Plant hormone treatments to alleviate the effects of salt stress on germination of Betula platyphylla seeds

Zhixin Li; Xiaona Pei; Shaopeng Yin; Xianbo Lang; Xiyang Zhao; Guan-Zheng Qu

doi:10.1007/s11676-018-0661-2

Journal of Forestry Research ›› 2019, Vol. 30 ›› Issue (3) : 779 -787. DOI: 10.1007/s11676-018-0661-2

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Plant hormone treatments to alleviate the effects of salt stress on germination of Betula platyphylla seeds

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Abstract

We analyzed the germination traits (germination rate, germination potential, and germination index) of seeds from 23 half-sib families of birch (Betula platyphylla). The germination rates of the 23 families ranged from 38.57 to 76.50%. Seeds from the eight families germinating at the highest rates were then used for germination experiments under salt stress. Germination rate, germination potential, and germination index of these eight half-sib families decreased with increasing salt concentrations. The effects of four different hormones (6-benzylaminopurine, 6BA; gibberellin, GA₃; naphthalene acetic acid, NAA; and melatonin) at various concentrations on the germination of seeds from the eight half-sib birch families under salt stress were investigated. Treatments with 6BA and GA₃ alleviated the effects of salt stress on seed germination, whereas treatments with NAA and melatonin aggravated the effects of salt stress. The most effective treatments for alleviating the effects of salt stress on birch seed germination were 10 mg/L 6BA and 300 mg/L GA₃. This study provides practical information for screening birch families for salt tolerance at the seed germination stage, and for cultivation of birch in saline environments.

Keywords

Betula platyphylla / Germination / Salt stress / Hormone

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Zhixin Li, Xiaona Pei, Shaopeng Yin, Xianbo Lang, Xiyang Zhao, Guan-Zheng Qu. Plant hormone treatments to alleviate the effects of salt stress on germination of Betula platyphylla seeds. Journal of Forestry Research, 2019, 30(3): 779-787 DOI:10.1007/s11676-018-0661-2

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References

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

[1]	Alarcon J, Sánchez M, Bolarin M, Torrecillas A. Water relations and osmotic adjustment in Lycopersicon esculentum an L. pennelli during short-term salt exposure and recovery. Physiol Plant, 1993, 89: 441-447.

[2]	Brady SM, McCourt P. Hormone cross talk in seed dormancy. Journey of Plant Growth Regulation, 2003, 22(1): 25-31.

[3]	Chen Q, Qi WB, Reiter RJ, Wei W, Wang BM. Exogenously applied melatonin stimulates root growth and raises endogenous indoleacetic acid in roots of etiolated seedlings of Brassica juncea. J Plant Physiol, 2009, 166: 324-328.

[4]	Crammer GR, Lanchli A, Polito VS. Displacement of Ca²⁺ by Na⁺ form the plasmalemma of root cells a primary response to stress. Plant Physiol, 1985, 79: 207-211.

[5]	Hansen JK, Roulund H. Genetic parameters for spiral grain, stem form, pilodyn and growth in 13 years old clones of Sitka Spruce (Picea sitchensis (Bong.) Carr.). Silvae Genetica, 1997, 46: 107-113.

[6]	Hu ZY, Liang GD, Huang H, Sun Q. Exogenous GA₃ presoaking treatment to pitaya seeds for improving germination. Genomics and Applied Biology, 2010, 3(29): 529-533.

[7]	Jiang J, Yang CP, Liu GF, Liu YX, Ren XQ. Analysis of genetic variation within and among Betula platyphylla provenance and provenance division using RAPD markers. Bull Bot Res, 2001, 21: 136-140.

[8]	Jiang TB, Zhou BR, Gao FL, Guo BZ. Genetic linkage maps of white birches (Betula platyphylla Suk. and B. pendula Roth) based on RAPD and AFLP markers. Mol Breeding, 2011, 27: 347-356.

[9]	Kandil A, Sharief E, Abido E. Effect of gibberellic acid on germination behaviour of sugar beet cultivars under salt stress conditions of Egypt. Sugar Tech, 2014, 2(16): 211-221.

[10]	Katembe IA, Ungar WJ, Mitchell JP. Effect of salinity on germination and seedling growth of two Atriplex species (Chenopodiaceae). Ann Bot, 1998, 82(2): 167-175.

[11]	Katsuhara M, Kawasaki T. Salt stress induced nuclear and DNA degradation in meristematic cells of barley roots. Plant Cell Physiol, 1996, 37(2): 169-173.

[12]	Kun Y, Aaron M, Joanna W, Wysocka D. ABA and GA signaling pathways interact and regulate seed germination and seedling development under salt stress. Acta Physiol Plant, 2011, 33: 261-271.

