Effects of Putrescine and Biofertilizers on Content of Na+ and K+ Root and Shoots, Stomatal Conductance, Leaf Area Index, and Yield of Wheat (Triticum aestivum L.) under Salinity Stress

Document Type : Research Article

Authors

1 PhD Graduated in Agronomy, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran

2 Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran

3 Department of Agriculture, Payame Noor University, Tehran, Iran

Abstract

Introduction
Salinity is one of the major constraints to wheat growth, which hampers production, causing yield loss in arid and semi-arid regions. Reductions in growth resulting from high salinity are because of both osmotic stress, inducing a water deficit, and the effects of excess Na+ and Cl ions on critical biochemical processes. Salt stress induces a significant reduction in photosynthesis through the reduction of leaf area and photosynthetic pigments. Several strategies have been developed to decrease the toxic effects caused by high salinity on plant growth. Among them, the use of plant growth-promoting rhizobacteria (PGPR) such as Pseudomonas and Mycorrhiza play an important role in yield improvement. Many studies have been published on the beneficial effects of bacterial inoculation on plant physiology and growth under salt stress. One of the common hypotheses employed in most of the studies conducted under salinity stress was the lowering of ethylene level by the ACC-deaminase activities of PGPR and improved plant growth and yield under salinity stress.
It was reported that the application of Pseudomonas spp. improved plant growth by decreasing the uptake of Na+ and increasing the activities of antioxidant enzymes under salinity stress. The selective uptake of K+ as opposed to Na+ is considered one of the important physiological mechanisms contributing to salt tolerance in many plant species. Inoculation with PGPR significantly decreased Na+ uptake and increased K+ content and enhanced levels of K+ that could be to mitigate oxidative stress imposed by higher salinity. Some researchers have reported that PGPR species like Azotobacter and Pseudomonas increased the growth and biomass of canola (Brassica napus L.) under salinity stress.
A Better understanding of wheat physiological responses under salinity may help in programs in which the objective is to improve the grain yield under salinity stress. Therefore, this study aimed to evaluate the physiological, stomata conductance, along with root and shoot Na+/ K+ ratios) of wheat to cycocel and PGPR application under salinity stress.
Material and Methods
A factorial experiment was conducted based on a randomized complete block design with three replications at the research greenhouse of the Faculty of Agriculture and Natural Resources, the University of Mohaghegh Ardabili in 2018. The experimental factors included salinity at four levels (no-salinity as control, salinity 40, 80, and 120 mM NaCl based salinity), application of biofertilizers at four levels (no biofertilizers as control, mycorrhiza application, application of both Pseudomonas and Flavobacterim, application of mycorrhiza with Pseudomonas and Flavobacterim) and putrescine foliar application at three levels (foliar application with water as control, foliar application of 0.5 and 1 mM putrescine). Mycorrhiza fungi were purchased from the Zist Fanavar Turan Institute and soils were treated based on the manufacturer’s protocol of 20 g of inoculums per m2 of soil. For inoculation, seeds were coated with gum Arabic as an adhesive and rolled into the suspension of bacteria until uniformly coated. The strains and cell densities of microorganisms used as PGPR in this experiment were 107 colony-forming units (CFU). Humidity ranged from 60-65%. The wheat cultivar "Gascogne" was used in the experiment. The optimum density of cultivar "Gaskogen" is 400 seeds m-2, so forty seeds of wheat were sown in each pot at a depth of 4 cm deep. The pots were immediately irrigated after planting. Nano putrescine zinc oxide powder was added to deionized water and was placed on ultrasonic equipment (100 w and 40 kHz) on a shaker for making a better solution. Foliar application with nano putrescine oxide was done in two stages of period growth (pre and post-4 booting stage).
Results and Discussion
The results showed that with increasing salinity, potassium content, stomata conductance, and leaf area index decreased but the application of putrescine and biofertilizers increased these traits. At the highest salinity level (120 mM), there was a decrease of 24.94 and 21.57% respectively in Na+ root and shoots in the application of mycorrhiza with Pseudomonas and Flavobacterim and foliar application of 1 mM putrescine in comparison with no application biofertilizer and putrescine in same salinity level. At the highest salinity level, application of mycorrhiza with Pseudomonas and Flavobacterim and foliar application of 1 mM putrescine increased K+  root (47.76%), shoots (21.66%) and grain yield (28.57%) in comparison with no application biofertilizer and putrescine in same salinity level. It seems that the application of biofertilizers and putrescine can increase the grain yield of wheat under salinity stress due to improve stomata conductance and leaf area index.

Keywords

Main Subjects

Open Access

©2022 The author(s). This article is licensed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.

