Fitness landscapes and life‐table response experiments predict the importance of local areas to population dynamics

Kane, Kristin; Sedinger, James S.; Gibson, Daniel D.; Blomberg, Erik J.; Atamian, Michael T.

doi:10.1002/ecs2.1869

Cited by 10 publications

(14 citation statements)

References 101 publications

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“…We also found chick survival near the FG transmission line was reduced in years of high raven numbers. However, on average, areas near the FG transmission line were associated with the highest levels of chick survival in our system, which suggests this habitat remained the best option for brood‐rearing (Kane et al ) despite high mortality during years of greater predator abundance. Raven densities have been reported to be greater near sage‐grouse brood‐rearing areas (Bui et al ), indicative of response (either numerical or functional) by ravens to increased food abundance.…”

Section: Discussionmentioning

confidence: 80%

Effects of power lines on habitat use and demography of greater sage‐grouse (Centrocercus urophasianus)

Gibson

Blomberg

Atamian

et al. 2018

Wildlife Monographs

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Energy development and its associated infrastructure, including power lines, may influence wildlife population dynamics through effects on survival, reproduction, and movements of individuals. These infrastructure impacts may be direct or indirect, the former occurring when development acts directly as an agent of mortality (e.g., collision) and the latter when impacts occur as a by-product of other processes that are altered by infrastructure presence. Functional or numerical responses by predators to power-line corridors are indirect impacts that may suppress demographic rates for certain species, and perceived predation risk may affect animal behaviors such as habitat selection. Greater sage-grouse (Centrocercus urophasianus) are a species of conservation concern across western North America that may be affected by power lines. Previous studies, however, have not provided evidence for causal mechanisms influencing demographic rates. Our primary objective was to assess the influence of power lines on multiple sage-grouse vital rates, greater sage-grouse habitat selection, and ultimately greater sage-grouse population dynamics. We used demographic and behavioral data for greater sage-grouse collected from 2003 to 2012 in central Nevada, USA, accounting for sources of underlying environmental heterogeneity. We also concurrently monitored populations of common ravens (Corvus corax), a primary predator of sage-grouse nests and young. We focused primarily on a single 345 kV transmission line that was constructed at the beginning of our study; however, we also determined if similar patterns were associated with other nearby, preexisting power lines. We found that numerous behaviors (e.g., nest-site selection, brood-site selection) and demographic rates (e.g., nest survival, recruitment, and population growth) were affected by power lines, and that these negative effects were predominantly explained by temporal variation in the relative abundance of common ravens. Specifically, in years of high common raven abundance, avoidance of the transmission line was extended farther from the line, re-nesting propensity was reduced, and nest survival was lower near the transmission line relative to areas more distant from the transmission line. Additionally, we found that before and immediately after construction of the transmission line, habitats near the footprint of the transmission line were generally more productive (e.g., greater reproductive success and population growth) than areas farther from the transmission line. However, multiple demographic rates (i.e., pre-fledging chick survival, annual male survival, per capita recruitment, and population growth) for groups of individuals that used habitats near the transmission line declined to a greater extent than for individuals using habitats more distant in the years following construction of the transmission line. These decreases were correlated with an increase in common raven abundance. The geographical extent to which power lines negatively influence greater sage-grous...

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Section: Discussionmentioning

confidence: 80%

Effects of power lines on habitat use and demography of greater sage‐grouse (Centrocercus urophasianus)

Gibson

Blomberg

Atamian

et al. 2018

Wildlife Monographs

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“…Given that long‐term forecasts for western North America suggest accelerating land‐use and climate changes in the coming decades (Garfin, Jardine, Merideth, Black, & LeRoy, 2013; Seager et al., 2012) we expect several patterns to emerge along elevational clines. First, within these dry habitats, sage‐grouse seek the relatively more productive sites during the brood‐rearing phase to extend access to succulent vegetation (Kane, Sedinger, Gibson, Blomberg, & Atamian, 2017). To mitigate plant desiccation birds can select wetland habitats (Donnelly et al., 2018; Donnelly, Naugle, Hagen, & Maestas, 2016), or in areas of high topographic relief, track succulent vegetation upslope or across aspects (Dahlgren, Messmer, et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

Using satellite‐derived estimates of plant phenological rhythms to predict sage‐grouse nesting chronology

