Spatial structure and species composition of soil seed banks in moving sand dune systems of northeast China

Chunping Miao; Xuehua Li; Meiyu Jia; Xu Han; Deming Jiang

doi:10.1007/s11676-015-0166-1

Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (1) : 75 -80. DOI: 10.1007/s11676-015-0166-1

Original Paper

Spatial structure and species composition of soil seed banks in moving sand dune systems of northeast China

Chunping Miao ¹^,²
, Xuehua Li ¹^,^b
, Meiyu Jia ¹^,²
, Xu Han ¹^,²
, Deming Jiang ¹

Author information +

History +

PDF

Abstract

Soil seed banks can provide a mechanistic for understanding the recruitment dynamics and can inform conservation management of ecosystems. To investigate the contribution of soil seed banks to vegetation restoration in moving sand dune systems, we compared seed structure and species similarity between soil seed banks and standing vegetation among moving sand dunes, ecotones and dune slacks in northeast China. Average seed density in dune slacks was greater than in ecotones or moving sand dunes. Seed density in the soil layer of 0–10 cm was greater than at 10–20 cm both in the moving sand dunes and the ecotones, but seed densities were similar at depths of 10–20 and 20–30 cm in moving sand dunes. Moreover, the spatial autocorrelation of seed density on moving sand dunes was weak but was strong on the ecotones and dune slacks. The species in the soil seed bank of moving sand dune systems were nearly all annuals, and the low similarity was mainly due to the lack of perennial species that were common in standing vegetation. Consequently, vegetation restoration cannot mainly rely on the soil seed banks in the moving sand dunes and more attention should be paid to protection of the dune slacks because they are the main source of seed disperse and seedling recruitment in moving sand dune systems.

Keywords

Compositional similarity / Seed density / Seedling recruitment / Species composition / Horqin sandy land

Cite this article

Download citation ▾

Chunping Miao, Xuehua Li, Meiyu Jia, Xu Han, Deming Jiang. Spatial structure and species composition of soil seed banks in moving sand dune systems of northeast China. Journal of Forestry Research, 2015, 27(1): 75-80 DOI:10.1007/s11676-015-0166-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Auld TD, Keith DA, Bradstock RA. Patterns in longevity of soil seed banks in fire-prone communities of south-eastern Australia. Aust J Bot, 2000, 48: 539-548.

[2]	Bai WM, Bao XM, Li LH. Effects of Agriophyllum squarrosum seed banks on its colonization in a moving sand dune in Hunshandake Sand Land of China. J Arid Environ, 2004, 59: 151-157.

[3]	Bakker JP, Poschlod P, Strykstra RJ, Bekker RM, Thompson K. Seed banks and seed dispersal: important topics in restoration ecology. Acta Bot Neerl, 1996, 45: 461-490.

[4]	Bakker C, de Graaf HF, Ernst W, van Bodegom P, Peter M. Does the seed bank contribute to the restoration of species-rich vegetation in wet dune slacks?. Appl Veg Sci, 2005, 8: 39-48.

[5]	Bertiller MB. Spatial patterns of the germinable soil seed bank in northern Patagonia. Seed Sci Res, 1998, 8: 39-45.

[6]	Bossuyt B, Hermy M. Seed bank assembly follows vegetation succession in dune slacks. J Veg Sci, 2004, 15: 449-456.

[7]	Bossuyt B, Cosyns E, Hoffmann M. The role of soil seed banks in the restoration of dry acidic dune grassland after burning of Ulex europaeus scrub. Appl Veg Sci, 2007, 10: 131-138.

[8]	Cao CY, Kou ZW, Jiang DM, Luo YM, Xiao XP. Interdune succession in the Kerqin Sandy Region. Acta Phytoecol Sin, 2004, 24(3): 262-267. (In Chinese with English abstract)

[9]	Chambers JC, MacMahon JA. A day in the life of a seed: movements and fates of seeds and their implications for natural and managed systems. Annu Rev Ecol Syst, 1994, 25: 263-292.

[10]	D’Odorico P, Bhattachan A, Davis KF, Ravi S, Runyan CW. Global desertification: drivers and feedbacks. Adv Water Resour, 2013, 51: 326-344.

