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Main Authors: Wang, Jiahe, Wu, Yan, Hou, Yuke, Li, Yang, Xu, Dachuan, Zhuge, Changjing, Han, Yue
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.20275
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author Wang, Jiahe
Wu, Yan
Hou, Yuke
Li, Yang
Xu, Dachuan
Zhuge, Changjing
Han, Yue
author_facet Wang, Jiahe
Wu, Yan
Hou, Yuke
Li, Yang
Xu, Dachuan
Zhuge, Changjing
Han, Yue
contents Cancer is a complex disease driven by dynamic regulatory shifts that cannot be fully captured by individual molecular profiling. We employ a data-driven approach to construct a coarse-grained dynamic network model based on hallmark interactions, integrating stochastic differential equations with gene regulatory network data to explore key macroscopic dynamic changes in tumorigenesis. Our analysis reveals that network topology undergoes significant reconfiguration before hallmark expression shifts, serving as an early indicator of malignancy. A pan-cancer examination across $15$ cancer types uncovers universal patterns, where Tissue Invasion and Metastasis exhibits the most significant difference between normal and cancer states, while the differences in Reprogramming Energy Metabolism are the least pronounced, consistent with the characteristic features of tumor biology. These findings reinforce the systemic nature of cancer evolution, highlighting the potential of network-based systems biology methods for understanding critical transitions in tumorigenesis.
format Preprint
id arxiv_https___arxiv_org_abs_2502_20275
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle How cancer emerges: Data-driven universal insights into tumorigenesis via hallmark networks
Wang, Jiahe
Wu, Yan
Hou, Yuke
Li, Yang
Xu, Dachuan
Zhuge, Changjing
Han, Yue
Quantitative Methods
Cancer is a complex disease driven by dynamic regulatory shifts that cannot be fully captured by individual molecular profiling. We employ a data-driven approach to construct a coarse-grained dynamic network model based on hallmark interactions, integrating stochastic differential equations with gene regulatory network data to explore key macroscopic dynamic changes in tumorigenesis. Our analysis reveals that network topology undergoes significant reconfiguration before hallmark expression shifts, serving as an early indicator of malignancy. A pan-cancer examination across $15$ cancer types uncovers universal patterns, where Tissue Invasion and Metastasis exhibits the most significant difference between normal and cancer states, while the differences in Reprogramming Energy Metabolism are the least pronounced, consistent with the characteristic features of tumor biology. These findings reinforce the systemic nature of cancer evolution, highlighting the potential of network-based systems biology methods for understanding critical transitions in tumorigenesis.
title How cancer emerges: Data-driven universal insights into tumorigenesis via hallmark networks
topic Quantitative Methods
url https://arxiv.org/abs/2502.20275