Arbuscular mycorrhizal fungi combined with exogenous calcium improves the growth of peanut (Arachis hypogaea L.) seedlings under continuous cropping

doi:10.1016/S2095-3119(19)62611-0

摘要/Abstract

Abstract:

The growth and yield of peanut are negatively affected by continuous cropping. Arbuscular mycorrhizal fungi (AMF) and calcium ions (Ca²⁺) have been used to improve stress resistance in other plants, but little is known about their roles in peanut seedling growth under continuous cropping. This study investigated the possible roles of the AMF Glomus mosseae combined with exogenous Ca²⁺ in improving the physiological responses of peanut seedlings under continuous cropping. G. mosseae combined with exogenous Ca²⁺ can enhance plant biomass, Ca²⁺ level, and total chlorophyll content. Under exogenous Ca²⁺ application, the F_v/F_m in arbuscular mycorrhizal (AM) plant leaves was higher than that in the control plants when they were exposed to high irradiance levels. The peroxidase, superoxide dismutase, and catalase activities in AM plant leaves also reached their maximums, and accordingly, the malondialdehyde content was the lowest compared to other treatments. Additionally, root activity, and content of total phenolics and flavonoids were significantly increased in AM plant roots treated by Ca²⁺ compared to either G. mosseae inoculation or Ca²⁺ treatment alone. Transcription levels of AhCaM, AhCDPK, AhRAM1, and AhRAM2 were significantly improved in AM plant roots under exogenous Ca²⁺ treatment. This implied that exogenous Ca²⁺ might be involved in the regulation of G. mosseae colonization of peanut plants, and in turn, AM symbiosis might activate the Ca²⁺ signal transduction pathway. The combination of AMF and Ca²⁺benefitted plant growth and development under continuous cropping, suggesting that it is a promising method to cope with the stress caused by continuous cropping.

Key words: Arachis hypogaea L. , arbuscular mycorrhizal fungi , continuous cropping , exogenous calcium

. [J]. Journal of Integrative Agriculture, 2019, 18(2): 407-416.

CUI Li, GUO Feng, ZHANG Jia-lei, YANG Sha, MENG Jing-jing, GENG Yun, WANG Quan, LI Xinguo, WAN Shu-bo. Arbuscular mycorrhizal fungi combined with exogenous calcium improves the growth of peanut (Arachis hypogaea L.) seedlings under continuous cropping[J]. Journal of Integrative Agriculture, 2019, 18(2): 407-416.

