Ground-active arthropod responses to rainfall-induced dune microhabitats in a desertified steppe ecosystem, China
LIU Rentao1,2*, ZHU Fan1, Yosef STEINBERGER2
1 Key Laboratory for Restoration and Reconstruction of Degraded Ecosystem in Northwestern China of Ministry of Education, Ningxia University, Yinchuan 750021, China; 2 The Mina & Everard Goodman Faculty of Life Sciences, Bar Ilan University, Ramat-Gan 52900, Israel
Ground-active arthropod responses to rainfall-induced dune microhabitats in a desertified steppe ecosystem, China
LIU Rentao1,2*, ZHU Fan1, Yosef STEINBERGER2
1 Key Laboratory for Restoration and Reconstruction of Degraded Ecosystem in Northwestern China of Ministry of Education, Ningxia University, Yinchuan 750021, China; 2 The Mina & Everard Goodman Faculty of Life Sciences, Bar Ilan University, Ramat-Gan 52900, Israel
摘要 Different microhabitats along dune slope were found to affect the distribution of plant performances and soil properties in desertified ecosystems. However, the ground-active arthropod responses to rainfall-induced dune microhabitats were largely unknown in desertified regions. At dune top, midslope and bottom, ground-active arthropods were sampled by the method of pitfall traps in addition to the herbaceous and soil measurements during spring, summer and autumn from 2012 to 2013. Ground-active arthropod had a strong dynamics in time, seasonally and yearly in responses to rainfall-induced dune microhabitats and the variations were significant higher than those of soil and herbaceous properties. The abundance distribution of dominant taxa (i.e. Melolonthidae, Carabidae, Glaphyridae, Tenebrionidae and Formicidae families) among dune microhabitats was similar between seasons within the same year, whereas they differed markedly between two sampling years with varying rainfall patterns. A significant (P<0.05) difference in total abundance, taxa richness and Shannon index among dune microhabitats was found only in certain season time, particularly in 2013; however, no significant (P>0.05) differences were found among dune microhabitats when averaged on three sampling seasons within the year of either 2012 or 2013. In all, the taxonomical structure differed considerably from the community structure in ground-active arthropod response to rainfall-induced dune microhabitats. The spatial distribution of taxonomical groups among dune microhabitats was significantly affected by inter-annual rainfall changes, whereas that of community structure was affected by both intra- and inter-annual rainfall changes in desertified ecosystems.
Abstract: Different microhabitats along dune slope were found to affect the distribution of plant performances and soil properties in desertified ecosystems. However, the ground-active arthropod responses to rainfall-induced dune microhabitats were largely unknown in desertified regions. At dune top, midslope and bottom, ground-active arthropods were sampled by the method of pitfall traps in addition to the herbaceous and soil measurements during spring, summer and autumn from 2012 to 2013. Ground-active arthropod had a strong dynamics in time, seasonally and yearly in responses to rainfall-induced dune microhabitats and the variations were significant higher than those of soil and herbaceous properties. The abundance distribution of dominant taxa (i.e. Melolonthidae, Carabidae, Glaphyridae, Tenebrionidae and Formicidae families) among dune microhabitats was similar between seasons within the same year, whereas they differed markedly between two sampling years with varying rainfall patterns. A significant (P<0.05) difference in total abundance, taxa richness and Shannon index among dune microhabitats was found only in certain season time, particularly in 2013; however, no significant (P>0.05) differences were found among dune microhabitats when averaged on three sampling seasons within the year of either 2012 or 2013. In all, the taxonomical structure differed considerably from the community structure in ground-active arthropod response to rainfall-induced dune microhabitats. The spatial distribution of taxonomical groups among dune microhabitats was significantly affected by inter-annual rainfall changes, whereas that of community structure was affected by both intra- and inter-annual rainfall changes in desertified ecosystems.
The Science Research Foundation of Ningxia Higher Education (NGY2015053), Ningxia Natural Science Foundation (NZ15025), and the National Natural Science Foundation of China (41101050).
