A systematic evaluation of normalization methods in quantitative label-free proteomics

Abstract To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation. Normalization is the process that aims to account for the bias and make samples more comparable. The selection of a proper normaliz...

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Published inBriefings in bioinformatics Vol. 19; no. 1; pp. 1 - 11
Main Authors Välikangas, Tommi, Suomi, Tomi, Elo, Laura L
Format Journal Article
LanguageEnglish
Published England Oxford University Press 01.01.2018
Oxford Publishing Limited (England)
Subjects
Animals
data collection
Databases, Protein
Datasets
DNA chips
DNA microarrays
gene expression regulation
Humans
Instrumentation
Mass spectrometry
Mass spectroscopy
Methods
Mice
Models, Statistical
Normalizing
Peptide Mapping - methods
Peptide Mapping - standards
Proteome - analysis
Proteomics
Proteomics - methods
Proteomics - standards
Regression analysis
Reliability analysis
Reproducibility
Reproducibility of Results
variance
Variation
proteomics
normalization
intragroup variation
quantitation
reproducibility
bias
label free
differential expression
mass spectrometry
logarithmic fold change
Online AccessGet full text
ISSN1467-5463
1477-4054
1477-4054
DOI10.1093/bib/bbw095

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Abstract Abstract To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation. Normalization is the process that aims to account for the bias and make samples more comparable. The selection of a proper normalization method is a pivotal task for the reliability of the downstream analysis and results. Many normalization methods commonly used in proteomics have been adapted from the DNA microarray techniques. Previous studies comparing normalization methods in proteomics have focused mainly on intragroup variation. In this study, several popular and widely used normalization methods representing different strategies in normalization are evaluated using three spike-in and one experimental mouse label-free proteomic data sets. The normalization methods are evaluated in terms of their ability to reduce variation between technical replicates, their effect on differential expression analysis and their effect on the estimation of logarithmic fold changes. Additionally, we examined whether normalizing the whole data globally or in segments for the differential expression analysis has an effect on the performance of the normalization methods. We found that variance stabilization normalization (Vsn) reduced variation the most between technical replicates in all examined data sets. Vsn also performed consistently well in the differential expression analysis. Linear regression normalization and local regression normalization performed also systematically well. Finally, we discuss the choice of a normalization method and some qualities of a suitable normalization method in the light of the results of our evaluation.
AbstractList Abstract To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation. Normalization is the process that aims to account for the bias and make samples more comparable. The selection of a proper normalization method is a pivotal task for the reliability of the downstream analysis and results. Many normalization methods commonly used in proteomics have been adapted from the DNA microarray techniques. Previous studies comparing normalization methods in proteomics have focused mainly on intragroup variation. In this study, several popular and widely used normalization methods representing different strategies in normalization are evaluated using three spike-in and one experimental mouse label-free proteomic data sets. The normalization methods are evaluated in terms of their ability to reduce variation between technical replicates, their effect on differential expression analysis and their effect on the estimation of logarithmic fold changes. Additionally, we examined whether normalizing the whole data globally or in segments for the differential expression analysis has an effect on the performance of the normalization methods. We found that variance stabilization normalization (Vsn) reduced variation the most between technical replicates in all examined data sets. Vsn also performed consistently well in the differential expression analysis. Linear regression normalization and local regression normalization performed also systematically well. Finally, we discuss the choice of a normalization method and some qualities of a suitable normalization method in the light of the results of our evaluation.
To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation. Normalization is the process that aims to account for the bias and make samples more comparable. The selection of a proper normalization method is a pivotal task for the reliability of the downstream analysis and results. Many normalization methods commonly used in proteomics have been adapted from the DNA microarray techniques. Previous studies comparing normalization methods in proteomics have focused mainly on intragroup variation. In this study, several popular and widely used normalization methods representing different strategies in normalization are evaluated using three spike-in and one experimental mouse label-free proteomic data sets. The normalization methods are evaluated in terms of their ability to reduce variation between technical replicates, their effect on differential expression analysis and their effect on the estimation of logarithmic fold changes. Additionally, we examined whether normalizing the whole data globally or in segments for the differential expression analysis has an effect on the performance of the normalization methods. We found that variance stabilization normalization (Vsn) reduced variation the most between technical replicates in all examined data sets. Vsn also performed consistently well in the differential expression analysis. Linear regression normalization and local regression normalization performed also systematically well. Finally, we discuss the choice of a normalization method and some qualities of a suitable normalization method in the light of the results of our evaluation.
