Pavlović, Milena; Scheffer, Lonneke; Motwani, Keshav; Kanduri, Chakravarthi; Kompova, Radmila & Vazov, Nikolay Aleksandrov
[Show all 41 contributors for this article](2021).
The immuneML ecosystem for machine learning analysis of adaptive immune receptor repertoires.
Nature Machine Intelligence.
3(11),
p. 936–944.
doi: 10.1038/s42256-021-00413-z.
Grytten, Ivar; Rand, Knut Dagestad; Nederbragt, Alexander Johan & Sandve, Geir Kjetil
(2020).
Assessing graph-based read mappers against a baseline approach highlights strengths and weaknesses of current methods.
BMC Genomics.
ISSN 1471-2164.
21.
doi: 10.1186/s12864-020-6685-y.
Full text in Research Archive
Grytten, Ivar; Rand, Knut Dagestad; Nederbragt, Alexander Johan; Storvik, Geir Olve; Glad, Ingrid Kristine & Sandve, Geir Kjetil
(2019).
Graph Peak Caller: Calling ChIP-seq peaks on graph-based reference genomes.
PLoS Computational Biology.
ISSN 1553-734X.
15(2),
p. 1–13.
doi: 10.1371/journal.pcbi.1006731.
Full text in Research Archive
Rand, Knut Dagestad; Grytten, Ivar; Nederbragt, Alexander Johan; Storvik, Geir Olve; Glad, Ingrid Kristine & Sandve, Geir Kjetil
(2017).
Coordinates and intervals in graph-based reference genomes.
BMC Bioinformatics.
ISSN 1471-2105.
18:263,
p. 1–8.
doi: 10.1186/s12859-017-1678-9.
Full text in Research Archive
Background: Recent large-scale undertakings such as ENCODE and Roadmap Epigenomics have generated experimental data mapped to the human reference genome (as genomic tracks) representing a variety of functional elements across a large number of cell types. Despite the high potential value of these publicly available data for a broad variety of investigations, little attention has been given to the analytical methodology necessary for their widespread utilisation. Findings: We here present a first principled treatment of the analysis of collections of genomic tracks. We have developed novel computational and statistical methodology to permit comparative and confirmatory analyses across multiple and disparate data sources. We delineate a set of generic questions that are useful across a broad range of investigations and discuss the implications of choosing different statistical measures and null models. Examples include contrasting analyses across different tissues or diseases. The methodology has been implemented in a comprehensive open-source software system, the GSuite HyperBrowser. To make the functionality accessible to biologists, and to facilitate reproducible analysis, we have also developed a web-based interface providing an expertly guided and customizable way of utilizing the methodology. With this system, many novel biological questions can flexibly be posed and rapidly answered. Conclusions: Through a combination of streamlined data acquisition, interoperable representation of dataset collections and customizable statistical analysis with guided setup and interpretation, the GSuite HyperBrowser represents a first comprehensive solution for integrative analysis of track collections across the genome and epigenome. The software is available at: https://hyperbrowser.uio.no