Unseen proteome: Mining below the tip of the Iceberg to find low abundance and membrane proteins

Susanne K. Pedersen; Jenny L. Harry; Lucille Sebastian; Jasmine Baker; Mathew D. Traini; John T. McCarthy; Abi Manoharan; Marc R. Wilkins; Andrew A. Gooley; Pier Giorgio Righetti; Nicolle H. Packer; Keith L. Williams; Ben R. Herbert

doi:10.1021/pr025588i

Unseen proteome: Mining below the tip of the Iceberg to find low abundance and membrane proteins

Susanne K. Pedersen
, Jenny L. Harry
, Lucille Sebastian
, Jasmine Baker
, Mathew D. Traini
, John T. McCarthy
, Abi Manoharan
, Marc R. Wilkins
, Andrew A. Gooley
, Pier Giorgio Righetti
, Nicolle H. Packer
, Keith L. Williams
, Ben R. Herbert

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

130 Citations (Scopus)

Abstract

Abundant and hydrophilic nonmembrane proteins with isoelectric points below pH 8 are the predominant proteins identified in most proteomics projects. In yeast, however, low-abundance proteins make up 80% of the predicted proteome, approximately 50% have pl's above pH 8 and 30% of the yeast ORFs are predicted to encode membrane proteins with at least 1 trans-membrane span. By applying highly solubilizing reagents and isoelectric fractionation to a membrane fraction of yeast we have a purified and identified 780 protein isoforms, representing 323 gene products, including 28% low abundance proteins and 49% membrane or membrane associated proteins. More importantly, considering the frequency and importance of co- and post-translational modifications, the separation of protein isoforms is essential and two-dimensional electrophoresis remains the only technique which offers sufficient resolution to address this at a proteomic level.

Original language	English
Pages (from-to)	303-311
Number of pages	9
Journal	Journal of Proteome Research
Volume	2
Issue number	3
DOIs	https://doi.org/10.1021/pr025588i
Publication status	Published - May 2003
Externally published	Yes

Keywords

Fractionation
Low-abundance proteins
Membrane proteins
Multi-compartment electrolyzer
Two-dimensional electrophoresis

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10.1021/pr025588iLicence: In Copyright

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Pedersen, S. K., Harry, J. L., Sebastian, L., Baker, J., Traini, M. D., McCarthy, J. T., Manoharan, A., Wilkins, M. R., Gooley, A. A., Righetti, P. G., Packer, N. H., Williams, K. L., & Herbert, B. R. (2003). Unseen proteome: Mining below the tip of the Iceberg to find low abundance and membrane proteins. Journal of Proteome Research, 2(3), 303-311. https://doi.org/10.1021/pr025588i

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title = "Unseen proteome: Mining below the tip of the Iceberg to find low abundance and membrane proteins",

abstract = "Abundant and hydrophilic nonmembrane proteins with isoelectric points below pH 8 are the predominant proteins identified in most proteomics projects. In yeast, however, low-abundance proteins make up 80\% of the predicted proteome, approximately 50\% have pl's above pH 8 and 30\% of the yeast ORFs are predicted to encode membrane proteins with at least 1 trans-membrane span. By applying highly solubilizing reagents and isoelectric fractionation to a membrane fraction of yeast we have a purified and identified 780 protein isoforms, representing 323 gene products, including 28\% low abundance proteins and 49\% membrane or membrane associated proteins. More importantly, considering the frequency and importance of co- and post-translational modifications, the separation of protein isoforms is essential and two-dimensional electrophoresis remains the only technique which offers sufficient resolution to address this at a proteomic level.",

keywords = "Fractionation, Low-abundance proteins, Membrane proteins, Multi-compartment electrolyzer, Two-dimensional electrophoresis",

author = "Pedersen, \{Susanne K.\} and Harry, \{Jenny L.\} and Lucille Sebastian and Jasmine Baker and Traini, \{Mathew D.\} and McCarthy, \{John T.\} and Abi Manoharan and Wilkins, \{Marc R.\} and Gooley, \{Andrew A.\} and Righetti, \{Pier Giorgio\} and Packer, \{Nicolle H.\} and Williams, \{Keith L.\} and Herbert, \{Ben R.\}",

year = "2003",

month = may,

doi = "10.1021/pr025588i",

language = "English",

volume = "2",

pages = "303--311",

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AU - Pedersen, Susanne K.

AU - Harry, Jenny L.

AU - Sebastian, Lucille

AU - Baker, Jasmine

AU - Traini, Mathew D.

AU - McCarthy, John T.

AU - Manoharan, Abi

AU - Wilkins, Marc R.

AU - Gooley, Andrew A.

AU - Righetti, Pier Giorgio

AU - Packer, Nicolle H.

AU - Williams, Keith L.

AU - Herbert, Ben R.

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AB - Abundant and hydrophilic nonmembrane proteins with isoelectric points below pH 8 are the predominant proteins identified in most proteomics projects. In yeast, however, low-abundance proteins make up 80% of the predicted proteome, approximately 50% have pl's above pH 8 and 30% of the yeast ORFs are predicted to encode membrane proteins with at least 1 trans-membrane span. By applying highly solubilizing reagents and isoelectric fractionation to a membrane fraction of yeast we have a purified and identified 780 protein isoforms, representing 323 gene products, including 28% low abundance proteins and 49% membrane or membrane associated proteins. More importantly, considering the frequency and importance of co- and post-translational modifications, the separation of protein isoforms is essential and two-dimensional electrophoresis remains the only technique which offers sufficient resolution to address this at a proteomic level.

KW - Fractionation

KW - Low-abundance proteins

KW - Membrane proteins

KW - Multi-compartment electrolyzer

KW - Two-dimensional electrophoresis

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SN - 1535-3893

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JO - Journal of Proteome Research

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ER -

Unseen proteome: Mining below the tip of the Iceberg to find low abundance and membrane proteins

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Keywords

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