基于受限噪声通道的深度神经网络识别功能内含子

2017 IEEE 27th International Workshop on Machine Learning for Signal Processing (MLSP) Pub Date : 2017-09-01 DOI:10.1109/MLSP.2017.8168186

Alan Joseph Bekker, M. Chorev, L. Carmel, J. Goldberger

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引用次数: 1

摘要

相当一部分内含子被认为参与细胞功能，但没有明显的方法来预测哪个特定的内含子可能是功能性的。对于每个内含子，我们给出了基于其进化模式的特征表示。对于一小部分内含子，我们也得到了它们是功能性的指示。对于所有其他的内含子，我们不知道它们是否有功能。我们的任务是估计多少内含子是功能性的，以及每个内含子是功能性的可能性有多大。我们定义了一个概率分类模型，该模型将给定的功能标签视为由深度神经网络模型创建的标签的噪声版本。利用期望最大化算法找到最大似然模型参数。我们发现，大约80%的功能性内含子仍未被识别，大约三分之一的内含子是功能性的。

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A deep neural network witharestricted noisy channel for identification of functional introns

An appreciable fraction of introns is thought to be involved in cellular functions, but there is no obvious way to predict which specific intron is likely to be functional. For each intron we are given a feature representation that is based on its evolutionary patterns. For a small subsets of introns we are also given an indication that they are functional. For all other introns it is not known whether they are functional or not. Our task is to estimate what fraction of introns are functional and, how likely it is that each individual intron is functional. We define a probabilistic classification model that treats the given functionality labels as noisy versions of labels created by a Deep Neural Network model. The maximum-likelihood model parameters are found by utilizing the Expectation-Maximization algorithm. We show that roughly 80% of the functional introns are still not recognized as such, and that roughly a third of all introns are functional.

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2017 IEEE 27th International Workshop on Machine Learning for Signal Processing (MLSP)

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