Effects of an ectomycorrhizal fungus on the growth and physiology of Pinus sylvestris var. mongolica seedlings subjected to saline–alkali stress

Dachuan Yin; Saiyaremu Halifu; Ruiqing Song; Jinyu Qi; Xun Deng; Jifeng Deng

doi:10.1007/s11676-019-01007-7

Journal of Forestry Research ›› 2019, Vol. 31 ›› Issue (3) : 781 -788. DOI: 10.1007/s11676-019-01007-7

Original Paper

Effects of an ectomycorrhizal fungus on the growth and physiology of Pinus sylvestris var. mongolica seedlings subjected to saline–alkali stress

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Abstract

This research investigates the mechanism of increased salinity tolerance of ectomycorrhizal fungi-inoculated P. sylvestris var. mongolica to provide a theoretical basis for the application of the fungus in saline soils. Growth effects due to inoculation of seedlings with Suillus luteus (a symbiotic ectomycorrhizal fungus), were determined in four kinds of saline–alkali soils. Growth and physiological indicators, including photosynthetic characteristics, plant height, biomass, photosynthetic pigments, catalase (CAT) and superoxide dismutase (SOD) enzyme levels, and malondialdehyde (MDA), an organic marker for oxidative stress, and soluble protein levels were determined. Mycorrhizal colonization rate decreased with increasing saline–alkalinity and growth of inoculated seedlings was significantly enhanced. Biomass and chlorophyll contents also increased significantly. SOD and CAT activities were higher than in non-inoculated seedlings. However, MDA content decreased in inoculated seedlings. Soluble protein content did not increase significantly. Inoculation with a symbiotic ectomycorrhizal fungus could enhance the saline–alkali tolerance of P. sylvestris var. mongolica. Growth and physiological performance of inoculated seedlings were significantly better than that of uninoculated seedlings. The results indicate that inoculated P. sylvestris var. mongolica seedlings may be useful in the improvement of saline–alkali lands.

Keywords

Ectomycorrhizal fungi / Saline–alkali stress / Pinus sylvestris var. mongolica / Physiological and biochemical mechanisms

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Dachuan Yin, Saiyaremu Halifu, Ruiqing Song, Jinyu Qi, Xun Deng, Jifeng Deng. Effects of an ectomycorrhizal fungus on the growth and physiology of Pinus sylvestris var. mongolica seedlings subjected to saline–alkali stress. Journal of Forestry Research, 2019, 31(3): 781-788 DOI:10.1007/s11676-019-01007-7

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References

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

[1]	Abbaspour H, Saeidi-Sar S, Afshari H, Abdel-Wahhab MA. Tolerance of Mycorrhiza infected Pistachio (Pistacia vera L.) seedling to drought stress under glasshouse conditions. J Plant Physiol, 2012, 169: 704-709.

[2]	Al-Karaki GN, Rusan RHM. Response of two tomato cultivars differing in salt tolerance to inoculation with mycorrhizal fungi under salt stress. Mycorrhiza, 2001, 11(1): 43-47.

[3]	Baar J, Stanton NL. Ectomycorrhizal fungi challenged by saprotrophic basidiomycetes and soil microfungi under different ammonium regimes in vitro. Mycol Res, 2000, 104: 691-697.

[4]	Christos DG, Konstantinos G, George Z. Mechanism of Coomassie brilliant blue G-250 binding to proteins: a hydrophobic assay for nanogram quantities of proteins. Anal Bioanal Chem, 2008, 391: 391-403.

[5]	Edda S, Oddsdottir ES, Eilenberg J, Sen R, Halldorsson G. The effects of insect pathogenic soil fungi and ectomycorrhizal inoculation of birch seedlings on the survival of Otiorhynchus larvae. Agric Entomol, 2010, 12: 319-324.

[6]	Feng G, Zhang F, Li X. Improved tolerance of maize plants to salt stress by arbuscular mycorrhiza is related to higher accumulation of soluble sugars in roots. Mycorrhiza, 2002, 12(4): 185-190.

[7]	Gauthier S, Bernier P, Kuuluvainen T. Boreal forest health and global change. Science, 2015, 349(6250): 819-822.

[8]	Hajiboland R, Aliasgharzadeh N, Laiegh SF. Colonization with arbuscular mycorrhizal fungi improves salinity tolerance of tomato (Solanum lycopersicum L.) plants. Plant Soil, 2010, 331(1/2): 313-327.

[9]	He ZQ, He CX, Zhang ZB. Changes of antioxidative enzymes and cell membrane osmosis in tomato colonized by arbuscular mycorrhizae under NaCl stress. Colloids Surf B, 2007, 59(2): 128-133.

[10]	Hirrel MC. The effect of sodium and chloride salts on the germination of Gigaspora margarita. Mycologia, 1981, 73(4): 610-617.

[11]	Jones HG, Jones MB (1989) Introduction: some terminology and common mechanisms. In: Jones HG, Flowers TJ, Jones MB (eds) Plants under stress: biochemistry, physiology and ecology and their application to plant improvement. Cambridge University Press, New York, pp 1–10

[12]	Kawanabe S, Zhu TC. Degeneration and conservation of Aneurolepidium chinense grassland in Northern China. J Jpn. Grassland Sci, 1991, 37: 91-99.

[13]	Latef AA, Chaoxing H. Effect of arbuscular mycorrhizal fungi on growth, mineral nutrition, antioxidant enzymes activity and fruit yield of tomato grown under salinity stress. Sci Hortic, 2011, 127(3): 228-233.