[13]	Lei XY, Zhu RY, Zhang GY, Dai YR. Attenuation of cold-induced apoptosis by exogenous melatonin in carrot suspension cells: the possible involvement of polyamines. J Pineal Res, 2004, 36: 126-131.

[14]	Li P, Fang GG, Sun CZ. Wood characteristics of pulpwood. Chem Indus For Prod, 1995, 15: 13-18.

[15]	Li KL, Jiang J, Jiang Y, Xia DA, Yang CP, Liu GF. Analysis of the genetic effects of seed and seedling traits of Betula platyphylla 5 × 5 complete diallel cross design. Journal of Beijing Forestry University, 2006, 28: 82-87.

[16]	Li X, Wang YD, Zhang WJ. Effects of different NAA, IAA, IBA treatment on seed germination of Momordica charantia. Guangdong Agricultural Sciences, 2008, 12(47): 47-48.

[17]	Liimatainen J, Karonen M, Sinkkonen J, Helander M, Salminen JP. Phenolic compounds of the inner bark of Betula pendula: seasonal and genetic variation and induction by wounding. J Chem Ecol, 2012, 38: 1410-1418.

[18]	Linnakoski R, Beer ZW, Rousi M, Solhein H, Wingfield MJ. Ophiostoma denticiliatum sp. nov. and other Ophiostoma species associated with the birch bark beetle in southern Norway. Persoonia, 2009, 23: 9-15.

[19]	Liu LC, Ye YX. Effects of different concentrations of GA₃, IAA and 6-BA on seed germination of snake melon. Journal of Yangtze University, 2011, 9(8): 229-233.

[20]	Liu J, Guo WQ, Shi DC. Seed germination, seedling survival and physiological response of sunflowers under saline and alkaline conditions. Photosynthetica, 2010, 48(2): 278-286.

[21]	Liu YY, Zhang XH, Chen JY. Effects of NaHCO₃ stress on seeds germination of Betula platyphylla. Jiangsu Agricultural Sciences, 2012, 40(9): 179-182.

[22]	Ma Y, Xia L, Liu WD. The impact of GA₃, 6-BA, Mn²⁺ on catalpa bungei seed germination. Chin Agric Sci Bull, 2013, 28(13): 40-46.

[23]	Manchester L, Tan DX, Reiter R, Park W, Monis K. High levels of melatonin in the seeds of edible plants: possible function in germ tissue protection. Life Sci, 2000, 67(25): 3023-3029.

[24]	Posmyk M, Janas KM. Melatonin in plants. Acta Physiol Plant, 2009, 31: 1-11.

[25]	Posmyk M, Balabusta M, Wieczorek M, Sliwinska E, Janas KM. Melatonin applied to cucumber (Cucumis sativus L) seeds improves germination during chilling stress. J Pineal Res, 2009, 46: 214-226.

[26]	Qiu JF, Manjula B, Zhang J, Wang LC, Wei CY. Influence of NAA and 2, 4-D on seed germination of chickpea. Journal of Jilin Agricultural Sciences, 2013, 38(6): 28-29, 33.

[27]	Rodriguez C, Mayo JC, Sainz RM, Antolín I, Herrera F, Martín V, Reiter RJ. Regulation of antioxidant enzymes: a significant role for melatonin. J Pineal Res, 2004, 36: 1-9.

[28]

Sarropoulou VN, Therios IN, Dimassi-Theriou KN. Melatonin promotes adventitious root regeneration in vitro shoot tip explants of the commercial sweet cherry rootstocks CAB-6P (Prunus cerasus L.), Gisela 6 (P. cerasus P. canescens), and MxM 60 (P. avium P. mahaleb). J Pineal Res, 2012, 52: 38-46.

[29]	Shen GZ, Liu XY, Shen SK, Wu YH, Wang YH. Effect of 6BA and NAA on germination characteristics of Anneslea fragrans seeds. Seeds, 2008, 3: 73-74.

[30]	Shi LW. Statistical analysis from entry to the master of SPSS 19.0, 2012 1 Beijing: Tsinghua University Press.

[31]	Sun Q, Wang JH, Sun BQ. Advances on seed vigor physiological and genetic mechanisms. Scientia Agricultural Sinica, 2007, 40(1): 48-53.

[32]	Tian YC. The effects of NAA to cucumber seeds germination and seedling growth during seed stage. Journal of Chifeng University, 2014, 10(30): 18-20.

[33]	Toshio Y, Eduardo B. Developing salt-tolerant crop plants: challenges and opportunities. Trends Plant Sci, 2005, 10: 615-620.

