Inomjon ISRAİLOV, Khamidulla SHERALİEV, Guliston ABDALOVA, Abduvali IMİNOV, Kholik ALLANOV, Aziz KARİMOV, Botir KHAİTOV

INTERACTIVE EFFECTS OF N FERTILIZATION AND BRADIRHIZOBIA JAPANICUM ON AGRONOMICAL TRAITS OF SOYBEAN IN SALT AFFECTED SOILS

Soil salinity has enormous negative impact on crop productivity leading to food insecurity and malnutrition, especially in arid regions. A field experiment was conducted during the summer seasons of 2018 and 2019 to evaluate the effects of various N fertilization rates in combination with Bradyrhizobium japonicum inoculation on the agronomic perfor-mance of soybean (Glycine max L) in saline soils (EC 5.8 dS m-1). The following fertilization treatments were applied: no fertilization (control), N0Р90К60, N30Р90К60, N60Р90К60 individually and in tandem with B. japonicum as a seed bio-inoculant. The experiment in a split-plot design, N fertilization as the main plot, the seed inoculation as the sub-plot was set up in three replicates. Soybean growth, nutrients uptake and yield parameters increased with increasing N fertili-zation rate, however, the effect was more pronounced with the seed inoculation. Averaged over the cropping seasons, the soybean yield was higher by 20.4%, 19.0%, 34.1% and 6.1% in the inoculated treatments of no-fertlization, N0Р90К60, N30Р90К60, N60Р90К60, respectively as compared to the similar fertilization treatments without the seed inoculation. As a result, fertilization rate of N30Р90К60 in with association B. japonicum inoculation was recommended as this study outcome due to the high soybean yield and quality seeds as the crucial components of sustainable agricultural production under salt-stressed field conditions.

Keywords:

soybean Bradyrhizobium japonicum, N fertilization, plant growth, nutrient content, salinity, yield, Glycine max,

