SEAStAR tools version 0.4.18 has been released on github. Also check out our "Quick Start" tutorial.
Follow @SEAStAR_meta on Twitter for news regarding software updates and other related information.
To submit bugs, suggestions, feature requests, etc., please visit the SEAStAR issues page on github.
SEAStAR is a package of open-source tools supporting the construction of analysis pipelines for environmental next-generation sequencing data. Version 0.4 includes new support for Illumina® reads in addition to SOLiD™ data, and provides high-performance tools for dealing with:
The prototype version of SEAStAR was developed and used to analyze the metagenome data in our publication: "Untangling Genomes from Metagenomes: Revealing an Uncultured Class of Marine Euryarchaeota".
SEAStAR was publicly released in the following phases (versions prior to 0.3 were prototypes):
Phase 1 (ver 0.3):
Phase 1 contained tools developed for working with SOLiD reads, converting them to colorspace FASTQ files, removing PCR duplicates, and trimming the reads based on quality and information content for various uses. These tools generate files that can be directly used with aligners and assemblers, such as BWA and Velvet.
Phase 2: (ver 0.4)
Phase 2 added support for Illumina sequence, and contains the tools we developed for processing SAM alignment files and assembled nucleotide or colorspace contigs into mate-paired assembly graphs with associated nucleotide contigs that can then be visualized and explored using GraphViz. This release also contains the tools for selecting and visualizing the best sequences from a reference database (e.g. the RDP 16S database) alignment with associated statistics such as coverage and relative abundance. In the case of alignments with RDP, these sequences can then be classified (using the RDP classifier) and visualized taxonomically. Also included are tools for splitting assembly graphs into parsimonious linear scaffold graphs, binning these scaffold graphs using tetra-nucleotide statistics, and constructing scaffold sequences with the order and orientation of contigs properly determined. Use of this full pipeline produces candidate genome assemblies ready for refinement, gap-filling (if desired) and annotation.