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A transcriptomics-native foundation model for universal cell representation and virtual cell synthesis.

Xiaohui Jiang1, Jichun Xie1,2,3

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Summary
This summary is machine-generated.

xVERSE is a new transcriptomics-native foundation model that improves single-cell data analysis by learning batch-invariant representations and generating realistic virtual cells. It outperforms existing methods in representation learning, spatial imputation, and rare cell type detection.

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generative pre-trainingsingle-cell omicsspatial omicstranscriptomics-native foundation modelvirtual cell synthesis

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Area of Science:

  • Computational Biology
  • Genomics
  • Artificial Intelligence

Background:

  • Current single-cell foundation models often use language architectures that disregard transcriptomic data distributions, leading to suboptimal performance compared to specialized methods.
  • This limitation hinders accurate analysis and interpretation of complex single-cell datasets.

Purpose of the Study:

  • To introduce xVERSE, a novel transcriptomics-native foundation model designed to overcome the limitations of existing models.
  • To enhance single-cell data analysis through batch-invariant representation learning and probabilistic generation of expression profiles.

Main Methods:

  • xVERSE employs a transcriptomics-native architecture, integrating batch-invariant representation learning with probabilistic expression profile generation.
  • The model was evaluated against leading foundation models, batch-effect correction methods, and spatial imputation techniques.

Main Results:

  • xVERSE achieved superior performance in representation learning, outperforming leading foundation models by 17.9% and batch-effect correction methods by 11.4%.
  • It demonstrated a 34.3% improvement over the second-best spatial imputation method and synthesized virtual cells indistinguishable from real data (AUROC ≈ 0.5).
  • xVERSE enabled accurate clustering and marker detection in small datasets, resolving rare cell types with as few as four cells, and improved cross-modality prediction generalizability.

Conclusions:

  • xVERSE represents a transformative framework for single-cell data analysis, offering enhanced capabilities beyond conventional models.
  • Its ability to preserve biological heterogeneity, diminish batch effects, and generate high-fidelity virtual cells unlocks new analytical possibilities, particularly for rare cell type identification and data augmentation.