通过整合机理建模和深度学习解码模式形成规则

Jia Lu, Nan Luo, Sizhe Liu, Kinshuk Sahu, Rohan Maddamsetti, Yasa Baig, Lingchong You
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引用次数: 0

摘要

利用活细胞进行自组织模式形成的预测性编程具有挑战性,主要原因是难以有效地浏览高维设计空间。模式的出现和特征对系统和环境参数都非常敏感。通常情况下,能够产生模式的最佳条件只占可能设计空间的一小部分。此外,模式的实验生成和量化通常需要大量人力,而且产量较低,因此仅凭试验和错误来优化模式的形成是不切实际的。为此,利用完善的机理模型进行模拟,有助于确定形成图案的最佳实验条件。然而,即使是中等复杂程度的系统,如果应用于较大的参数空间,也会使这些模拟的计算量过大。在本研究中,我们展示了如何将机械建模与机器学习相结合,从而大大加快对模式化电路设计空间的探索,并帮助推导出人类可理解的设计规则。我们将这一策略应用于利用合成基因电路对铜绿假单胞菌的自组织环模式进行编程。我们的方法包括利用模拟数据训练神经网络,使其预测模式形成的速度比机理模型快 1000 万倍。这个神经网络随后被用来预测大量参数组合的模式形成,远远超过了训练数据集的大小,也超过了仅使用机理模型的计算可行性。通过这种方法,我们确定了许多能够产生理想模式的参数组合,但这些组合仍只占已探索参数空间的极小一部分。接下来,我们利用机理模型对候选方案进行了验证,并确定了粗粒度的模式规则。我们在实验中演示了在所学规则的指导下生成和控制图案。我们的工作凸显了将机理建模与机器学习相结合,对活细胞中的复杂动力学进行合理工程设计的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Decoding pattern formation rules by integrating mechanistic modeling and deep learning
Predictive programming of self-organized pattern formation using living cells is challenging in major part due to the difficulty in navigating through the high-dimensional design space effectively. The emergence and characteristics of patterns are highly sensitive to both system and environmental parameters. Often, the optimal conditions able to generate patterns represent a small fraction of the possible design space. Furthermore, the experimental generation and quantification of patterns is typically labor intensive and low throughput, making it impractical to optimize pattern formation solely based on trials and errors. To this end, simulations using a well-formulated mechanistic model can facilitate the identification of optimal experimental conditions for pattern formation. However, even a moderately complex system can make these simulations computationally prohibitive when applied to a large parameter space. In this study, we demonstrate how integrating mechanistic modeling with machine learning can significantly accelerate the exploration of design space for patterning circuits and aid in deriving human-interpretable design rules. We apply this strategy to program self-organized ring patterns in Pseudomonas aeruginosa using a synthetic gene circuit. Our approach involved training a neural network with simulated data to predict pattern formation 10 million times faster than the mechanistic model. This neural network was then used to predict pattern formation across a vast array of parameter combinations, far exceeding the size of the training dataset and what was computationally feasible using the mechanistic model alone. By doing so, we identified many parameter combinations able to generate desirable patterns, which still represent an extremely small fraction of explored parametric space. We next used the mechanistic model to validate top candidates and identify coarse-grained rules for patterning. We experimentally demonstrated the generation and control of patterning guided by the learned rules. Our work highlights the effectiveness in integrating mechanistic modeling and machine learning for rational engineering of complex dynamics in living cells.
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