Paper List
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An AI Implementation Science Study to Improve Trustworthy Data in a Large Healthcare System
This paper addresses the critical gap between theoretical AI research and real-world clinical implementation by providing a practical framework for as...
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The BEAT-CF Causal Model: A model for guiding the design of trials and observational analyses of cystic fibrosis exacerbations
This paper addresses the critical gap in cystic fibrosis exacerbation management by providing a formal causal framework that integrates expert knowled...
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Hierarchical Molecular Language Models (HMLMs)
This paper addresses the core challenge of accurately modeling context-dependent signaling, pathway cross-talk, and temporal dynamics across multiple ...
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Stability analysis of action potential generation using Markov models of voltage‑gated sodium channel isoforms
This work addresses the challenge of systematically characterizing how the high-dimensional parameter space of Markov models for different sodium chan...
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Approximate Bayesian Inference on Mechanisms of Network Growth and Evolution
This paper addresses the core challenge of inferring the relative contributions of multiple, simultaneous generative mechanisms in network formation w...
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EnzyCLIP: A Cross-Attention Dual Encoder Framework with Contrastive Learning for Predicting Enzyme Kinetic Constants
This paper addresses the core challenge of jointly predicting enzyme kinetic parameters (Kcat and Km) by modeling dynamic enzyme-substrate interaction...
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Tissue stress measurements with Bayesian Inversion Stress Microscopy
This paper addresses the core challenge of measuring absolute, tissue-scale mechanical stress without making assumptions about tissue rheology, which ...
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DeepFRI Demystified: Interpretability vs. Accuracy in AI Protein Function Prediction
This study addresses the critical gap between high predictive accuracy and biological interpretability in DeepFRI, revealing that the model often prio...
A Multi-Label Temporal Convolutional Framework for Transcription Factor Binding Characterization
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30秒速读
IN SHORT: This paper addresses the critical limitation of existing TF binding prediction methods that treat transcription factors as independent entities, failing to capture their cooperative regulatory mechanisms through multi-label classification.
核心创新
- Methodology First application of Temporal Convolutional Networks (TCNs) to multi-label transcription factor binding prediction, enabling simultaneous prediction of multiple TF binding events from DNA sequences.
- Methodology Development of three multi-label datasets (D-5TF-3CL, D-7TF-4CL, H-M-E2F) from ENCODE ChIP-seq data, specifically designed to study TF cooperativity.
- Biology Demonstration that deep learning models can learn biologically meaningful TF correlations and cooperative patterns directly from DNA sequence data, revealing both known and novel TF interactions.
主要结论
- TCN-based models significantly outperform RNN baselines in multi-label TF prediction, achieving average F1-score improvements of +0.17 to +0.26 across datasets (p<0.05).
- The model captures biologically relevant TF correlations, with TCN achieving AP scores of 0.73±0.01 on the H-M-E2F dataset compared to 0.52±0.00 for RNN baselines.
- TCNs demonstrate robust performance even with limited data, maintaining AP >0.7 on 152 out of 165 binary classification datasets despite moderate correlation (Pearson r=0.61) between performance and dataset size.
摘要: Transcription factors (TFs) regulate gene expression through complex and cooperative mechanisms. While many TFs act together, the logic underlying TFs binding and their interactions is not fully understood yet. Most current approaches for TF binding site prediction focus on individual TFs and binary classification tasks, without a full analysis of the possible interactions among various TFs. In this paper we investigate DNA TF binding site recognition as a multi-label classification problem, achieving reliable predictions for multiple TFs on DNA sequences retrieved in public repositories. Our deep learning models are based on Temporal Convolutional Networks (TCNs), which are able to predict multiple TF binding profiles, capturing correlations among TFs and their cooperative regulatory mechanisms. Our results suggest that multi-label learning leading to reliable predictive performances can reveal biologically meaningful motifs and co-binding patterns consistent with known TF interactions, while also suggesting novel relationships and cooperation among TFs.