Opportunities for RNA sequencing in physiology: from big data to understanding homeostasis and heterogeneity.

Authors

Jeremy W. Prokop, Corewell Health West
Stephanie M Bilinovich
Ember Tokarski
Sangeetha Vishweswaraiah
Sophie VanderWeele
Akansha S Das
Surya B Chhetri
Alexander Dao
Sanjana Arora, Corewell Health West
Austin Goodyke, Corewell Health West
Katie L Buelow, Corewell Health East
Mason Westgate, Corewell Health West
Elizabeth A. VanSickle, Corewell Health West
Claudia J Edell
Lance N Benson
Daniel B Campbell
Caleb P. Bupp, Corewell Health West
Amanda Holsworth, Corewell Health West
Nicholas L. Hartog, Corewell Health West
Jena M. Krueger, Corewell Health West
Marcos Cordoba, Corewell Health West
Matthew Sims, Corewell Health East
Maximiliano A. Tamae Kakazu, Corewell Health West
Angela M. Peraino, Corewell Health West
Stewart Graham, Corewell Health East
Tim Triche
Elora Hussain, Corewell Heath East
Mara L. Leimanis-Laurens, Corewell Health West
Connie M Krawczyk
Jennifer S Pollock
Surender Rajasekaran, Corewell Health West

Document Type

Article

Publication Date

2-1-2026

Publication Title

Function (Oxford, England)

Abstract

The quantity of physiological data has grown exponentially, yielding insights into mechanisms of phenotypic and disease pathways. Among the powerful tools for physiological omics is the study of RNA, where broad sequencing of RNA leads to hypothesis generation and testing while providing observational discovery. Emphasis has been placed on RNA molecules that code for proteins, even though they represent a minority of total RNA. Diverse sequencing methods have rapidly expanded the identification of non-protein-coding molecules, including nonsense-mediated decay and long non-coding RNAs (lncRNA), which now represent the most diverse class of RNA. Increasing attention needs to be paid to the data processing of RNA sequencing to interpret transcript-level mapping data in the context of protein biology, as many protein-coding genes have diverse noncoding transcripts. Over the past several years, single-cell and spatial transcriptomics have yielded unprecedented insights into cellular, tissue, and organ physiology. Building on these advancements, bulk RNA sequencing tools have begun producing robust deconvolution methods that enhance the analysis of human genes, the detection of foreign RNA from bacteria and viruses, and provide deep insights into complex immunological events, such as B- and T-cell recombination. Over a million RNA-sequencing datasets have been generated, providing resources for data scientists to reprocess data and expand larger databases. From model organisms to complex human diseases, RNA sequencing resources continue to transform our knowledge of the complexity of personalized disease insights. Observational science is at the core of physiology, and growth of RNA sequencing represents a significant tool for physiologists.

Volume

7

Issue

1

First Page

0192025

Recommended Citation

Prokop JW, Bilinovich SM, Tokarski E, Vishweswaraiah S, VanderWeele S, Das AS et al Arora S, Goodyke A, Buelow KL, Westgate M, VanSickle EA, Bupp CP, Holsworth A, Hartog NL, Krueger JM, Cordoba M, Sims M, Tamae Kakazu MA, Peraino AM, Graham SF, Hussain E, Leimanis-Laurens ML, Rajasekaran S] Opportunities for RNA sequencing in physiology: from big data to understanding homeostasis and heterogeneity. Function (Oxf). 2026 Feb 1;7(1):e0192025. doi: 10.1152/function.019.2025. PMID: 41401424.

DOI

10.1152/function.019.2025

ISSN

2633-8823

PubMed ID

41401424