从DNA序列数据中划分细菌生态型的算法的准确性和效率。

Q4 Health Professions

International Journal of Bioinformatics Research and Applications Pub Date : 2014-01-01 DOI:10.1504/IJBRA.2014.062992

Juan Carlos Francisco, Frederick M Cohan, Danny Krizanc

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引用次数: 7

摘要

鉴定密切相关的、生态上不同的细菌种群将有利于在系统学、流行病学和生物技术等许多领域工作的微生物学家。几个实验室最近开发了旨在区分这种“生态型”的算法。我们研究了这些算法中的四种从序列数据中正确识别生态型的能力。我们在稳定生态型模型下生成的具有已知历史和栖息地关联的合成序列以及从死亡谷分离的芽孢杆菌菌株的数据上测试了算法，其中先前的工作已经证实了多种生态型的存在。我们发现，在这两种情况下，其中一种算法(生态型模拟)的性能明显优于其他算法(AdaptML, GMYC, BAPS)。不幸的是，它也是四种方法中效率最低的。虽然生态型模拟是最准确的，但它在测试的算法中却是最慢的。提高其效率的尝试正在进行中。

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Accuracy and efficiency of algorithms for the demarcation of bacterial ecotypes from DNA sequence data.

Identification of closely related, ecologically distinct populations of bacteria would benefit microbiologists working in many fields including systematics, epidemiology and biotechnology. Several laboratories have recently developed algorithms aimed at demarcating such 'ecotypes'. We examine the ability of four of these algorithms to correctly identify ecotypes from sequence data. We tested the algorithms on synthetic sequences, with known history and habitat associations, generated under the stable ecotype model and on data from Bacillus strains isolated from Death Valley where previous work has confirmed the existence of multiple ecotypes. We found that one of the algorithms (ecotype simulation) performs significantly better than the others (AdaptML, GMYC, BAPS) in both instances. Unfortunately, it was also shown to be the least efficient of the four. While ecotype simulation is the most accurate, it is by a large margin the slowest of the algorithms tested. Attempts at improving its efficiency are underway.

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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.