Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies

LifeLines Cohort Study; Mathias Gorski; Humaira Rasheed; Alexander Teumer; Laurent F Thomas; Sarah E Graham; Gardar Sveinbjornsson; Thomas W Winkler; Felix Günther; Klaus J Stark; Jin-Fang Chai; Bamidele O Tayo; Matthias Wuttke; Yong Li; Adrienne Tin; Tarunveer S Ahluwalia; Johan Ärnlöv; Bjørn Olav Åsvold; Stephan J L Bakker; Bernhard Banas; Nisha Bansal; Mary L Biggs; Ginevra Biino; Michael Böhnke; Eric Boerwinkle; Erwin P Bottinger; Hermann Brenner; Ben Brumpton; Robert J Carroll; Layal Chaker; John Chalmers; Miao-Li Chee; Miao-Ling Chee; Ching-Yu Cheng; Audrey Y Chu; Marina Ciullo; Massimiliano Cocca; James P Cook; Josef Coresh; Daniele Cusi; Martin H de Borst; Frauke Degenhardt; Kai-Uwe Eckardt; Karlhans Endlich; Michele K Evans; Mary F Feitosa; Andre Franke; Sandra Freitag-Wolf; Wolfgang Lieb; Michael H Preuss; Silke Szymczak

doi:10.1016/j.kint.2022.05.021

Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies

LifeLines Cohort Study, Mathias Gorski, Humaira Rasheed, Alexander Teumer, Laurent F Thomas, Sarah E Graham, Gardar Sveinbjornsson, Thomas W Winkler, Felix Günther, Klaus J Stark, Jin-Fang Chai, Bamidele O Tayo, Matthias Wuttke, Yong Li, Adrienne Tin, Tarunveer S Ahluwalia, Johan Ärnlöv, Bjørn Olav Åsvold, Stephan J L Bakker, Bernhard BanasNisha Bansal, Mary L Biggs, Ginevra Biino, Michael Böhnke, Eric Boerwinkle, Erwin P Bottinger, Hermann Brenner, Ben Brumpton, Robert J Carroll, Layal Chaker, John Chalmers, Miao-Li Chee, Miao-Ling Chee, Ching-Yu Cheng, Audrey Y Chu, Marina Ciullo, Massimiliano Cocca, James P Cook, Josef Coresh, Daniele Cusi, Martin H de Borst, Frauke Degenhardt, Kai-Uwe Eckardt, Karlhans Endlich, Michele K Evans, Mary F Feitosa, Andre Franke, Sandra Freitag-Wolf, Wolfgang Lieb, Michael H Preuss, Silke Szymczak

40 Zitate (Scopus)

Abstract

Estimated glomerular filtration rate (eGFR) reflects kidney function. Progressive eGFR-decline can lead to kidney failure, necessitating dialysis or transplantation. Hundreds of loci from genome-wide association studies (GWAS) for eGFR help explain population cross section variability. Since the contribution of these or other loci to eGFR-decline remains largely unknown, we derived GWAS for annual eGFR-decline and meta-analyzed 62 longitudinal studies with eGFR assessed twice over time in all 343,339 individuals and in high-risk groups. We also explored different covariate adjustment. Twelve genome-wide significant independent variants for eGFR-decline unadjusted or adjusted for eGFR-baseline (11 novel, one known for this phenotype), including nine variants robustly associated across models were identified. All loci for eGFR-decline were known for cross-sectional eGFR and thus distinguished a subgroup of eGFR loci. Seven of the nine variants showed variant-by-age interaction on eGFR cross section (further about 350,000 individuals), which linked genetic associations for eGFR-decline with age-dependency of genetic cross-section associations. Clinically important were two to four-fold greater genetic effects on eGFR-decline in high-risk subgroups. Five variants associated also with chronic kidney disease progression mapped to genes with functional in-silico evidence (UMOD, SPATA7, GALNTL5, TPPP). An unfavorable versus favorable nine-variant genetic profile showed increased risk odds ratios of 1.35 for kidney failure (95% confidence intervals 1.03-1.77) and 1.27 for acute kidney injury (95% confidence intervals 1.08-1.50) in over 2000 cases each, with matched controls). Thus, we provide a large data resource, genetic loci, and prioritized genes for kidney function decline, which help inform drug development pipelines revealing important insights into the age-dependency of kidney function genetics.

