I am not sure to see what you mean by "retrieve 3'UTRs" exactly. Is the goal to improve the existing gene annotation (by extending the annotated 3'UTRs for instance)?

Also,
Since polyAs are added on RNAs you will not find them in the genomic sequence, the annotated CDS nor in the mapped reads. That is normal.

I have the annotated genome, without 3utr information. I also have the transcriptome reads. I want to pick every single 3utr. If I map against the genome, sometimes is impossible to decide where a 3utr finish and the next 5utr starts.

My assembled transcripts doesnt have polyA. But I already know what happened. It's cos' the library construction cut them off.

I just aligned the transcripts against CDS and cut the transcripts after the stopcodon alignment. Just want to know if it's right or if there is a tool to retrieve my 3UTRs.

If you read again what I wrote, you'll see that I was talking about assembled transcripts.

Yes, that is a limitation of most RNA-seq technologies. As long as RNA fragmentation is required you can never be sure that a given read comes from the transcript it maps to. It can come from another splicing isoform or even from another gene as you mention.

What I do not understand is how "de novo" transcript assembly would solve that problem, because ambiguities will remain. If a read pair maps to a genomic area that is both annotated as 3'UTR and 5'UTR the only way I can imagine to solve the assignation issue is to simultaneously estimate expression levels by taking into account read quantities (with a method like Cufflinks for instance).


When an annotated genome is available the mapping strategy is usually preferred because de novo transcript assembly is not a straightforward process. I guess that your alignments can tell you how much your assembly match with the annotation.