References

  1. Alvarez, M. I., Sueldo, R. J., & Barassi, C. A. (1996). Effect of Azospirillum on coleoptile growth in wheat seedling under water stress. Cereal Research Communication, 24, 101-107.
  2. Asch, F., Dingkuhn, M., & Droffling, K. (2000). Salinity increases CO2 assimilation but reduces growth in field growth irrigated rice. Plant Soil, 218, 1-10. https://doi.org/10.1023/A:1014953504021
  3. Ashraf, M., & McNielly, T. (2004). Salinity tolerance in Brassica oil seeds. Critical Reviews in Plant, 34, 34-45. https://doi.org/10.1080/07352680490433286
  4. Atiya, A. M., Poortvliet, E., Stromberg, R., & Yngve, A. (2011). Polyamines in foods: development of a food database. Food Nutrition Research, 14(55), 1-15. https://doi.org/10.3402/fnr.v55i0.5572
  5. Auge, R. M. (2004). Arbuscular mycorrhizae and soil/plant water relations. Canadian Journal of Soil Science, 84, 373-381.
  6. Baniasadi, F., Saffari, V. R., & Maghsoudi moud, A. (2015). Effect of putrescine on some physiological and morphological characteristics of pot marigold (Calendula officinalis) under salinity stress. Envirometal Stresses in Crop Science, 8(1), 73-82. https://doi.org/10.22077/escs.2015.202
  7. Bashan, Y., Ivanony, Y. H., & Saad, A. (1989). Nonspecific response in plant growth, yield and root colonization of non-cereal crop plant to inoculation with Azospirilum brasilense. Canadian Journal of Botany, 67, 1317-1324. https://doi.org/10.1139/b89-175
  8. Beltrano, J., Montaldi, E., Bartoli, C., & Carbone, A. (1997). Emission of water stress ethylene in wheat (Triticum aestivum) ears: Effects of rewatering. Plant Growth Regulation, 21, 121-126.
  9. Boomsma, C. R., & Vyn, T. J. (2008). Maize drought tolerance: Potential improvements through arbuscular mycorrhizal symbiosis. Field Crops Research, 108, 14-31. https://doi.org/10.1016/j.fcr.2008.03.002
  10. Chelah, M. K. B., Nordin, M. N. B., Musliania, M. I., Khanif, Y. M., & Jahan, M. S. (2011). Composting increases BRIS soil health and sustains rice production on BRIS soil. Scienceasia, 37, 291-295. https://doi.org/10.2306/scienceasia1513-1874.2011.37.291
  11. Chen, Z., Newman, I., Zhuo, M., Mendham, N., Zhang, G., & Shabala, S. (2005) Screening plants for salt tolerance by measuring K+ flux:a case study for barely. Plant Cell and Environment, 28, 1230-1246. https://doi.org/10.1111/j.1365-3040.2005.01364.x
  12. Colla, G., Rouphael, Y., Cardarelli, M., Tullio, M., Carlos, M. R., & Elvira, R. (2008). Alleviation of salt stress by arbuscular mycorrhizal in zucchini plants grown at low and high phosphorus concentration. Biology and Fertility of Soils, 44, 501-509. https://doi.org/1007/s00374-007-0232-8
  13. Colom, M. R., & Vazzana, C. (2003). Photosynthesis and PSII functionality of drought resistant and drought sensitive weeping lovegrass plant. Environmental and Experimental Botany, 49, 135-144.
  14. Cuartero, J., Bolarin, M. C., Asins, M. J., & Moreno, V. (2006). Increasing salt tolerance in tomato. Journal of Experimental Botany, 57, 1045-1058. https://doi.org/10.1093/jxb/erj102
  15. Duponnois, R., Galiana, A., & Prin, Y. (2008). The Mycorrhizosphere effect: A multitrophic interaction complex improves mycorrhizal symbiosis and plant growth. In: Siddiqui Z.A., Akhtar M.S., Futai K. (eds) Mycorrhizae: Sustainable Agriculture and forestry, Dordrecht: Springer.
  16. Elhindi, K. M., El-Din, A. S., & Elgorban, A. M. (2016). The impact of arbuscular mycorrhizal fungi in mitigating saltinduced adverse effects in sweet basil (Ocimum basilicum). Saudi Journal of Biological Science, 1-33. https://doi.org/10.1016/j.sjbs.2016.02.010
  17. Garg, N., & Bhandari, P. (2015). Silicon nutrition and mycorrhizal inoculations improve growth, nutrient status, K+/Na+ ratio and yield of Cicer arietinum genotypes under salinity stress. Plant Growth Regulation, 371-378. https://doi.org/10.1007/s10725-015-0099-x
  18. Giri, B., Kapoor, R., & Mukerji, K. G. (2007). Improved tolerance of Acacia nilotica to salt stress by arbuscular mycorrhiza, Glomus fasciculatum may be partly related to elevated K/Na ratios in root and shoot tissues. Microbial Ecology, 54, 753-760. https://doi.org/10.1007/s00248-007-9239-9