Originalsprache	Englisch
Zeitschrift	Kidney International
Jahrgang	102
Ausgabenummer	3
Seiten (von - bis)	624-639
Seitenumfang	16
ISSN	0085-2538
DOIs	https://doi.org/10.1016/j.kint.2022.05.021
Publikationsstatus	Veröffentlicht - 09.2022

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10.1016/j.kint.2022.05.021

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LifeLines Cohort Study, Gorski, M., Rasheed, H., Teumer, A., Thomas, L. F., Graham, S. E., Sveinbjornsson, G., Winkler, T. W., Günther, F., Stark, K. J., Chai, J.-F., Tayo, B. O., Wuttke, M., Li, Y., Tin, A., Ahluwalia, T. S., Ärnlöv, J., Åsvold, B. O., Bakker, S. J. L., ... Szymczak, S. (2022). Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies. Kidney International, 102(3), 624-639. https://doi.org/10.1016/j.kint.2022.05.021

@article{122f37238edc444eb5ee409eb1bddd56,

title = "Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies",

abstract = "Estimated glomerular filtration rate (eGFR) reflects kidney function. Progressive eGFR-decline can lead to kidney failure, necessitating dialysis or transplantation. Hundreds of loci from genome-wide association studies (GWAS) for eGFR help explain population cross section variability. Since the contribution of these or other loci to eGFR-decline remains largely unknown, we derived GWAS for annual eGFR-decline and meta-analyzed 62 longitudinal studies with eGFR assessed twice over time in all 343,339 individuals and in high-risk groups. We also explored different covariate adjustment. Twelve genome-wide significant independent variants for eGFR-decline unadjusted or adjusted for eGFR-baseline (11 novel, one known for this phenotype), including nine variants robustly associated across models were identified. All loci for eGFR-decline were known for cross-sectional eGFR and thus distinguished a subgroup of eGFR loci. Seven of the nine variants showed variant-by-age interaction on eGFR cross section (further about 350,000 individuals), which linked genetic associations for eGFR-decline with age-dependency of genetic cross-section associations. Clinically important were two to four-fold greater genetic effects on eGFR-decline in high-risk subgroups. Five variants associated also with chronic kidney disease progression mapped to genes with functional in-silico evidence (UMOD, SPATA7, GALNTL5, TPPP). An unfavorable versus favorable nine-variant genetic profile showed increased risk odds ratios of 1.35 for kidney failure (95\% confidence intervals 1.03-1.77) and 1.27 for acute kidney injury (95\% confidence intervals 1.08-1.50) in over 2000 cases each, with matched controls). Thus, we provide a large data resource, genetic loci, and prioritized genes for kidney function decline, which help inform drug development pipelines revealing important insights into the age-dependency of kidney function genetics.",

author = "\{LifeLines Cohort Study\} and Mathias Gorski and Humaira Rasheed and Alexander Teumer and Thomas, \{Laurent F\} and Graham, \{Sarah E\} and Gardar Sveinbjornsson and Winkler, \{Thomas W\} and Felix G{\"u}nther and Stark, \{Klaus J\} and Jin-Fang Chai and Tayo, \{Bamidele O\} and Matthias Wuttke and Yong Li and Adrienne Tin and Ahluwalia, \{Tarunveer S\} and Johan {\"A}rnl{\"o}v and {\AA}svold, \{Bj{\o}rn Olav\} and Bakker, \{Stephan J L\} and Bernhard Banas and Nisha Bansal and Biggs, \{Mary L\} and Ginevra Biino and Michael B{\"o}hnke and Eric Boerwinkle and Bottinger, \{Erwin P\} and Hermann Brenner and Ben Brumpton and Carroll, \{Robert J\} and Layal Chaker and John Chalmers and Miao-Li Chee and Miao-Ling Chee and Ching-Yu Cheng and Chu, \{Audrey Y\} and Marina Ciullo and Massimiliano Cocca and Cook, \{James P\} and Josef Coresh and Daniele Cusi and \{de Borst\}, \{Martin H\} and Frauke Degenhardt and Kai-Uwe Eckardt and Karlhans Endlich and Evans, \{Michele K\} and Feitosa, \{Mary F\} and Andre Franke and Sandra Freitag-Wolf and Wolfgang Lieb and Preuss, \{Michael H\} and Silke Szymczak",

