Migratory behavior and winter geography drive differential range shifts of eastern birds in response to recent climate change

Rushing, Clark S.; Royle, J. Andrew; Ziolkowski, David J.; Pardieck, Keith L.

doi:10.1073/pnas.2000299117

Cited by 85 publications

(85 citation statements)

References 54 publications

(62 reference statements)

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“…Some species may have even shifted their ranges northwards, either temporarily or through the winter, appearing on more checklists because they became more common in the area affected by the heat wave. Recent evidence suggests that, as a result of a warming winter climate, resident birds (including most of those tested) are responding more strongly than other bird groups by shifting northward and colonizing new areas along northern leading edge of their breeding ranges (La Sorte and Thompson 2007, Rushing et al 2020).…”

Section: Resultsmentioning

confidence: 99%

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

2021

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Extreme weather events are increasing in frequency and intensity as a result of modern climate change. During winter, species may be especially vulnerable to extreme weather as they are surviving on scarce resources and living at the edge of their thermal limits. We compiled data from eBird, a global citizen science initiative, to examine how 41 eastern North American birds shifted their occurrence and abundance patterns immediately following two recent extreme weather events each affecting > 2 million km2, the intrusion of a polar vortex and a winter heat wave. eBird data is continuously collected at high spatiotemporal resolution across large spatial extents, allowing us to compare species' responses immediately before and after these extreme events with trends in other winters across geographic scales. Overall, we found that birds responded differently to each extreme weather event. Bird occurrence rates did not change following the polar vortex, but where species occurred, population density was temporarily reduced, suggesting reductions in number of individuals driven by decreases in behavioral activity or temporary movement out of the area. However, birds demonstrated widespread increases in occurrence and increases in density and number of individuals where they occurred for at least 20 days after the heat wave, hinting at longer‐term range changes. Smaller‐bodied, warm‐adapted passerines tended to be most sensitive to extreme weather and responded most negatively to the polar vortex and most positively to the heat wave, while larger‐bodied, cold‐adapted waterbirds expressed only mild responses to either event. Thus, certain species may be exceptionally sensitive to extreme weather events while others are less sensitive. As climate change progresses and climatic variability increases, researchers and managers must better quantify the broad‐scale sensitivity of different species to multiple types of extreme weather events.

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Section: Resultsmentioning

confidence: 99%

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

2021

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“…This counterintuitive result occurs because climate change opens up newly available thermal niche space in waters north of the current day geographic range 20 , and the evolution of CTmin extends this range expansion further still. Northward range expansion with climate change due to increasing habitat availability has also been documented in birds 38-41 , plants 42 , other fishes 43-45 , and pest species (such as ticks 46-48 and mountain pine beetle 49,50 ), as well as in large scale analyses of diverse taxa assessing the ‘fingerprints’ of climate change impacts 51,52 . However, it is likely that evolution of CTmax will also play a role in responses to environmental change 53-55 .…”

Section: Discussionmentioning

confidence: 98%

Evolution of thermal physiology alters the projected range of threespine stickleback under climate change

Mogensen

Barry

et al. 2021

Preprint

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Species distribution models (SDMs) are widely adopted to predict range shifts but can be unreliable under climate change scenarios because they do not account for evolution. The thermal physiology of a species is a key determinant of range but the impact of thermal trait evolution on SDMs has not been addressed. We identified a genetic basis for physiological traits that evolve in response to temperature change in threespine stickleback. Using these data, we created geographic range projections under two climate change scenarios where trait data was either static (‘no evolution’ model), allowed to evolve in agreement with published evolutionary rates for the trait (‘evolution’ model), or allowed to evolve with the rate of evolution scaled in association with the variance that is explained by QTL (‘PVE’ model). Here, we show that incorporating these traits and their evolution into SDMs substantially altered the predicted ranges for a widespread panmictic marine population, with increases in area of over 7-fold. Evolution-informed SDMs should therefore improve the precision of forecasting range dynamics under climate change, thereby aiding in their application to management and the protection of biodiversity.

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“…Migratory and insectivorous species are declining in temperate regions (Sanderson et al, 2006;Bowler et al, 2019;Rushing et al, 2020). Climate and land-use change often pose greater threats to migratory species than resident species due to the potential effects of these factors on the availability of arthropod prey and thermoregulation during periods of high energy demands (Both et al, 2010;McKechnie and Wolf, 2010;Pearce-Higgins et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Declines in Common and Migratory Breeding Landbird Species in South Korea Over the Past Two Decades

Kim

Choi

et al. 2021

Front. Ecol. Evol.

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Population declines in terrestrial bird species have been reported across temperate regions in the world and are attributed to habitat loss, climate change, or other direct mortality sources. North American and European studies indicate that long-distance migrants, common species, and species associated with grasslands and agricultural lands are declining at the greatest rates. However, data from East Asia on avian population trends and associated drivers are extremely sparse. We modeled changes in occupancy of 52 common breeding landbird species in South Korea between 1997–2005 and 2013–2019. Thirty-eight percent of the species showed evidence of declines, and seven of these were declining severely (46–95%). Occupancy of Black-capped Kingfisher (Halcyon pileata) populations have dropped the most precipitously over the study period. Among declining species, long-distance migrants (9/20) and common species (14/20) showed more rapid declines than other groups. Declines of five species were associated with climate change, and two species appeared to be affected by land-cover change. However, causes of change in occupancy of other species (46/52) remains cryptic. Based on our results, we suggest an immediate re-evaluation of species’ conservation status and legal protection levels for seven severely declining species in South Korea, and a dedicated survey design and analysis effort for the continued monitoring landbird populations. Because many species exhibiting declines migrate from beyond national boundaries, international collaborations will be required to better quantify population trends across the full annual cycle, and to understand mechanisms for these declines.

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Migratory behavior and winter geography drive differential range shifts of eastern birds in response to recent climate change

Cited by 85 publications

References 54 publications

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

Extreme winter weather disrupts bird occurrence and abundance patterns at geographic scales

Evolution of thermal physiology alters the projected range of threespine stickleback under climate change

Declines in Common and Migratory Breeding Landbird Species in South Korea Over the Past Two Decades

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