Effects of clipping on nitrogen allocation strategy and compensatory growth of Leymus chinensis under saline-alkali conditions

doi:10.13287/j.1001-9332.201707.040

Abstract

Abstract: Soil salinization and overgrazing are two main factors limiting animal husbandry in the Songnen Grassland. Leymus chinensis is a dominant rhizome grass, resistant to grazing as well as to-lerant to salt stress. Foliar labeled with ¹⁵N-urea was used to study the nitrogen allocation strategy and compensatory growth response to clipping under saline-alkali conditions. The results showed that the total absorbed ¹⁵N allocated to the aboveground part was more than 60%. Compared with the control treatment (no saline-alkali, no clipping), saline-alkali increased the distribution of ¹⁵N by 5.1% in root; the ¹⁵N distribution into aboveground in the moderate clipping and saline-alkali treatment was 11.6% higher than that of the control, exhibiting over-compensatory growth of aboveground biomass and total biomass, however, ¹⁵N allocated to stem base was significantly increased by 9.5% under severe clipping level and saline-alkali addition, showing under-compensatory growth of shoot, root and total biomass. These results suggested that L. chinensis adapted to mode-rate clipping by over-compensatory growth under salt-alkali stress condition. However, L. chinensis would take a relatively conservative growth strategy through the enhanced N allocation to stem base for storage under severe saline-alkali and clipping conditions.

ZHENG Cong-cong, WANG Yong-jing, SUN Hao, WANG Xin-yu, GAO Ying-zhi. Effects of clipping on nitrogen allocation strategy and compensatory growth of Leymus chinensis under saline-alkali conditions[J]. Chinese Journal of Applied Ecology, 2017, 28(7): 2222-2230.

