Mining the plasma proteome for disease applications across seven logs of protein abundance

Q. Zhang; V. Faca; S. Hanash

doi:10.1021/pr101052y

Mining the plasma proteome for disease applications across seven logs of protein abundance

Q. Zhang, V. Faca, S. Hanash

Research output: Contribution to journal › Review article › peer-review

55 Scopus citations

Abstract

The current state of proteomics technologies has sufficiently advanced to allow in-depth quantitative analysis of the plasma proteome and development of a related knowledge base. Here we review approaches that have been applied to increase depth of analysis by mass spectrometry given the substantial complexity of plasma and the vast dynamic range of protein abundance. Fractionation strategies resulting in reduced complexity of individual fractions followed by mass spectrometry analysis of digests from individual fractions has allowed well in excess of 1000 proteins to be identified and quantified with high confidence that span more than seven logs of protein abundance. Such depth of analysis has contributed to elucidation of plasma proteome variation in health and of protein changes associated with disease states.

Original language	English (US)
Pages (from-to)	46-50
Number of pages	5
Journal	Journal of Proteome Research
Volume	10
Issue number	1
DOIs	https://doi.org/10.1021/pr101052y
State	Published - Jan 7 2011
Externally published	Yes

Keywords

Biomarker
Dynamic range
Fractionation
Mass spectrometry
Plasma proteome
Protein abundance

ASJC Scopus subject areas

Biochemistry
General Chemistry

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10.1021/pr101052y

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abstract = "The current state of proteomics technologies has sufficiently advanced to allow in-depth quantitative analysis of the plasma proteome and development of a related knowledge base. Here we review approaches that have been applied to increase depth of analysis by mass spectrometry given the substantial complexity of plasma and the vast dynamic range of protein abundance. Fractionation strategies resulting in reduced complexity of individual fractions followed by mass spectrometry analysis of digests from individual fractions has allowed well in excess of 1000 proteins to be identified and quantified with high confidence that span more than seven logs of protein abundance. Such depth of analysis has contributed to elucidation of plasma proteome variation in health and of protein changes associated with disease states.",

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AU - Faca, V.

AU - Hanash, S.

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N2 - The current state of proteomics technologies has sufficiently advanced to allow in-depth quantitative analysis of the plasma proteome and development of a related knowledge base. Here we review approaches that have been applied to increase depth of analysis by mass spectrometry given the substantial complexity of plasma and the vast dynamic range of protein abundance. Fractionation strategies resulting in reduced complexity of individual fractions followed by mass spectrometry analysis of digests from individual fractions has allowed well in excess of 1000 proteins to be identified and quantified with high confidence that span more than seven logs of protein abundance. Such depth of analysis has contributed to elucidation of plasma proteome variation in health and of protein changes associated with disease states.

AB - The current state of proteomics technologies has sufficiently advanced to allow in-depth quantitative analysis of the plasma proteome and development of a related knowledge base. Here we review approaches that have been applied to increase depth of analysis by mass spectrometry given the substantial complexity of plasma and the vast dynamic range of protein abundance. Fractionation strategies resulting in reduced complexity of individual fractions followed by mass spectrometry analysis of digests from individual fractions has allowed well in excess of 1000 proteins to be identified and quantified with high confidence that span more than seven logs of protein abundance. Such depth of analysis has contributed to elucidation of plasma proteome variation in health and of protein changes associated with disease states.

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KW - Fractionation

KW - Mass spectrometry

KW - Plasma proteome

KW - Protein abundance

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Mining the plasma proteome for disease applications across seven logs of protein abundance

Abstract

Keywords

ASJC Scopus subject areas

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