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planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/data_managers/data_manager_star_index_builder commit 4888c06bc87c2b236fae379c4220a23aae036cd6 |
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README.md |
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diff -r f537d3e00eb8 -r 50ca9af6db2e README.md --- a/README.md Fri Jun 23 04:26:07 2017 -0400 +++ /dev/null Thu Jan 01 00:00:00 1970 +0000 |
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@@ -1,40 +0,0 @@ -##What it does## - -This is a Galaxy datamanager for the rna STAR gap-aware RNA aligner. It's a hack of Dan Blankenberg's BWA data manager -and works on any fasta file you have already downloaded with the all fasta data manager - start there! - -Warning - this is not well tested and there are some complexities to do with splice junction annotation in rna star -indexes - feedback welcomed. Send code. - -Note, currently you'll need a small patch to prevent an error when you try to generate splice junction indexes described at -https://bitbucket.org/galaxy/galaxy-central/pull-request/510/fix-for-data-manager-failure-to-update-a#comment-3265356 - -Please read the fine manual - that and the google group are the places to learn about the options above. - -*Note on sjdbOverhang* - -From https://groups.google.com/forum/#!topic/rna-star/h9oh10UlvhI:: - - James is right, using large enough --sjdbOverhang is safer and should not generally cause any problems with reads of varying length. If your reads are very short, <50b, then I would strongly recommend using optimum --sjdbOverhang=mateLength-1 - By mate length I mean the length of one of the ends of the read, i.e. it's 100 for 2x100b PE or 1x100b SE. For longer reads you can simply use generic --sjdbOverhang 100. - It is a bit confusing because of the way I named this parameter. --sjdbOverhang Noverhang is only used at the genome generation step for constructing the reference sequence out of the annotations. - Basically, the Noverhang exonic bases from the donor site and Noverhang exonic bases from the acceptor site are spliced together for each of the junctions, and these spliced sequences are added to the genome sequence. - - At the mapping stage, the reads are aligned to both genomic and splice sequences simultaneously. If a read maps to one of spliced sequences and crosses the "junction" in the middle of it, the coordinates of two pspliced pieces are translated back to genomic space and added to the collection of mapped pieces, which are then all "stitched" together to form the final alignment. Since in the process of "maximal mapped length" search the read is split into pieces of no longer than --seedSearchStartLmax (=50 by default) bases, even if the read (mate) is longer than --sjdbOverhang, it can still be mapped to the spliced reference, as long as --sjdbOverhang > --seedSearchStartLmax. - - Cheers - Alex - -*Note on gene model requirements for splice junctions* - -From https://groups.google.com/forum/#!msg/rna-star/3Y_aaTuzBrE/lUylTB8h5vMJ:: - - When you generate a genome with annotations, you need to specify --sjdbOverhang value, which ideally should be equal to (oneMateLength-1), or you could use a generic value of ~100. - - Your gtf lines look fine to me. STAR needs 3 features from a GTF file: - 1. Chromosome names in col.1 that agree with chromosome names in genome .fasta files. If you have "chr2L" names in the genome .fasta files, and "2L" in the .gtf file, then you need to use --sjdbGTFchrPrefix chr option. - 2. 'exon' in col.3 for the exons of all transcripts (this name can be changed with --sjdbGTFfeatureExon) - 3. 'transcript_id' attribute that assigns each exon to a transcript (--this name can be changed with --sjdbGTFtagExonParentTranscript) - - Cheers - Alex |