[14]	Lugo AE. Forestry in the Anthropocene. Science, 2015 349 6250 771

[15]	McMillen BG, Juniper S, Abbott LK. Inhibition of hyphal growth of a vesicular-arbuscular mycorrhizal fungus in soil containing sodium chloride limits the spread of infection from spores. Soil Biol Biochem, 1998, 30(13): 1639-1646.

[16]	Mucha J, Dahm H, Strzelczyk E, Werner A. Synthesis of enzymes connected with mycoparasitism by ectomycorrhizal fungi. Arch Microbiol, 2006, 185: 69-77.

[17]	Munns R, James RA, Läuchli A. Approaches to increasing the salt tolerance of wheat and other cereals. J Exp Bot, 2006, 57(5): 1025-1043.

[18]	Pfeiffer CM, Bloss HE. Growth and nutrition of guayule (Parthenium argentatum) in a saline soil as influenced by vesicular arbuscular mycorrhiza and phosphorus fertilization. New Phytol, 1988, 108(3): 315-321.

[19]	Poss JA, Pond E, Menge JA. Effect of salinity on mycorrhizal onion and tomato in soil with and without additional phosphate. Plant Soil, 1985, 88(3): 307-319.

[20]	Rabie GH. Influence of arbuscular mycorrhizal fungi and kinetin on the response of mungbean plants to irrigation with seawater. Mycorrhiza, 2005, 15(3): 225-230.

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

[22]	Sharma R, Rajak RC, Pandey AK. Evidence of antagonistic interactions between rhizosphere and mycorrhizal fungi associated with Dendrocalamus strictus (Bamboo). J Yeast Fungal Res, 2010, 1: 112-117.

[23]	Shaw TM, Dighton J, Sanders FE. Interactions between ectomycorrhizal and saprotrophic fungi on agar and in association with seedlings of lodgepole pine (Pinus contorta). Mycol Res, 1995, 99: 159-165.

[24]	Shen LY, Mao YM, Lu JY. Effects of arbuscular mycorrhizae on salt tolerance of wild jujube (Zizyphus spinosusu Hu.) seedlings. Acta Pedol Sin, 2004, 41(3): 426-433.

[25]	Song XS, Hu WH, Mao WH, Ogweno JO, Zhou YH, Yu JQ. Response of ascorbate peroxidase isoenzymes and ascorbate regeneration system to abiotic stresses in Cucumis sativus. Plant Physiol Biochem, 2005, 43: 1082-1088.

[26]	Song LN, Zhu JJ, Yan QL. Comparison of intrinsic water use efficiency between different aged Pinus sylvestris var. mongolica wide windbreaks in semiarid sandy land of northern China. Agrofor Syst, 2015, 89: 477-489.

[27]	Stocker T, Qin D, Plattner G (2013) Climate change 2013: the physical science basis. Cambridge University Press, Cambridge, pp 46–48

[28]	Sugden A, Fahrenkamp-Uppenbrink J, Malakoff D. Forest health in a changing world. Science, 2015, 349(6250): 800-801.

[29]	Trumbore S, Brando P, Hartmann H. Forest health and global change. Science, 2015, 349(6250): 814-818.

[30]	Vinale F, D’Ambrosio G, Abadi K, Scala F, Marra R, Turra D, Woo SL, Lorito M. Application of Trichoderma harzianum (T22) and Trichoderma atroviride (P1) as plant growth promoters, and their compatibility with copper oxychloride. J Z J Univ Sci, 2004, 30: 2-8.

[31]	Wasowicz W, Jean N, Peratz A. Optimized steps in fluorometric determination of thiobarbituric acid reactive substances in serum; importance of extraction pH and influence of sample preservation and storage. Clin Chem, 1993, 38(12): 2522-2526.

[32]	William PI, Paul RB. Extinction coefficients of chlorophyll a and b in N, N-dimethyl formamide and 80% acetone. Plant Physiol, 1985, 77: 483-485.

[33]	Wu XY, Jiang FQ, Li XD. Major features of decline of Pinus sylvestris var. mongolica plantation on sandy land. Chin J Appl Ecol, 2004, 15(12): 2221-2224.

[34]	Wu QS, Xia RX, Hu ZJ. Effect of arbuscular mycorrhiza on the drought tolerance of Poncrius trifoliata seedlings. Front For China, 2006, 1: 100-104.

[35]	Yang XH, Zhang KB, Jia BQ, Ci LJ. Desertification assessment in China: an overview. J Arid Environ, 2005, 63: 517-531.

[36]	Yang JY, Zheng W, Tian Y, Wu Y, Zhou DW. Effects of various mixed salt-alkaline stresses on growth, photosynthesis, and photosynthetic pigment concentrations of Medicago ruthenica seedlings. Photosynthetica, 2011, 49(2): 275-284.

[37]	Yin DC, Deng X, Chet Ilan, Song RQ. Physiological responses of Pinus sylvestris var. Mongolica seedlings to the interaction between Suillus luteus and Trichoderma virens. Curr Microbiol, 2014, 69: 334-342.

[38]	Yin DC, Qi JY, Deng JF, Du H, Deng X. Effects of ectomycorrhizal cooperating with exogenous calcium on Pinus sylvestris var. mongolica growth. China Environ Sci, 2017, 37(6): 2295-2304.

[39]	Zeng DH, Jiang FQ, Fan ZP. Stability of Mongolian pine plantationson sandy land. Chin J Appl Ecol, 1996, 7(4): 337-343.

[40]	Zhang Y, Zhong CL, Chen Y, Chen Z, Jiang QB, Wu C, Pinyopusarerk K. Improving drought tolerance of Causarina equisetifolia seedlings by arbuscular mycorrhizas under glasshouse conditions. New For, 2010, 40: 261-271.