Statistical testing in transcriptomic-neuroimaging studies: A how-to and evaluation of methods assessing spatial and gene specificity

Yongbin Wei; Siemon C. de Lange; Rory Pijnenburg; Lianne H. Scholtens; Dirk Jan Ardesch; Kyoko Watanabe; Danielle Posthuma; Martijn P. van den Heuvel

doi:10.1002/hbm.25711

Statistical testing in transcriptomic-neuroimaging studies: A how-to and evaluation of methods assessing spatial and gene specificity

Yongbin Wei, Siemon C. de Lange, Rory Pijnenburg, Lianne H. Scholtens, Dirk Jan Ardesch, Kyoko Watanabe, Danielle Posthuma, Martijn P. van den Heuvel^*

^*Corresponding author for this work

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Multiscale integration of gene transcriptomic and neuroimaging data is becoming a widely used approach for exploring the molecular underpinnings of large-scale brain organization in health and disease. Proper statistical evaluation of determined associations between imaging-based phenotypic and transcriptomic data is key in these explorations, in particular to establish whether observed associations exceed “chance level” of random, nonspecific effects. Recent approaches have shown the importance of statistical models that can correct for spatial autocorrelation effects in the data to avoid inflation of reported statistics. Here, we discuss the need for examination of a second category of statistical models in transcriptomic-neuroimaging analyses, namely those that can provide “gene specificity.” By means of a couple of simple examples of commonly performed transcriptomic-neuroimaging analyses, we illustrate some of the potentials and challenges of transcriptomic-imaging analyses, showing that providing gene specificity on observed transcriptomic-neuroimaging effects is of high importance to avoid reports of nonspecific effects. Through means of simulations we show that the rate of reported nonspecific effects (i.e., effects that cannot be specifically linked to a specific gene or gene-set) can run as high as 60%, with only less than 5% of transcriptomic-neuroimaging associations observed through ordinary linear regression analyses showing both spatial and gene specificity. We provide a discussion, a tutorial, and an easy-to-use toolbox for the different options of null models in transcriptomic-neuroimaging analyses.

Original language	English
Pages (from-to)	885-901
Number of pages	17
Journal	Human Brain Mapping
Volume	43
Issue number	3
Early online date	4 Dec 2021
DOIs	https://doi.org/10.1002/hbm.25711
Publication status	Published - 15 Feb 2022

Bibliographical note

Publisher Copyright:
© 2021 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.

Funding

Martijn P. van den Heuvel was supported by an ALW open (ALWOP.179), a VIDI (452-16-015) grant from the Netherlands Organization for Scientific Research (NWO), and an ERC Consolidator grant (ID 101001062) of the European Research Council. D.P. was supported by The Netherlands Organization for Scientific Research (NWO VICI 453-14-005 and NWO Gravitation: BRAINSCAPES: A Roadmap from Neurogenetics to Neurobiology 024.004.012) and a European Research Council advanced grant (ERC-2018-AdG GWAS2FUNC 834057). Siemon C. de Lange was supported by the Amsterdam Neuroscience alliance grant and ZonMw Open Competition, project REMOVE 09120011910032. Human neuroimaging data were kindly provided by the Human Connectome Project, WU-Minn Consortium (Principal Investigators: David Van Essen and Kamil Ugurbil; 1U54MH091657) funded by the 16 NIH Institutes and Centers that support the NIH Blueprint for Neuroscience Research; and by the McDonnell Center for Systems Neuroscience at Washington University. Martijn P. van den Heuvel was supported by an ALW open (ALWOP.179), a VIDI (452‐16‐015) grant from the Netherlands Organization for Scientific Research (NWO), and an ERC Consolidator grant (ID 101001062) of the European Research Council. D.P. was supported by The Netherlands Organization for Scientific Research (NWO VICI 453‐14‐005 and NWO Gravitation: BRAINSCAPES: A Roadmap from Neurogenetics to Neurobiology 024.004.012) and a European Research Council advanced grant (ERC‐2018‐AdG GWAS2FUNC 834057). Siemon C. de Lange was supported by the Amsterdam Neuroscience alliance grant and ZonMw Open Competition, project REMOVE 09120011910032. Human neuroimaging data were kindly provided by the Human Connectome Project, WU‐Minn Consortium (Principal Investigators: David Van Essen and Kamil Ugurbil; 1U54MH091657) funded by the 16 NIH Institutes and Centers that support the NIH Blueprint for Neuroscience Research; and by the McDonnell Center for Systems Neuroscience at Washington University.

Funders	Funder number
NIH Blueprint for Neuroscience Research
VIDI
National Institutes of Health
McDonnell Center for Systems Neuroscience
Not added	101001062, 452-16-015
ZonMw Open Competition	09120011910032, 1U54MH091657
Horizon 2020 Framework Programme	101001062, 834057
European Research Council	VICI 453‐14‐005, 024.004.012
National Institute of Mental Health	U54MH091657

Access to Document

10.1002/hbm.25711

Persistent URL (handle)