通讯作者:
LIU Rentao
E-mail: liubarilanu@gmail.com; liu_rt@nxu.edu.cn
引用本文:
LIU Rentao, ZHU Fan, Yosef STEINBERGER. Ground-active arthropod responses to rainfall-induced dune microhabitats in a desertified steppe ecosystem, China[J]. 干旱区科学, 2016, 8(4): 632-646.
LIU Rentao, ZHU Fan, Yosef STEINBERGER. Ground-active arthropod responses to rainfall-induced dune microhabitats in a desertified steppe ecosystem, China. Journal of Arid Land, 2016, 8(4): 632-646.
Agrawal R K. 1986. On the compensation effect. Journal of Thermal Analysis, 31(1): 73–86. Andrén H. 1994. Effects of habitat fragmentation on birds and mammals in landscapes with different proportions of suitable habitat: a review. Oikos, 71(3): 355–366. Arim M, Marquet P A, Jaksic F M. 2007. On the relationship between productivity and food chain length at different ecological levels. The American Naturalist, 169(1): 62–72. Breckle S W, Yair A, Veste M. 2008. Arid Dune Ecosystems: The Nizzana Sands in the Negev Desert. Berlin Heidelberg: Springer-Verlag. Canepuccia A D, Isacch J P, Gagliardini D A, et al. 2007. Waterbird response to changes in habitat area and diversity generated by rainfall in a SW Atlantic coastal lagoon. Waterbirds, 30(4): 541–553. Canepuccia A D, Farias A A, Escalante A H, et al. 2008. Differential responses of marsh predators to rainfall-induced habitat loss and subsequent variations in prey availability. Canadian Journal of Zoology, 86(5): 407–418. Canepuccia A D, Cicchino A C, Escalante A H, et al. 2009. Differential responses of marsh arthropods to rainfall-induced habitat loss. Zoological Studies, 48(2): 174–183. de Bruyn L A L. 1999. Ants as bio-indicators of soil function in rural environments. Agriculture, Ecosystems & Environment, 74(1–3): 425–441.Dijkstra F A, Augustine D J, Brewer P, et al. 2012. Nitrogen cycling and water pulses in semiarid grasslands: are microbial and plant processes temporally asynchronous?. Oecologia, 170(3): 799–808. Doblas-Miranda E, Sánchez-Piñero F, González-Megías A. 2007. Soil macroinvertebrate fauna of a Mediterranean arid system: composition and temporal changes in the assemblage. Soil Biology and Biochemistry, 39(8): 1916–1925. Doblas-Miranda E, Sánchez-Piñero F, González-Megías A. 2009. Different microhabitats affect soil macro-invertebrate assemblages in a Mediterranean arid ecosystem. Applied Soil Ecology, 41(3): 329–335. Driscoll D A. 2004. Extinction and outbreaks accompany fragmentation of a reptile community. Ecological Applications, 14(1): 220–240. Duffy J E. 2003. Biodiversity loss, trophic skew and ecosystem functioning. Ecology Letters, 6(8): 680–687. Dunning J B, Danielson B J, Pulliam H R. 1992. Ecological processes that affect populations in complex landscapes. Oikos, 65(1): 169–175. Eyre M D, Luff M L, Rushton S P, et al. 1989. Ground beetles and weevils (Carabidae and Curculionoidea) as indicators of grassland management practices. Journal of Applied Entomology, 107(1–5): 508–517. Farias A A, Jaksic F M. 2007. Effects of functional constraints and opportunism on the functional structure of a vertebrate predator assemblage. Journal of Animal Ecology, 76(2): 246–257. Frampton G K, Van den Brink P J, Gould P J L. 2000. Effects of spring drought and irrigation on farmland arthropods in southern Britain. Journal of Applied Ecology, 37(5): 865–883. Han R Y, Chen Y Y, Li W X. 2014. The distribution and relationships of ground vegetation, soil seed bank and soil water content of fixed sand under different micro-landform conditions. Pratacultural Science, 31(10): 1825–1832. (in Chinese)Holland J D, Fahrig L, Cappuccino N. 2005. Body size affects the spatial scale of habitat-beetle interactions. Oikos, 110(1): 101–108. Holt R D, Lawton J H, Polis G A, et al. 1999. Trophic rank and the species-area relationship. Ecology, 80(5): 1495–1504. Institute of Soil Sciences, Chinese Academy of Sciences (ISSCAS). 