Stoner

Messmer

Larsen

et al. 2020

Ecology and Evolution

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The “green wave” hypothesis posits that during spring consumers track spatial gradients in emergent vegetation and associated foraging opportunities. This idea has largely been invoked to explain animal migration patterns, yet the general phenomenon underlies trends in vertebrate reproductive chronology as well. We evaluated the utility of this hypothesis for predicting spatial variation in nest initiation of greater sage‐grouse ( Centrocerus urophasianus ), a species of conservation concern in western North America. We used the Normalized Difference Vegetation Index (NDVI) to map the green wave across elevation and then compiled dates and locations of >450 sage‐grouse nests from 20 study sites (2000–2014) to model nest initiation as a function of the start of the growing season (SOS), defined here as the maximum daily rate of increase in NDVI. Individual sites were drawn from three ecoregions, distributed over 4.5° latitude, and spanning 2,300 m in elevation, which captured the climatic, edaphic, and floristic diversity of sagebrush ecosystems in the southern half of current sage‐grouse range. As predicted, SOS displayed a significant, positive relationship with elevation, occurring 1.3 days later for each 100 m increase in elevation. In turn, sage‐grouse nest initiation followed SOS by 22 ± 10 days ( r 2 = .57), with hatch dates falling on or just prior to the peak of the growing season. By timing nesting to the green wave, sage‐grouse chicks hatched when the abundance of protein‐rich invertebrate biomass is hypothesized to be nearing a seasonal high. This adaptation likely represents a strategy for maximizing reproductive success in the arid, variable environments that define sagebrush ecosystems. Given projected changes in climate and land use, these results can be used to predict periods of relative sensitivity to habitat disturbance for sage‐grouse. Moreover, the near real‐time availability of satellite imagery offers a heretofore underutilized means of mapping the green wave, planning habitat restoration, and monitoring range conditions.

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“…The resulting overall value per pixel was between 0 (not suitable) and 1 (maximally suitable). Statistical habitat suitability models are not constructed with multiple HSIs or an evenness index (e.g., [33,34]). However, in the absence of sufficient demographic data, the above methods account for both the contribution of seasonal habitat suitability and whether some seasonal habitats were deficient and, as a result, lowered the overall habitat suitability [33,34] as the evenness index does.…”

Section: Greater Sage-grouse Habitat Suitabilitymentioning

confidence: 99%

“…Despite million-dollar investments in restoration, significant differences in habitat suitability indices between CUSTODIAL and PREFERRED management rarely exceeded 5% in absolute value for GSG (Table 8) and 10% for UPD (Table 9). This was expected because RSFs incorporate important physical characteristics of the landscape that do not change at all, such as distance to roads, leks, and moist summer vegetation for chick rearing (Supplemental File S6) [33,34]. Therefore, absolute values of 5% and 10%, respectively, change in habitat suitability might represent a sizable improvement to GSG and UPD demography.…”

Section: Unified Ecological Departure Vs Habitat Suitabilitymentioning

confidence: 99%

Landscape Conservation Forecasting for Data-Poor at-Risk Species on Western Public Lands, United States

Provencher

Badik

Anderson

et al. 2021

Climate

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Managing vast federal public lands governed by multiple land use policies creates challenges when demographic data on at-risk species are lacking. The U.S. Bureau of Land Management Cedar City Field Office used this project in the Black Mountains (Utah) to inform vegetation management supporting at-risk greater sage-grouse and Utah prairie dog planning. Ecological systems were mapped from satellite remote sensing imagery and used to model species habitat suitability under two levels of management activity (custodial, preferred) and climate scenarios for historic and two global circulation models. Spatial state-and-transition models of ecological systems were simulated for all six scenarios up to 60 years while coupled with expert-developed habitat suitability indices. All ecological systems are at least moderately departed from reference conditions in 2012, whereas habitat suitability was 50.5% and 48.4% for sage-grouse and prairie dog, respectively. Management actions replaced non-native annual grasslands with perennial grasses, removed conifers, and controlled exotic forbs. The drier climate most affected ecological departure and prairie dog habitat suitability at 30 years only. Different climates influenced spatial patterns of sage-grouse habitat suitability, but nonspatial values were unchanged. Climate impacts on fire, vegetation succession, and restoration explain many results. Front-loading restoration is predicted to benefit under future drier climate.

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Fitness landscapes and life‐table response experiments predict the importance of local areas to population dynamics

Cited by 10 publications

References 101 publications

Effects of power lines on habitat use and demography of greater sage‐grouse (Centrocercus urophasianus)

Effects of power lines on habitat use and demography of greater sage‐grouse (Centrocercus urophasianus)

Using satellite‐derived estimates of plant phenological rhythms to predict sage‐grouse nesting chronology

Landscape Conservation Forecasting for Data-Poor at-Risk Species on Western Public Lands, United States

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