AI Article Synopsis
- Whole-genome sequencing (WGS) is revealing disease-related variants in various diseases, but accurate annotation remains a challenge for researchers due to the need for reliable computational methods.
- A new tool called gNOME has been developed to streamline the annotation and analysis of genetic variants, offering a user-friendly interface and comprehensive summaries across different levels.
- gNOME has been tested against existing datasets for cancers and has proven effective in accurately annotating variants and identifying significant genetic associations while being freely accessible to researchers.
Article Abstract
Whole-genome sequencing (WGS) studies are uncovering disease-associated variants in both rare and nonrare diseases. Utilizing the next-generation sequencing for WGS requires a series of computational methods for alignment, variant detection, and annotation, and the accuracy and reproducibility of annotation results are essential for clinical implementation. However, annotating WGS with up to date genomic information is still challenging for biomedical researchers. Here, we present one of the fastest and highly scalable annotation, filtering, and analysis pipeline-gNOME-to prioritize phenotype-associated variants while minimizing false-positive findings. Intuitive graphical user interface of gNOME facilitates the selection of phenotype-associated variants, and the result summaries are provided at variant, gene, and genome levels. Moreover, the enrichment results of specific variants, genes, and gene sets between two groups or compared with population scale WGS datasets that is already integrated in the pipeline can help the interpretation. We found a small number of discordant results between annotation software tools in part due to different reporting strategies for the variants with complex impacts. Using two published whole-exome datasets of uveal melanoma and bladder cancer, we demonstrated gNOME's accuracy of variant annotation and the enrichment of loss-of-function variants in known cancer pathways. gNOME Web server and source codes are freely available to the academic community (http://gnome.tchlab.org).
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4130156 | PMC |
| http://dx.doi.org/10.1002/humu.22520 | DOI Listing |
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