Megaherbivores and small burrowing mammals commonly coexist and play important functional roles in grassland ecosystems worldwide. The interactive effects of these two functional groups of herbivores in shaping the structure and function of grassland ecosystems are poorly understood. In North America's central grasslands, domestic cattle (Bos taurus) have supplanted bison (Bison bison), and now coexist with prairie dogs (Cynomys spp.), a keystone burrowing rodent. Understanding the ecological relationships between cattle and prairie dogs and their independent and interactive effects is essential to understanding the ecology and important conservation issues affecting North American grassland ecosystems. To address these needs, we established a long-term manipulative experiment that separates the independent and interactive effects of prairie dogs and cattle using a 2 x 2 factorial design. Our study is located in the Janos-Casas Grandes region of northwestern Chihuahua, Mexico, which supports one of the largest remaining complexes of black-tailed prairie dogs (C. ludovicianus). Two years of posttreatment data show nearly twofold increases in prairie dog abundance on plots grazed by cattle compared to plots without cattle. This positive effect of cattle on prairie dogs resulted in synergistic impacts when they occurred together. Vegetation height was significantly lower on the plots where both species co-occurred compared to where either or both species was absent. The treatments also significantly affected abundance and composition of other grassland animal species, including grasshoppers and banner-tailed kangaroo rats (Dipodomys spectabilis). Our results demonstrate that two different functional groups of herbivorous mammals, burrowing mammals and domestic cattle, have distinctive and synergistic impacts in shaping the structure and function of grassland ecosystems.
Aim The aims were: (1) evaluate the potential of Watson's framework for studying species composition in fragments and islands for a specific landscape type: cryptobiotic crust systems in the arid south‐western US; (2) expand Watson's original model to include ephemeral/non‐equilibrium systems by revising his categories of patch age and matrix contrast; and (3) examine the interplay between patch dynamics and species autecology, demonstrating the need for more work on ephemeral patchy systems.
Location Cryptobiotic crust systems in two piñon‐juniper sites in Central New Mexico, western North America.
Results Watson's patch age designation was not applicable to our system because of its ephemeral or non‐equilibrial nature. Based on this result, we constructed what we refer to as a ‘speed key’ that includes equilibrium and non‐equilibrium patches of all kinds. For this model we maintained one of Watson's original traits: patch origin, and amended two others to describe persistence and permeability across the matrix. Importantly, persistence and matrix permeability must be evaluated as functions of the organisms under consideration. Systems that may be in equilibrium for one taxon may well be non‐equilibrial (ephemeral) for another. A patch that appears to be in high contrast with its intervening matrix may actually be in low contrast, depending on the dispersal ability of the organism through that matrix.
Main conclusions To improve substantially on our understanding of patchy systems (whether islands or fragments) it is important to account explicitly for relevant organismal life‐history traits in the designation of those systems. Too often, patches are defined by how the researcher views them from his/her own spatio‐temporal viewpoint. Once we move to an organism‐centred understanding of these patches we may find surprising and novel comparisons that allow us to move across scales and inform our view of ecological patterns and processes. By incorporating non‐equilibrium systems into a model of insularity, this work has general implications that go beyond the scope of cryptobiotic crusts to add to the current dialogue in biogeography.
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