Clinical-transcriptional prioritization of the circulating proteome in human heart failure

Andrew S. Perry; Kaushik Amancherla; Xiaoning Huang; Michelle L. Lance; Eric Farber-Eger; Priya Gajjar; Junedh Amrute; Lindsey Stolze; Shilin Zhao; Quanhu Sheng; Cassandra M. Joynes; Zhongsheng Peng; Toshiko Tanaka; Stavros G. Drakos; Kory J. Lavine; Craig Selzman; Joseph R. Visker; Thirupura S. Shankar; Luigi Ferrucci; Saumya Das; Jane Wilcox; Ravi B. Patel; Ravi Kalhan; Sanjiv J. Shah; Keenan A. Walker; Quinn Wells; Nathan Tucker; Matthew Nayor; Ravi V. Shah; Sadiya S. Khan

doi:10.1016/j.xcrm.2024.101704

Clinical-transcriptional prioritization of the circulating proteome in human heart failure

Andrew S. Perry, Kaushik Amancherla, Xiaoning Huang, Michelle L. Lance, Eric Farber-Eger, Priya Gajjar, Junedh Amrute, Lindsey Stolze, Shilin Zhao, Quanhu Sheng, Cassandra M. Joynes, Zhongsheng Peng, Toshiko Tanaka, Stavros G. Drakos, Kory J. Lavine, Craig Selzman, Joseph R. Visker, Thirupura S. Shankar, Luigi Ferrucci, Saumya DasJane Wilcox, Ravi B. Patel, Ravi Kalhan, Sanjiv J. Shah, Keenan A. Walker, Quinn Wells, Nathan Tucker, Matthew Nayor, Ravi V. Shah^*, Sadiya S. Khan^*

^*Corresponding author for this work

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

1 Scopus citations

Abstract

Given expanding studies in epidemiology and disease-oriented human studies offering hundreds of associations between the human “ome” and disease, prioritizing molecules relevant to disease mechanisms among this growing breadth is important. Here, we link the circulating proteome to human heart failure (HF) propensity (via echocardiographic phenotyping and clinical outcomes) across the lifespan, demonstrating key pathways of fibrosis, inflammation, metabolism, and hypertrophy. We observe a broad array of genes encoding proteins linked to HF phenotypes and outcomes in clinical populations dynamically expressed at a transcriptional level in human myocardium during HF and cardiac recovery (several in a cell-specific fashion). Many identified targets do not have wide precedent in large-scale genomic discovery or human studies, highlighting the complementary roles for proteomic and tissue transcriptomic discovery to focus epidemiological targets to those relevant in human myocardium for further interrogation.

Original language	English (US)
Article number	101704
Journal	Cell Reports Medicine
Volume	5
Issue number	9
DOIs	https://doi.org/10.1016/j.xcrm.2024.101704
State	Published - Sep 17 2024

Keywords

heart failure
multiomics
proteomics
snRNA-seq
transcriptomics

ASJC Scopus subject areas

General Biochemistry, Genetics and Molecular Biology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.xcrm.2024.101704

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Perry, A. S., Amancherla, K., Huang, X., Lance, M. L., Farber-Eger, E., Gajjar, P., Amrute, J., Stolze, L., Zhao, S., Sheng, Q., Joynes, C. M., Peng, Z., Tanaka, T., Drakos, S. G., Lavine, K. J., Selzman, C., Visker, J. R., Shankar, T. S., Ferrucci, L., ... Khan, S. S. (2024). Clinical-transcriptional prioritization of the circulating proteome in human heart failure. Cell Reports Medicine, 5(9), Article 101704. https://doi.org/10.1016/j.xcrm.2024.101704

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title = "Clinical-transcriptional prioritization of the circulating proteome in human heart failure",

abstract = "Given expanding studies in epidemiology and disease-oriented human studies offering hundreds of associations between the human “ome” and disease, prioritizing molecules relevant to disease mechanisms among this growing breadth is important. Here, we link the circulating proteome to human heart failure (HF) propensity (via echocardiographic phenotyping and clinical outcomes) across the lifespan, demonstrating key pathways of fibrosis, inflammation, metabolism, and hypertrophy. We observe a broad array of genes encoding proteins linked to HF phenotypes and outcomes in clinical populations dynamically expressed at a transcriptional level in human myocardium during HF and cardiac recovery (several in a cell-specific fashion). Many identified targets do not have wide precedent in large-scale genomic discovery or human studies, highlighting the complementary roles for proteomic and tissue transcriptomic discovery to focus epidemiological targets to those relevant in human myocardium for further interrogation.",

