequencing cycle. We have also developed the 3′-capped nucleotide reversible terminators to solve the problem of deciphering the homopolymeric regions of the template in conventional pyrosequencing. The 3′-capping moiety on the DNA extension product temporarily terminates the polymerase reaction, which allows only one nucleotide to be incorporated during each sequencing cycle. Thus, the number of nucleotides in the homopolymeric regions are unambiguously determined using the 3′-capped NRTs. It has been established that millions of DNA templates can be immobilized on a chip surface through a variety of approaches. Therefore, the integration of these high-density DNA chips with the molecular-level SBS approaches described in this Account is expected to generate a high-throughput and accurate DNA sequencing system with wide applications in biological research and health care.

UR - http://www.scopus.com/inward/record.url?scp=77951239240&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=77951239240&partnerID=8YFLogxK

U2 - 10.1021/ar900255c

DO - 10.1021/ar900255c

M3 - Article

C2 - 20121268

AN - SCOPUS:77951239240

VL - 43

SP - 551

EP - 563

JO - Accounts of Chemical Research

JF - Accounts of Chemical Research

SN - 0001-4842

IS - 4

ER -