Hi Veronica

adapters might "become" part of your genome (you see this in a few draft genomes) or cause bridges.

You could try searching your genomes against all the possible adapter/primer sequences. If you find got enough hits, you definitely know you have a somewhat major issue.

More often they might just negatively effect your N50.
But anyway 12bp headcrop seems high (of course this might have been caused by your qual values or as a way to remove adapter. In the latter case, they can also be on the other end, as you can get read-through)

How much work did you put in and what size is the genome?

Cheers,
b

But how many matches of primers/adapters to your sequence is actually true contamination or actual biological sequence? How can you distinguish these two? I mean, surely there is a possibility that actual biological sequences have the same sequences as adapter/primers.

If I do a BLAST search of adapter sequences, you get all sorts of matches in databases. Is this contamination or what?

Hi,

This is of course difficult to say.
Also with your BLAST searches. But if you re-assemble a genome from scratch with stringent adapter removal and the adapters dissappear it is a good indication. (Yeah I do this sometimes for some courses I teach)

That said of course the match length and its e-value gives you an indication.

Cheers
Björn

Hi Björn,

I've put quite a bit of time into this assembly so I would rather "fix" it if possible rather than scrap it and start again. It is a de novo transcriptome assembly not a genome.

I tried searching for the adapter sequences using blast but ran into the problem of interpretation. Is a 10 bp 100% identity match real adapter/primer contamination? I guess I don't know how to use match length and e-value to determine this.

I decided to remove the transcripts that have obvious matches (nearly the whole length of the primer or adapter present in the sequence) but those partial sequence hits I just left in.

Thanks for your replies!
Veronica

Provided e.g. Roche MID tags have 10 or 11 nt in length, it is perfectly valid to interpret such matches are true, and trim them away with their upstream/downstream regions. But, you have to understand what happened in the lab. From a bioinformatician's side of view, 10nt match seems too weak and crappy, even worse there are 2-3 sequencing errors. You really have to dive into the details of the sequencing technology and of the lab protocol, otherwise it is just bad guesswork. In certain locations within a read I do treat such matches as e.g. MID tags. Same for some adapter remnants which have been cleaved by a restriction endonuclease.
Hi Veronica,

This is still not correct. How about partial PCR products? How about truncated adapters somebody left in after improper trimming? How about partial adapters left in after vendor-specific trimming (e.g. trimming becased on some quality criteria)? Of course you don't want to leave them in the dataset. A typical place where most adapter-trimming tools fail. You also have to anticipate e.g. two sample molecules stitched together via some adapter/linker/artifact, which are mostly somehow distorted, for example truncated or contain some short linker sequence.

The only general advice would be: Trim more rather than less and start with trimming of the original data, not of some partially trimmed data. It is much more difficult to uncover partial targets which somebody left in.

Martin