1978. Physical and Chemical Analysis Methods of Soils. Shanghai: Shanghai Science Technology Press. (in Chinese)Irmler U. 2003. The spatial and temporal pattern of carabid beetles on arable fields in northern Germany (Schleswig-Holstein) and their value as ecological indicators. Agriculture, Ecosystems & Environment, 98(1–3): 141–151. Isla F I, Gaido E S. 2001. Geological evolution of the Mar Chiquita lagoon. In: Iribarne O O. Mar Chiquita Biosphere Reserve: Physical, Biological and Ecological Characteristics. Mar del Plata, Argentina: Editorial Martin Press, 19–30. (in Spanish)Jackson R B, Manwaring J H, Caldwell M M. 1990. Rapid physiological adjustment of roots to localized soil enrichment. Nature, 344(6261): 58–60. Kidron G J, Yair A. 1997. Rainfall-runoff relationship over encrusted dune surfaces, Nizzana, western Negev, Israel. Earth Surface Processes and Landforms, 22(12): 1169–1184. Kidron G J. 1999. Differential water distribution over dune slopes as affected by slope position and microbiotic crust, Negev Desert, Israel. Hydrological Processes, 13(11): 1665–1682. Lavelle P, Spain A V. 2001. Soil Ecology. Amsterdam: Kluwer Scientific Publications. Lepš J, Šmilauer P. 2003. Multivariate Analysis of Ecological Data using CANOCO. Cambridge: Cambridge University Press. Li J, Shi J, Luo Y Q, et al. 2012. Plant and insect diversity along an experimental gradient of larch-birch mixtures in Chinese boreal forests. Turkish Journal of Agriculture and Forestry, 36(2): 247–255. Lima M, Stenseth N C, Jaksic F M. 2002. Food web structure and climate effects on the dynamics of small mammals and owls in semi-arid Chile. Ecology Letters, 5(2): 273–284. Lindberg N. 2003. Soil fauna and global change: responses to experimental drought, irrigation, fertilisation and soil warming. PhD Dissertation. Uppsala: Swedish University of Agricultural Sciences. Liu J L, Zhao W Z, Li F R. 2014. An overview on the distribution pattern of soil animal responses to precipitation pulses in arid desert ecosystems. Journal of Desert Research, 34(5): 1337–1342. (in Chinese)Liu R T, Zhao H L, Zhao X Y, et al. 2009. Soil macrofaunal response to sand dune conversion from mobile dunes to fixed dunes in Horqin Sandy Land, northern China. European Journal of Soil Biology, 45(5–6): 417–422. Liu R T. 2012. Relationships between soil fauna and rainfall change in desert steppe: A review. Chinese Journal of Ecology, 31(3): 760–765. (in Chinese)Liu R T, Zhu F, Song N P, et al. 2013. Seasonal distribution and diversity of ground arthropods in microhabitats following a shrub plantation age sequence in desertified steppe. PLoS One, 8(10): e77962. Maestre F T, Cortina J, Bautista S, et al. 2003. Small-scale environmental heterogeneity and spatiotemporal dynamics of seedling establishment in a semiarid degraded ecosystem. Ecosystems, 6(7): 630–643. Martin T E. 2001. Abiotic vs. biotic influences on habitat selection of coexisting species: climate change impacts?. Ecology, 82(1): 175–188. Mazía C N, Chaneton E J, Kitzberger T. 2006. Small-scale