PO.BCS02.05 · 生物信息与计算
Revealing dynamic temporal trajectories and underlying regulatory networks with Cflows
作者与单位
摘要 Abstract
While single-cell technologies provide snapshots of tumor states, building continuous trajectories and uncovering causative gene regulatory networks remains a significant challenge. We present Cflows, an AI framework that combines neural ODE networks with Granger causality to infer continuous cell state transitions and gene regulatory interactions from static scRNA-seq data. In a new 5-time point dataset capturing tumorsphere development over 30 days, Cflows reconstructs two types of trajectories leading to tumorsphere formation or apoptosis. Trajectory-based cell-of-origin analysis delineated a novel cancer stem cell profile characterized by CD44 hi EPCAM + CAV1 + , and uncovered a cell cycle-dependent enrichment of tumorsphere-initiating potential in G2/M or S-phase cells. Cflows uncovers ESRRA as a crucial causal driver of the tumor-forming gene regulatory network. Indeed, ESRRA inhibition significantly reduces tumor growth and metastasis in vivo. Cflows offers a powerful framework for uncovering cellular transitions and dynamic regulatory networks from static single-cell data.
利益披露 Disclosure
S. Gupta, None..
X. Sun, None..
A. Tong, None..
M. Kuchroo, None..
D. Bhaskar, None..
C. Liu, None..
A. Venkat, None..
B. P. San Juan, None..
L. Rangel, None..
V. Rodriguez, None..
J. G. Lock, None.