Genome Biology (Feb 2024)

Mapping the functional impact of non-coding regulatory elements in primary T cells through single-cell CRISPR screens

  • Celia Alda-Catalinas,
  • Ximena Ibarra-Soria,
  • Christina Flouri,
  • Jorge Esparza Gordillo,
  • Diana Cousminer,
  • Anna Hutchinson,
  • Bin Sun,
  • William Pembroke,
  • Sebastian Ullrich,
  • Adam Krejci,
  • Adrian Cortes,
  • Alison Acevedo,
  • Sunir Malla,
  • Carl Fishwick,
  • Gerard Drewes,
  • Radu Rapiteanu

DOI
https://doi.org/10.1186/s13059-024-03176-z
Journal volume & issue
Vol. 25, no. 1
pp. 1 – 27

Abstract

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Abstract Background Drug targets with genetic evidence are expected to increase clinical success by at least twofold. Yet, translating disease-associated genetic variants into functional knowledge remains a fundamental challenge of drug discovery. A key issue is that the vast majority of complex disease associations cannot be cleanly mapped to a gene. Immune disease-associated variants are enriched within regulatory elements found in T-cell-specific open chromatin regions. Results To identify genes and molecular programs modulated by these regulatory elements, we develop a CRISPRi-based single-cell functional screening approach in primary human T cells. Our pipeline enables the interrogation of transcriptomic changes induced by the perturbation of regulatory elements at scale. We first optimize an efficient CRISPRi protocol in primary CD4+ T cells via CROPseq vectors. Subsequently, we perform a screen targeting 45 non-coding regulatory elements and 35 transcription start sites and profile approximately 250,000 T -cell single-cell transcriptomes. We develop a bespoke analytical pipeline for element-to-gene (E2G) mapping and demonstrate that our method can identify both previously annotated and novel E2G links. Lastly, we integrate genetic association data for immune-related traits and demonstrate how our platform can aid in the identification of effector genes for GWAS loci. Conclusions We describe “primary T cell crisprQTL” — a scalable, single-cell functional genomics approach for mapping regulatory elements to genes in primary human T cells. We show how this framework can facilitate the interrogation of immune disease GWAS hits and propose that the combination of experimental and QTL-based techniques is likely to address the variant-to-function problem.

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