A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)

Benjamin P. Kellman; Yujie Zhang; Emma Logomasini; Eric Meinhardt; Karla P. Godinez-Macias; Austin W.T. Chiang; James T. Sorrentino; Chenguang Liang; Bokan Bao; Yusen Zhou; Sachiko Akase; Isami Sogabe; Thukaa Kouka; Elizabeth A. Winzeler; Iain B.H. Wilson; Matthew P. Campbell; Sriram Neelamegham; Frederick J. Krambeck; Kiyoko F. Aoki-Kinoshita; Nathan E. Lewis

doi:10.3762/BJOC.16.215

A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)

Benjamin P. Kellman
, Yujie Zhang
, Emma Logomasini
, Eric Meinhardt
, Karla P. Godinez-Macias
, Austin W.T. Chiang
, James T. Sorrentino
, Chenguang Liang
, Bokan Bao
, Yusen Zhou
, Sachiko Akase
, Isami Sogabe
, Thukaa Kouka
, Elizabeth A. Winzeler
, Iain B.H. Wilson
, Matthew P. Campbell
, Sriram Neelamegham
, Frederick J. Krambeck
, Kiyoko F. Aoki-Kinoshita
, Nathan E. Lewis

Department of Chemical and Biological Engineering

University of California at San Diego
SUNY Buffalo
Soka University
University of Natural Resources and Life Sciences, Vienna
Griffith University Queensland
Johns Hopkins University
ReacTech Inc.

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

Systems glycobiology aims to provide models and analysis tools that account for the biosynthesis, regulation, and interactions with glycoconjugates. To facilitate these methods, there is a need for a clear glycan representation accessible to both computers and humans. Linear Code, a linearized and readily parsable glycan structure representation, is such a language. For this reason, Linear Code was adapted to represent reaction rules, but the syntax has drifted from its original description to accommodate new and originally unforeseen challenges. Here, we delineate the consensuses and inconsistencies that have arisen through this adaptation. We recommend options for a consensus-based extension of Linear Code that can be used for reaction rule specification going forward. Through this extension and specification of Linear Code to reaction rules, we aim to minimize inconsistent symbology thereby making glycan database queries easier. With a clear guide for generating reaction rule descriptions, glycan synthesis models will be more interoperable and reproducible thereby moving glycoinformatics closer to compliance with FAIR standards. Here, we present Linear Code for Reaction Rules (LiCoRR), version 1.0, an unambiguous representation for describing glycosylation reactions in both literature and code.

Original language	English
Pages (from-to)	2645-2662
Number of pages	18
Journal	Beilstein Journal of Organic Chemistry
Volume	16
DOIs	https://doi.org/10.3762/BJOC.16.215
State	Published - 2020

Keywords

Glycoinformatics
Linear code
Systems glycobiology

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10.3762/BJOC.16.215

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Kellman, B. P., Zhang, Y., Logomasini, E., Meinhardt, E., Godinez-Macias, K. P., Chiang, A. W. T., Sorrentino, J. T., Liang, C., Bao, B., Zhou, Y., Akase, S., Sogabe, I., Kouka, T., Winzeler, E. A., Wilson, I. B. H., Campbell, M. P., Neelamegham, S., Krambeck, F. J., Aoki-Kinoshita, K. F., & Lewis, N. E. (2020). A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR). Beilstein Journal of Organic Chemistry, 16, 2645-2662. https://doi.org/10.3762/BJOC.16.215

@article{6cb6d30041a1457095cff12d920dbd0c,

title = "A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)",

abstract = "Systems glycobiology aims to provide models and analysis tools that account for the biosynthesis, regulation, and interactions with glycoconjugates. To facilitate these methods, there is a need for a clear glycan representation accessible to both computers and humans. Linear Code, a linearized and readily parsable glycan structure representation, is such a language. For this reason, Linear Code was adapted to represent reaction rules, but the syntax has drifted from its original description to accommodate new and originally unforeseen challenges. Here, we delineate the consensuses and inconsistencies that have arisen through this adaptation. We recommend options for a consensus-based extension of Linear Code that can be used for reaction rule specification going forward. Through this extension and specification of Linear Code to reaction rules, we aim to minimize inconsistent symbology thereby making glycan database queries easier. With a clear guide for generating reaction rule descriptions, glycan synthesis models will be more interoperable and reproducible thereby moving glycoinformatics closer to compliance with FAIR standards. Here, we present Linear Code for Reaction Rules (LiCoRR), version 1.0, an unambiguous representation for describing glycosylation reactions in both literature and code.",

