波蒂病毒科多蛋白的自动分割

Q4 Health Professions

International Journal of Bioinformatics Research and Applications Pub Date : 2015-11-01 DOI:10.1504/IJBRA.2015.073238

J. Vargas, J. A. Velasco, G. Alvarez, Diego Linares, E. Bravo

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引用次数: 0

摘要

本文描述了一种针对波蒂病毒科病毒多蛋白的自动分割方法。它使用机器学习技术来预测切割位点，该位点定义了所述多蛋白在功能成熟过程中被切割的片段。分割应用程序在网站上公开可用，也可以通过web服务接口访问。预测模型的平均灵敏度为0.79，马修斯相关系数平均值为0.23。该方法能够正确预测来自Potyvirus和Rymovirus属的序列片段(与先前发表的片段一致)。然而，当面对非典型序列或属于potyvirridae家族中较不常见属的病毒时，准确的预测能力受到影响。今后的工作将集中于在这方面建立更大的灵活性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Automatic segmentation of Potyviridae family polyproteins

We describe an automatic segmentation method for polyproteins of the viruses belonging to the Potyviridae family. It uses machine learning techniques in order to predict the cleavage site which define the segments in which said polyproteins are cut in their process of functional maturation. The segmentation application is publicly available for use on a website and it can be accessed through the web service interface too. The prediction models have an average sensitivity of 0.79 and a Matthews correlation coefficient average of 0.23. This method is capable of predicting correctly (coinciding with previously published segmentation) the segmentation of sequences which come from Potyvirus and Rymovirus, genera. However accurate prediction capabilities are affected when faced with either atypical sequences or viruses belonging to less common genera in the Potyviridae family. Future work will focus on establishing greater flexibility in this sense.

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来源期刊

International Journal of Bioinformatics Research and Applications Health Professions-Health Information Management

CiteScore

0.60

自引率

0.00%

发文量

期刊介绍： Bioinformatics is an interdisciplinary research field that combines biology, computer science, mathematics and statistics into a broad-based field that will have profound impacts on all fields of biology. The emphasis of IJBRA is on basic bioinformatics research methods, tool development, performance evaluation and their applications in biology. IJBRA addresses the most innovative developments, research issues and solutions in bioinformatics and computational biology and their applications. Topics covered include Databases, bio-grid, system biology Biomedical image processing, modelling and simulation Bio-ontology and data mining, DNA assembly, clustering, mapping Computational genomics/proteomics Silico technology: computational intelligence, high performance computing E-health, telemedicine Gene expression, microarrays, identification, annotation Genetic algorithms, fuzzy logic, neural networks, data visualisation Hidden Markov models, machine learning, support vector machines Molecular evolution, phylogeny, modelling, simulation, sequence analysis Parallel algorithms/architectures, computational structural biology Phylogeny reconstruction algorithms, physiome, protein structure prediction Sequence assembly, search, alignment Signalling/computational biomedical data engineering Simulated annealing, statistical analysis, stochastic grammars.