Extended local similarity analysis (eLSA) of microbial community and other time series data with replicates
Extended local similarity analysis (eLSA) of microbial community and other time series data with replicates
Date
2011-12-14
Authors
Xia, Li C.
Steele, Joshua A.
Cram, Jacob A.
Cardon, Zoe G.
Simmons, Sheri L.
Vallino, Joseph J.
Fuhrman, Jed A.
Sun, Fengzhu
Steele, Joshua A.
Cram, Jacob A.
Cardon, Zoe G.
Simmons, Sheri L.
Vallino, Joseph J.
Fuhrman, Jed A.
Sun, Fengzhu
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10.1186/1752-0509-5-S2-S15
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Abstract
The increasing availability of time series microbial community data from metagenomics and other molecular biological studies has enabled the analysis of large-scale microbial co-occurrence and association networks. Among the many analytical techniques available, the Local Similarity Analysis (LSA) method is unique in that it captures local and potentially time-delayed co-occurrence and association patterns in time series data that cannot otherwise be identified by ordinary correlation analysis. However LSA, as originally developed, does not consider time series data with replicates, which hinders the full exploitation of available information. With replicates, it is possible to understand the variability of local similarity (LS) score and to obtain its confidence interval. We extended our LSA technique to time series data with replicates and termed it extended LSA, or eLSA. Simulations showed the capability of eLSA to capture subinterval and time-delayed associations. We implemented the eLSA technique into an easy-to-use analytic software package. The software pipeline integrates data normalization, statistical correlation calculation, statistical significance evaluation, and association network construction steps. We applied the eLSA technique to microbial community and gene expression datasets, where unique time-dependent associations were identified. The extended LSA analysis technique was demonstrated to reveal statistically significant local and potentially time-delayed association patterns in replicated time series data beyond that of ordinary correlation analysis. These statistically significant associations can provide insights to the real dynamics of biological systems. The newly designed eLSA software efficiently streamlines the analysis and is freely available from the eLSA homepage, which can be accessed at http://meta.usc.edu/softs/lsa
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© The Author(s), 2011. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in BMC Systems Biology 5 Suppl 2 (2011): S15, doi:10.1186/1752-0509-5-S2-S15.
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BMC Systems Biology 5 Suppl 2 (2011): S15