habitat use and assemblage structure of ground-dwelling beetles in a Patagonian shrub steppe. Journal of Arid Environments, 67(2): 177–194. Nummelin M, Fürsch H. 1992. Coccinellids of the Kibale forest, Western Uganda: a comparison between virgin and managed sites. Tropical Zoology, 5(2): 155–166. Olff H, Ritchie M E. 1998. Effects of herbivores on grassland plant diversity. Trends in Ecology & Evolution, 13(7): 261–265. Ostfeld R S, Keesing F. 2000. Pulsed resources and community dynamics of consumers in terrestrial ecosystems. Trends in Ecology & Evolution, 15(6): 232–237. Pan D Y, Bouchard A, Legendre P, et al. 1998. Influence of edaphic factors on the spatial structure of inland halophytic communities: a case study in China. Journal of Vegetation Science, 9(6): 797–804. Parker M, Nally R M. 2002. Habitat loss and the habitat fragmentation threshold: an experimental evaluation of impacts on richness and total abundances using grassland invertebrates. Biological Conservation, 105(2): 217–229. Pen-Mouratov S, Hu C, Hindin E, et al. 2010. Effect of sand-dune slope orientation on soil free-living nematode abundance and diversity. Helminthologia, 47(3): 179–188. Porhajašová J, Pet?valský V, Šustek Z, et al. 2008. Long-termed changes in ground beetle (Coleoptera: Carabidae) assemblages in a field treated by organic fertilizers. Biologia, 63(6): 1184–1195. Pugnaire F I, Haase P, Puigdefábregas J. 1996. Facilitation between higher plant species in a semiarid environment. Ecology, 77(5): 1420–1426. Rainio J, 2013. Seasonal variation of Carabid beetle (Coleoptera: Carabidae) abundance and diversity in Ranomafana National Park, Madagascar. Journal of Entomology and Zoology Studies, 1(5): 92–98. Rozé F, Lemauviel S. 2004. Sand dune restoration in North Brittany, France: a 10-year monitoring study. Restoration Ecology, 12(1): 29–35. Sabino C M, Teixeira F P F, Zee D M W, et al. 1993. Restoring the beach profile with vegetation. In: Magoon O T, Wilson W S, Converse H, et al. Coastal Zone 93. New York: American Society of Civil Engineers, 2312–2323. Sackmann P, Flores G E. 2009. Temporal and spatial patterns of tenebrionid beetle diversity in NW Patagonia, Argentina. Journal of Arid Environments, 73(12): 1095–1102. Sala E. 2006. Top predators provide insurance against climate change. Trends in Ecology & Evolution, 21(9): 479–480. Sebastiá M T. 2004. Role of topography and soils in grassland structuring at the landscape and community scales. Basic and Applied Ecology, 5(4): 331–346. Song N P, Yang M X, Wang L, et al. 2014. Monthly variation in soil moisture under Caragana intermedia stands grown in desert steppe. Chinese Journal of Ecology, 33(10): 2618–2624. (in Chinese)Spaargaren O C, Deckers J. 1998. The world reference base for soil resources. In: Schulte A, Ruhiyat D. Soils of Tropical Forest Ecosystems. Berlin Heidelberg: Springer, 1001–1002. Staley J T, Mortimer S R, Morecroft M D, et al. 2007. Summer drought alters plant-mediated competition between foliar- and root-feeding insects. Global Change Biology, 13(4): 866–877. Thomas C D. 2000. Dispersal and extinction in fragmented landscapes. Proceedings of the Royal Society of London, 267(1439): 139–145. Wardle D A, Bardgett R D, Klironomos J N, et al. 2004. Ecological linkages between aboveground and belowground biota. Science, 304(5677): 1629–1633. Yin W Y. 2001. Pictorial Keys to Soil Animals of China. Beijing: Science Press. (in Chinese)
2016, Vol. 8 
