Linda Vigilant  Justin Roy  Brenda J. Bradley  Colin J. Stoneking  Martha M. Robbins  Tara S. Stoinski 《Behavioral ecology and sociobiology》2015,69(7):1163-1172

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Takao Sasaki  Blake Colling  Anne Sonnenschein  May M Boggess  Stephen C. Pratt 《Behavioral ecology and sociobiology》2015,69(5):707-714

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Carl N. Keiser  Colin M. Wright  Nishant Singh  Joseph A. DeShane  Andreas P. Modlmeier  Jonathan N. Pruitt 《Behavioral ecology and sociobiology》2015,69(3):395-405

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David A. Galbraith  Ying Wang  Gro V. Amdam  Robert E. Page  Christina M. Grozinger 《Behavioral ecology and sociobiology》2015,69(9):1511-1518

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Graham L. Banes  Biruté M. F. Galdikas  Linda Vigilant 《Behavioral ecology and sociobiology》2015,69(11):1785-1794

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Vincent Fugère  M. Teague O’Mara  Rachel A. Page 《Behavioral ecology and sociobiology》2015,69(8):1353-1364

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Longwu Wang  Canchao Yang  Anders P. Møller  Wei Liang  Xin Lu 《Behavioral ecology and sociobiology》2015,69(11):1761-1767

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James F. A. Traniello  Theo C. M. Bakker 《Behavioral ecology and sociobiology》2015,69(10):1573-1574

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Jurriaan M. De Vos  Lucas N. Joppa  John L. Gittleman  Patrick R. Stephens  Stuart L. Pimm 《Conservation biology》2015,29(2):452-462

A key measure of humanity's global impact is by how much it has increased species extinction rates. Familiar statements are that these are 100–1000 times pre‐human or background extinction levels. Estimating recent rates is straightforward, but establishing a background rate for comparison is not. Previous researchers chose an approximate benchmark of 1 extinction per million species per year (E/MSY). We explored disparate lines of evidence that suggest a substantially lower estimate. Fossil data yield direct estimates of extinction rates, but they are temporally coarse, mostly limited to marine hard‐bodied taxa, and generally involve genera not species. Based on these data, typical background loss is 0.01 genera per million genera per year. Molecular phylogenies are available for more taxa and ecosystems, but it is debated whether they can be used to estimate separately speciation and extinction rates. We selected data to address known concerns and used them to determine median extinction estimates from statistical distributions of probable values for terrestrial plants and animals. We then created simulations to explore effects of violating model assumptions. Finally, we compiled estimates of diversification—the difference between speciation and extinction rates for different taxa. Median estimates of extinction rates ranged from 0.023 to 0.135 E/MSY. Simulation results suggested over‐ and under‐estimation of extinction from individual phylogenies partially canceled each other out when large sets of phylogenies were analyzed. There was no evidence for recent and widespread pre‐human overall declines in diversity. This implies that average extinction rates are less than average diversification rates. Median diversification rates were 0.05–0.2 new species per million species per year. On the basis of these results, we concluded that typical rates of background extinction may be closer to 0.1 E/MSY. Thus, current extinction rates are 1,000 times higher than natural background rates of extinction and future rates are likely to be 10,000 times higher. Estimación de la Tasa Normal de Extinción de Especies  相似文献   

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Sebastian Seibold  Roland Brandl  Jörn Buse  Torsten Hothorn  Jürgen Schmidl  Simon Thorn  Jörg Müller 《Conservation biology》2015,29(2):382-390

To reduce future loss of biodiversity and to allocate conservation funds effectively, the major drivers behind large‐scale extinction processes must be identified. A promising approach is to link the red‐list status of species and specific traits that connect species of functionally important taxa or guilds to resources they rely on. Such traits can be used to detect the influence of anthropogenic ecosystem changes and conservation efforts on species, which allows for practical recommendations for conservation. We modeled the German Red List categories as an ordinal index of extinction risk of 1025 saproxylic beetles with a proportional‐odds linear mixed‐effects model for ordered categorical responses. In this model, we estimated fixed effects for intrinsic traits characterizing species biology, required resources, and distribution with phylogenetically correlated random intercepts. The model also allowed predictions of extinction risk for species with no red‐list category. Our model revealed a higher extinction risk for lowland and large species as well as for species that rely on wood of large diameter, broad‐leaved trees, or open canopy. These results mirror well the ecological degradation of European forests over the last centuries caused by modern forestry, that is the conversion of natural broad‐leaved forests to dense conifer‐dominated forests and the loss of old growth and dead wood. Therefore, conservation activities aimed at saproxylic beetles in all types of forests in Central and Western Europe should focus on lowlands, and habitat management of forest stands should aim at increasing the amount of dead wood of large diameter, dead wood of broad‐leaved trees, and dead wood in sunny areas.  相似文献