Testing the Role of Meander Cutoff in Promoting Gene Flow across a Riverine Barrier in Ground Skinks (Scincella lateralis)

Nathan D Jackson,Christopher C Austin,Carles Lalueza-Fox

doi:10.1371/journal.pone.0062812

Nathan D Jackson, Christopher C Austin + Show 1 more

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https://doi.org/10.1371/journal.pone.0062812

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Abstract

Despite considerable attention, the long-term impact of rivers on species diversification remains uncertain. Meander loop cutoff (MLC) is one river phenomenon that may compromise a river’s diversifying effects by passively transferring organisms from one side of the river to the other. However, the ability of MLC to promote gene flow across rivers has not been demonstrated empirically. Here, we test several predictions of MLC-mediated gene flow in populations of North American ground skinks (Scincella lateralis) separated by a well-established riverine barrier, the Mississippi River: 1) individuals collected from within meander cutoffs should be more closely related to individuals across the river than on the same side, 2) individuals within meander cutoffs should contain more immigrants than individuals away from meander cutoffs, 3) immigration rates estimated across the river should be highest in the direction of the cutoff event, and 4) the distribution of alleles native to one side of the river should be better predicted by the historical rather than current path of the river. To test these predictions we sampled 13 microsatellite loci and mitochondrial DNA from ground skinks collected near three ancient meander loops. These predictions were generally supported by genetic data, although support was stronger for mtDNA than for microsatellite data. Partial support for genetic divergence of samples within ancient meander loops also provides evidence for the MLC hypothesis. Although a role for MLC-mediated gene flow was supported here for ground skinks, the transient nature of river channels and morphologies may limit the long-term importance of MLC in stemming population divergence across major rivers.

Highlights

Much attention has been paid to understanding the role of large rivers in biogeography, their impact on species diversification is still controversial [1,2,3,4,5,6]
We investigate the role of Meander loop cutoff (MLC) in facilitating gene flow between lineages of a common lizard species that are separated by a well-known riverine barrier, the Mississippi River
Given that we have sampled within the putative contact zone between two genetically distinct populations, a Wahlund effect produced by the co-occurrence of unique gene pools within sampling sites is a likely reason for the observed disequilibrium

Summary

Introduction

Much attention has been paid to understanding the role of large rivers in biogeography, their impact on species diversification is still controversial [1,2,3,4,5,6]. Major rivers undoubtedly impede dispersal for many terrestrial organisms, but these rivers may not be sufficiently impenetrable or long-lived to commonly facilitate speciation [1,7]. Meander loop cutoff (MLC) is an additional factor often cited to explain why rivers are poor long-term dispersal barriers [1,3,5,8,9,10]. Often cited as a problem for the riverine barrier hypothesis, passive transport due to MLC has yet to be empirically demonstrated, likely due in part to the logistical challenge of collecting large samples of individuals along a series of these ancient meander loops

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