Metabarcoding Options to Study Eukaryotic Endoparasites of Birds

Overview

Journal Ecol Evol

Date 2021 Aug 25

PMID 34429884

Citations 4

Authors

Vincent Bourret

Rafael Gutierrez Lopez

Martim Melo

Claire Loiseau

Affiliations

Soon will be listed here.

Abstract

There is growing interest in the study of avian endoparasite communities, and metabarcoding is a promising approach to complement more conventional or targeted methods. In the case of eukaryotic endoparasites, phylogenetic diversity is extreme, with parasites from 4 kingdoms and 11 phyla documented in birds. We addressed this challenge by comparing different primer sets across 16 samples from 5 bird species. Samples consisted of blood, feces, and controlled mixes with known proportions of bird and nematode DNA. Illumina sequencing revealed that a 28S primer set used in combination with a custom blocking primer allowed detection of various plasmodiid parasites and filarioid nematodes in the blood, coccidia in the feces, as well as two potentially pathogenic fungal groups. When tested on the controlled DNA mixes, these primers also increased the proportion of nematode DNA by over an order of magnitude. An 18S primer set, originally designed to exclude metazoan sequences, was the most effective at reducing the relative number of avian DNA sequences and was the only one to detect in the blood. Expectedly, however, it did not allow nematode detection and also failed to detect avian malaria parasites. This study shows that a 28S set including a blocking primer allows detection of several major and very diverse bird parasite clades, while reliable amplification of all major parasite groups may require a combination of markers. It helps clarify options for bird parasite metabarcoding, according to priorities in terms of the endoparasite clades and the ecological questions researchers wish to focus on.

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Metabarcoding options to study eukaryotic endoparasites of birds.

Bourret V, Gutierrez Lopez R, Melo M, Loiseau C Ecol Evol. 2021; 11(16):10821-10833.

PMID: 34429884 PMC: 8366860. DOI: 10.1002/ece3.7748.

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