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Abdel Latef, A.A.H., A.M. Omer, A.A. Badawy, M.S. Osman and M.M. Ragaey. 2021. Strategy of salt tolerance and interactive impact of Azotobacter chroococcum and/or Alcaligenes faecalis inoculation on canola (Brassica napus L.) plants grown in saline soil. Plants 10(1): 110.
Abdelghany, A.M., S. Zhang, M. Azam, A.S. Shaibu, Y. Feng, J. Qi, Y. Li, Y. Tian, H. Hong and B. Li. 2020. Natural variation in fatty acid composition of diverse world soybean germplasms grown in china. Agron.10: 24.
Abdiev, A., B. Khaitov, K. Toderich, K.W. Park. 2019. Growth, nutrient uptake and yield parameters of chickpea (Cicer arietinum L.) enhance by Rhizobium and Azotobacter inoculations in saline soil. J. Plant Nutr. 42(20): 2703-2714.
Allanov, K., K. Sheraliev, C. Ulugov, S. Ahmurzayev, O. Sottorov, B. Khaitov and K.W. Park. 2019. Integrated effects of mulching treatment and nitrogen fertilization on cotton performance under dryland agriculture. Commun. Soil Sci.Plant Anal. 50(15): 1907-1918.
Ashraf, M. and P.J.C..Harris 2013. Photosynthesis under stressful environments: An overview. Photosynth. 51: 163–190.
Asik, F.F. and H. Arioglu. 2020. The effect of rhizobium inoculation and nitrogen application on various agronomical and quality characteristics of peanut grown as a main crop. Turk J. Field Crops. 25(2): 100-106.
Azam, M., S. Zhang, J. Qi, A.M. Abdelghany, A.S. Shaibu, S. Ghosh, Y. Feng, Y. Huai and J. Gebregziabher. 2021. Profiling and associations of seed nutritional characteristics in Chinese and USA soybean cultivars. J. Food Compos. Anal. 98: 103803.
Aziz, I., T. Mahmood and K.R. Islam. 2013. Effect of long term no-till and conventional tillage practices on soil quality. Soil Tillage Res. 131: 28-35.
Cafaro La Menza, N., J.P. Monzon, J.E. Specht, J.L. Lindquist, T.J. Arkebauer, G. Graef and P. Grassini. 2019. Nitrogen limitation in high-yield soybean: Seed yield, N accumulation, and N-use efficiency. Field Crops Res. 237: 74–81.
Chalon, S. 2006. Omega-3 fatty acids and monoamine neurotransmission. Prostaglandins Leukot. Essent. Fat. Acids 75: 259–269.
da Mota R.P., R. De Camargo, E.M. Lemes, R.M.Q. Lana, R.F. de Almeida and E.R. de Moraes. 2019. Biosolid and sugarcane filter cake in the composition of organomineral fertilizer on soybean responses. Int. J. Recycl. Org. Waste Agric. 8(2): 131-137.
FAOSTAT. 2020. FAOSTAT database. Food Agric. Organ. UN. (accessed on 26 October 2022).
Gebauer, S.K., T.L. Psota, W.S. Harris and P.M. Kris-Etherton. 2006. n-3 fatty acid dietary recommendations and food sources to achieve essentiality and cardiovascular benefits. Am. J. Clin. Nutr. 83: 1526S–1535S.
Hammerschmiedt, T., J. Holatko, M. Sudoma, A. Kintl, J. Vopravil, P. Ryant and M. Brtnicky. 2021. Biochar and sulphur enriched digestate: utilization of agriculture associated waste products for improved soil carbon and nitrogen content, microbial activity, and plant growth. Agron. 11(10): 2041.
Horneck, D.A. and D. Hanson. 1998. Determination of potassium and sodium by flame emission spectrophotometry. Handbook of reference methods for plant analysis. 19: 153-155.
Htwe, A.Z., S.M. Moh, K. Moe and T.Yamakawa. 2019. Biofertilizer production for agronomic application and evaluation of its symbiotic effectiveness in soybeans. Agron. 9(4): 162.
Hungria, M., M.A. Nogueira, L.J.M. Campos, P. Menna, F. Brandi and Y.G. Ramos. 2020.Seed pre-inoculation with Bradyrhizobium as time-optimizing option for large-scale soybean cropping systems. Embrapa Soja-Artigo em periódico indexado (ALICE).
Ilker, E., M. Kocaturk, A. Kadiroglu, A. Yildirim, G. Ozturk, H. Yildiz, and I. Koken, 2018a. Adaptation Abilities and Quality Parameters of Selected Soybean Lines under Double Cropping in the Mediterranean Region. Turkish Journal of Field Crops 23 (1): 49-55. DOI: 10.17557/tjfc.421584
Ilker, E., M. Kocaturk, A. Kadiroglu, M. Altinbas, A. Yildirim, G. Ozturk and H. Yildiz. 2018b. Stability Analyses for Double Cropping in Soybean [(Glycine max L.) Merrill]. Turkish Journal of Field Crops 23 (2): 80-84.
Israilov, I., H. Atabaeva and N. Umarova. 2012. Soybean. Tashkent, Uzbekistan; TDAU University Press. Jaga, P.K. and S.A. Sharma. 2015. Effect of biofertilizer and fertilizers on productivity of soybean. Ann. Plant Soil Res. 17(2): 171-174.
Jahangir, M.M., M. Jahiruddin, H. Akter, R. Pervin and K.R. Islam. 2021. Cropping diversity with rice influences soil aggregate formation and nutrient storage under different tillage systems. J. Plant Nutr. Soil Sci. 184(1): 150-162.
Januszewska A, E.M. Siedlecka, P. Glamowski and I. Tomasiak. 1999. Determination of oil content in rapeseeds using two methods–soxhlet extraction and pulsed nuclear magnetic resonance spectrometry. PN-EN ISO 659:1999.
Khaitov, B., J. Vollmann, J.Y. Pyon, K.W. Park. 2020. Improvement of salt tolerance and growth in common bean (Phaseolus vulgaris L.) by co-inoculation with native rhizobial strains. J. Agric. Sci. Tech. 22(1): 209-220.
