Abstract
Changing drainage patterns have played a significant role in the evolution of western North American aquatic taxa. Relict dace, Relictus solitarius, is a Great Basin endemic cyprinid with a native range that is restricted to four valleys in eastern Nevada. Relictus solitarius now occupies spring systems that are the remnants of Pleistocene-era pluvial lakes, although it may have occurred in the area for much longer. Here we use mitochondrial DNA sequence data to assess range-wide genetic diversity of R. solitarius, and to estimate divergence times to determine whether pluvial drainages played an important role in shaping intraspecific genetic diversity. Genetic diversification within R. solitarius began during the early to mid-Pleistocene, separating populations within two sets of valleys (Butte/Ruby and Goshute/Steptoe). Additional diversification in each of the two sets of valleys occurred more recently, in the mid- to late-Pleistocene. Holocene desiccation has further isolated populations, and each population sampled contains unique mtDNA haplotypes. Pluvial drainage patterns did contribute to the genetic structure observed within R. solitarius, but most of the intraspecific diversification does not appear to be associated with the Last Glacial Maximum. Holocene desiccation has also contributed to the observed genetic structure. The relict dace populations we sampled are all unique, and we recommend that future management efforts should strive to preserve as much of the genetic diversity as possible.
Highlights
Western North American drainage patterns have been dramatically altered throughout the Cenozoic as a result of a myriad of geological processes and global climate shifts
We explored genetic variation at hierarchical geographic levels to determine which level best explains the observed variation
DNA sequencing yielded 1047 base pairs of NADH subunit 2 (ND2) that we combined with 1140 base pairs of cyt b from 79 relict dace individuals representing 8 populations
Summary
Western North American drainage patterns have been dramatically altered throughout the Cenozoic as a result of a myriad of geological processes and global climate shifts. The modern Great Basin comprises a series of endorheic hydrological basins (closed drainages with no outlet to the ocean). These basins formed as a result of the uplift and episodic extension of western. The westward extension of the Great Basin continued through the Miocene, and is still underway [1,2]. These drastic changes to the landscape sometimes disrupted regional hydrology. Several western North American freshwater fishes exhibit deep genetic divergences associated with these ancient changes to the landscape [10,11,12,13,14], and many exhibit intra-specific cryptic genetic diversity [15,16,17,18,19,20,21,22]
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