Persistent link

Cite this

@article{a7cd21cd23f44fcd96920ac4930c4c2f,

title = "Statistical testing in transcriptomic-neuroimaging studies: A how-to and evaluation of methods assessing spatial and gene specificity",

abstract = "Multiscale integration of gene transcriptomic and neuroimaging data is becoming a widely used approach for exploring the molecular underpinnings of large-scale brain organization in health and disease. Proper statistical evaluation of determined associations between imaging-based phenotypic and transcriptomic data is key in these explorations, in particular to establish whether observed associations exceed “chance level” of random, nonspecific effects. Recent approaches have shown the importance of statistical models that can correct for spatial autocorrelation effects in the data to avoid inflation of reported statistics. Here, we discuss the need for examination of a second category of statistical models in transcriptomic-neuroimaging analyses, namely those that can provide “gene specificity.” By means of a couple of simple examples of commonly performed transcriptomic-neuroimaging analyses, we illustrate some of the potentials and challenges of transcriptomic-imaging analyses, showing that providing gene specificity on observed transcriptomic-neuroimaging effects is of high importance to avoid reports of nonspecific effects. Through means of simulations we show that the rate of reported nonspecific effects (i.e., effects that cannot be specifically linked to a specific gene or gene-set) can run as high as 60\%, with only less than 5\% of transcriptomic-neuroimaging associations observed through ordinary linear regression analyses showing both spatial and gene specificity. We provide a discussion, a tutorial, and an easy-to-use toolbox for the different options of null models in transcriptomic-neuroimaging analyses.",

author = "Yongbin Wei and \{de Lange\}, \{Siemon C.\} and Rory Pijnenburg and Scholtens, \{Lianne H.\} and Ardesch, \{Dirk Jan\} and Kyoko Watanabe and Danielle Posthuma and \{van den Heuvel\}, \{Martijn P.\}",

note = "Publisher Copyright: {\textcopyright} 2021 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.",

year = "2022",

month = feb,

day = "15",

doi = "10.1002/hbm.25711",

language = "English",

volume = "43",

pages = "885--901",

journal = "Human Brain Mapping",

issn = "1065-9471",

publisher = "Wiley-Liss Inc.",

number = "3",

}

TY - JOUR

T1 - Statistical testing in transcriptomic-neuroimaging studies

T2 - A how-to and evaluation of methods assessing spatial and gene specificity

AU - Wei, Yongbin

AU - de Lange, Siemon C.

AU - Pijnenburg, Rory

AU - Scholtens, Lianne H.

AU - Ardesch, Dirk Jan

AU - Watanabe, Kyoko

AU - Posthuma, Danielle

AU - van den Heuvel, Martijn P.

PY - 2022/2/15

Y1 - 2022/2/15

N2 - Multiscale integration of gene transcriptomic and neuroimaging data is becoming a widely used approach for exploring the molecular underpinnings of large-scale brain organization in health and disease. Proper statistical evaluation of determined associations between imaging-based phenotypic and transcriptomic data is key in these explorations, in particular to establish whether observed associations exceed “chance level” of random, nonspecific effects. Recent approaches have shown the importance of statistical models that can correct for spatial autocorrelation effects in the data to avoid inflation of reported statistics. Here, we discuss the need for examination of a second category of statistical models in transcriptomic-neuroimaging analyses, namely those that can provide “gene specificity.” By means of a couple of simple examples of commonly performed transcriptomic-neuroimaging analyses, we illustrate some of the potentials and challenges of transcriptomic-imaging analyses, showing that providing gene specificity on observed transcriptomic-neuroimaging effects is of high importance to avoid reports of nonspecific effects. Through means of simulations we show that the rate of reported nonspecific effects (i.e., effects that cannot be specifically linked to a specific gene or gene-set) can run as high as 60%, with only less than 5% of transcriptomic-neuroimaging associations observed through ordinary linear regression analyses showing both spatial and gene specificity. We provide a discussion, a tutorial, and an easy-to-use toolbox for the different options of null models in transcriptomic-neuroimaging analyses.

AB - Multiscale integration of gene transcriptomic and neuroimaging data is becoming a widely used approach for exploring the molecular underpinnings of large-scale brain organization in health and disease. Proper statistical evaluation of determined associations between imaging-based phenotypic and transcriptomic data is key in these explorations, in particular to establish whether observed associations exceed “chance level” of random, nonspecific effects. Recent approaches have shown the importance of statistical models that can correct for spatial autocorrelation effects in the data to avoid inflation of reported statistics. Here, we discuss the need for examination of a second category of statistical models in transcriptomic-neuroimaging analyses, namely those that can provide “gene specificity.” By means of a couple of simple examples of commonly performed transcriptomic-neuroimaging analyses, we illustrate some of the potentials and challenges of transcriptomic-imaging analyses, showing that providing gene specificity on observed transcriptomic-neuroimaging effects is of high importance to avoid reports of nonspecific effects. Through means of simulations we show that the rate of reported nonspecific effects (i.e., effects that cannot be specifically linked to a specific gene or gene-set) can run as high as 60%, with only less than 5% of transcriptomic-neuroimaging associations observed through ordinary linear regression analyses showing both spatial and gene specificity. We provide a discussion, a tutorial, and an easy-to-use toolbox for the different options of null models in transcriptomic-neuroimaging analyses.

UR - https://www.scopus.com/pages/publications/85120870949

UR - https://www.scopus.com/inward/citedby.url?scp=85120870949&partnerID=8YFLogxK

U2 - 10.1002/hbm.25711

DO - 10.1002/hbm.25711

M3 - Article

C2 - 34862695

SN - 1065-9471

VL - 43

SP - 885

EP - 901

JO - Human Brain Mapping

JF - Human Brain Mapping

IS - 3

ER -

Statistical testing in transcriptomic-neuroimaging studies: A how-to and evaluation of methods assessing spatial and gene specificity

Abstract

Bibliographical note

Funding

Access to Document

Persistent URL (handle)

Other files and links

Fingerprint

Cite this