Divya Vasudev scite author profile

Species within a guild vary their use of time, space and resources, thereby enabling sympatry. As intra-guild competition intensifies, such behavioural adaptations may become prominent. We assessed mechanisms of facilitating sympatry among dhole (Cuon alpinus), leopard (Panthera pardus) and tiger (Panthera tigris) in tropical forests of India using camera-trap surveys. We examined population-level temporal, spatial and spatio-temporal segregation among them across four reserves representing a gradient of carnivore and prey densities. Temporal and spatial overlaps were higher at lower prey densities. Combined spatio-temporal overlap was minimal, possibly due to chance. We found fine-scale avoidance behaviours at one high-density reserve. Our results suggest that: (i) patterns of spatial, temporal and spatio-temporal segregation in sympatric carnivores do not necessarily mirror each other; (ii) carnivores are likely to adopt temporal, spatial, and spatio-temporal segregation as alternative mechanisms to facilitate sympatry; and (iii) carnivores show adaptability across a gradient of resource availability, a driver of inter-species competition. We discuss behavioural mechanisms that permit carnivores to co-occupy rather than dominate functional niches, and adaptations to varying intensities of competition that are likely to shape structure and dynamics of carnivore guilds.

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From dispersal constraints to landscape connectivity: lessons from species distribution modeling

Vasudev

et al. 2015

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Connectivity plays a crucial role in determining the spread, viability, and persistence of populations across space. Dispersal across landscapes, or the movement of individuals or genes among resource patches, is critical for functional connectivity. Yet current connectivity modelling typically uses information on species location or habitat preference rather than movement, which unfortunately may not capture key dispersal limitations. We argue that recent developments in species distribution modelling provide insightful lessons for addressing this gap and advancing our understanding of connectivity. We suggest shifting the focus of connectivity modelling from locating where animals potentially disperse to a process‐based approach directed towards understanding and mapping factors that limit successful dispersal. To do so, we propose defining species dispersal requirements through identifying spatial, environmental and intrinsic constraints to successful dispersal, analogous to identifying environmental dimensions that define niches. We discuss the benefits of this constraint‐based framework for understanding the distribution of species, predicting species responses to climate change, and connectivity conservation practice. We illustrate how the framework can aid in identifying potential detrimental effects of human activities on connectivity and species persistence, and can spur the implementation of innovative conservation strategies. The proposed framework clarifies the validity and contextual utility of objectives and measures in existing connectivity models, and identifies gaps that may impede our understanding of connectivity and its integration into successful conservation strategies. We expect that this framework will facilitate a mechanistic approach to understanding and conserving connectivity, which will aid in effectively predicting and mitigating effects of ongoing environmental change.

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Divergent Perspectives on Landscape Connectivity Reveal Consistent Effects from Genes to Communities

Fletcher

Burrell

Reichert

et al. 2016

Curr Landscape Ecol Rep

107

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Landscape connectivity is increasingly emphasized due to its relevance for interpreting effects of environmental change. Yet substantial uncertainty remains regarding the quantification of connectivity and the extent to which connectivity influences biodiversity. We review and synthesize 370 articles published since 2005 on the quantification and effects of landscape connectivity on biodiversity. We find a notable change in the quantification of connectivity from structural to functional approaches, a rise in network approaches, and a decline in approaches based on metapopulation theory. Most studies (54 %) did not test for the effects of connectivity, but of those that did, 91 % found effects on biodiversity, with over five times as many positive as negative effects reported. These effects were largely consistent across levels of biological organization, despite diverse perspectives on movement and connectivity across these domains. Nevertheless, we argue that several outstanding issues need to be addressed to advance our understanding of the effects of connectivity and its importance for conservation. These issues include the need for greater emphasis on estimating connectivity effects, explicitly incorporating the problem of scale, capturing impacts of movement processes relevant to different levels of organization, proper accounting of uncertainty, and isolating connectivity effects relative to other issues influencing biodiversity.

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Divya Vasudev

Spatio-temporal interactions facilitate large carnivore sympatry across a resource gradient

From dispersal constraints to landscape connectivity: lessons from species distribution modeling

Divergent Perspectives on Landscape Connectivity Reveal Consistent Effects from Genes to Communities

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