Exploring the role of physiology and biotic interactions in determining elevational ranges of tropical animals

Jankowski, Jill E.; Londoño, Gustavo A.; Robinson, Scott K.; Chappell, Mark A.

doi:10.1111/j.1600-0587.2012.07785.x

Cited by 156 publications

(152 citation statements)

References 126 publications

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“…To characterize the distribution of HPS caused by ANDV, two modeling approaches were compared: generalized linear models (GLM) with binomial error [67] and the Maximum Entropy algorithm (MaxEnt) [68,69,70]. We first performed an exploratory analysis comparing environmental variables between sites with and without HPS cases with Kruskal-Wallis tests.…”

Section: Methodsmentioning

confidence: 99%

Estimating Hantavirus Risk in Southern Argentina: A GIS-Based Approach Combining Human Cases and Host Distribution

Andreo

Neteler

Rocchini

et al. 2014

Viruses

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We use a Species Distribution Modeling (SDM) approach along with Geographic Information Systems (GIS) techniques to examine the potential distribution of hantavirus pulmonary syndrome (HPS) caused by Andes virus (ANDV) in southern Argentina and, more precisely, define and estimate the area with the highest infection probability for humans, through the combination with the distribution map for the competent rodent host (Oligoryzomys longicaudatus). Sites with confirmed cases of HPS in the period 1995–2009 were mostly concentrated in a narrow strip (~90 km × 900 km) along the Andes range from northern Neuquén to central Chubut province. This area is characterized by high mean annual precipitation (~1,000 mm on average), but dry summers (less than 100 mm), very low percentages of bare soil (~10% on average) and low temperatures in the coldest month (minimum average temperature −1.5 °C), as compared to the HPS-free areas, features that coincide with sub-Antarctic forests and shrublands (especially those dominated by the invasive plant Rosa rubiginosa), where rodent host abundances and ANDV prevalences are known to be the highest. Through the combination of predictive distribution maps of the reservoir host and disease cases, we found that the area with the highest probability for HPS to occur overlaps only 28% with the most suitable habitat for O. longicaudatus. With this approach, we made a step forward in the understanding of the risk factors that need to be considered in the forecasting and mapping of risk at the regional/national scale. We propose the implementation and use of thematic maps, such as the one built here, as a basic tool allowing public health authorities to focus surveillance efforts and normally scarce resources for prevention and control actions in vast areas like southern Argentina.

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Section: Methodsmentioning

confidence: 99%

Estimating Hantavirus Risk in Southern Argentina: A GIS-Based Approach Combining Human Cases and Host Distribution

Andreo

Neteler

Rocchini

et al. 2014

Viruses

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“…Aggressive asymmetries are also common in avian altitudinal replacement zones [45]. Mismatches of fundamental versus realized altitudinal distributions provide indirect evidence of behavioral interference, and greater mismatch in one species suggests that aggressive interactions are asymmetrical [47]. These scenarios raise the prospect under climate change of subordinate high-elevation species being squeezed into extinction if dominant low-elevation species shift upslope, or of dominant highelevation species preventing the upward movement of subordinate species, which are then left occupying a physiologically suboptimal habitat [17,19].…”

Section: Behavioral Interference In Competition Experimentsmentioning

confidence: 99%

“…For example, the generalization that interspecific interference usually impedes coexistence might not hold when interference causes spatial or temporal resource partitioning (e.g., territoriality or habitat shifts). Current theory also fails to fully address the consequences of asymmetries in behavioral interference [79,80], while empirical research suggests that asymmetries are common and closely linked to the ecological and evolutionary consequences of the interactions [25,27,42,45,47]. Learned mate and competitor recognition also pose interesting and largely unexplored challenges (Box 4; see Outstanding Questions) [81,82].…”