[11]	De Villiers AJ, Van Rooyen MW, Theron GK. Similarity between the soil seed bank and the standing vegetation in the Strandveld Succulent Karoo, South Africa. Land Degrad Dev, 2003, 14: 527-540.

[12]	Dolle M, Schmidt W. The relationship between soil seed bank, above-ground vegetation and disturbance intensity on old-field successional permanent plots. Appl Veg Sci, 2009, 12: 415-428.

[13]	Dreber N, Esler KJ. Spatio-temporal variation in soil seed banks under contrasting grazing regimes following low and high seasonal rainfall in arid Namibia. J Arid Environ, 2011, 75: 174-184.

[14]	Hölzel N, Otte A. Assessing soil seed bank persistence in flood-meadows: the search for reliable traits. J Veg Sci, 2004, 15: 93-100.

[15]	Jiang DM, Miao CP, Li XH, Zhou QL, Alamusa.. Spatial heterogeneity of plant species on the windward slope of moving sand dunes in a semi-arid region of China. J Arid Land, 2013, 5: 80-88.

[16]	Kalamees R, Pussa K, Zobel K, Zobel M. Restoration potential of the persistent soil seed bank in successional calcareous(alvar) grasslands in Estonia. Appl Veg Sci, 2012, 15: 208-218.

[17]	Li YL, Cui JY, Zhao XY, Zhao HL. Floristic composition of vegetation and the soil seed bank in different types of dunes of Kerqin Steppe. Arid Land Res Manag, 2004, 18: 283-293.

[18]	Liu ZM, Li XL, Yan QL, Wu JG. Species richness and vegetation pattern in dune slacks of an active dune field in Inner Mongolia, China. Biol Conserv, 2007, 140: 29-39.

[19]	Ma MJ, Zhou XH, Ma Z, Du GZ. Composition of the soil seed bank and vegetation changes after wetland drying and soil salinization on the Tibetan Plateau. Ecol Eng, 2012, 44: 18-24.

[20]	Major J, Pyott WT. Buried viable seeds in two California bunchgrass sites and their bearing on the definition of a flora. Plant Ecol, 1966, 13: 253-282.

[21]	Miao CP, Li XH, Jiang DM. Spatial variability of Agriophyllum squarrosum across scales and along the slope on an active sand dune in semi-Arid China. Arid Land Res Manag, 2013, 27: 231-244.

[22]	Morgan JW. Composition and seasonal flux of the soil seed bank of species-rich Themeda triandra grasslands in relation to burning history. J Veg Sci, 1998, 9: 145-156.

[23]	Okubo A, Levin SA. A theoretical framework for data analysis of wind dispersal of seeds and pollen. Ecology, 1989, 70: 329-338.

[24]	Ravi S, Breshears DD, Huxman TE, D’Odorico P. Land degradation in drylands: interations among hydrologic-aeolian erosion and vegetation dynamic. Geomorphology, 2010, 116: 236-245.

[25]	Scott AJ, Morgan JW. Resilience, persistence and relationship to standing vegetation in soil seed banks of semi-arid Australian old fields. Appl Veg Sci, 2012, 15: 48-61.

[26]	Thompson K. Small-scale heterogeneity in the seed bank of an acidic grassland. J Ecol, 1986, 74: 733-738.

[27]	Thompson K, Grime JP. Seasonal variation in the seed banks of herbaceous species in ten contrasting habitats. J Ecol, 1979, 67: 893-921.

[28]	Wang G, Liang X. The dynamics of seed bank on shapotou artificially stabilized dunes. Acta Bot Sin, 1995, 37: 231-237.

[29]	Yan QL, Liu ZM, Zhu JJ, Luo YM, Wang HM, Jiang DM. Structure, pattern and mechanisms of formation of seed banks in sand dune systems in northeastern Inner Mongolia, China. Plant Soil, 2005, 277: 175-184.

[30]	Yan QL, Liu ZM, Zhu JJ. Temperoral variation of soil seed banks in two different dune systems in northeastern Inner Mongolia, China. Environ Geol, 2009, 58: 615-624.

[31]	Zhang J, Zhao H, Zhang T, Zhao X, Drake S. Community succession along a chronosequence of vegetation restoration on sand dunes in Horqin Sandy Land. J Arid Environ, 2005, 62: 555-566.