Adaptive responses of eremophyte Pugionium cornutum seedlings to different concentrations of NaCl

doi:10.11686/cyxb2015115

Abstract

Abstract: To investigate the adaptive mechanisms of Pugionium cornutum seedlings at different NaCl concentrations, 5-week-old seedlings were treated with a series of external NaCl concentrations (5, 25, 50, 100 and 200 mmol/L). The seedlings exhibited different adaptive mechanisms at different NaCl concentrations. At low salt concentrations (5 mmol/L NaCl), leaf dry weight and water content significantly increased by 25% and 35% respectively compared to the control (P<0.05). The adaptation of P. cornutum to low salt concentrations was mainly due to the rapid growth and increased water content of the plant, which could dilute the excessively absorbed Na⁺ to below toxic levels. At moderate salt concentrations (50 mmol/L NaCl), a strong controlled K⁺ and promoted Na⁺ transportation from root to leaf was observed, and leaf Na⁺ concentration was 8-fold higher than that in the control plants (P<0.05). This adaptation might be explained by the plant’s ability to compartmentalize excess Na⁺ into the vacuole in leaf cells, which could protect leaves from Na⁺ toxicity and produce a 75% decrease in leaf osmotic potential (P<0.05). Therefore, the ability of plants to resist the osmotic stress induced by NaCl was enhanced and normal plant growth could be maintained. The adaptation of P. cornutum to high concentrations of salt (200 mmol/L NaCl) was caused by a strong controlled Na⁺ and promoted K⁺ transportation from the outside into the plant and then from root to leaf. This resulted in a 55% increase in leaf K⁺ concentration under the high-concentration treatment compared to the 50 mmol/L treatment (P<0.05), with a corresponding increase from 10.28% to 12.51% in the contribution of K⁺ to osmotic potential. This mechanism could help to maintain a low Na⁺/K⁺ within the cytoplasm, reduce Na⁺ toxicity to cells, balance the osmotic pressure from vacuole and apoplast to cytoplasm, and reduce osmotic stress on cells due to the primary location of K⁺ mainly in the cytoplasm. However, leaf dry weight significantly decreased by 51% at 200 mmol/L NaCl grown for 7 d compared to control (P<0.05), indicating that P. cornutum seedling has limited salt tolerance.

YUE Li-Jun, YUN Kun, LI Hai-Wei, KANG Jian-Jun, WANG Suo-Min. Adaptive responses of eremophyte Pugionium cornutum seedlings to different concentrations of NaCl[J]. Acta Prataculturae Sinica, 2016, 25(1): 144-152.

