Your search keyword '"Aguilar-Pontes MV"' showing total 2 results

1. The gold-standard genome of Aspergillus niger NRRL 3 enables a detailed view of the diversity of sugar catabolism in fungi

Author

Aguilar-Pontes, MV, Brandl, J, McDonnell, E, Strasser, K, Nguyen, TTM, Riley, R, Mondo, S, Salamov, A, Nybo, JL, Vesth, TC, Grigoriev, IV, Andersen, MR, Tsang, A, and de Vries, RP

Subjects

Microbiology, Biological Sciences, Human Genome, Genetics, Aspergillus, Genomic diversity, Gold standard genome, Sugar catabolism, Mycology & Parasitology

Abstract

The fungal kingdom is too large to be discovered exclusively by classical genetics. The access to omics data opens a new opportunity to study the diversity within the fungal kingdom and how adaptation to new environments shapes fungal metabolism. Genomes are the foundation of modern science but their quality is crucial when analysing omics data. In this study, we demonstrate how one gold-standard genome can improve functional prediction across closely related species to be able to identify key enzymes, reactions and pathways with the focus on primary carbon metabolism. Based on this approach we identified alternative genes encoding various steps of the different sugar catabolic pathways, and as such provided leads for functional studies into this topic. We also revealed significant diversity with respect to genome content, although this did not always correlate to the ability of the species to use the corresponding sugar as a carbon source.

Published

2018

2. The gold-standard genome of Aspergillus niger NRRL 3 enables a detailed view of the diversity of sugar catabolism in fungi.

Author

Aguilar-Pontes, MV, Brandl, J, McDonnell, E, Strasser, K, Nguyen, TTM, Riley, R, Mondo, S, Salamov, A, Nybo, JL, Vesth, TC, Grigoriev, IV, Andersen, MR, Tsang, A, and de Vries, RP

Subjects

Aspergillus, Genomic diversity, Gold standard genome, Sugar catabolism, Genetics, Human Genome, Microbiology, Mycology & Parasitology

Abstract

The fungal kingdom is too large to be discovered exclusively by classical genetics. The access to omics data opens a new opportunity to study the diversity within the fungal kingdom and how adaptation to new environments shapes fungal metabolism. Genomes are the foundation of modern science but their quality is crucial when analysing omics data. In this study, we demonstrate how one gold-standard genome can improve functional prediction across closely related species to be able to identify key enzymes, reactions and pathways with the focus on primary carbon metabolism. Based on this approach we identified alternative genes encoding various steps of the different sugar catabolic pathways, and as such provided leads for functional studies into this topic. We also revealed significant diversity with respect to genome content, although this did not always correlate to the ability of the species to use the corresponding sugar as a carbon source.

Published

2018