Environmental DNA reflects common haplotypic variation

Abstract Analysis of environmental DNA (eDNA) has gained widespread usage for taxonomically based biodiversity assessment. While interest in applying non-invasive eDNA monitoring for population genetic assessments has grown, its usage in this sphere remains limited. One barrier to uptake is that the effectiveness of eDNA detection below the species level remains to be determined for multiple species and environments. Here, we test the utility of this emergent technology in a population genetic framework using eDNA samples derived from water along New Zealand’s South Island (Otago Coast: n=9; Kaikōura: n=7) and DNA obtained from tissue samples (n=76) of individual blackfoot pāua (Haliotis iris) sampled from New Zealand’s Otago coast. We recovered four mitochondrial haplotypes from eDNA versus six from the tissue samples collected. Three common haplotypes were recovered with both eDNA and tissue samples, while only one out of three rare haplotypes – represented in tissue samples by one individual each – was recovered with our eDNA methods. We demonstrate that eDNA monitoring is an effective tool for recovering common genetic diversity from pāua, although rare (< 5%) haplotypes are seldom recovered. Our results show the potential of eDNA to identify population-level haplotypes for gastropods in the marine environment identification below the species level and for studying the population genetic diversity of gastropods. This work supports eDNA methods as effective, non-invasive tools for genetic monitoring. Non-invasive eDNA sampling could minimize target organism stress and human interaction enabling population genetic research for hard-to-sample, delicate, or sensitive species.