References

[1] Ren J Z. System Coupling of the Meta-ecosystem Consisted of Mountain, Desert and Oasis in Hexi corridor, Gansu, China[M]. Beijing: Science Press, 2007.
[2] Xing X N. Water and Salt Migration in Soil under Brackish Drip Irrigation Condition[D]. Lanzhou: Lanzhou University, 2010.
[3] Rozema J, Flowers T J. Crops for a salinized world. Science, 2008, 322: 1478-1480.
[4] Liu H L, Yang G H, Zhang S J. Impact of the irrigation diverted water from the Huanghe River on land salinification in Mongolia Hetao regions. Journal of Anhui Agriculture Science, 2006, 34(5): 948-950.
[5] Tai S X, He Q, Bi J. Study on appraisal and conservation measures of entironment in West Inner Mongolia. Arid Zone Research, 2007, 24(3): 364-368.
[6] Wang Y D, Li S Y, Xu X W, et al . Soil salinization of the windbreak forest belts irrigated with saline water alongside the Tarim desert highway. Acta Pedologica Sinica, 2012, 49(5): 886-891.
[7] Flowers T J, Troke P F, Yeo A R. The mechanism of salt tolerance in halophytes. Annual Review of Plant Physiology, 1977, 28: 89-121.
[8] Greenway H, Munns R. Mechanisms of salt tolerance in nonhalophytes. Annual Review of Plant Physiology, 1980, 31: 149-190.
[9] Blumwald E, Aharon G S, Apse M P. Sodium transport in plant cells. Biochimica et Biophysica Acta, 2000, 1465(1-2): 140-151.
[10] Cramer G R, Läuchli A, Polito V S. Displacement of Ca 2+ by Na + from the plasmalemma of root cells.Plant Physiology, 1985, 79(1): 207-211.
[11] Zhong H, Läuehli A. Spatial and temporal aspects of growth in the primary root of cotton seedlings: effects of NaCl and CaCl 2 . Journal of Experimental Botany, 1993, 44(261): 763-771.
[12] Munns R, Tester M. Mechanisms of salinity tolerance. Annual Review of Plant Biology, 2008, 59: 651-681.
[13] Hao L Z, Zhai S, Jia J, et al . A study on vegetative growth law and leaf anatomy of Pugionium cornutum (L.) Gaertn. Acta Agriculturae Boreali-Sinica, 2004, 19(4): 66-69.
[14] Hao L Z, Hu N B, Zhang J W, et al . Problems in focus for the development and utilization of Pugionium cornutum . China Vegetables, 2005, (3): 39.
[15] Lu S W, Jia H W. Preliminary study on the biological characteristics and utilization of Pugionium cornutum . Scientific and Technical Information of Soil and Water Conservation, 2005, (5): 41-42.
[16] Jia J B, Liu X Y. The value and utilization of Pugionium cornutum . Anhui Agricultural Science Bulletin, 2007, 13(14): 82-83.
[17] Yu Q S, Wang Q, Wang A L, et al . Interspecific delimitation and phylogenetic origin of Pugionium (Brassicaceae). Journal of Systematics and Evolution, 2010, 48(3): 195-206.
[18] Niu H Q, Li F Q, Tan H, et al . Feasibility analysis of general weather conditions for airport site. Beijing Agriculture, 2013, (30): 38-40.
[19] Yue L J, Li S X, Ma Q, et al . NaCl stimulates growth and alleviates water stress in the xerophyte Zygophyllum xanthoxylum . Journal of Arid Environments, 2012, 87: 153-160.
[20] Kang J J, Wang S M, Zhao M, et al . Tentative research of Na compound fertilizer at seedling stage on enhancing drought resistance of Haloxylon ammodendron . Acta Prataculturae Sinica, 2011, 20(2): 127-133.
[21] Li H Y, Zheng Q S, Jiang C Q, et al . A comparison of stress effects between chloridion and sodium ion on grain amaranth seedlings under NaCl stress. Acta Prataculturae Sinica, 2010, 19(5): 63-70.
[22] Zhou X R, Yue L J, Wang S M. Sodium compound fertilizer improved growth and drought tolerance of Zygophyllum xanthoxylum seedling under drought stress. Acta Prataculturae Sinica, 2014, 23(6): 142-147.
