Abstract
The sequencing of ancient DNA samples provides a novel way to find, characterize, and distinguish exogenous genomes of endogenous targets. After sequencing, computational composition analysis enables filtering of undesired sources in the focal organism, with the purpose of improving the quality of assemblies and subsequent data analysis. More importantly, such analysis allows extinct and extant species to be identified without requiring a specific or new sequencing run. However, the identification of exogenous organisms is a complex task, given the nature and degradation of the samples, and the evident necessity of using efficient computational tools, which rely on algorithms that are both fast and highly sensitive. In this work, we relied on a fast and highly sensitive tool, FALCON-meta, which measures similarity against whole-genome reference databases, to analyse the metagenomic composition of an ancient polar bear (Ursus maritimus) jawbone fossil. The fossil was collected in Svalbard, Norway, and has an estimated age of 110,000 to 130,000 years. The FASTQ samples contained 349 GB of nonamplified shotgun sequencing data. We identified and localized, relative to the FASTQ samples, the genomes with significant similarities to reference microbial genomes, including those of viruses, bacteria, and archaea, and to fungal, mitochondrial, and plastidial sequences. Among other striking features, we found significant similarities between modern-human, some bacterial and viral sequences (contamination) and the organelle sequences of wild carrot and tomato relative to the whole samples. For each exogenous candidate, we ran a damage pattern analysis, which in addition to revealing shallow levels of damage in the plant candidates, identified the source as contamination.
Highlights
Due to constant low temperatures, glacial ice and permafrost environments provide potential conditions for long-term survival of DNA molecules, increasing the likelihood of ancient DNAauthentication [1,2,3,4]
The sequencing of the ancient polar bear (PB) genome [6,7] and its comparison against the genomes of other bears revealed an evolutionary history characterized by gene flow across species [8], allowed the identification of an endogenous bear retrovirus [9], and provided evidence of past climate change [7]
We study the metagenomic composition of a sequenced polar bear tooth sample, using the FALCON-meta tool
Summary
Due to constant low temperatures, glacial ice and permafrost environments provide potential conditions for long-term survival of DNA molecules, increasing the likelihood of ancient DNA (aDNA)authentication [1,2,3,4]. The jawbone fossil of an ancient polar bear (Ursus maritimus) is one of the best-preserved fossils discovered so far given its age [5]. This fossil was collected in the Poolepynten. The sequencing of the ancient polar bear (PB) genome [6,7] and its comparison against the genomes of other bears revealed an evolutionary history characterized by gene flow across species [8], allowed the identification of an endogenous bear retrovirus [9], and provided evidence of past climate change [7]. The sequencing of ancient species allows DNA of endogenous and exogenous origins to be identified. In addition to rare examples of addition of exogenous ancient microorganisms [11,12], contamination is known to be a primary cause of inclusion of exogenous microorganisms [1,13]
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