Abstract
Ecosystems transition quickly in the Anthropocene, whereas biodiversity adapts more slowly. Here we simulated a shifting woodland ecosystem on the Colorado Plateau of western North America by using as its proxy over space and time the fundamental niche of the Arizona black rattlesnake (Crotalus cerberus). We found an expansive (= end-of-Pleistocene) range that contracted sharply (= present), but is blocked topographically by Grand Canyon/Colorado River as it shifts predictably northwestward under moderate climate change (= 2080). Vulnerability to contemporary wildfire was quantified from available records, with forested area reduced more than 27% over 13 years. Both ‘ecosystem metrics' underscore how climate and wildfire are rapidly converting the Plateau ecosystem into novel habitat. To gauge potential effects on C. cerberus, we derived a series of relevant ‘conservation metrics' (i.e. genetic variability, dispersal capacity, effective population size) by sequencing 118 individuals across 846 bp of mitochondrial (mt)DNA-ATPase8/6. We identified five significantly different clades (net sequence divergence = 2.2%) isolated by drainage/topography, with low dispersal (FST = 0.82) and small sizes (2Nef = 5.2). Our compiled metrics (i.e. small-populations, topographic-isolation, low-dispersal versus conserved-niche, vulnerable-ecosystem, dispersal barriers) underscore the susceptibility of this woodland specialist to a climate and wildfire tandem. We offer adaptive management scenarios that may counterbalance these metrics and avoid the extirpation of this and other highly specialized, relictual woodland clades.
Highlights
Geomorphic processes drive major ecosystem shifts, whereas more gradual changes in the natural environment promote their diversification
Based on the insights gained from estimating these niche and conservation metrics, we offer potential policy enhancements that could facilitate the management of both the ecosystem and its biodiversity moving forward
With less stringent climate predictors [21], the ecological niche model (ENM) further condensed to higher elevations at the northern periphery of the core area, but with a major extension to the extreme northwest (2080: figure 2c; contemporary range of C. cerberus framed in green)
Summary
Geomorphic processes drive major ecosystem shifts, whereas more gradual changes in the natural environment promote their diversification. This synergistic ontogeny forms the baseline for a contemporary perspective on ecosystem evolution where environmental transformations are both shared and codependent with resident biodiversity [1]. It yields a series of ‘ecosystem metrics’ that document the manner by which ecosystems transition over time, and the concomitant constraints that can emerge with these shifts [2], when transformations are inordinately forced. Conservation metrics are most derived from molecular data that, in turn, can determine the origin of populations (via coalescence among clades), their levels of connectivity (by quantifying gene flow), as well as their persistence over time (by estimating genetic diversity, demographic trends and effective sizes) [5,6]
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