Presentation proposals and poster abstracts can be submitted through
Submitted abstracts should describe original or recent scientific works in the areas listed below.
- Databases, data mining algorithms and visualization tools for variants analysis.
Current genomic databases contain millions of SNVs and vast amounts of related annotation data.
Information continues to flow into these resources at ever increasing speeds. Making biologically relevant
sense of this data deluge requires the development of better-defined data collection and access strategies.
This topic is of particular interest to researchers working on storage, retrieval, and visualization of variation data.
We will focus explicitly on two subsection of this topic: the development of SNV-related ontologies and
methods for the automatic extraction of SNV data from literature.
- Methods for predicting regulatory/structural/functional impacts of SNVs.
Experimental study of functional effects of SNVs is complicated by a number of factors (e.g. compounding effects of variation
in other genetic regions including linkage disequilibrium, problems with crystallization, expression related changes in
phenotype, etc) and generally results in a very expensive and not very accurate estimation of real effect. A number of
tools have been recently developed to evaluate regulatory, functional and structural effects of SNVs in silica.
This topic encompasses the variants with protein and RNA effects, as well as variants in regulatory and functionally
un-annotated regions. This year we would like to explicitly encourage submission relating to the studies of regulatory
SNVs and genetic variation in drug response.
- Personal Genomics, GWAS studies and SNV prioritization.
The recent development in sequencing technologies has moved personal genomics (and thereby personalized medicine) much
closer to reality. Genome wide association studies have become increasingly relied upon for disease-gene discoveries.
Yet, a number of studies show that the discovered disorder associated SNVs do not account fully for the observed genetic
risk. Thus, the GWAS should ideally provide preliminary genetic information, which could then be analyzed in silica in
concert with other evidence (e.g. meta-analysis of a few GWAS or epistasis analysis within a single GWAS).
In particular we will encourage the submissions addressing the detection of causative and marker SNVs and those tracking
the possible relationships between different region of the genome.
- Population genomics and phylogenetic analysis.
Variation is the driving force of evolution. SNVs are the most common form of genetic variation.
SNVs have been shown to be very useful for typing and resolving relationships between organisms of different species.
This research topic would encompass the discussion of advantages and limitations of SNV based algorithms for the analysis
of population genomic data and phylogenetically conserved genomic regions. We particularly encourage submissions discussing
SNVs in animal and bacterial models, as well as metagenomic studies.