keywords = "heart failure, multiomics, proteomics, snRNA-seq, transcriptomics",

author = "Perry, {Andrew S.} and Kaushik Amancherla and Xiaoning Huang and Lance, {Michelle L.} and Eric Farber-Eger and Priya Gajjar and Junedh Amrute and Lindsey Stolze and Shilin Zhao and Quanhu Sheng and Joynes, {Cassandra M.} and Zhongsheng Peng and Toshiko Tanaka and Drakos, {Stavros G.} and Lavine, {Kory J.} and Craig Selzman and Visker, {Joseph R.} and Shankar, {Thirupura S.} and Luigi Ferrucci and Saumya Das and Jane Wilcox and Patel, {Ravi B.} and Ravi Kalhan and Shah, {Sanjiv J.} and Walker, {Keenan A.} and Quinn Wells and Nathan Tucker and Matthew Nayor and Shah, {Ravi V.} and Khan, {Sadiya S.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors",

year = "2024",

month = sep,

day = "17",

doi = "10.1016/j.xcrm.2024.101704",

language = "English (US)",

volume = "5",

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Perry, AS, Amancherla, K, Huang, X, Lance, ML, Farber-Eger, E, Gajjar, P, Amrute, J, Stolze, L, Zhao, S, Sheng, Q, Joynes, CM, Peng, Z, Tanaka, T, Drakos, SG, Lavine, KJ, Selzman, C, Visker, JR, Shankar, TS, Ferrucci, L, Das, S, Wilcox, J , Patel, RB , Kalhan, R , Shah, SJ, Walker, KA, Wells, Q, Tucker, N, Nayor, M, Shah, RV & Khan, SS 2024, 'Clinical-transcriptional prioritization of the circulating proteome in human heart failure', Cell Reports Medicine, vol. 5, no. 9, 101704. https://doi.org/10.1016/j.xcrm.2024.101704

TY - JOUR

T1 - Clinical-transcriptional prioritization of the circulating proteome in human heart failure

AU - Perry, Andrew S.

AU - Amancherla, Kaushik

AU - Huang, Xiaoning

AU - Lance, Michelle L.

AU - Farber-Eger, Eric

AU - Gajjar, Priya

AU - Amrute, Junedh

AU - Stolze, Lindsey

AU - Zhao, Shilin

AU - Sheng, Quanhu

AU - Joynes, Cassandra M.

AU - Peng, Zhongsheng

AU - Tanaka, Toshiko

AU - Drakos, Stavros G.

AU - Lavine, Kory J.

AU - Selzman, Craig

AU - Visker, Joseph R.

AU - Shankar, Thirupura S.

AU - Ferrucci, Luigi

AU - Das, Saumya

AU - Wilcox, Jane

AU - Patel, Ravi B.

AU - Kalhan, Ravi

AU - Shah, Sanjiv J.

AU - Walker, Keenan A.

AU - Wells, Quinn

AU - Tucker, Nathan

AU - Nayor, Matthew

AU - Shah, Ravi V.

AU - Khan, Sadiya S.

PY - 2024/9/17

Y1 - 2024/9/17

N2 - Given expanding studies in epidemiology and disease-oriented human studies offering hundreds of associations between the human “ome” and disease, prioritizing molecules relevant to disease mechanisms among this growing breadth is important. Here, we link the circulating proteome to human heart failure (HF) propensity (via echocardiographic phenotyping and clinical outcomes) across the lifespan, demonstrating key pathways of fibrosis, inflammation, metabolism, and hypertrophy. We observe a broad array of genes encoding proteins linked to HF phenotypes and outcomes in clinical populations dynamically expressed at a transcriptional level in human myocardium during HF and cardiac recovery (several in a cell-specific fashion). Many identified targets do not have wide precedent in large-scale genomic discovery or human studies, highlighting the complementary roles for proteomic and tissue transcriptomic discovery to focus epidemiological targets to those relevant in human myocardium for further interrogation.

AB - Given expanding studies in epidemiology and disease-oriented human studies offering hundreds of associations between the human “ome” and disease, prioritizing molecules relevant to disease mechanisms among this growing breadth is important. Here, we link the circulating proteome to human heart failure (HF) propensity (via echocardiographic phenotyping and clinical outcomes) across the lifespan, demonstrating key pathways of fibrosis, inflammation, metabolism, and hypertrophy. We observe a broad array of genes encoding proteins linked to HF phenotypes and outcomes in clinical populations dynamically expressed at a transcriptional level in human myocardium during HF and cardiac recovery (several in a cell-specific fashion). Many identified targets do not have wide precedent in large-scale genomic discovery or human studies, highlighting the complementary roles for proteomic and tissue transcriptomic discovery to focus epidemiological targets to those relevant in human myocardium for further interrogation.

KW - heart failure

KW - multiomics

KW - proteomics

KW - snRNA-seq

KW - transcriptomics

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U2 - 10.1016/j.xcrm.2024.101704

DO - 10.1016/j.xcrm.2024.101704

M3 - Article

C2 - 39226894

AN - SCOPUS:85204510565

SN - 2666-3791

VL - 5

JO - Cell Reports Medicine

JF - Cell Reports Medicine

IS - 9

M1 - 101704

ER -

Clinical-transcriptional prioritization of the circulating proteome in human heart failure

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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