A systematic approach to modeling, capturing, and disseminating proteomics experimental data

Chris F. Taylor; Norman W. Paton; Kevin L. Garwood; Paul D. Kirby; David A. Stead; Zhikang Yin; Eric W. Deutsch; Laura Selway; Janet Walker; Isabel Riba Garcia; Shabaz Mohammed; Michael J. Deery; Julie A. Howard; Tom Dunkley; Ruedi Aebersold; Douglas B. Kell; Kathryn S. Lilley; Peter Roepstorff; John R. Yates; Andy Brass; Alistair J P Brown; Phil Cash; Simon J. Gaskell; Simon J. Hubbard; Stephen G. Oliver

doi:10.1038/nbt0303-247

A systematic approach to modeling, capturing, and disseminating proteomics experimental data

Chris F. Taylor, Norman W. Paton, Kevin L. Garwood, Paul D. Kirby, David A. Stead, Zhikang Yin, Eric W. Deutsch, Laura Selway, Janet Walker, Isabel Riba Garcia, Shabaz Mohammed, Michael J. Deery, Julie A. Howard, Tom Dunkley, Ruedi Aebersold, Douglas B. Kell, Kathryn S. Lilley, Peter Roepstorff, John R. Yates, Andy BrassAlistair J P Brown, Phil Cash, Simon J. Gaskell, Simon J. Hubbard, Stephen G. Oliver

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Abstract

Both the generation and the analysis of proteome data are becoming increasingly widespread, and the field of proteomics is moving incrementally toward high-throughput approaches. Techniques are also increasing in complexity as the relevant technologies evolve. A standard representation of both the methods used and the data generated in proteomics experiments, analogous to that of the MIAME (minimum information about a microarray experiment) guidelines for transcriptomics, and the associated MAGE (microarray gene expression) object model and XML (extensible markup language) implementation, has yet to emerge. This hinders the handling, exchange, and dissemination of proteomics data. Here, we present a UML (unified modeling language) approach to proteomics experimental data, describe XML and SQL (structured query language) implementations of that model, and discuss capture, storage, and dissemination strategies. These make explicit what data might be most usefully captured about proteomics experiments and provide complementary routes toward the implementation of a proteome repository.

Original language	English
Pages (from-to)	247-254
Number of pages	7
Journal	Nature biotechnology
Volume	21
Issue number	3
DOIs	https://doi.org/10.1038/nbt0303-247
Publication status	Published - 1 Mar 2003

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Manchester Institute of Biotechnology

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Taylor, C. F., Paton, N. W., Garwood, K. L., Kirby, P. D., Stead, D. A., Yin, Z., Deutsch, E. W., Selway, L., Walker, J., Riba Garcia, I., Mohammed, S., Deery, M. J., Howard, J. A., Dunkley, T., Aebersold, R., Kell, D. B., Lilley, K. S., Roepstorff, P., Yates, J. R., ... Oliver, S. G. (2003). A systematic approach to modeling, capturing, and disseminating proteomics experimental data. Nature biotechnology, 21(3), 247-254. https://doi.org/10.1038/nbt0303-247

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title = "A systematic approach to modeling, capturing, and disseminating proteomics experimental data",

abstract = "Both the generation and the analysis of proteome data are becoming increasingly widespread, and the field of proteomics is moving incrementally toward high-throughput approaches. Techniques are also increasing in complexity as the relevant technologies evolve. A standard representation of both the methods used and the data generated in proteomics experiments, analogous to that of the MIAME (minimum information about a microarray experiment) guidelines for transcriptomics, and the associated MAGE (microarray gene expression) object model and XML (extensible markup language) implementation, has yet to emerge. This hinders the handling, exchange, and dissemination of proteomics data. Here, we present a UML (unified modeling language) approach to proteomics experimental data, describe XML and SQL (structured query language) implementations of that model, and discuss capture, storage, and dissemination strategies. These make explicit what data might be most usefully captured about proteomics experiments and provide complementary routes toward the implementation of a proteome repository.",

author = "Taylor, {Chris F.} and Paton, {Norman W.} and Garwood, {Kevin L.} and Kirby, {Paul D.} and Stead, {David A.} and Zhikang Yin and Deutsch, {Eric W.} and Laura Selway and Janet Walker and {Riba Garcia}, Isabel and Shabaz Mohammed and Deery, {Michael J.} and Howard, {Julie A.} and Tom Dunkley and Ruedi Aebersold and Kell, {Douglas B.} and Lilley, {Kathryn S.} and Peter Roepstorff and Yates, {John R.} and Andy Brass and Brown, {Alistair J P} and Phil Cash and Gaskell, {Simon J.} and Hubbard, {Simon J.} and Oliver, {Stephen G.}",

year = "2003",

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doi = "10.1038/nbt0303-247",

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Taylor, CF, Paton, NW, Garwood, KL, Kirby, PD, Stead, DA, Yin, Z, Deutsch, EW, Selway, L, Walker, J, Riba Garcia, I, Mohammed, S, Deery, MJ, Howard, JA, Dunkley, T, Aebersold, R, Kell, DB, Lilley, KS, Roepstorff, P, Yates, JR, Brass, A, Brown, AJP, Cash, P, Gaskell, SJ, Hubbard, SJ & Oliver, SG 2003, 'A systematic approach to modeling, capturing, and disseminating proteomics experimental data', Nature biotechnology, vol. 21, no. 3, pp. 247-254. https://doi.org/10.1038/nbt0303-247

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AU - Taylor, Chris F.

AU - Paton, Norman W.

AU - Garwood, Kevin L.

AU - Kirby, Paul D.

AU - Stead, David A.

AU - Yin, Zhikang

AU - Deutsch, Eric W.

AU - Selway, Laura

AU - Walker, Janet

AU - Riba Garcia, Isabel

AU - Mohammed, Shabaz

AU - Deery, Michael J.

AU - Howard, Julie A.

AU - Dunkley, Tom

AU - Aebersold, Ruedi

AU - Kell, Douglas B.

AU - Lilley, Kathryn S.

AU - Roepstorff, Peter

AU - Yates, John R.

AU - Brass, Andy

AU - Brown, Alistair J P

AU - Cash, Phil

AU - Gaskell, Simon J.

AU - Hubbard, Simon J.

AU - Oliver, Stephen G.

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AB - Both the generation and the analysis of proteome data are becoming increasingly widespread, and the field of proteomics is moving incrementally toward high-throughput approaches. Techniques are also increasing in complexity as the relevant technologies evolve. A standard representation of both the methods used and the data generated in proteomics experiments, analogous to that of the MIAME (minimum information about a microarray experiment) guidelines for transcriptomics, and the associated MAGE (microarray gene expression) object model and XML (extensible markup language) implementation, has yet to emerge. This hinders the handling, exchange, and dissemination of proteomics data. Here, we present a UML (unified modeling language) approach to proteomics experimental data, describe XML and SQL (structured query language) implementations of that model, and discuss capture, storage, and dissemination strategies. These make explicit what data might be most usefully captured about proteomics experiments and provide complementary routes toward the implementation of a proteome repository.

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EP - 254

JO - Nature biotechnology

JF - Nature biotechnology

IS - 3

ER -

A systematic approach to modeling, capturing, and disseminating proteomics experimental data

Abstract

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