Telomemore Enables Single-cell Analysis of Cell Cycle and Chromatin Condensation

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Date 2025 Jan 29

PMID 39878215

Authors

Iryna Yakovenko

Ionut Sebastian Mihai

Martin Selinger

William Rosenbaum

Andy Dernstedt

Remigius Groning

Johan Trygg

Laura Carroll

Mattias Forsell

Johan Henriksson

Affiliations

Soon will be listed here.

Abstract

Single-cell RNA-seq methods can be used to delineate cell types and states at unprecedented resolution but do little to explain why certain genes are expressed. Single-cell ATAC-seq and multiome (ATAC + RNA) have emerged to give a complementary view of the cell state. It is however unclear what additional information can be extracted from ATAC-seq data besides transcription factor binding sites. Here, we show that ATAC-seq telomere-like reads counter-inituively cannot be used to infer telomere length, as they mostly originate from the subtelomere, but can be used as a biomarker for chromatin condensation. Using long-read sequencing, we further show that modern hyperactive Tn5 does not duplicate 9 bp of its target sequence, contrary to common belief. We provide a new tool, Telomemore, which can quantify nonaligning subtelomeric reads. By analyzing several public datasets and generating new multiome fibroblast and B-cell atlases, we show how this new readout can aid single-cell data interpretation. We show how drivers of condensation processes can be inferred, and how it complements common RNA-seq-based cell cycle inference, which fails for monocytes. Telomemore-based analysis of the condensation state is thus a valuable complement to the single-cell analysis toolbox.

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