Ciência habilitada por dados de espécimes

de Oliveira, M. H. V., B. M. Torke, and T. E. Almeida. 2021. An inventory of the ferns and lycophytes of the Lower Tapajós River Basin in the Brazilian Amazon reveals collecting biases, sampling gaps, and previously undocumented diversity. Brittonia 73: 459–480. https://doi.org/10.1007/s12228-021-09668-7

Ferns and lycophytes are an excellent group for conservation and species distribution studies because they are closely related to environmental changes. In this study, we analyzed collection gaps, sampling biases, richness distribution, and the species conservation effectiveness of protected areas i…

Scherrer, D., M. Esperon‐Rodriguez, L. J. Beaumont, V. L. Barradas, and A. Guisan. 2021. National assessments of species vulnerability to climate change strongly depend on selected data sources J. S. Cabral [ed.],. Diversity and Distributions 27: 1367–1382. https://doi.org/10.1111/ddi.13275

Aim: Correlative species distribution models (SDMs) are among the most frequently used tools for conservation planning under climate and land use changes. Conservation-focused climate change studies are often conducted on a national or local level and can use different sources of occurrence records …

Klisz, M., R. Puchałka, M. Netsvetov, Y. Prokopuk, M. Vítková, J. Sádlo, R. Matisons, et al. 2021. Variability in climate-growth reaction of Robinia pseudoacacia in Eastern Europe indicates potential for acclimatisation to future climate. Forest Ecology and Management 492: 119194. https://doi.org/10.1016/j.foreco.2021.119194

As a consequence of native tree species decline and distribution range contraction in Europe, acclimation of the non-native tree species at the edge of their distribution is gaining importance. Although non-native tree species may provide sustainable ecosystem services, as a potentially invasive spe…

Mazijk, R., M. D. Cramer, and G. A. Verboom. 2021. Environmental heterogeneity explains contrasting plant species richness between the South African Cape and southwestern Australia. Journal of Biogeography 48: 1875–1888. https://doi.org/10.1111/jbi.14118

Aim: Given the importance of environmental heterogeneity as a driver of species richness through its effects on species diversification and coexistence, we asked whether the dramatic difference in species richness per unit area between two similar Mediterranean‐type biodiversity hotspots is explaine…

Rock, B. M., and B. H. Daru. 2021. Impediments to Understanding Seagrasses’ Response to Global Change. Frontiers in Marine Science 8. https://doi.org/10.3389/fmars.2021.608867

Uncertainties from sampling biases present challenges to ecologists and evolutionary biologists in understanding species sensitivity to anthropogenic climate change. Here, we synthesize possible impediments that can constrain research to assess present and future seagrass response from climate chang…

Briscoe Runquist, R. D., T. A. Lake, and D. A. Moeller. 2021. Improving predictions of range expansion for invasive species using joint species distribution models and surrogate co‐occurring species. Journal of Biogeography 48: 1693–1705. https://doi.org/10.1111/jbi.14105

Aims: Species distribution models (SDMs) are often used to forecast potential distributions of important invasive or rare species. However, situations where models could be the most valuable ecologically or economically, such as for predicting invasion risk, often pose the greatest challenges to SDM…

Saldaña‐López, A., M. Vilà, F. Lloret, J. Manuel Herrera, and P. González‐Moreno. 2021. Assembly of species’ climatic niches of coastal communities does not shift after invasion Z. Botta‐Dukát [ed.],. Journal of Vegetation Science 32. https://doi.org/10.1111/jvs.12989

Question: Do invasions by invasive plant species with contrasting trait profiles (Arctotheca calendula, Carpobrotus spp., Conyza bonariensis, and Opuntia dillenii) change the climatic niche of coastal plant communities? Location: Atlantic coastal habitats in Huelva (Spain). Methods: We identifi…

Follak, S., L. Bakacsy, F. Essl, L. Hochfellner, K. Lapin, M. Schwarz, B. Tokarska-Guzik, and D. Wołkowycki. 2021. Monograph of invasive plants in Europe N°6: Asclepias syriaca L. Botany Letters 168: 422–451. https://doi.org/10.1080/23818107.2021.1886984

This work synthesizes all aspects of Asclepias syriaca L. (Apocynaceae) including the taxonomy, distribution, history of introduction and spread, ecology, biology, uses and benefits, impacts on biodiversity and agriculture, legislation, and management. Asclepias syriaca is a perennial broad-leaved s…

Géron, C., J. J. Lembrechts, J. Borgelt, J. Lenoir, R. Hamdi, G. Mahy, I. Nijs, and A. Monty. 2021. Urban alien plants in temperate oceanic regions of Europe originate from warmer native ranges. Biological Invasions 23: 1765–1779. https://doi.org/10.1007/s10530-021-02469-9

When colonizing new areas, alien plant species success can depend strongly on local environmental conditions. Microclimatic barriers might be the reason why some alien plant species thrive in urban areas, while others prefer rural environments. We tested the hypothesis that the climate in the native…

Puchałka, R., M. K. Dyderski, M. Vítková, J. Sádlo, M. Klisz, M. Netsvetov, Y. Prokopuk, et al. 2021. Black locust ( Robinia pseudoacacia L.) range contraction and expansion in Europe under changing climate. Global Change Biology 27: 1587–1600. https://doi.org/10.1111/gcb.15486

Robinia pseudoacacia is one of the most frequent non‐native species in Europe. It is a fast‐growing tree of high economic and cultural importance. On the other hand, it is an invasive species, causing changes in soil chemistry and light regime, and consequently altering the plant communities. Previo…