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Related Experiment Video

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

Jorge Blanco Mendana1, Margaret Donovan1, Lindsey Gengelbach O'Brien1

  • 1University of Minnesota Genomics Center, Minneapolis, Minneapolis, United States.

Elife
|February 5, 2025
PubMed
Summary

Targeted Genetically-Encoded Multiplexing (TaG-EM) uses genetic barcoding in Drosophila to label specific cell populations. This method enables precise cell type identification in transcriptomic atlases and facilitates large-scale behavioral studies.

Keywords:
D. melanogasterbehaviorgenetic barcodinggeneticsgenomicsnext-generation sequencingsingle-cell transcriptomics

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Area of Science:

  • Developmental Biology
  • Genomics
  • Neuroscience

Background:

  • Single-cell sequencing reveals gene expression dynamics and cellular heterogeneity.
  • Linking anatomical data to transcriptomic clusters and identifying cell types remains challenging.
  • Existing methods lack efficient in vivo cell population tagging for transcriptomic analysis.

Purpose of the Study:

  • To develop a genetic barcoding method for in vivo tagging of specific cell populations in Drosophila.
  • To enable positive identification of cell types within single-cell sequencing datasets.
  • To facilitate population-scale behavioral measurements using next-generation sequencing.

Main Methods:

  • Developed Targeted Genetically-Encoded Multiplexing (TaG-EM) using DNA barcodes inserted into UAS-GFP constructs.
  • Utilized Drosophila genetic tools for targeted in vivo labeling of cell populations.
  • Read out DNA barcodes via next-generation sequencing.

Main Results:

  • TaG-EM allows for the in vivo tagging of defined cell populations with unique DNA barcodes.
  • Barcodes enable positive identification of cell types in transcriptomic atlases and detection of multiplet droplets.
  • TaG-EM facilitates population-scale behavioral measurements through next-generation sequencing.

Conclusions:

  • TaG-EM provides a straightforward approach for multiplexing and reliably annotating single-cell transcriptomic experiments.
  • The method enhances the ability to link gene expression data with anatomical information.
  • TaG-EM opens possibilities for large-scale behavioral screens in Drosophila.