Deterministic Genetic Barcoding for Multiplexed Behavioral and Single-cell Transcriptomic Studies

Overview

Journal Elife

Date 2025 Feb 5

PMID 39908076

Authors

Jorge Blanco Mendana

Margaret Donovan

Lindsey Gengelbach OBrien

Benjamin Auch

John Garbe

Daryl M Gohl

Affiliations

Soon will be listed here.

Abstract

Advances in single-cell sequencing technologies have provided novel insights into the dynamics of gene expression and cellular heterogeneity within tissues and have enabled the construction of transcriptomic cell atlases. However, linking anatomical information to transcriptomic data and positively identifying the cell types that correspond to gene expression clusters in single-cell sequencing data sets remains a challenge. We describe a straightforward genetic barcoding approach that takes advantage of the powerful genetic tools in to allow in vivo tagging of defined cell populations. This method, called rgeted enetically-ncoded ultiplexing (TaG-EM), involves inserting a DNA barcode just upstream of the polyadenylation site in a Gal4-inducible construct so that the barcode sequence can be read out during single-cell sequencing, labeling a cell population of interest. By creating many such independently barcoded fly strains, TaG-EM enables positive identification of cell types in cell atlas projects, identification of multiplet droplets, and barcoding of experimental timepoints, conditions, and replicates. Furthermore, we demonstrate that TaG-EM barcodes can be read out using next-generation sequencing to facilitate population-scale behavioral measurements. Thus, TaG-EM has the potential to enable large-scale behavioral screens in addition to improving the ability to multiplex and reliably annotate single-cell transcriptomic experiments.

Citing Articles

Deterministic genetic barcoding for multiplexed behavioral and single-cell transcriptomic studies.

Blanco Mendana J, Donovan M, OBrien L, Auch B, Garbe J, Gohl D Elife. 2025; 12.

PMID: 39908076 PMC: 11798575. DOI: 10.7554/eLife.88334.

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