keywords = "Glycoinformatics, Linear code, Systems glycobiology",

author = "Kellman, \{Benjamin P.\} and Yujie Zhang and Emma Logomasini and Eric Meinhardt and Godinez-Macias, \{Karla P.\} and Chiang, \{Austin W.T.\} and Sorrentino, \{James T.\} and Chenguang Liang and Bokan Bao and Yusen Zhou and Sachiko Akase and Isami Sogabe and Thukaa Kouka and Winzeler, \{Elizabeth A.\} and Wilson, \{Iain B.H.\} and Campbell, \{Matthew P.\} and Sriram Neelamegham and Krambeck, \{Frederick J.\} and Aoki-Kinoshita, \{Kiyoko F.\} and Lewis, \{Nathan E.\}",

note = "Publisher Copyright: {\textcopyright} 2020 Kellman et al.; licensee Beilstein-Institut. License and terms: see end of document.",

year = "2020",

doi = "10.3762/BJOC.16.215",

language = "English",

volume = "16",

pages = "2645--2662",

journal = "Beilstein Journal of Organic Chemistry",

issn = "2195-951X",

publisher = "Beilstein-Institut Zur Forderung der Chemischen Wissenschaften",

}

Kellman, BP, Zhang, Y, Logomasini, E, Meinhardt, E, Godinez-Macias, KP, Chiang, AWT, Sorrentino, JT, Liang, C, Bao, B, Zhou, Y, Akase, S, Sogabe, I, Kouka, T, Winzeler, EA, Wilson, IBH, Campbell, MP, Neelamegham, S, Krambeck, FJ, Aoki-Kinoshita, KF & Lewis, NE 2020, 'A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)', Beilstein Journal of Organic Chemistry, vol. 16, pp. 2645-2662. https://doi.org/10.3762/BJOC.16.215

TY - JOUR

T1 - A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)

AU - Kellman, Benjamin P.

AU - Zhang, Yujie

AU - Logomasini, Emma

AU - Meinhardt, Eric

AU - Godinez-Macias, Karla P.

AU - Chiang, Austin W.T.

AU - Sorrentino, James T.

AU - Liang, Chenguang

AU - Bao, Bokan

AU - Zhou, Yusen

AU - Akase, Sachiko

AU - Sogabe, Isami

AU - Kouka, Thukaa

AU - Winzeler, Elizabeth A.

AU - Wilson, Iain B.H.

AU - Campbell, Matthew P.

AU - Neelamegham, Sriram

AU - Krambeck, Frederick J.

AU - Aoki-Kinoshita, Kiyoko F.

AU - Lewis, Nathan E.

PY - 2020

Y1 - 2020

N2 - Systems glycobiology aims to provide models and analysis tools that account for the biosynthesis, regulation, and interactions with glycoconjugates. To facilitate these methods, there is a need for a clear glycan representation accessible to both computers and humans. Linear Code, a linearized and readily parsable glycan structure representation, is such a language. For this reason, Linear Code was adapted to represent reaction rules, but the syntax has drifted from its original description to accommodate new and originally unforeseen challenges. Here, we delineate the consensuses and inconsistencies that have arisen through this adaptation. We recommend options for a consensus-based extension of Linear Code that can be used for reaction rule specification going forward. Through this extension and specification of Linear Code to reaction rules, we aim to minimize inconsistent symbology thereby making glycan database queries easier. With a clear guide for generating reaction rule descriptions, glycan synthesis models will be more interoperable and reproducible thereby moving glycoinformatics closer to compliance with FAIR standards. Here, we present Linear Code for Reaction Rules (LiCoRR), version 1.0, an unambiguous representation for describing glycosylation reactions in both literature and code.

AB - Systems glycobiology aims to provide models and analysis tools that account for the biosynthesis, regulation, and interactions with glycoconjugates. To facilitate these methods, there is a need for a clear glycan representation accessible to both computers and humans. Linear Code, a linearized and readily parsable glycan structure representation, is such a language. For this reason, Linear Code was adapted to represent reaction rules, but the syntax has drifted from its original description to accommodate new and originally unforeseen challenges. Here, we delineate the consensuses and inconsistencies that have arisen through this adaptation. We recommend options for a consensus-based extension of Linear Code that can be used for reaction rule specification going forward. Through this extension and specification of Linear Code to reaction rules, we aim to minimize inconsistent symbology thereby making glycan database queries easier. With a clear guide for generating reaction rule descriptions, glycan synthesis models will be more interoperable and reproducible thereby moving glycoinformatics closer to compliance with FAIR standards. Here, we present Linear Code for Reaction Rules (LiCoRR), version 1.0, an unambiguous representation for describing glycosylation reactions in both literature and code.

KW - Glycoinformatics

KW - Linear code

KW - Systems glycobiology

UR - https://www.scopus.com/pages/publications/85098284567

U2 - 10.3762/BJOC.16.215

DO - 10.3762/BJOC.16.215

M3 - Article

AN - SCOPUS:85098284567

SN - 2195-951X

VL - 16

SP - 2645

EP - 2662

JO - Beilstein Journal of Organic Chemistry

JF - Beilstein Journal of Organic Chemistry

ER -

A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)

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Keywords

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