IMAS enables target-aware integration of tumour multiomics to resolve communication-guided regulatory mechanisms

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The paper studies how to integrate sparse, heterogeneous tumor multiomics datasets to discover interpretable regulatory mechanisms, proposing IMAS, a target-aware framework that uses a pan-cancer single-cell multiomic resource to contextualize new tumor data. Using shared latent-space modeling with target-domain adaptation, IMAS improves correspondence between predicted and observed RNA and transcription factor profiles and then reconstructs structured RNA–TF coupling networks, refining intercellular signaling via ligand-informed communication modeling and organizing regulatory programs by communication-associated ordering. In independent colon cancer datasets, IMAS improved cluster-resolved correspondence and identified communication-guided regulatory cascades across malignant epithelial states, with a LAMB1-centered analysis illustrating progressive reinforcement of local regulatory structure and enabling perturbation-based probing of context-specific dependencies. The study explicitly notes that IMAS focuses on constructing consistent, interpretable mechanism-discovery scaffolds rather than exhaustively predicting all possible outcomes. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Tumour multiomic datasets are often sparse, heterogeneous and limited in size, hindering robust and interpretable discovery of regulatory mechanisms. Here we present IMAS (Integrative Multiomic Augmentation System), a target-aware integrative framework for multiomic data augmentation and mechanism prioritization that leverages a pan-cancer single-cell multiomic resource to contextualize new tumour datasets and identify reliable sample-specific mechanistic hypotheses. IMAS combines shared latent-space modelling with target-domain adaptation to improve correspondence between predicted and observed RNA and TF profiles while concentrating explanatory predictive supports within the target dataset. Building on this adapted representation, IMAS reconstructs structured RNA-TF coupling networks, refines intercellular signaling through ligand-informed communication modelling, and organizes regulatory programs along communication-associated ordering. In independent colon cancer data, IMAS improved cluster-resolved correspondence and revealed communication-guided regulatory cascades across malignant epithelial states. A LAMB1-centred analysis further demonstrates how the framework supports progressive reinforcement of local regulatory structure and enables perturbation-based probing of context-specific dependencies. Rather than exhaustively predicting all possible outcomes, IMAS provides a target-aware and interpretable strategy to construct consistent and interpretable mechanism-discovery scaffolds and prioritize regulatory dependencies in data-limited tumour systems.
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Abstract Tumour multiomic datasets are often sparse, heterogeneous and limited in size, hindering robust and interpretable discovery of regulatory mechanisms. Here we present IMAS, a target-aware integrative framework for multiomic data augmentation and mechanism prioritization that leverages a pan-cancer single-cell multiomic resource to contextualize new tumour datasets and identify reliable sample-specific mechanistic hypotheses. IMAS combines shared latent-space modelling with target-domain adaptation to improve correspondence between predicted and observed RNA and TF profiles while concentrating explanatory predictive supports within the target dataset. Building on this adapted representation, IMAS reconstructs structured RNA–TF coupling networks, refines intercellular signaling through ligand-informed communication modelling, and organizes regulatory programs along communication-associated ordering. In independent colon cancer data, IMAS improved cluster-resolved correspondence and revealed communication-guided regulatory cascades across malignant epithelial states. A LAMB1-centred analysis further demonstrates how the framework supports progressive reinforcement of local regulatory structure and enables perturbation-based probing of context-specific dependencies. Rather than exhaustively predicting all possible outcomes, IMAS provides a target-aware and interpretable strategy to construct consistent and interpretable mechanism-discovery scaffolds and prioritize regulatory dependencies in data-limited tumour systems. Competing Interest Statement The authors have declared no competing interest. Footnotes We have revised Figures 4 and 5. The corresponding Results and Discussion sections have also been updated.

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License: CC-BY-4.0