Paper List
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Evolutionarily Stable Stackelberg Equilibrium
通过要求追随者策略对突变入侵具有鲁棒性,弥合了斯塔克尔伯格领导力模型与演化稳定性之间的鸿沟。
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Recovering Sparse Neural Connectivity from Partial Measurements: A Covariance-Based Approach with Granger-Causality Refinement
通过跨多个实验会话累积协方差统计,实现从部分记录到完整神经连接性的重建。
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Atomic Trajectory Modeling with State Space Models for Biomolecular Dynamics
ATMOS通过提供一个基于SSM的高效框架,用于生物分子的原子级轨迹生成,弥合了计算昂贵的MD模拟与时间受限的深度生成模型之间的差距。
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Slow evolution towards generalism in a model of variable dietary range
通过证明是种群统计噪声(而非确定性动力学)驱动了模式形成和泛化食性的演化,解决了间接竞争下物种形成的悖论。
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Grounded Multimodal Retrieval-Augmented Drafting of Radiology Impressions Using Case-Based Similarity Search
通过将印象草稿基于检索到的历史病例,并采用明确引用和基于置信度的拒绝机制,解决放射学报告生成中的幻觉问题。
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Unified Policy–Value Decomposition for Rapid Adaptation
通过双线性分解在策略和价值函数之间共享低维目标嵌入,实现对新颖任务的零样本适应。
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Mathematical Modeling of Cancer–Bacterial Therapy: Analysis and Numerical Simulation via Physics-Informed Neural Networks
提供了一个严格的、无网格的PINN框架,用于模拟和分析细菌癌症疗法中复杂的、空间异质的相互作用。
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Sample-Efficient Adaptation of Drug-Response Models to Patient Tumors under Strong Biological Domain Shift
通过从无标记分子谱中学习可迁移表征,利用最少的临床数据实现患者药物反应的有效预测。
A Multi-Label Temporal Convolutional Framework for Transcription Factor Binding Characterization
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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.