Abstract
Oases are common in desert regions of northwestern China and are major sites for human settlement. The implementation of oasis conservation planning has led to afforestation with appropriate shrubs and trees in the native grasslands surrounding inhabited oases. However, little is known about how this Land use change from native grassland to shrub and tree plantations influences the composition of ground-dwelling arthropod communities and the performance of their different trophic groups. To address this, we measured activity density, taxon richness, and relative abundance of four different ground arthropod trophic groups (spiders, beetle predators, beetle herbivores, and beetle detritivores) and several environmental variables affecting arthropod distributions (vegetation cover, ground temperature, soil moisture, soil properties, and leaf litter) along an experimentally established land use change gradient of a mature shrub (Haloxylon ammodendron) planation, a mature poplar (Populus gansuensis) plantation and a mature pine (Pinus sylvestris) plantation, as well as a native grassland from which all cultivated systems were converted. We found that converted shrub plantation had much lower activity density of predatory, herbivorous, and detritivorous beetles; similar activity density of spiders; and similar taxa richness of all four trophic groups relative to the native grassland. However, converted forest plantations regardless of tree species had much higher activity density of spiders, lower activity density of the three beetle groups, much higher richness of predatory beetles, and lower richness of herbivorous and detritivorous beetles. We also found a change in the composition of the ground arthropod community that was largely driven by changes in ground temperature and leaf litter mass. We conclude that conversion of native grassland to shrub and tree plantations can significantly affect ground-dwelling arthropod communities, reducing the activity of ground-dwelling beetle assemblages while increasing that of ground-dwelling spider assemblages. These findings are important for conserving native arthropod diversity in desert ecosystems.
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Acknowledgments
We thank the Linze Inland Research Station of the Chinese Academy of Sciences for providing the facilities and hospitality for our studies. We also thank the landholders for allowing access to their cultivated plantations. This research was co-funded by the National Natural Science Foundation of China (31170496, 41471210, 41201248) and the Cross and Team Cooperation Program for Science and Technology Innovation at the Chinese Academy of Sciences (29Y229H11).
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Feng, Q., Li, FR., Liu, JL. et al. Ground-dwelling arthropod community response to native grassland conversion in a temperate desert of northwestern China. J Insect Conserv 19, 105–117 (2015). https://doi.org/10.1007/s10841-014-9751-4
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DOI: https://doi.org/10.1007/s10841-014-9751-4