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confidence: 99%

Causes and Consequences of Behavioral Interference between Species

Grether

Peiman

Tobias

et al. 2017

Trends in Ecology & Evolution

140

162

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Behavioral interference between species, such as territorial aggression, courtship, and mating, is widespread in animals. While aggressive and reproductive forms of interspecific interference have generally been studied separately, their many parallels and connections warrant a unified conceptual approach. Substantial evidence exists that aggressive and reproductive interference have pervasive effects on species coexistence, range limits, and evolutionary processes, including divergent and convergent forms of character displacement. Alien species invasions and climate change-induced range shifts result in novel interspecific interactions, heightening the importance of predicting the consequences of species interactions, and behavioral interference is a fundamental but neglected part of the equation. Here, we outline priorities for further theoretical and empirical research on the ecological and evolutionary consequences of behavioral interference. Interspecific Aggression and Reproductive InterferenceFew subjects in animal behavior have attracted more attention than aggression and sex, yet research tends to stop at species boundaries even when the behaviors themselves do not. Aggressive and sexual interactions between species are surprisingly common and share many parallels in their causes and ecological and evolutionary effects [1][2][3][4][5][6]. Both types of behavioral interference (Box 1) have been hypothesized to: (i) arise as a byproduct of intraspecific interactions (Box 2); (ii) cause local extinction as well as temporal and spatial habitat partitioning; (iii) prevent species from coexisting that otherwise would be expected to coexist; (iv) enable coexistence between species that otherwise would not be expected to coexist; (v) promote or prevent species range shifts and the spread of invasive species; (vi) cause sympatric species to diverge or converge through character displacement processes; (vii) cause populations within a species to diverge from each other due to character displacement in areas of sympatry; and (viii) contribute to reproductive isolation and speciation ( Figure 1).Despite their connections, aggressive interference and reproductive interference (see Glossary) have largely been studied by different researchers in relation to different theoretical frameworks [2,4,7] and in different study systems [3], even though many closely related species interfere with each other in both ways (see Table S1 in [8]). We do not believe that these two categories of interspecific interactions should be synonymized, because this would obscure important differences between them. Instead, we propose that their similarities and interrelationships merit a common conceptual framework, which we introduce here ( Figure 1). TrendsAggressive and reproductive forms of behavioral interference between species are widespread in animals and share many parallels in their underlying causes and their ecological and evolutionary effects.Behavioral interference can determine whether species coexist and, thus, affects speci...

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“…Endotherm distributions may be less directly linked to bioclimatic variables than ectotherm distributions (Huey 1991, Buckley et al 2012, Huey et al 2012, Soininen and Luoto 2014, but see Jankowski et al 2013) -especially for lower temperature limits ( Fig. 2A).…”

mentioning

confidence: 99%

Avian SDMs: current state, challenges, and opportunities

Engler

Stiels

Schidelko

et al. 2017

Journal of Avian Biology

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Quantifying species distributions using species distribution models (SDMs) has emerged as a central method in modern biogeography. These empirical models link species occurrence data with spatial environmental information. Since their emergence in the 1990s, thousands of scientific papers have used SDMs to study organisms across the entire tree of life, with birds commanding considerable attention. Here, we review the current state of avian SDMs and point to challenges and future opportunities for specific applications, ranging from conservation biology, invasive species and predicting seabird distributions, to more general topics such as modeling avian diversity, niche evolution and seasonal distributions at a biogeographic scale. While SDMs have been criticized for being phenomenological in nature, and for their inability to explicitly account for a variety of processes affecting populations, we conclude that they remain a powerful tool to learn about past, current, and future species distributions -at least when their limitations and assumptions are recognized and addressed. We close our review by providing an outlook on prospects and synergies with other disciplines in which avian SDMs can play an important role.

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Exploring the role of physiology and biotic interactions in determining elevational ranges of tropical animals

Cited by 156 publications

References 126 publications

Estimating Hantavirus Risk in Southern Argentina: A GIS-Based Approach Combining Human Cases and Host Distribution

Estimating Hantavirus Risk in Southern Argentina: A GIS-Based Approach Combining Human Cases and Host Distribution

Causes and Consequences of Behavioral Interference between Species

Avian SDMs: current state, challenges, and opportunities

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