year = "2022",

month = sep,

doi = "10.1016/j.kint.2022.05.021",

language = "English",

volume = "102",

pages = "624--639",

journal = "Kidney International",

issn = "0085-2538",

publisher = "Elsevier B.V.",

number = "3",

}

LifeLines Cohort Study, Gorski, M, Rasheed, H, Teumer, A, Thomas, LF, Graham, SE, Sveinbjornsson, G, Winkler, TW, Günther, F, Stark, KJ, Chai, J-F, Tayo, BO, Wuttke, M, Li, Y, Tin, A, Ahluwalia, TS, Ärnlöv, J, Åsvold, BO, Bakker, SJL, Banas, B, Bansal, N, Biggs, ML, Biino, G, Böhnke, M, Boerwinkle, E, Bottinger, EP, Brenner, H, Brumpton, B, Carroll, RJ, Chaker, L, Chalmers, J, Chee, M-L, Chee, M-L, Cheng, C-Y, Chu, AY, Ciullo, M, Cocca, M, Cook, JP, Coresh, J, Cusi, D, de Borst, MH, Degenhardt, F, Eckardt, K-U, Endlich, K, Evans, MK, Feitosa, MF, Franke, A, Freitag-Wolf, S, Lieb, W, Preuss, MH & Szymczak, S 2022, 'Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies', Kidney International, Jg. 102, Nr. 3, S. 624-639. https://doi.org/10.1016/j.kint.2022.05.021

Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies. / LifeLines Cohort Study; Gorski, Mathias; Rasheed, Humaira et al.
in: Kidney International, Jahrgang 102, Nr. 3, 09.2022, S. 624-639.

Publikation: Beiträge in Fachzeitschriften › Zeitschriftenaufsätze › Forschung › Begutachtung