[23] Ma Q, Yue L J, Zhang J L, et al . Sodium chloride improves photosynthesis and water status in the succulent xerophyte Zygophyllum xanthoxylum . Tree Physiology, 2012, 32(1): 4-13.
[24] Wang S M, Zheng W J, Ren J Z, et al . Selectivity of various types of salt-resistant plants for K + over Na + . Journal of Arid Environments, 2002, 52(4): 457-472.
[25] Flowers T J, Hajibaheri M A, Clipson N J W. Halophytes. The Quarterly Review of Biology, 1986, 61(3): 313-337.
[26] Yang M F, Yang C, Hou W L, et al . Effects of NaCl and KCl stress on the roots and shoots of Suaeda . Journal of Shandong Normal University (Natural Science), 2002, 17(1): 68-72.
[27] Wang S M, Wan C G, Wang Y R, et al . The characteristics of Na + , K + and free proline distribution in several drought-resistant plants of the Alxa Desert, China. Journal of Arid Environments, 2004, 56(3): 525-539.
[28] Kamel M. Osmotic adjustment in three succulent species of Zygophyllaceae . African Journal of Ecology, 2008, 46(1): 96-104.
[29] Flowers T J, Colmer T D. Salinity tolerance in halophytes. New Phytologist, 2008, 179(4): 945-963.
[30] Albert R. Salt regulation in halophytes. Oecologia, 1975, 21(1): 57-71.
[31] Zhao K F. The plant adaptation to saline adversity. Bulletin of Biology, 2002, 37(6): 7-10.
[32] Maathuis F J M, Amtmann A. K + nutrition and Na + toxicity: The basis of cellular K + /Na + ratio. Annals of Botany, 1999, 84(2): 123-133.
[33] Munns R. Comparative physiology of salt and water stress. Plant, Cell and Environment, 2002, 25(2): 239-250.
[34] Ma X L, Zhang Q, Shi H Z, et al . Molecular cloning and different expression of a vacuolar Na + /H + antiporter gene in Suaeda salsa under salt stress. Biologia Pantarum, 2004, 48(2): 219-225.
[35] Bao A K, Wang Y W, Xi J J, et al . Co-expression of xerophyte Zygophyllum xanthoxylum ZxNHX and ZxVP 1-1 enhances salt and drought tolerance in transgenic Lotus corniculatus by increasing cations accumulation. Functional Plant Biology, 2014, 41(2): 203-214.
[36] Blumwald E. Engineering salt tolerance in plants. Biotechnology and Genetic Engineering Reviews, 2003, 20(1): 261-276.
[37] Munns R. Physiological processes limiting plant growth in saline soils: some dogmas and hypotheses. Plant, Cell and Environment, 1993, 16(1): 15-24.
[38] Wang C M, Zhang J L, Liu X S, et al . Puccinellia tenuiflora maintains a low Na + level under salinity by limiting unidirectional Na + influx resulting in a high selectivity for K + over Na + . Plant, Cell and Environment, 2009, 32(5): 486-496.
[39] Wang X F, Wang C M, Zhang J L, et al . Development of plant regeneration system via tissue culture in Puccinellia tenuiflora . Acta Prataculturae Sinica, 2014, 23(6): 355-360.
[40] Song J, Feng G, Tian C Y, et al . Osmotic adjustment traits of Suaeda physophora , Haloxylon ammodendron and Haloxylon persicum in filed or controlled conditions. Plant Science, 2006, 170(1): 113-119.
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[2] 刑小宁. 微咸水滴灌条件下土壤水、盐运移的试验研究[D]. 兰州: 兰州大学, 2010.
[4] 刘和林, 杨改河, 张生军. 内蒙古河套灌区引黄灌溉对盐渍化的影响分析. 安徽农业科学, 2006, 34(5): 948-950.
[5] 邰生霞, 何桥, 毕佳. 内蒙古西部区环境评价. 干旱区研究, 2007, 24(3): 364-368.
[6] 王永东, 李生宇, 徐新文, 等. 塔里木沙漠公路防护林咸水灌溉土壤盐渍化状况研究. 土壤学报, 2012, 49(5): 886-891.
[13] 郝丽珍, 翟胜, 贾晋, 等. 沙芥营养生长规律及叶片解剖结构的研究. 华北农学报, 2004, 19(4): 66-69.
[14] 郝丽珍, 胡宁宝, 张进文, 等. 沙芥开发利用中应注意的问题. 中国蔬菜, 2005, (3): 39.
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[26] 杨明锋, 杨超, 候文莲, 等. NaCl和KCl胁迫对碱蓬根和地上部分生长的效应. 山东师大学报(自然科学版), 2002, 17(1): 68-72.
[31] 赵可夫. 植物对盐渍逆境的适应. 生物学通报, 2002, 37(6): 7-10.
[39] 王雪芳, 王春梅, 张金林, 等. 小花碱茅组织培养植株再生体系的建立. 草业学报, 2014, 23(6): 355-360.