Sex differences in brain protein expression and disease

Aliza P. Wingo; Yue Liu; Ekaterina S. Gerasimov; Selina M. Vattathil; Jiaqi Liu; David J. Cutler; Michael P. Epstein; Gabriëlla A.M. Blokland; Madhav Thambisetty; Juan C. Troncoso; Duc M. Duong; David A. Bennett; Allan I. Levey; Nicholas T. Seyfried; Thomas S. Wingo

doi:10.1038/s41591-023-02509-y

Sex differences in brain protein expression and disease

Aliza P. Wingo^*, Yue Liu, Ekaterina S. Gerasimov, Selina M. Vattathil, Jiaqi Liu, David J. Cutler, Michael P. Epstein, Gabriëlla A.M. Blokland, Madhav Thambisetty, Juan C. Troncoso, Duc M. Duong, David A. Bennett, Allan I. Levey, Nicholas T. Seyfried, Thomas S. Wingo^*

^*Corresponding author for this work

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

Abstract

Most complex human traits differ by sex, but we have limited insight into the underlying mechanisms. Here, we investigated the influence of biological sex on protein expression and its genetic regulation in 1,277 human brain proteomes. We found that 13.2% (1,354) of brain proteins had sex-differentiated abundance and 1.5% (150) of proteins had sex-biased protein quantitative trait loci (sb-pQTLs). Among genes with sex-biased expression, we found 67% concordance between sex-differentiated protein and transcript levels; however, sex effects on the genetic regulation of expression were more evident at the protein level. Considering 24 psychiatric, neurologic and brain morphologic traits, we found that an average of 25% of their putatively causal genes had sex-differentiated protein abundance and 12 putatively causal proteins had sb-pQTLs. Furthermore, integrating sex-specific pQTLs with sex-stratified genome-wide association studies of six psychiatric and neurologic conditions, we uncovered another 23 proteins contributing to these traits in one sex but not the other. Together, these findings begin to provide insights into mechanisms underlying sex differences in brain protein expression and disease.

Original language	English
Pages (from-to)	2224–2232
Number of pages	9
Journal	Nature Medicine
Volume	29
DOIs	https://doi.org/10.1038/s41591-023-02509-y
Publication status	Published - Sept 2023

Keywords

SYSTEMIC-LUPUS-ERYTHEMATOSUS
GENETIC ARCHITECTURE
ADAPTER PROTEIN
KINASE-A
ASSOCIATION
DISORDERS
MICROGLIA
GALECTIN-3
PATHWAY
STXBP3

Access to Document

10.1038/s41591-023-02509-yLicence: CC BY

Cite this

Wingo, A. P., Liu, Y., Gerasimov, E. S., Vattathil, S. M., Liu, J., Cutler, D. J., Epstein, M. P., Blokland, G. A. M., Thambisetty, M., Troncoso, J. C., Duong, D. M., Bennett, D. A., Levey, A. I., Seyfried, N. T., & Wingo, T. S. (2023). Sex differences in brain protein expression and disease. Nature Medicine, 29, 2224–2232. https://doi.org/10.1038/s41591-023-02509-y

@article{437306dd87c840b7a67319448ae2f2de,

title = "Sex differences in brain protein expression and disease",

abstract = "Most complex human traits differ by sex, but we have limited insight into the underlying mechanisms. Here, we investigated the influence of biological sex on protein expression and its genetic regulation in 1,277 human brain proteomes. We found that 13.2% (1,354) of brain proteins had sex-differentiated abundance and 1.5% (150) of proteins had sex-biased protein quantitative trait loci (sb-pQTLs). Among genes with sex-biased expression, we found 67% concordance between sex-differentiated protein and transcript levels; however, sex effects on the genetic regulation of expression were more evident at the protein level. Considering 24 psychiatric, neurologic and brain morphologic traits, we found that an average of 25% of their putatively causal genes had sex-differentiated protein abundance and 12 putatively causal proteins had sb-pQTLs. Furthermore, integrating sex-specific pQTLs with sex-stratified genome-wide association studies of six psychiatric and neurologic conditions, we uncovered another 23 proteins contributing to these traits in one sex but not the other. Together, these findings begin to provide insights into mechanisms underlying sex differences in brain protein expression and disease.",

keywords = "SYSTEMIC-LUPUS-ERYTHEMATOSUS, GENETIC ARCHITECTURE, ADAPTER PROTEIN, KINASE-A, ASSOCIATION, DISORDERS, MICROGLIA, GALECTIN-3, PATHWAY, STXBP3",

author = "Wingo, {Aliza P.} and Yue Liu and Gerasimov, {Ekaterina S.} and Vattathil, {Selina M.} and Jiaqi Liu and Cutler, {David J.} and Epstein, {Michael P.} and Blokland, {Gabri{\"e}lla A.M.} and Madhav Thambisetty and Troncoso, {Juan C.} and Duong, {Duc M.} and Bennett, {David A.} and Levey, {Allan I.} and Seyfried, {Nicholas T.} and Wingo, {Thomas S.}",

