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Novel Sequence Discovery by Subtractive Genomics
Published on: January 25, 2019
Disentangling cobionts and contamination in long-read genomic data using sequence composition.
1Tree of Life, Wellcome Sanger Institute, Wellcome Genome Campus, Hinxton CB10 1SA, UK.
This study introduces a novel computational method for separating mixed genomes from environmental samples. It leverages sequence composition to identify symbionts and contaminants, reducing reliance on reference databases.
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Area of Science:
- Genomics
- Bioinformatics
- Computational Biology
Background:
- Genome sequencing projects are expanding to diverse life forms, creating computational challenges in analyzing mixed-species samples.
- Environmental samples frequently contain target organisms alongside symbiotic partners (cobionts) and contaminants, necessitating effective sequence separation methods.
- Current reference-based methods struggle with underrepresented eukaryotic taxa, highlighting the need for alternative approaches.
Purpose of the Study:
- To develop and evaluate a computational strategy for distinguishing between target organisms, cobionts, and contaminants in sequencing data.
- To minimize dependence on comprehensive reference databases by utilizing intrinsic sequence composition differences.
- To enable the analysis of complex environmental samples, including those from the Darwin Tree of Life project.
Main Methods:
- Utilizing variational autoencoders to learn two-dimensional representations of read tetranucleotide composition.
- Visualizing these learned embeddings to identify distinct organismal components within a sample.
- Integrating additional data like coding density, coverage, and taxonomic labels for annotation and assessment.
- Applying the method to large-scale insect genome data from the Darwin Tree of Life project.
Main Results:
- Distinct clusters representing different organisms were successfully visualized in the sequence composition embeddings.
- The approach demonstrated scalability to millions of sequences, enabling analysis of unassembled read sets.
- Interactive visualization facilitated rapid assessment and identification of sample components.
- A significant portion of cobionts identified by reference-based screening were corroborated, and novel genomes were retrieved.
Conclusions:
- Sequence composition analysis, particularly using dimensionality reduction techniques like variational autoencoders, offers a powerful, reference-light approach for dissecting complex environmental sequencing data.
- This method effectively identifies symbionts and contaminants and aids in retrieving genomes lacking robust reference data.
- The approach is scalable and valuable for large-scale genome sequencing initiatives like the Darwin Tree of Life project.