Khan, S., A.E.L. Hesham, M. Qiao, S. Rehman and J.Z. He. 2010. Effects of Cd and Pb on soil microbial community structure and activities. Environ. Sci. Pollut. Res. 17: 288–296.
Kocaturk, M., P. Cubukcu, A.T. Goksoy, M. Sincik, E. Ilker, A. Kadiroglu, A. Yildirim. 2019. GGE biplot analysis of genotype× environment interaction in soybean grown as a second crop. Turk. J. Field Crops. 24(2): 145-154
Mahanta, D., R.K. Rai, S.D. Mishra, A. Raja, T.J. Purakayastha and E. Varghese. 2014. Influence of phosphorus and biofertilizers on soybean and wheat root growth and properties. Field Crops Res. 166: 1-9.
Marro, N., N. Cofré, G. Grilli, C. Alvarez, D. Lucas, D. Maestri and C. Urcelay. 2020. Soybean yield, protein content and oil quality in response to interaction of arbuscular mycorrhizal fungi and native microbial populations from mono- and rotation-cropped soils. Appl. Soil Ecol.152: 103575.
Mourtzinis, S., A.P. Gaspar, S.L. Naeve and S.P. Conley. 2017. Planting date, maturity, and temperature effects on soybean seed yield and composition. J. Agron. 109: 2040–2049.
NIAST. Methods of analysis of soil and plant. 2000. NIAST (National Institute of Agricultural Science and Technology) Suwon, Korea.
Nosheen, S., I. Ajmal and Y. Song. 2021. Microbes as biofertilizers, a potential approach for sustainable crop production. Sustainability 13: 1868.
Ozturk, E. 2021. Critical dose of nitrogen and phosphorus for the enhanced growth, yield, and quality components in mustard (Sinapsis Arvensis L.) In a semi arid environment. Turk. J. Field Crops. 26(2): 244-252.
Silva, L.R., C. Bento, A. Carolina Goncalves, J. David FloresFélix, M. Helena Ramírez-Bahena, A. Peix and E. Velázquez. 2017. Legume bioactive compounds: Influence of rhizobial inoculation. AIMS Microbiol. 3: 267–278.
Soba, D., I. Aranjuelo, B. Gakière, F. Gilard, U. Pérez-López, A. Mena-Petite and A. Sanz-Saez. 2021.Soybean inoculated with one bradyrhizobium strain isolated at elevated [co2] show an impaired c and n metabolism when grown at ambient [CO2]. Front. Plant Sci.12.
Son, T.T.N., V.V. Thu, L.H. Man, H. Kobayashi and R. Yamada. 2004. Effect of long-term application of organic and biofertilizer on soil fertility under rice-soybean-rice cropping system. Omonrice 12: 45-51.
SOYSTATS. 2020. Available online: http://soystats.com/international-world-vegetable-oilconsumption/ (accessed on 26 October 2021).
Stojsin M.M., S. Petrovic, M. Dimitrijevic, J. Šućur Elez, Đ. Malenčić, V. Zecevic and D. Knezevic. 2022. Effect of salinity stress on antioxidant activity and grain yield of different wheat genotypes. Turk. J. Field Crops 27(1): 33-40.
Sulieman, S., C.V. Ha, M.N. Esfahani, Y. Watanabe, R. Nishiyama, C.T.B. Pham, D.V. Nguyen and L.S.P. Tran. 2015. A promising new genetic resource for improved drought tolerance in soybean when solely dependent on symbiotic N2 fixation. BioMed Res. Int. 687213.
Szpunar-Krok, E., A. Wondołowska-Grabowska, D. BobreckaJamro, M. Jańczak-Pieniążek, A. Kotecki and M. Kozak. 2021, Effect of nitrogen fertilisation and inoculation with bradyrhizobium japonicum on the fatty acid profile of soybean (Glycine max (L.) Merrill) Seeds. Agron. 11(5): 941.
Tarekegn, M.A. and K. Kibret. 2017. Effects of rhizobium, nitrogen and phosphorus fertilizers on growth, nodulation, yield and yield attributes of soybean at Pawe Northwestern Ethiopia. World Sci. News 67(2): 201-218.
Toker, C., J. Gorham and M.I. Cagirgan. 2009. Certain ion accumulations in barley mutants exposed to drought and salinity. Turk. J. Field Crops. 14(2): 162-169.
Torres, D., I. Benavidez, F. Donadio, E. Mongiardini, S. Rosas, S. Spaepen and F. Cassán. 2018. New insights into auxin metabolism in Bradyrhizobium japonicum. Res. Microbiol. 169(6): 313-323.
Wang, X., B. Liu, G. Wu, Y. Sun, X. Guo, Z. Jin, W. Xu, Y. Zhao, F. Zhang, C. Zou and X. Chen. 2018. Environmental costs and mitigation potential in plastic-greenhouse pepper production system in China: A life cycle asessment. Agric. Syst. 167: 186-194.
Wirasnita, R., T. Hadibarata, Y.M. Novelina, A.R.M. Yusoff and Z. Yusop. 2013. A modified methylation method to determine fatty acid content by gas chromatography. Bull. Korean Chem. Soc. 34(11): 3239-3242.
Yucel, D., C. Yucel, E.L. Aksakal, K. Barik, M. Khosa, I. Aziz, K.R. Islam. 2015. Impacts of biosolids application on soil quality under alternate year no-till corn-soybean rotation. Water Air Soil Pollut. 226(6): 1-11.
Zhang, J., Y. Ge, F. Han, B. Li, S. Yan, J. Sun and L. Wang. 2014. Isoflavone content of soybean cultivars from maturity group 0 to VI grown in northern and southern China. J. Am. Oil Chem. Soc. 91: 1019–1028.
Zimmer, S., M. Messmer, T. Haase, H.P. Piepho, A. Mindermann, H. Schulz, A. Habekuß, F. Ordon, K.P. Wilbois and J. Heß. 2016. Effects of soybean variety and Bradyrhizobium strains on yield, protein content and biological nitrogen fixation under cool growing conditions in Germany. Eur. J. Agron. 72: 38–46.