参考文献

Adolfsson L, Nziengui H, Abreu LN, Simura J, Beebo A, Herdean A, Aboalizadeth J, Siroka J, Moritz T, Novak O, Karin L, Schoefs B, Spetea C. 2017. Enhanced secondary- and hormone metabolism in leaves of arbuscular mcorrhizal Medicago truncatula. Plant Physiology, 175, 392–411.
Andrade S A L D, Domingues Jr A P, Mazzafera P. 2015. Photosynthesis is induced in rice plants that associate with arbuscular mycorrhizal fungi and are grown under arsenate and arsenite stress. Chemosphere, 134, 141–149.
Arnon D I. 1949. copper enzymes in isolated chloroplasts: Polyphenoloxidase in Beta vulgaris. Plant Physiology, 24, 1.
Bati C B, Santilli E, Lombardo L. 2015. Effect of arbuscular mycorrhizal fungi on growth and on micronutrient and macronutrient uptake and allocation in olive plantlets growing under high total Mn levels. Mycorrhiza, 25, 97–108.
Bowler C, Fluhr R. 2000. The role of calcium and activated oxygens as signals for controlling cross-tolerance. Trends in Plant Science, 5, 241–246.
Cabral C, Ravnskov S, Tringovska I, Wollenweber B. 2016. Arbuscular mycorrhizal fungi modify nutrient allocation and composition in wheat (Triticum aestivum L.) subjected to heat-stress. Plant and Soil, 408, 385–399.
Cameron D D, Neal A L, van Wees S C, Ton J. 2013. Mycorrhiza-induced resistance: More than the sum of its parts? Trends in Plant Science, 18, 539–545.
Carling D E, Roncadori R W, Hussey R S. 1995. Interactions of arbuscular mycorrhizae, Meloidogyne arenaria, and phosphorus fertilization on peanut. Mycorrhiza, 6, 9–13.
Chandrasekaran M, Boughattas S, Hu S, Oh S H, Sa T. 2014. A meta-analysis of arbuscular mycorrhizal effects on plants grown under salt stress. Mycorrhiza, 24, 611–625.
Chen M, Li X, Yang Q, Chi X, Pan L, Yang Z, Wang T, Wang M, Yu S. 2012. Soil eukaryotic microorganism succession as affected by continuous cropping of peanut-pathogenic and beneficial fungi were selected. PLoS ONE, 7, e40659.
Chi XY, Hu R B, Yang Q L, Zhang X W, Pan L J, Chen M N, Yang Z, Wang T, He Y N, Yu S L. 2012. Validation of reference genes for gene expression studies in peanut by quantitative real-time RT-PCR. Molecular Genetics and Genomics, 287, 167–176.
Chun O K, Daeok Kim A, Chang Y L. 2003. Superoxide radical scavenging activity of the major polyphenols in fresh plums. Journal of Agricultural and Food Chemistry, 51, 8067–8072.
Comas L H, Eissenstat D M, Lakso A N, Norby R, Fitter A, Jackson R. 2000. Assessing root death and root system dynamics in a study of grape canopy pruning. New Phytologist, 147, 171–178.
Garcia K, Chasman D, Roy S, Ane J M. 2017. Physiological responses and gene co-expression network of mycorrhizal roots under K+ deprivation. Plant Physiology, 173, 1811–1823.
Govindarajulu M, Pfeffer P E, Jin H, Abubaker J, Douds D D, Allen J W, Bücking H, Lammers P J, Shacharhill Y. 2005. Nitrogen transfer in the arbuscular mycorrhizal symbiosis. Nature, 435, 819–823.
Higgs J. 2003. The beneficial role of peanuts in the diet – Part 2. Nutrient Food Science, 33, 56–64.
Huang Y Q, Han X R, Yang J F, Liang C H, Zhan X M. 2013. Autotoxicity of peanut and identification of phytotoxic substances in rhizosphere soil. Allelopathy Journal, 31, 297–308.
Jaffe L A, Weisenseel M H, Jaffe L F. 1975. Calcium accumulations within the growing tips of pollen tubes. Journal of Cell Biology, 67, 488–492.
Javot H, Penmetsa R V, Terzaghi N, Cook D R, Harrison M J. 2007. A Medicago truncatula phosphate transporter indispensable for the arbuscular mycorrhizal symbiosis. Proceedings of the National Academy of Science of the United States of America, 104, 1720–1725.
Jia Z, Tang M, Wu J. 1999. The determination of flavonoid contents in mulberry and their scavenging effects on superoxide radicals. Food Chemistry, 64, 555–559.
Kazan K, Manners J M. 2009. Linking development to defense: Auxin in plant-pathogen interactions. Trends in Plant Science, 14, 373–382.
Van Kooten O, Snel J F H. 1990. The use of chlorophyll fluorescence nomenclature in plant stress physiology. Photosynthesis Research, 25, 147–150.
Köhl L, Lukasiewicz C E, Heijden M G A V D. 2015. Establishment and effectiveness of inoculated arbuscular mycorrhizal fungi in agricultural soils. Plant Cell and Environment, 39, 136–146.
Lei B, Huang Y, Xie J J, Liu Z X, Zhen A, Fan M L, Bie Z L. 2014. Increased cucumber salt tolerance by grafting on pumpkin rootstoch and after application of calcium. Biologia Plantarum, 58, 179–184.
Leifheit E F, Veresoglou S D, Lehmann A, Morris E K, Rillig M C. 2014. Multiple factors influence the role of arbuscular mycorrhizal fungi in soil aggregation a meta-analysis. Plant and Soil, 374, 523–537.
Li X, Ding C, Zhang T, Wang X. 2014. Fungal pathogen accumulation at the expense of plant-beneficial fungi as a consequence of consecutive peanut monoculturing. Soil Biology and Biochemistry, 72, 11–18.
Li X, Rezaei R, Li P, Wu G. 2011. Composition of amino acids in feed ingredients for animal diets. Amino Acids, 40, 1159–1168.
Li Y, Fang F, Guo F, Meng J J, Li X G, Xia G M, Wan S B. 2015. Isolation and functional characterization of CDPKs gene from Arachis hypogaea under salt stress. Functional Plant Biology, 42, 274–283.
