Building a Learnable Universal Coordinate System for Single-cell Atlas with a Joint-VAE Model

Overview

Journal Commun Biol

Specialty Biology

Date 2024 Aug 12

PMID 39134617

Authors

Haoxiang Gao

Kui Hua

Xinze Wu

Lei Wei

Sijie Chen

Qijin Yin

Rui Jiang

Xuegong Zhang

Affiliations

Soon will be listed here.

Abstract

A universal coordinate system that can ensemble the huge number of cells and capture their heterogeneities is of vital importance for constructing large-scale cell atlases as references for molecular and cellular studies. Studies have shown that cells exhibit multifaceted heterogeneities in their transcriptomic features at multiple resolutions. This nature of complexity makes it hard to design a fixed coordinate system through a combination of known features. It is desirable to build a learnable universal coordinate model that can capture major heterogeneities and serve as a controlled generative model for data augmentation. We developed UniCoord, a specially-tuned joint-VAE model to represent single-cell transcriptomic data in a lower-dimensional latent space with high interpretability. Each latent dimension can represent either discrete or continuous feature, and either supervised by prior knowledge or unsupervised. The latent dimensions can be easily reconfigured to generate pseudo transcriptomic profiles with desired properties. UniCoord can also be used as a pre-trained model to analyze new data with unseen cell types and thus can serve as a feasible framework for cell annotation and comparison. UniCoord provides a prototype for a learnable universal coordinate framework to enable better analysis and generation of cells with highly orchestrated functions and heterogeneities.

Citing Articles

Variational inference of single cell time series.

Xu B, Braun R bioRxiv. 2024; .

PMID: 39257806 PMC: 11384007. DOI: 10.1101/2024.08.29.610389.

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