Genome-wide Chromosome-specific Aneuploidy Engineering and Phenotypic Characterization with CRISPR-Taiji

  1. Hugang Feng
  2. Daqi Deng
  3. Rashmi Dahiya
  4. Libin Wang
  5. Jingkun Zeng
  6. Benjy Jek Yang Tan
  7. Fiona Byrne
  8. Scott T. C. Shepherd
  9. Jiahao Wang
  10. Sarah C. Johnson
  11. Alison Harrod
  12. Karen A. Lane
  13. Annika Fendler
  14. Anne-Laure Cattin
  15. Zayd Tippu
  16. Meilun Nie
  17. Yiming Zhao
  18. Ruijia Wang
  19. Wei Ai
  20. Omar Bouricha
  21. Taja Barber
  22. Yuliia Dovga
  23. Yihan Xu
  24. Weiming Shen
  25. Zhen Sun
  26. Hongye Wang
  27. Jiufei Zhu
  28. Yimeng Xu
  29. Liani G. Devito
  30. Lyn Healy
  31. Eugénie S. Lim
  32. Samuel M. O’Toole
  33. Scott Akker
  34. William M. Drake
  35. Haojie Jin
  36. Jessica A. Downs
  37. Sarah E. McClelland
  38. John F. X. Diffley
  39. Peter Ly
  40. Samra Turajlic
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Abstract

Aneuploidy, the gain or loss of chromosomes, is prevalent in both normal and disease conditions, however, experimental approaches to engineer and study aneuploidy remain limited, leaving its functional significance under-characterized. Here, we present CRISPR-Taiji (CRISPRt), an efficient method for inducing chromosome-specific mis-segregation and aneuploidy generation across all 24 human chromosomes via dead Cas9 (dCas9)-induced centromeric chromatin relaxation. Using CRISPRt with scRNA-seq, we generated the first comprehensive transcriptomic alteration landscape of nearly all autosomal aneuploidies at chromosome-arm resolution. This genotype-phenotype map provides causal evidence linking recurrent aneuploidies in clear cell renal cell carcinoma (ccRCC) to molecular and clinical phenotypes observed in patient tumors. Notably, chromosome 3(p) loss, the ccRCC initiating event, specifically drives strong interferon signaling activation, offering novel insights into ccRCC tumorigenesis and immune modulation. Overall, we establish CRISPRt as a simple, efficient and scalable approach for chromosome-specific aneuploidy engineering and characterization in preclinical models to advance aneuploidy research across diverse biological contexts.

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