note = "Funding Information: We are grateful to participants of the BLSA, ROS/MAP, Banner Sun Health Research Institute studies and the Mount Sinai Brain Bank. This work was supported by grant nos. P30AG010161 (D.A.B.), P30AG072975 (D.A.B.), R01AG015819 (D.A.B.), R01AG017917 (D.A.B.), U01AG061356 (D.A.B.); I01 BX003853 (A.P.W.); IK4 BX005219 (A.P.W.); I01 BX005686 (A.P.W.); R01 AG072120 (A.P.W. and T.S.W.); R01 AG075827 (T.S.W. and A.P.W.); R01 AG056533 (T.S.W. and A.P.W.), RF1AG071170 (M.P.E. and D.J.C.), P30 AG066507 (J.C.T.), U19AG033655 (J.C.T.), P30 AG066511 (A.I.L.), U01 AG061357 (A.I.L., N.T.S.) and U54 AG065187 (A.I.L.), and in part by the intramural program of the National Institute on Aging. The views expressed in this work do not necessarily represent the views of the Veterans Administration or the United States Government. Publisher Copyright: {\textcopyright} 2023, This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.",

year = "2023",

month = sep,

doi = "10.1038/s41591-023-02509-y",

language = "English",

volume = "29",

pages = "2224–2232",

journal = "Nature Medicine",

issn = "1078-8956",

publisher = "Nature Publishing Group",

}

TY - JOUR

T1 - Sex differences in brain protein expression and disease

AU - Wingo, Aliza P.

AU - Liu, Yue

AU - Gerasimov, Ekaterina S.

AU - Vattathil, Selina M.

AU - Liu, Jiaqi

AU - Cutler, David J.

AU - Epstein, Michael P.

AU - Blokland, Gabriëlla A.M.

AU - Thambisetty, Madhav

AU - Troncoso, Juan C.

AU - Duong, Duc M.

AU - Bennett, David A.

AU - Levey, Allan I.

AU - Seyfried, Nicholas T.

AU - Wingo, Thomas S.

N1 - Funding Information: We are grateful to participants of the BLSA, ROS/MAP, Banner Sun Health Research Institute studies and the Mount Sinai Brain Bank. This work was supported by grant nos. P30AG010161 (D.A.B.), P30AG072975 (D.A.B.), R01AG015819 (D.A.B.), R01AG017917 (D.A.B.), U01AG061356 (D.A.B.); I01 BX003853 (A.P.W.); IK4 BX005219 (A.P.W.); I01 BX005686 (A.P.W.); R01 AG072120 (A.P.W. and T.S.W.); R01 AG075827 (T.S.W. and A.P.W.); R01 AG056533 (T.S.W. and A.P.W.), RF1AG071170 (M.P.E. and D.J.C.), P30 AG066507 (J.C.T.), U19AG033655 (J.C.T.), P30 AG066511 (A.I.L.), U01 AG061357 (A.I.L., N.T.S.) and U54 AG065187 (A.I.L.), and in part by the intramural program of the National Institute on Aging. The views expressed in this work do not necessarily represent the views of the Veterans Administration or the United States Government. Publisher Copyright: © 2023, This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.

PY - 2023/9

Y1 - 2023/9

N2 - Most complex human traits differ by sex, but we have limited insight into the underlying mechanisms. Here, we investigated the influence of biological sex on protein expression and its genetic regulation in 1,277 human brain proteomes. We found that 13.2% (1,354) of brain proteins had sex-differentiated abundance and 1.5% (150) of proteins had sex-biased protein quantitative trait loci (sb-pQTLs). Among genes with sex-biased expression, we found 67% concordance between sex-differentiated protein and transcript levels; however, sex effects on the genetic regulation of expression were more evident at the protein level. Considering 24 psychiatric, neurologic and brain morphologic traits, we found that an average of 25% of their putatively causal genes had sex-differentiated protein abundance and 12 putatively causal proteins had sb-pQTLs. Furthermore, integrating sex-specific pQTLs with sex-stratified genome-wide association studies of six psychiatric and neurologic conditions, we uncovered another 23 proteins contributing to these traits in one sex but not the other. Together, these findings begin to provide insights into mechanisms underlying sex differences in brain protein expression and disease.

AB - Most complex human traits differ by sex, but we have limited insight into the underlying mechanisms. Here, we investigated the influence of biological sex on protein expression and its genetic regulation in 1,277 human brain proteomes. We found that 13.2% (1,354) of brain proteins had sex-differentiated abundance and 1.5% (150) of proteins had sex-biased protein quantitative trait loci (sb-pQTLs). Among genes with sex-biased expression, we found 67% concordance between sex-differentiated protein and transcript levels; however, sex effects on the genetic regulation of expression were more evident at the protein level. Considering 24 psychiatric, neurologic and brain morphologic traits, we found that an average of 25% of their putatively causal genes had sex-differentiated protein abundance and 12 putatively causal proteins had sb-pQTLs. Furthermore, integrating sex-specific pQTLs with sex-stratified genome-wide association studies of six psychiatric and neurologic conditions, we uncovered another 23 proteins contributing to these traits in one sex but not the other. Together, these findings begin to provide insights into mechanisms underlying sex differences in brain protein expression and disease.

KW - SYSTEMIC-LUPUS-ERYTHEMATOSUS

KW - GENETIC ARCHITECTURE

KW - ADAPTER PROTEIN

KW - KINASE-A

KW - ASSOCIATION

KW - DISORDERS

KW - MICROGLIA

KW - GALECTIN-3

KW - PATHWAY

KW - STXBP3

U2 - 10.1038/s41591-023-02509-y

DO - 10.1038/s41591-023-02509-y

M3 - Article

SN - 1078-8956

VL - 29

SP - 2224

EP - 2232

JO - Nature Medicine

JF - Nature Medicine

ER -