Drastic population fluctuations explain the rapid extinction of the passenger pigeon

Hung, Chih Ming; Shaner, Pei Jen L.; Zink, Robert M.; Liu, Wei-Chung; Chu, Te Chin; Huang, Wen; Li, Shou Hsien

doi:10.1073/pnas.1401526111

Cited by 145 publications

(139 citation statements)

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“…One such method is the Pairwise Sequentially Markovian Coalescent model (PSMC; Li & Durbin, 2011). It allows for the tracking of species’ effective population size ( N e ) from 10 thousand years ago (kya) through to Early Pleistocene/Late Pliocene (~3 million years ago [Mya]) from the genome of just one individual (Hung et al., 2014; Nadachowska‐Brzyska, Li, Smeds, Zhang, & Ellegren, 2015; Zhao et al., 2013). It therefore the ideal tool to study whether the changes in range size through time, as determined by SDM, reflect the changes in population size.…”

Section: Introductionmentioning

confidence: 99%

Past and potential future population dynamics of three grouse species using ecological and whole genome coalescent modeling

Kozma

Lillie

Benito

et al. 2018

Ecology and Evolution

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Studying demographic history of species provides insight into how the past has shaped the current levels of overall biodiversity and genetic composition of species, but also how these species may react to future perturbations. Here we investigated the demographic history of the willow grouse (Lagopus lagopus), rock ptarmigan (Lagopus muta), and black grouse (Tetrao tetrix) through the Late Pleistocene using two complementary methods and whole genome data. Species distribution modeling (SDM) allowed us to estimate the total range size during the Last Interglacial (LIG) and Last Glacial Maximum (LGM) as well as to indicate potential population subdivisions. Pairwise Sequentially Markovian Coalescent (PSMC) allowed us to assess fluctuations in effective population size across the same period. Additionally, we used SDM to forecast the effect of future climate change on the three species over the next 50 years. We found that SDM predicts the largest range size for the cold‐adapted willow grouse and rock ptarmigan during the LGM. PSMC captured intraspecific population dynamics within the last glacial period, such that the willow grouse and rock ptarmigan showed multiple bottlenecks signifying recolonization events following the termination of the LGM. We also see signals of population subdivision during the last glacial period in the black grouse, but more data are needed to strengthen this hypothesis. All three species are likely to experience range contractions under future warming, with the strongest effect on willow grouse and rock ptarmigan due to their limited potential for northward expansion. Overall, by combining these two modeling approaches, we have provided a multifaceted examination of the biogeography of these species and how they have responded to climate change in the past. These results help us understand how cold‐adapted species may respond to future climate changes.

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Section: Introductionmentioning

confidence: 99%

Past and potential future population dynamics of three grouse species using ecological and whole genome coalescent modeling

Kozma

Lillie

Benito

et al. 2018

Ecology and Evolution

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“…The potential for rediscovering our lost natural history has been on the minds of ecologists with the recent centennial anniversary of the death of the last captive passenger pigeon ( Ectopistes migratorius Linnaeus) in 1914, and the controversial “resighting” of the ivory‐billed woodpecker ( Campephilus principalis Linnaeus, Fitzpatrick et al., 2005 but see Sibley, Bevier, Patten, & Elphick, 2006). Indeed, much recent research has focused on these recently extinct, iconic North American birds (e.g., Gotelli, Chao, Colwell, Hwang, & Graves, 2012; Hung et al., 2014; Stanton, 2014), but this research largely focuses on attempts to determine exact extinction dates and immediate causes of extinction. By contrast, another iconic, extinct, North American bird, the Carolina parakeet ( Conuropsis carolinensis Linnaeus), has received relatively less attention, especially over the past 30 years.…”

Section: Introductionmentioning

confidence: 99%

Lazarus ecology: Recovering the distribution and migratory patterns of the extinct Carolina parakeet

Burgio

Carlson

Tingley

2017

Ecology and Evolution

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The study of the ecology and natural history of species has traditionally ceased when a species goes extinct, despite the benefit to current and future generations of potential findings. We used the extinct Carolina parakeet as a case study to develop a framework investigating the distributional limits, subspecific variation, and migratory habits of this species as a means to recover important information about recently extinct species. We united historical accounts with museum collections to develop an exhaustive, comprehensive database of every known occurrence of this once iconic species. With these data, we combined species distribution models and ordinal niche comparisons to confront multiple conjectured hypotheses about the parakeet's ecology with empirical data on where and when this species occurred. Our results demonstrate that the Carolina parakeet's range was likely much smaller than previously believed, that the eastern and western subspecies occupied different climatic niches with broad geographical separation, and that the western subspecies was likely a seasonal migrant while the eastern subspecies was not. This study highlights the novelty and importance of collecting occurrence data from published observations on extinct species, providing a starting point for future investigations of the factors that drove the Carolina parakeet to extinction. Moreover, the recovery of lost autecological knowledge could benefit the conservation of other parrot species currently in decline and would be crucial to the success of potential de‐extinction efforts for the Carolina parakeet.