To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation. Normalization is the process that aims to account for the bias and make samples more comparable. The selection of a proper normalization method is a pivotal task for the reliability of the downstream analysis and results. Many normalization methods commonly used in proteomics have been adapted from the DNA microarray techniques. Previous studies comparing normalization methods in proteomics have focused mainly on intragroup variation. In this study, several popular and widely used normalization methods representing different strategies in normalization are evaluated using three spike-in and one experimental mouse label-free proteomic data sets. The normalization methods are evaluated in terms of their ability to reduce variation between technical replicates, their effect on differential expression analysis and their effect on the estimation of logarithmic fold changes. Additionally, we examined whether normalizing the whole data globally or in segments for the differential expression analysis has an effect on the performance of the normalization methods. We found that variance stabilization normalization (Vsn) reduced variation the most between technical replicates in all examined data sets. Vsn also performed consistently well in the differential expression analysis. Linear regression normalization and local regression normalization performed also systematically well. Finally, we discuss the choice of a normalization method and some qualities of a suitable normalization method in the light of the results of our evaluation.To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation. Normalization is the process that aims to account for the bias and make samples more comparable. The selection of a proper normalization method is a pivotal task for the reliability of the downstream analysis and results. Many normalization methods commonly used in proteomics have been adapted from the DNA microarray techniques. Previous studies comparing normalization methods in proteomics have focused mainly on intragroup variation. In this study, several popular and widely used normalization methods representing different strategies in normalization are evaluated using three spike-in and one experimental mouse label-free proteomic data sets. The normalization methods are evaluated in terms of their ability to reduce variation between technical replicates, their effect on differential expression analysis and their effect on the estimation of logarithmic fold changes. Additionally, we examined whether normalizing the whole data globally or in segments for the differential expression analysis has an effect on the performance of the normalization methods. We found that variance stabilization normalization (Vsn) reduced variation the most between technical replicates in all examined data sets. Vsn also performed consistently well in the differential expression analysis. Linear regression normalization and local regression normalization performed also systematically well. Finally, we discuss the choice of a normalization method and some qualities of a suitable normalization method in the light of the results of our evaluation.
Author Elo, Laura L
Suomi, Tomi
Välikangas, Tommi
AuthorAffiliation 1 Computational Biomedicine Group at the Turku Centre for Biotechnology Finland
2 Computational Biomedicine research group at the Turku Centre for Biotechnology Finland
3 Computational Biomedicine at Turku Centre for Biotechnology, University of Turku, Finland
AuthorAffiliation_xml – name: 2 Computational Biomedicine research group at the Turku Centre for Biotechnology Finland
– name: 3 Computational Biomedicine at Turku Centre for Biotechnology, University of Turku, Finland
– name: 1 Computational Biomedicine Group at the Turku Centre for Biotechnology Finland
Author_xml – sequence: 1
  givenname: Tommi
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  fullname: Välikangas, Tommi
  organization: Computational Biomedicine Group at the Turku Centre for Biotechnology Finland
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  givenname: Tomi
  surname: Suomi
  fullname: Suomi, Tomi
  organization: Computational Biomedicine research group at the Turku Centre for Biotechnology Finland
– sequence: 3
  givenname: Laura L
  surname: Elo
  fullname: Elo, Laura L
  email: laura.elo@utu.fi
  organization: Computational Biomedicine at Turku Centre for Biotechnology, University of Turku, Finland
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Issue 1
Keywords proteomics
normalization
intragroup variation
quantitation
reproducibility
bias
label free
differential expression
mass spectrometry
logarithmic fold change
Language English
License This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.
The Author 2016. Published by Oxford University Press.
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Snippet Abstract To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the...
To date, mass spectrometry (MS) data remain inherently biased as a result of reasons ranging from sample handling to differences caused by the instrumentation....
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SubjectTerms Animals
data collection
Databases, Protein
Datasets
DNA chips
DNA microarrays
gene expression regulation
Humans
Instrumentation
Mass spectrometry
Mass spectroscopy
Methods
Mice
Models, Statistical
Normalizing
Peptide Mapping - methods
Peptide Mapping - standards
Proteome - analysis
Proteomics
Proteomics - methods
Proteomics - standards
Regression analysis
Reliability analysis
Reproducibility
Reproducibility of Results
variance
Variation
Title A systematic evaluation of normalization methods in quantitative label-free proteomics
URI https://www.ncbi.nlm.nih.gov/pubmed/27694351
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https://www.proquest.com/docview/1835351325
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https://pubmed.ncbi.nlm.nih.gov/PMC5862339
Volume 19
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