Applications of de Bruijn graphs in microbiome research

Abstract: High‐throughput sequencing has become an increasingly central component of microbiome research. The development of de Bruijn graph‐based methods for assembling high‐throughput sequencing data has been an important part of the broader adoption of sequencing as part of biological studies. Recent advances in the construction and representation of de Bruijn graphs have led to new approaches that utilize the de Bruijn graph data structure to aid in different biological analyses. One type of application of these met… Show more

“…Michel‐Mata et al [31] introduced a deep learning algorithm to predict microbiome composition. Reviews are also essential for peers to learn and begin their studies readily. Dufault‐Thompson et al [32] provided a comprehensive and insightful review of de Bruijn graphs' progress and future applications in microbiome studies. Wang et al [33] reviewed plant genetics‐mediated remodeling of microbiota and techniques in response to stress, and Yang et al [34] reviewed the advantages of the targeted approach in integrating metagenome data for accurate protein structure prediction.…”

iMeta: Integrated meta‐omics for biology and environments

“…Michel‐Mata et al [31] introduced a deep learning algorithm to predict microbiome composition. Reviews are also essential for peers to learn and begin their studies readily. Dufault‐Thompson et al [32] provided a comprehensive and insightful review of de Bruijn graphs' progress and future applications in microbiome studies. Wang et al [33] reviewed plant genetics‐mediated remodeling of microbiota and techniques in response to stress, and Yang et al [34] reviewed the advantages of the targeted approach in integrating metagenome data for accurate protein structure prediction.…”

iMeta: Integrated meta‐omics for biology and environments

“…One can think of a colored de Bruijn graph as a compressed representation of the k -mers in a collection of datasets, but which retains enough information (i.e., the color of every k -mer) in order to identify each dataset in this combined graph. Applications include [34, 3, 19, 33, 10], just to name a few.…”

“…One can think of a colored de Bruijn graph as a compressed representation of the k -mers in a collection of datasets, but which retains enough information (i.e., the color of every k -mer) in order to identify each dataset in this combined graph. Later applications include pangenomics [37], RNA-seq quantification [5], bacterial genome querying [22], alignment and reference-free phylogenomics [37], microbiome research [13], just to name a few.…”

Extremely-fast construction and querying of compacted and colored de Bruijn graphs with GGCAT