Liese A, Romeis T. 2013. Biochemical regulation of in vivo function of plant calcium-dependent protein kinases (CDPK). Biochimica et Biophysica Acta, 1833, 1582–1589.
Lin K, Tsou C, Hwang S, Chen L, Lo H. 2006. Paclobutrazol pre-treatment enhanced flooding tolerance of sweet potato. Journal of Plant Physiology, 163, 750–760.
Liu W, Wang Q, Wang B, Wang X, Franks A E. 2015. Changes in the abundance and structure of bacterial communities under long-term fertilization treatments in a peanut monocropping system. Plant and Soil, 395, 415–427.
Livak K J, Schmittgen T D. 2001. Analysis of relative gene expression data using real-time quantitative PCR and the 2－ΔΔCt method. Methods, 25, 402–408.
Maclean A M, Bravo A, Harrison M J. 2017. Plant signaling and metabolic pathways enabling arbuscular mycorrhizal symbiosis. The Plant Cell, 29, 2319–2335.
McGonigle T P, Miller M H, Evans D G, Fairchild G L, Swan J A. 1990. A new method which gives an objective measure of colonization of roots by vesicular-arbuscular mycorrhizal fungi. New Phytologist, 115, 495–501.
Michalak A. 2006. Phenolic compounds and their antioxidant activity in plants growing under heavy metal stress. Polish Journal of Environmental Studies, 15, 523–530.
Nadeem S M, Ahmad M, Zahir Z A, Javaid A, Ashraf M. 2014. The role of mycorrhizae and plant growth promoting rhizobacteria (PGPR) in improving crop productivity under stressful environments. Biotechnology Advances, 32, 429–448.
Norman J R, Atkinson D, Hooker J E. 1996. Arbuscular mycorrhizal fungal-induced alteration to root architecture in strawberry and induced resistance to the root pathogen Phytophthora fragariae. Plant and Soil, 185, 191–198.
Pietta P G. 2000. Flavonoids as antioxidants. Journal of Natural Products, 63, 1035–1042.
Rich M K, Schorderet M, Bapaume L, Falquet L, Morel P, Vandenbussche M, Reinhardt D. 2015. The petunia GRAS transcription factor ATA/RAM1 regulates symbiotic gene expression and fungal morphogenesis in arbuscular mycorrhiza. Plant Physiology, 168, 788–797.
Ruge H, Flosdorff S, Ebersberger I, Chigri F, Vothknecht U C. 2016. The calmodulin-like proteins AtCML4 and AtCML5 are single-pass membrane proteins targeted to the endomembrane system by an N-terminal signal anchor sequence. Journal of Experimental Botany, 67, 3985–3996.
She S, Niu J, Zhang C, Xiao Y, Chen W, Dai L, Liu X, Yin H. 2017. Significant relationship between soil bacterial community structure and incidence of bacterial wilt disease under continuous cropping system. Archives of Microbiology, 199, 267–275.
Shipton P J. 2003. Monoculture and soilborne plant pathogens. Annual Review of Phytopathology, 15, 387–407.
Smith S E, Read D J. 2008. Mycorrhizal Symbiosis. 3rd ed. Academic Press, London.
Stewart R R C, Bewley J D. 1980. Lipid peroxidation associated with accelerated aging of soybean axes. Plant Physiology, 65, 245–248.
Sung J M, Jeng T L. 1994. Lipid peroxidation and peroxide-scavenging enzymes associated with accelerated aging of peanut seed. Physiologia Plantarum, 91, 51–55.
Wahid A, Ghazanfar A. 2006. Possible involvement of some secondary metabolites in salt tolerance of sugarcane. Journal of Plant Physiology, 163, 723–730.
Wang E, Schornack S, Marsh J K, Gobbato E, Schwessinger B, Eastmond P, Schultze M, Kamoun S, Oldroyd G E D. 2012. A common signaling process that promotes mycorrhizal and oomycete colonization of plants. Current Biology, 22, 2242–2246.
Wu Y N, He X H. 2010. Contributions of arbuscular mycorrhizal fungi to growth, photosynthesis, root morphology and ionic balance of citrus seedlings under salt stress. Acta Physiologiae Plantarum, 32, 297–304.
Xiong W, Zhao Q, Zhao J, Xun W, Li R, Zhang R, Wu H, Shen Q. 2015. Different continuous cropping spans significantly affect microbial community membership and structure in a vanilla-grown soil as revealed by deep pyrosequencing. Microbial Ecology, 70, 209–218.
Yang S, Wang F, Guo F, Meng J J, Li X G, Dong S T, Wan S B. 2013. Exogenous calcium alleviates photoinhibition of PSII by improving the xanthophyll cycle in peanut (Arachis hypogaea) leaves during heat stress under high irradiance. PLoS ONE, 8, e71214.
Yang S, Wang F, Guo F, Meng J J, Li X G, Wan S B. 2015. Calcium contributes to photoprotection and repair of photosystem II in peanut leaves during heat and high irradiance. Journal of Integrative Plant Biology, 57, 486–495.
Yang Y R, Han X Z, Liang Y, Ghosh A, Chen J, Tang M. 2015. The combined effects of arbuscular mycorrhizal fungi (AMF) and lead (Pb) stress on Pb accumulation, plant growth parameters, photosythesis, and antioxidant enzymes in Robinia pseudoacacia L. PLoS ONE, 10, e0145726.
Yin Y, Yang R, Han Y, Gu Z. 2015. Comparative proteomic and physiological analyses reveal the protective effect of exogenous calcium on the germinating soybean response to salt stress. Journal of Proteomics, 113, 110–126.
Yoon G M, Cho H S, Ha H J, Liu J R, Lee H S. 1999. Characterization of NtCDPK1, a calcium-dependent protein kinase gene in Nicotiana tabacum, and the activity of its encoded protein. Plant Molecular Biology, 39, 991–1001.
Zhang G, Liu Y, Ni Y, Meng Z, Lu T, Li T. 2014. Exogenous calcium alleviates low night temperature stress on the photosynthetic apparatus of tomato leaves. PLoS ONE, 9, e97322.