  19. Glick, B. R., Penrose, D., & Wendo, M. (2001). Bacterial promotion of plant growth. Biotechnology Advance, 19, 135-138. https://doi.org/10.1016/s0734-9750(00)00065-3
  20. Grattan, S. R., & Grieve, C. M. (1999) Salinity-mineral nutrient relations in horticultural crops. Journal of Horticultural Science, 78, 127-157.
  21. Hadi, H., Seyed Sharifi, R., & Namvar, A. (2016). Phytoprotectants and Abiotic Stresses. Urmia University press. 342p.
  22. Hagh Bahari, M., & Seyed Sharifi, S. (2013). Influence of seed inoculation with plant growth promoting rhizobacteria (PGPR) on yield, grain filling rate and period of wheat in different levels of soil salinity. Environmental Stresses in Crop Sciences, 6(1), 65-75. https://doi.org/22077/escs.2013.138
  23. Hammer, E. C., Nasr, H., Pallon, J., Olsson, P. A., & Wallander, H. (2011). Elemental composition of arbuscular mycorrhizal fungi at high salinity. Mycorrhiza, 21, 117-129. https://doi.org/1007/s00572-010-0316-4
  24. Hanafy Ahmed, A. H., Darwish, E., Hamoda, S. A. F., & Alobaidy, M. G. (2013). Effect of putrescine and humic acid on growth, yield and chemical composition of cotton plants grown under saline soil conditions. American-Eurasian Journal of Agricultural and Environmental Sciences, 13, 479-497. https://doi.org/5829/idosi.aejaes.2013.13.04.1965
  25. He, T., & Cramer, G. R. (1993). Salt tolerance of rapid cycling Brassica species in relation to K+ /Na+ ratio and selectivity at the whole plant and callus levels. Journal of Plant Nutrition, 16, 1263-1277.
  26. Hussein, M. M., Nadia, H. M., EL-Gereadly, & EL-Desuki, M. (2006). Role of puterscine in resistance to salinity of Pea plants (Pisum sativum). Journal of Applied Science Research, 2(9), 598-604.
  27. Jamil, M., Rehman,, Jae Lee, K., Man Kim, J., Kim, H. S., & Rha, E. S. (2007). Salinity reduced growth PS2 Photo chemistry and chlorophyll content in Radish. Science Agriculture, 64, 111-118. https://doi.org/10.1590/S0103-90162007000200002
  28. Kafi, M., & Stewart, D. A. (1998). Effect of salinity on growth and yield of nine types of wheat. Agronomy Food Science, 12(1), 77-85.
  29. Karlidag, H., Esitken, A., Yildirim, E., Figen-Donmez, M., & Turan, M. (2011). Effects of plant growth promoting bacteria on yield, growth, leaf water content, membrane permeability and ionic composition of strawbwrry under saline conditions. Journal of Plant Nutrrition, 23, 157-174. https://doi.org/101080/01904167.2011.531356
  30. Kaya, C., Akram, N., Ashraf, M., & Sonmez, O. (2018). Exogenous application of humic acid mitigates salinitystress in maize (Zea mays) plants by improving some key physicobiochemical attributes. Cereal Research Communications, 46(1), 67-78. https://doi.org/10.1556/0806.45.2017.064
  31. Kheirizadeh Arough, Y., Seyed Sharifi, R., Sedghi, M., & Barmaki, M. (2016). Effect of zinc and bio fertilizers on antioxidant enzymes activity, chlorophyll content, soluble sugars and proline in Triticale under salinity condition. Notula Botanica Horticultural Agro Cluj-Napoca, 44(1), 116-124. https://doi.org/15835/nbha44110224
  32. Mass, E. V., & Poss, J. A. (1989). Salt sensitivity of wheat at various growth stages. Irrigation Science 10(1), 29-40.
  33. Moradi, F., & Abdelbagi, M. I. (2007). Response of photosynthesis, chlorophyll fluorescence and ROS- scavenging systems to salt stress during seeding and reproductive stages in rice. Annals Botany, 1-13. https://doi.org/1093/aob/mcm052
  34. Moradi, L., & Seyed Sharifi, R. (2018). Response of antioxidant enzymes, chlorophyll content and leaf area index of Rye to seed inoculation with plant growth promoting bacteria under salinity conditions. Crop Physiology Journal, 7(38), 77-93.
  35. Munns, R., James, R. A., & Lauchli, A. (2006). Approaches to increasing the salt tolerance of wheat and other cereals. Journal Experimental Botany, 57, 1025-1043. https://doi.org/10.1093/jxb/erj100