References

[1] Gao Y, Wang D, Xing F, et al. Combined effects of resource heterogeneity and simulated herbivory on plasticity of clonal integration in a rhizomatous perennial herb. Plant Biology, 2014, 16: 774-782
[2] Liu GX, Han JG. Seedling establishment of wild and cultivated Leymus chinensis (Trin.) Tzvel. under diffe-rent seeding depths. Journal of Arid Environments, 2008, 72: 279-284
[3] Zhou C (周婵), Yang Y-F (杨允菲). Physiological response to salt-alkali stress in experimental populations in two ecotypes of Leymus chinensis in the Songnen Plain of China. Chinese Journal of Applied Ecology (应用生态学报), 2003, 14(11): 1842-1846 (in Chinese)
[4] Shi D, Wang D. Effects of various salt-alkaline mixed stresses on Aneurolepidium chinense (Trin.) Kitag. Plant and Soil, 2005, 271: 15-26
[5] Wang Y-M (王玉猛), Ren L-F (任立飞), Tian Q-Y (田秋英), et al. Physiological roles of rhizomes in response to short-term salinity in Leymus chinensis. Chinese Journal of Plant Ecology (植物生态学报), 2006, 30(6): 954-959 (in Chinese)
[6] Yuan B-Z (原保忠), Wang J (王静), Zhao S-L (赵松岭), et al. An approach to the mechanism of plant compensation. Chinese Journal of Ecology (生态学杂志), 1998, 17(5): 45-49 (in Chinese)
[7] Stowe KA, Marquis RJ, Hochwender CG, et al. The evolutionary ecology of tolerance to consumer damage. Annual Review of Ecology and Systematics, 2000, 31: 565-595
[8] Belsky AJ. Does herbivory benefit plants? A review of the evidence. The American Naturalist, 1986, 127: 870-892
[9] McNaughton SJ. Compensatory plant growth as a response to herbivory. Oikos, 1983, 40: 329-336
[10] Orians CM, Thorn A, Gómez S. Herbivore-induced resource sequestration in plants: Why bother? Oecologia, 2011, 167: 1-9
[11] An H, Li GQ. Effects of grazing on carbon and nitrogen in plants and soils in a semiarid desert grassland, China. Journal of Arid Land, 2015, 7: 341-349
[12] Gómez S, Ferrieri RA, Schueller M, et al. Methyl jasmonate elicits rapid changes in carbon and nitrogen dynamics in tomato. New Phytologist, 2010, 188: 835-844
[13] Rong Y-P (戎郁萍), Han J-G (韩建国), Wang P (王培), et al. Effects of cutting rate on carbohydrate reserves and nitrogen content of Russian wildryegrass (Psathyrostachys perennis Keng). Grassland of China (中国草地), 2000(2): 28-34 (in Chinese)
[14] Schmitt A, Pausch J, Kuzyakov Y. C and N allocation in soil under ryegrass and alfalfa estimated by ¹³C and ¹⁵N labelling. Plant and Soil, 2013, 368: 581-590
[15] Polley HW, Detling JK. Defoliation, nitrogen, and competition: Effects on plant growth and nitrogen nutrition. Ecology, 1989, 70: 721
[16] Ryle GJA, Powell CE, Gordon AJ. Short-term changes in CO₂ evolution associated with nitrogenase activity in white clover in response to defoliation and photosynthesis. Journal of Experimental Botany, 1985, 36: 634-643
[17] Li J-H (李金花), Li Z-Q (李镇清), Wang G (王刚). Effect of different grazing intensities on the nutrient contents of Artemisia frigida and Potentilla acaulis. Acta Prataculturae Sinica (草业学报), 2003, 12(6): 30-35 (in Chinese)
[18] Unkovich M, Sanford P, Pate J, et al. Effects of grazing on plant and soil nitrogen relations of pasture-crop rotations. Australian Journal of Agricultural Research, 1997, 49: 475-485
[19] Wang Q-B (汪庆兵), Zhang J-F (张建锋), Chen G-C (陈光才). Review of nitrogen cycle in plant-soil system based on application of ¹⁵N tracer technique. Journal of Tropical and Subtropical Botany (热带亚热带植物学报), 2013, 21(5): 479-488 (in Chinese)
[20] Li Y-Q (李永旗), Xia S-N (夏绍南), Li P-C (李鹏程), et al. Effects of foliar spring urea on nitrogen absorption,distribution,physiological and biochemical characteristic of cotton plant at the flowering and boll-forming stages. Journal of Nuclear Agricultural Sciences (核农学报), 2016, 30(3): 580-587 (in Chinese)
[21] Diabate B, Gao YZ, Li YH, et al. Associations between species distribution patterns and soil salinity in the Songnen grassland. Arid Land Research & Management, 2015, 29: 199-209
[22] Saia S, Urso V, Amato G, et al. Mediterranean forage legumes grown alone or in mixture with annual ryegrass: Biomass production, N₂ fixation, and indices of intercrop efficiency. Plant and Soil, 2016, 402: 1-13
[23] Wang S-P (汪诗平), Wang Y-F (王艳芬). Study on over-compensation growth of Cleistogenes squarrosa population in Inner Mongolia Steppe. Acta Botanica Sinica(植物学报), 2001, 43(4): 413-418 (in Chinese)
[24] Zhao W, Chen SP, Lin GH. Compensatory growth responses to clipping defoliation in Leymus chinensis (Poaceae) under nutrient addition and water deficiency conditions. Plant Ecology, 2008, 196: 85-99
[25] Ma Y-S (马银山), Du G-Z (杜国祯), Zhang S-T (张世挺). The impacts of fertilization and clipping on compensatory growth of Poa crymophila. Acta Ecologica Sinica (生态学报), 2010, 20(2): 279-287 (in Chinese)
[26] Guo YJ, Han L, Li GD, et al. The effects of defoliation on plant community, root biomass and nutrient allocation and soil chemical properties on semi-arid steppes in northern China. Journal of Arid Environments, 2012, 78: 128-134
[27] Zhong M-Y (钟梦莹), Fan Q-L (樊青丽), Zhang Y-J (张亚军), et al. Morphological plasticity and the biomass allocation models of miniaturized Leymus chinensis. Acta Agrestia Sinica (草地学报) 2013, 21(2): 260-264 (in Chinese)
[28] Zhao W, Chen SP, Han XG, et al. Effects of long-term grazing on the morphological and functional traits of Leymus chinensis in the semiarid grassland of Inner Mongolia, China. Ecological Research, 2009, 24: 99-108
[29] Birgit P, Thomas D, Wolfgang W, et al. A simple method for in situ-labelling with ¹⁵N and ¹³C of grassland plant species by foliar brushing. Methods in Ecology & Evolution, 2011, 2: 326-332
[30] Shen Q-R (沈其荣), Xu G-H (徐国华). Foliar absorption and translocation of labeled urea-¹⁵N in corn and wheat. Acta Pedologica Sinica (土壤学报), 2001, 38(1): 67-74 (in Chinese)
[31] Yang Y-F (杨允菲), Li J-D (李建东). Biomass allocation and growth analysis on the ramets of Phragmites communis populations in different habitats in the Songnen Plains of China. Chinese Journal of Applied Ecology (应用生态学报), 2003, 14(1): 30-34 (in Chinese)
[32] Tao L, Hunter MD. Allocation of resources away from sites of herbivory under simultaneous attack by aboveground and belowground herbivores in the common milkweed, Asclepias syriaca. Arthropod: Plant Interactions, 2013, 7: 217-224