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“…Conversion of key refugia for the once abundant Rocky Mountain grasshopper (Melanoplus spretus) resulted in the extinction of a species that once existed in the USA in its trillions, and was thought to be an ineradicable pest (Lockwood & DeBrey 1990). Similarly, the passenger pigeon (Ectopistes migratorius) was once the most abundant bird in the world, with flocks of birds covering the sky for miles, yet recent research suggests that human exploitation coincided with natural population fluctuations to drive the species to extinction in just 50 years (Hung et al 2014). …”

Section: The Challenge Of Conservation Planning For Migratory Speciesmentioning

confidence: 99%

“…The impact of fluctuations on population persistence is a function of the number of subpopulations and the synchronicity of fluctuation across those populations (Lawton et al 1994). Both theory and empirical evidence predict that extinction risk is higher in species with highly fluctuating populations (Pimm et al 1988;Hung et al 2014 . These species evolved in a landscape where environmental conditions are dynamic, and strategies such as opportunistic breeding and diet switching may facilitate the ability of arid-zone birds to recover from bottlenecks (Dean 2004).…”

Section: 6 Trends In Habitat Suitability Fluctuate According To Geogmentioning

confidence: 99%

“…Such questions will be difficult, if not impossible, to answer empirically, but simulation experiments may provide some insights (Keith et al 2008). Recent work on the demise of the passenger pigeon (Ectopistes migratorius; Hung et al 2014) highlights that even hugely abundant species can decline rapidly if fluctuating environmental conditions coincide with increased threats. The lack of ecological knowledge in most existing nomadic species limits our understanding of the thresholds beyond which nomads are unlikely to bounce back from range declines, and we lack understanding on the extent to which the ability to recover depends on the timing and frequency of fluctuations.…”

Section: Future Directionsmentioning

confidence: 99%

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Conserving migratory and nomadic species

Runge¹

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Migration is an incredible phenomenon. Across cultures it moves and inspires us, from the first song of a migratory bird arriving in spring, to the sight of thousands of migratory wildebeest thundering across African plains. Not only important to us as humans, migratory species play a major role in ecosystem functioning across the globe. Migratory species use multiple landscapes and can have dramatically different ecologies across their lifecycle, making huge contributions to resource fluxes and nutrient transport. However, migrants around the world are in decline. In this thesis I examine our conservation response to these declines, exploring how well current approaches account for the unique needs of migratory species, and develop ways to improve on these. The movements of migratory species across time and space make their conservation a multidimensional problem, requiring actions to mitigate threats across jurisdictions, across habitat types and across time. Incorporating such linkages can make a dramatic difference to conservation success, yet migratory species are often treated for the purposes of conservation planning as if they were stationary, ignoring the complex linkages between sites and resources. In this thesis I measure how well existing global conservation networks represent these linkages, discovering major gaps in our current protection of migratory species. I then go on to develop tools for improving conservation of migratory species across two areas: prioritizing actions across species and designing conservation networks.Protected areas are one of our most effective conservation tools, and expanding the global protected area estate remains a priority at an international level. Globally, about 12.9% of the landscape is covered by protected areas, and in Chapter 2 I examine how well migratory birds are represented within current protected areas, specifically taking into account their need for protection across the annual cycle. I discover that just 9% of migratory birds meet standard protection targets across all parts of their migratory distribution, their breeding, non-breeding and passage distributions, in stark contrast to the 45% of non-migratory birds meeting the same targets. There is currently a major push to increase the size and comprehensiveness of the global protected area estate, and these findings highlight the need for greater emphasis on collaboration across nations to incorporate migratory connectivity into our approaches to protected area placement.One of the challenges to incorporating migratory connectivity into systematic conservation planning is that often we have only a poor understanding of the patterns of movements of migratory species ii in space and time. In Chapter 3 and 4 I develop a tool for discovering spatial dynamics in highly mobile yet data-poor species, unlocking valuable information for improved extinction risk assessment and conservation planning. Using Australian arid-zone nomadic birds as a case study, I reveal enormous variability in predicted spa...

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Drastic population fluctuations explain the rapid extinction of the passenger pigeon

Cited by 145 publications

References 45 publications

Past and potential future population dynamics of three grouse species using ecological and whole genome coalescent modeling

Past and potential future population dynamics of three grouse species using ecological and whole genome coalescent modeling

Lazarus ecology: Recovering the distribution and migratory patterns of the extinct Carolina parakeet

Conserving migratory and nomadic species

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