The Subcellular Distribution of miRNA Isoforms, tRNA-Derived Fragments, and rRNA-Derived Fragments Depends on Nucleotide Sequence and Cell Type

Authors

Tess Cherlin, Thomas Jefferson UniversityFollow
Yi Jing, Thomas Jefferson UniversityFollow
Siddhartha Shah, Thomas Jefferson University
Anne Kennedy, Thomas Jefferson UniversityFollow
Aristeidis Telonis, Thomas Jefferson UniversityFollow
Venetia Pliatsika, Thomas Jefferson UniversityFollow
Haley Wilson, Thomas Jefferson UniversityFollow
Lily Thompson, Thomas Jefferson UniversityFollow
Panagiotis Vlantis, Thomas Jefferson University
Phillipe Loher, Thomas Jefferson UniversityFollow
Benjamin Leiby, Thomas Jefferson UniversityFollow
Isidore Rigoutsos, Thomas Jefferson UniversityFollow

Document Type

Article

Publication Date

9-12-2024

Comments

This article is the author's final published version in BMC Biology, Volume 22, Issue 1, 2024, Article number 205.

The published version is available at https://doi.org/10.1186/s12915-024-01970-6.

Copyright © The Author(s) 2024

Abstract

BACKGROUND: MicroRNA isoforms (isomiRs), tRNA-derived fragments (tRFs), and rRNA-derived fragments (rRFs) represent most of the small non-coding RNAs (sncRNAs) found in cells. Members of these three classes modulate messenger RNA (mRNA) and protein abundance and are dysregulated in diseases. Experimental studies to date have assumed that the subcellular distribution of these molecules is well-understood, independent of cell type, and the same for all isoforms of a sncRNA.

RESULTS: We tested these assumptions by investigating the subcellular distribution of isomiRs, tRFs, and rRFs in biological replicates from three cell lines from the same tissue and same-sex donors that model the same cancer subtype. In each cell line, we profiled the isomiRs, tRFs, and rRFs in the nucleus, cytoplasm, whole mitochondrion (MT), mitoplast (MP), and whole cell. Using a rigorous mathematical model we developed, we accounted for cross-fraction contamination and technical errors and adjusted the measured abundances accordingly. Analyses of the adjusted abundances show that isomiRs, tRFs, and rRFs exhibit complex patterns of subcellular distributions. These patterns depend on each sncRNA's exact sequence and the cell type. Even in the same cell line, isoforms of the same sncRNA whose sequences differ by a few nucleotides (nts) can have different subcellular distributions.

CONCLUSIONS: SncRNAs with similar sequences have different subcellular distributions within and across cell lines, suggesting that each isoform could have a different function. Future computational and experimental studies of isomiRs, tRFs, and rRFs will need to distinguish among each molecule's various isoforms and account for differences in each isoform's subcellular distribution in the cell line at hand. While the findings add to a growing body of evidence that isomiRs, tRFs, rRFs, tRNAs, and rRNAs follow complex intracellular trafficking rules, further investigation is needed to exclude alternative explanations for the observed subcellular distribution of sncRNAs.

Recommended Citation

Cherlin, Tess; Jing, Yi; Shah, Siddhartha; Kennedy, Anne; Telonis, Aristeidis; Pliatsika, Venetia; Wilson, Haley; Thompson, Lily; Vlantis, Panagiotis; Loher, Phillipe; Leiby, Benjamin; and Rigoutsos, Isidore, "The Subcellular Distribution of miRNA Isoforms, tRNA-Derived Fragments, and rRNA-Derived Fragments Depends on Nucleotide Sequence and Cell Type" (2024). Computational Medicine Center Faculty Papers. Paper 58.
https://jdc.jefferson.edu/tjucompmedctrfp/58

Creative Commons License

This work is licensed under a Creative Commons Attribution-Noncommercial-No Derivative Works 4.0 License.

PubMed ID

39267057

Language

English