TY - JOUR
T1 - Correction for both common and rare cell types in blood is important to identify genes that correlate with age
AU - BIOS Consortium
AU - Pellegrino-Coppola, Damiano
AU - Claringbould, Annique
AU - Stutvoet, Maartje
AU - Heijmans, Bastiaan T.
AU - ‘t Hoen, Peter A.C.
AU - van Meurs, Joyce
AU - Isaacs, Aaron
AU - Jansen, Rick
AU - Franke, Lude
AU - Pool, René
AU - van Dongen, Jenny
AU - Hottenga, Jouke J.
AU - van Greevenbroek, Marleen M.J.
AU - Stehouwer, Coen D.A.
AU - van der Kallen, Carla J.H.
AU - Schalkwijk, Casper G.
AU - Wijmenga, Cisca
AU - Zhernakova, Sasha
AU - Tigchelaar, Ettje F.
AU - Beekman, Marian
AU - Deelen, Joris
AU - van Heemst, Diana
AU - Veldink, Jan H.
AU - van den Berg, Leonard H.
AU - van Duijn, Cornelia M.
AU - Hofman, Bert A.
AU - Uitterlinden, André G.
AU - Jhamai, P. Mila
AU - Verbiest, Michael
AU - Suchiman, H. Eka D.
AU - Verkerk, Marijn
AU - van der Breggen, Ruud
AU - van Rooij, Jeroen
AU - Lakenberg, Nico
AU - Mei, Hailiang
AU - van Iterson, Maarten
AU - van Galen, Michiel
AU - Bot, Jan
AU - Zhernakova, Dasha V.
AU - van ‘t Hof, Peter
AU - Deelen, Patrick
AU - Nooren, Irene
AU - Moed, Matthijs
AU - Luijk, René
AU - Bonder, Marc Jan
AU - van Dijk, Freerk
AU - Arindrarto, Wibowo
AU - Kielbasa, Szymon M.
AU - Swertz, Morris A.
AU - van Zwet, Erik W.
N1 - Publisher Copyright:
© 2021, The Author(s).
PY - 2021/12
Y1 - 2021/12
N2 - Background: Aging is a multifactorial process that affects multiple tissues and is characterized by changes in homeostasis over time, leading to increased morbidity. Whole blood gene expression signatures have been associated with aging and have been used to gain information on its biological mechanisms, which are still not fully understood. However, blood is composed of many cell types whose proportions in blood vary with age. As a result, previously observed associations between gene expression levels and aging might be driven by cell type composition rather than intracellular aging mechanisms. To overcome this, previous aging studies already accounted for major cell types, but the possibility that the reported associations are false positives driven by less prevalent cell subtypes remains. Results: Here, we compared the regression model from our previous work to an extended model that corrects for 33 additional white blood cell subtypes. Both models were applied to whole blood gene expression data from 3165 individuals belonging to the general population (age range of 18–81 years). We evaluated that the new model is a better fit for the data and it identified fewer genes associated with aging (625, compared to the 2808 of the initial model; P ≤ 2.5⨯10−6). Moreover, 511 genes (~ 18% of the 2808 genes identified by the initial model) were found using both models, indicating that the other previously reported genes could be proxies for less abundant cell types. In particular, functional enrichment of the genes identified by the new model highlighted pathways and GO terms specifically associated with platelet activity. Conclusions: We conclude that gene expression analyses in blood strongly benefit from correction for both common and rare blood cell types, and recommend using blood-cell count estimates as standard covariates when studying whole blood gene expression.
AB - Background: Aging is a multifactorial process that affects multiple tissues and is characterized by changes in homeostasis over time, leading to increased morbidity. Whole blood gene expression signatures have been associated with aging and have been used to gain information on its biological mechanisms, which are still not fully understood. However, blood is composed of many cell types whose proportions in blood vary with age. As a result, previously observed associations between gene expression levels and aging might be driven by cell type composition rather than intracellular aging mechanisms. To overcome this, previous aging studies already accounted for major cell types, but the possibility that the reported associations are false positives driven by less prevalent cell subtypes remains. Results: Here, we compared the regression model from our previous work to an extended model that corrects for 33 additional white blood cell subtypes. Both models were applied to whole blood gene expression data from 3165 individuals belonging to the general population (age range of 18–81 years). We evaluated that the new model is a better fit for the data and it identified fewer genes associated with aging (625, compared to the 2808 of the initial model; P ≤ 2.5⨯10−6). Moreover, 511 genes (~ 18% of the 2808 genes identified by the initial model) were found using both models, indicating that the other previously reported genes could be proxies for less abundant cell types. In particular, functional enrichment of the genes identified by the new model highlighted pathways and GO terms specifically associated with platelet activity. Conclusions: We conclude that gene expression analyses in blood strongly benefit from correction for both common and rare blood cell types, and recommend using blood-cell count estimates as standard covariates when studying whole blood gene expression.
KW - Aging
KW - Cell counts correction
KW - Gene expression
KW - Platelet activity
KW - Whole blood
UR - http://www.scopus.com/inward/record.url?scp=85102912904&partnerID=8YFLogxK
U2 - 10.1186/s12864-020-07344-w
DO - 10.1186/s12864-020-07344-w
M3 - Article
C2 - 33722199
AN - SCOPUS:85102912904
SN - 1471-2164
VL - 22
JO - BMC Genomics
JF - BMC Genomics
IS - 1
M1 - 184
ER -