  36. Nadeem, S. M., Zahir, Z. A., Naveed, M., Arshad, M., & Shahzad, S. M. (2006). Variation in growth and ion uptake of maize due to inoculation with plant growth promoting rhizobacteria under salt stress. Soil and Environment, 25, 78-84.
  37. Ortas, I., Sari, N., Akpinar, C., & Yetisir, H. (2011). Screening mycorrhiza species for plant growth, P and Zn uptake in pepper seedling grown under greenhouse conditions. Scientia Horticulturae, 128(2), 92-98. https://doi.org/10.1016/j.scienta.2010.12.014
  38. Parvaiz, A., & Satyawati, S. (2008). Salt stress and phyto-biochemical responses of plants-a review. Plant, Soil and Environment, 54, 89-99.
  39. Prasad, T. N., Sudhakar, P., Sreenivasulu, Y., Latha, P., Munaswamy, V., Raja Reddy, K., Sreeprasad, T. S., & Sajanlal, P. R. (2012). Effect of nanoscale Zinc-oxide particles on the germination, growth and yield of peanut. Journal of Plant Nutrition, 35, 905-927. https://doi.org/1080/01904167.2012.663443
  40. Ravikumar, S., Kathiresan, K., Ignatiammal, S. T. M., Selvam, M. B., & Shanthy, S. (2004). Nitrogen fixation Azotobacters from mangrove habitat and their utility as marine biofertilizers. Journal of Experimental Biology, 15, 157-160. https://doi.org/1016/j.jembe.2004.05.020
  41. Rabie, A. M., & Almadini, G. H. (2005). Role of bioinoculants in development of salt-tolerance of Vicia faba plants under salinity stress. African Journal of Biotechnology, 4(3), 210-222.
  42. Rengel, Z. (1992). The role of calcium in salt toxicity. Plant, Cell and Environment, 15, 625-632. https://doi.org/1111/j.1365-3040.1992.tb01004.x
  43. Rodriguez, H., & Fraga, R. (1999). Phosphate solubilizing bacteria and their role in plant growth promotion. Biotechnology Advances, 17, 319-339. https://doi.org/1016/S0734-9750(99)00014-2
  44. Sandhya, V., Ali, S. K. Z., Grover, M., Reddy, G., & Venkateswarlu, B. (2010). Effect of plant growth promoting Pseudomonas spp. on compatible solutes, antioxidant status and plant growth of maize under drought stress. Plant Growth Regulation, 62, 21-30.
  45. Seyed Sharifi, R., & Golineghad, E. (2021). Evalution Agronomic and Morphophysiological Traits of Crop Plants. University of Mohaghegh Ardabili press. 400 pp.
  46. Sfakianaki, M., Sfichi, L., & Kotzabasis, K. (2006). The involvement of LHCII-associated polyamines in the response of the photosynthetic apparatus to low temperature. Journal of Photochemistry and Photobiology B: Biology, 84, 181-188. https://doi.org/1016/j.jphotobiol.2006.03.003
  47. Shiyab, S. (2011). Effects of NaCl application to hydroponic nutrient solution on macro and micro elements and protein content of hot pepper (Capsicum annuum). Journal of Food, Agriculture and Environment, 9, 350-356.
  48. Talaat, I. M., Bekheta, M. A., & Mahgoub, M. H. (2005). Physiological response of periwinkle plants (Catharanthus roseus) to tryptophan and putrescine. International Journal of Agriculture and Biology, 7, 210-213.
  49. Wang, H., Ju, X., Wei, Y., Li, B., Zhao, L., & Hu, K. (2010) Simulation of bromide and nitrate leaching under heavy rainfall and high-intensity irrigation rates in North China Plain. Agricultural Water Management, 97(10), 1646-1654. https://doi.org/1016/j.agwat.2010.05.022
  50. Wu, S. C., Cao, Z. H., Li, Z. G., Cheung, K. C., & Wong, M. H. (2005). Effects of bio fertilizer containing N-fixer, P and K solubilizers and AM fungi on maize growth: a greenhouse trial. Geoderma, 125, 155-166. https://doi.org/1016/j.geoderma.2004.07.003
  51. Zahir, Z. A., Munir, A., Asghar, H. N., Arshad, M., & Shaharoona, B. (2008). Effectiveness of rhizobacteria containing ACC-deaminase for growth promotion of peas (Pisum sativum) under drought conditions. Journal of Microbioogyl Biotechnology, 18, 958-963.
  52. Zhu, X., Song, F., & Xu, (2010). Influence of arbuscular mycorrhiza on lipid peroxidation and antioxidant enzyme activity of maize plants under temperature stress. Mycorrhiza, 20, 325-332.
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History

  • Receive Date: 10 October 2022
  • Revise Date: 11 December 2022
  • Accept Date: 18 December 2022
  • First Publish Date: 18 December 2022

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