TrimNN: Characterizing Cellular Community Motifs for Studying Multicellular Topological Organization in Complex Tissues

Overview

Journal Res Sq

Date 2025 Jan 29

PMID 39877090

Authors

Yang Yu

Shuang Wang

Jinpu Li

Meichen Yu

Kyle McCrocklin

Jing-Qiong Kang

Anjun Ma

Qin Ma

Dong Xu

Juexin Wang

Affiliations

Soon will be listed here.

Abstract

The spatial arrangement of cells plays a pivotal role in shaping tissue functions in various biological systems and diseased microenvironments. However, it is still under-investigated of the topological coordinating rules among different cell types as tissue spatial patterns. Here, we introduce the angulation cellular community otif eural etwork (), a bottom-up approach to estimate the prevalence of sizeable conservative cell organization patterns as Cellular Community () motifs in spatial transcriptomics and proteomics. Different from clustering cell type composition from classical top-down analysis, TrimNN differentiates cellular niches as countable topological blocks in recurring interconnections of various types, representing multicellular neighborhoods with interpretability and generalizability. This graph-based deep learning framework adopts inductive bias in CCs and uses a semi-divide and conquer approach in the triangulated space. In spatial omics studies, various sizes of CC motifs identified by TrimNN robustly reveal relations between spatially distributed cell-type patterns and diverse phenotypical biological functions.

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