[34]	Wang GY, Han SD, Zhao YP, Zhou XM, Li XZ. The effect of NaCl stress, Ca²⁺ and GA₃ on three kinds of vegetable seed germination in cucurbita. Journal of Plant Resource and Environment, 2005, 14(1): 26-30.

[35]	Wei ZG, Yang CP, Pan H. Identification of molecular markers associated with birch fiber length trait by multiple regression analysis. Molecular Plant Breeding, 2006, 4: 835-840.

[36]	Wei ZG, Zhang KX, Yang CC, Liu GF, Liu GJ, Zhang HG. Genetic linkage maps of Betula platyphylla Suk based on ISSR and AFLP markers. Plant Molecular Biology Reporter, 2010, 28: 169-175.

[37]	Xu HG. The halophyte and salinization ecological governance, 2004, Beijing: China Agricultural Science and Technology Press.

[38]	Xu JR. Quantitative genetics of forest, 2006 1 Beijing: China Forestry Publishing.

[39]	Xu XY. Effects of salt stress on seeds germinnation and seedlings growth of Betula platyphylla. Chinese Forestry, 2011, 1: 49.

[40]	Yamaguchi S, Kamiya Y. Gibberellins and light stimulated seed germination. Journey of Plant Growth Regulation, 2001, 20(4): 369-376.

[41]	Yan XF, Shi C, Zhang KW, Zhou LB. Stress effects of mixed sodium salt on seed germination of two kinds of birch tree seeds. Journal of Central South University of Forestry & Technology, 2010, 6(30): 50-54.

[42]	Yang CP, Liu GF, Wei ZG, Wu YL, Zhou YM. Study on intensive breeding technique of accelerating Betula platyphylla flowering and seeding early. Scientia Silvae Sinicae, 2004, 40: 14-17.

[43]	Yang CW, Chong JN, Li CY, Kim CM, Shi DC, Wang DL. Osmotic adjustment and ion balance traits of an alkali resistant halophyte Kochia sieversiana during adaptation to salt and alkali conditions. Plant Soil, 2007, 294(1): 263-276.

[44]	Zeng TFX, Sheng JYX, Jin GYY. Plant hormones, 1978, Beijing: Science Press 169 204

[45]	Zeng J, Zou YP, Bai JY, Zheng HS. RAPD analysis of genetic variation in natural populations of Betula alnoide from Guangxi, China. Euphytica, 2003, 134: 33-41.

[46]	Zhan YG, Su T, Han M, Sun D. A multiplex polymerase chain reaction method for rapid detection of foreign genes in transgenic birch (Betula platyphylla). Bulletin of Botanical Research, 2006, 26: 480-485.

[47]	Zhang N. Regulation of melatonin on germination and seedling growth under osmotic stress in cucumber, 2014, Beijing: China Agricultural University 1 94

[48]	Zhang FP, Lai QC. The effects of 6-BA et al on seed germination and seeding previous vigor of Lycopersicon esculentum. Bulletin of Agricultural Science and Technology, 2008, 6: 36-38.

[49]	Zhang SG, Gao JY, Song JZ, Weng YJ. Mitigative effects of 6-BA on salt stress-induced injuries in wheat germination. Seeds, 1998, 6: 25-28.

[50]	Zhang LJ, Yuan YJ, Wang CG, Pan XL. Physiological effects of NAA and SA on seed germination of cornus officinalis. Journal of Shanxi Normal University, 2006, 4(20): 75-79.

[51]	Zhang N, Zhang HJ, Yang RC, Huang YY, Guo YD. Advances in melatonin and its functions in plants. Agricultural Science & Technology, 2012, 13(9): 1833-1837.

[52]	Zhang N, Zhao B, Zhang HJ, Weeda S, Yang C, Yang ZC, Ren S, Guo YD. Metatonin promotes water-stress tolerance, lateral root formation, and seed germination in cucumber (Cucumis sativus L). J Pineal Res, 2013, 54: 15-23.

[53]	Zhang N, Jiang Q, Li DB, Cai LT, Zhang HJ, Si WJ, Fan XF, Guo YD. Effect of exogenous melatonin on germination of pennisetum alopecuroides under NaCl stress. Journal of China Agricultural University, 2014, 4(8): 54-60.

[54]	Zhao XY, Wang JH, Zhang JF, Zhang SG, Zhang JG, Ma JW. Study on phenotypic traits and germination characters of four taxons of catalpa genus seed. Journal of Northwest A&F University, 2008, 12(36): 149-154.

[55]	Zheng SS, Sun CF, Sun HC, Liu LT, Zhao JF, Li CD. Effects of different exogenous hormones on physiological characteristics of main stem leaves at flower and boll stage in cotton. Scientia Agricultura Sinica, 2009, 42(12): 4383-4389.