Hi all,

Well is seems maybe strange to ask about obsolete research topics in bioinformatics, but I think for a beginner or a new researcher it is a helpful thing to know obsolete topics. What I mean by obsolete is research topics which are not of big interest.

The first thing that comes to my mind is protein secondary structure prediction. It seems pretty clear to me that no big performance improvements have happened in the last 5 years (if not 10 years). It seems to have reached a plateau already years ago, so making a new secondary structure prediction method would seem an obsolete research topic.

1. Short-read (<50bp) alignment algorithms. We will not need to align short reads as sequence reads keep getting longer. It is interesting to see how this subfield gets nearly saturated and then fades away in only two years. A few other NGS related methods will be ended up like this. Algorithm development is data driven, while NGS is moving too fast.

2. I used to do a brief review a few years ago about clustering algorithms which are mostly related to microarray data and homology identification. My impression that time was we do not need a new microarray data clustering algorithm (homology clustering may still have some room). Nonetheless, I do not really work with microarray data, so could be wrong on this point.

A second unrelated obsolete research topic just occurred to me: development of improved microarray normalization methods. Mind you, I fully appreciate the importance of good normalization methods - they can make a huge difference in terms of what one can get out of a microarray study.

However, I consider it obsolete to develop new microarray normalization methods for two reasons:

1. The methods seem to have reached the limit of what is possible. Methods have for 10 years been able to correct for just about any systematic biases in microarray data, be that the amount of sample loaded, dye effects, print tip effects, and other spacial effects.

2. Microarrays are to a large extend being replaced by RNA-seq methods, which only adds to obsoleteness of developing new methods to normalize the data.

It might be an interesting exercise to check out the original Pedro's List (some of you will know what that is) and consider which tools have persisted, which evolved, and which have vanished. Of course, some of the vanished ones will have been funding-related and not topic-specific deaths.

What about methods for multiple testing correction in genome-wide association studies (GWAS)?

On one hand, a p-value of 5e-8 for "genome-wide significance" is the de facto standard for GWAS, based on some work showing that testing all common variants results in about 1 million effectively independent tests. Furthermore, if I'm following up findings in replication studies or in the lab, I'm going to take my top x% of genes/variants, based on whatever I can afford, not whatever the corrected p-value happens to be.

But on the other hand I have attended the IGES meeting for the last 5 years, and there are always several talks and many posters on new methodology for correcting p-values for multiple testing in GWAS.

I don't think people are working on "protein music" anymore :-)

Ross D. King and Colin G. Angus
PM—Protein music
Comput Appl Biosci (1996) 12(3): 251-252 doi:10.1093/bioinformatics/12.3.251

http://bioinformatics.oxfordjournals.org/content/12/3/251.full.pdf+htm

"We present the program PM for the analysis of protein sequence information using audification..."

1. Optimal pairwise global alignment, see Needleman and Wunch (1970) for solution.

2. Optimal pairwise local alignment, see Smith and Waterman (1981) for solution.

I suppose that in-silico gene prediction (from a sequence as start) for prokaryotes will be going the way of the dodo pretty quickly because

1. there are already a couple which do the job "good enough"
2. the ever growing databases at EMBL and NCBI provide a good BLAST base so that assignment is done more and more on similarity.
3. doing an RNA profiling is comparatively cheap nowadays and gives much better accuracy on the transcript boundaries, from which with a bit of curation one should be able to get pretty good gene boundaries

Protein secondary structure prediction using a 3-letter alphabet is pretty dead, but there may be some life left in developing more detailed views of local protein structure.

RNA secondary structure prediction still needs a lot of work, particularly for the more unusual RNA structures that involve things other than pairing on the Watson-Crick edge.

In-silico prediction of prokaryote genes is still far form a solved problem. People have mostly punted on the short proteins, and the RNA genes are still woefully underannotated. The archaeal gene predictions are particularly bad.

How about RNA secondary structure prediction ? Is the topic 'hot' anymore?

De novo gene prediction and genome annotation based on conservation, GC content, HMMs, etc.

These kind of methods were hot when sequencing ESTs and full-length transcripts was prohibitively expensive. Now you can just sequence the transcriptome and let the data tell you what regions of the genome are being transcribed and what the exon/intron structures of those transcripts are (both canonical and minor isoforms).

As RNA-seq and related assembly methods improve, annotating a new genome will become increasingly routine and automated. A lot of genome and cDNA 'finishing' tasks have already been eliminated by these new types of data and related analysis pipelines.

The dogma of disordered (regions of) proteins. It seems to be a very interesting yet important topic in structural bioinformatics. Although there are a number of programs, I was unable to find a reliable one.

The importance of this area has been highlighted in Breaking the Protein Rules.