depends what they are.

If they are polyA rich - they are probably a result of image artefacts (ie not derived from templates) - often caused by flowcell edges on newer systems. Other imaging problems can also give you spurious reads with low complexity sequences. As repeats are also low-complexity these spurious reads tend to cluster there and often with a few 'differences'....... you need to filter them out. Unfortunately as they are image artefacts they tend to have good base scores, so you have to use rules based on their sequence composition and/or their positions in the tiles. Some people have written tile edgae and 'bad region' detection methods and these can be used to exclude reads that fall within them. Im afraid images still tell you a lot about your 'end data' and how well set up your system is.

clivey,
Thank you for your answer. I have checked the reads. They, however, are not poly A reached. Could the reads at the repeat regions are real signal? How could we determine if such a pattern is pure technology artifact? Thanks.

interesting,

well - look at the X and Y corordinates of the reads , are they spatially correlated ? when you look at the images is there anything about them that wrong ? have you managed to create primer-dimers, or other strange contructs that would be over-represented ? if your library prep unbiased in terms of sampling statistics and complexity ? impossible to say without seeing data - and I can only point you to known artiefacts.

Satellite repeats? They tend to always give signals in ChIP-seq, but I thought it was because of gaps in the alignment, i. e. sequences will pile up (with more mismatches) if copies of the repeats are present in the genome but not in the aligned reference. This often occurs in repeats that have a high SNP density.

Hi, some repeats are actually responsible for binding sites. You can read this following paper regarding regarding that observation. Bourque et al. (2008) Evolution of the mammalian transcription factor binding repertoire via transposable elements. Genome Res. 2008 Oct 3.

Maybe you're finding new examples of it.

It is possible that some of these signals correspond to true instances of the TF binding to repeats. However, everyone working with ChIP-seq data has seen the larger problem; large areas of the genome where many thousands of reads stack up on top of each other. These regions are typically associated with repeat elements such as LINEs and SINEs. They show up in the same genomic location no matter what TF you ChIP, and they also show up in controls (like WCE), suggesting that they are not IP signals. Tim Danford in our lab calls these artifacts "towers".

We think that towers are related to repeat copy numbers. Imagine that there is a type of satellite repeat (e.g. some type of SINE) that is present in only one copy in the reference genome. Of course, when you do the experiment, you are not sampling from the reference genome, you are sampling from the genome of your cells. What if that same SINE is present 1000 times in your cell's genome? When you sequence, you may randomly pick up background signal along each of those thousand copies (no antibody is perfect). When you map these tags back to the reference genome, they all go to only one place, since the reference has only one copy of the repeat. Therefore, you see those towers in every experiment that you do on those cells.

The answer to your question about "do we need to throw these things out" is no, but you do need some sort of control run (WCE, or something else) for each different genotype that you work with.