TY - JOUR

T1 - Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies

AU - LifeLines Cohort Study

AU - Gorski, Mathias

AU - Rasheed, Humaira

AU - Teumer, Alexander

AU - Thomas, Laurent F

AU - Graham, Sarah E

AU - Sveinbjornsson, Gardar

AU - Winkler, Thomas W

AU - Günther, Felix

AU - Stark, Klaus J

AU - Chai, Jin-Fang

AU - Tayo, Bamidele O

AU - Wuttke, Matthias

AU - Li, Yong

AU - Tin, Adrienne

AU - Ahluwalia, Tarunveer S

AU - Ärnlöv, Johan

AU - Åsvold, Bjørn Olav

AU - Bakker, Stephan J L

AU - Banas, Bernhard

AU - Bansal, Nisha

AU - Biggs, Mary L

AU - Biino, Ginevra

AU - Böhnke, Michael

AU - Boerwinkle, Eric

AU - Bottinger, Erwin P

AU - Brenner, Hermann

AU - Brumpton, Ben

AU - Carroll, Robert J

AU - Chaker, Layal

AU - Chalmers, John

AU - Chee, Miao-Li

AU - Chee, Miao-Ling

AU - Cheng, Ching-Yu

AU - Chu, Audrey Y

AU - Ciullo, Marina

AU - Cocca, Massimiliano

AU - Cook, James P

AU - Coresh, Josef

AU - Cusi, Daniele

AU - de Borst, Martin H

AU - Degenhardt, Frauke

AU - Eckardt, Kai-Uwe

AU - Endlich, Karlhans

AU - Evans, Michele K

AU - Feitosa, Mary F

AU - Franke, Andre

AU - Freitag-Wolf, Sandra

AU - Lieb, Wolfgang

AU - Preuss, Michael H

AU - Szymczak, Silke

PY - 2022/9

Y1 - 2022/9

N2 - Estimated glomerular filtration rate (eGFR) reflects kidney function. Progressive eGFR-decline can lead to kidney failure, necessitating dialysis or transplantation. Hundreds of loci from genome-wide association studies (GWAS) for eGFR help explain population cross section variability. Since the contribution of these or other loci to eGFR-decline remains largely unknown, we derived GWAS for annual eGFR-decline and meta-analyzed 62 longitudinal studies with eGFR assessed twice over time in all 343,339 individuals and in high-risk groups. We also explored different covariate adjustment. Twelve genome-wide significant independent variants for eGFR-decline unadjusted or adjusted for eGFR-baseline (11 novel, one known for this phenotype), including nine variants robustly associated across models were identified. All loci for eGFR-decline were known for cross-sectional eGFR and thus distinguished a subgroup of eGFR loci. Seven of the nine variants showed variant-by-age interaction on eGFR cross section (further about 350,000 individuals), which linked genetic associations for eGFR-decline with age-dependency of genetic cross-section associations. Clinically important were two to four-fold greater genetic effects on eGFR-decline in high-risk subgroups. Five variants associated also with chronic kidney disease progression mapped to genes with functional in-silico evidence (UMOD, SPATA7, GALNTL5, TPPP). An unfavorable versus favorable nine-variant genetic profile showed increased risk odds ratios of 1.35 for kidney failure (95% confidence intervals 1.03-1.77) and 1.27 for acute kidney injury (95% confidence intervals 1.08-1.50) in over 2000 cases each, with matched controls). Thus, we provide a large data resource, genetic loci, and prioritized genes for kidney function decline, which help inform drug development pipelines revealing important insights into the age-dependency of kidney function genetics.

AB - Estimated glomerular filtration rate (eGFR) reflects kidney function. Progressive eGFR-decline can lead to kidney failure, necessitating dialysis or transplantation. Hundreds of loci from genome-wide association studies (GWAS) for eGFR help explain population cross section variability. Since the contribution of these or other loci to eGFR-decline remains largely unknown, we derived GWAS for annual eGFR-decline and meta-analyzed 62 longitudinal studies with eGFR assessed twice over time in all 343,339 individuals and in high-risk groups. We also explored different covariate adjustment. Twelve genome-wide significant independent variants for eGFR-decline unadjusted or adjusted for eGFR-baseline (11 novel, one known for this phenotype), including nine variants robustly associated across models were identified. All loci for eGFR-decline were known for cross-sectional eGFR and thus distinguished a subgroup of eGFR loci. Seven of the nine variants showed variant-by-age interaction on eGFR cross section (further about 350,000 individuals), which linked genetic associations for eGFR-decline with age-dependency of genetic cross-section associations. Clinically important were two to four-fold greater genetic effects on eGFR-decline in high-risk subgroups. Five variants associated also with chronic kidney disease progression mapped to genes with functional in-silico evidence (UMOD, SPATA7, GALNTL5, TPPP). An unfavorable versus favorable nine-variant genetic profile showed increased risk odds ratios of 1.35 for kidney failure (95% confidence intervals 1.03-1.77) and 1.27 for acute kidney injury (95% confidence intervals 1.08-1.50) in over 2000 cases each, with matched controls). Thus, we provide a large data resource, genetic loci, and prioritized genes for kidney function decline, which help inform drug development pipelines revealing important insights into the age-dependency of kidney function genetics.

U2 - 10.1016/j.kint.2022.05.021

DO - 10.1016/j.kint.2022.05.021

M3 - Journal articles

C2 - 35716955

SN - 0085-2538

VL - 102

SP - 624

EP - 639

JO - Kidney International

JF - Kidney International

IS - 3

ER -

Genetic loci and prioritization of genes for kidney function decline derived from a meta-analysis of 62 longitudinal genome-wide association studies

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