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The response of flue-cured tobacco cultivar K326 to nitrogen fertilizer rate in China

Published online by Cambridge University Press:  17 September 2020

Yanjie Chen
Affiliation:
Yunnan Agricultural University, Kunming650201, Yunnan, China Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Ke Ren
Affiliation:
Yunnan Agricultural University, Kunming650201, Yunnan, China Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Xian He
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Yi Chen
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Binbin Hu
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Xiaodong Hu
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Junying Li
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Yan Jin
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
Zhengxiong Zhao*
Affiliation:
Yunnan Agricultural University, Kunming650201, Yunnan, China
Congming Zou*
Affiliation:
Yunnan Academy of Tobacco Agricultural Sciences, Kunming650021, China
*
Author for correspondence: Zhengxiong Zhao, E-mail: [email protected]; Congming Zou, E-mail: [email protected]
Author for correspondence: Zhengxiong Zhao, E-mail: [email protected]; Congming Zou, E-mail: [email protected]

Abstract

Nitrogen is an important element for the growth of flue-cured tobacco and is closely related to its yield and quality. In order to pursue higher economic benefits, excessive fertilizer is generally applied in flue-cured tobacco production, which is unfavourable for the sustainable development of flue-cured tobacco production and for the environment. In 2016 and 2017, experiments using different nitrogen fertilizer application rates in flue-cure tobacco were conducted in Yunnan province, and the changes in agronomic, economic and chemical indices as well as in residual soil nitrogen were compared. Linear and quadratic models were used to compare the response of tobacco to nitrogen fertilizer. With increasing nitrogen fertilizer rate, the proportions of superior to medium tobacco and the average price of flue-cured tobacco leaves initially increased and then decreased, while fresh weight, dry weight and the proportion of inferior tobacco showed the opposite trend. Total sugar and reducing sugar contents decreased with increasing nitrogen fertilizer rates, while total nitrogen and nicotine contents increased. Sensory evaluation scores had the highest value when 90 kg N/ha and 120 kg N/ha were applied. Soil nitrate contents increased as nitrogen fertilizer rate increased. The quadratic model was suitable for the response of cultivar K326 to nitrogen and 90 kg N/ha could meet the needs of cultivar K326.

Type
Crops and Soils Research Paper
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

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Footnotes

*

These authors contributed equally to this work.

References

Aulakh, MS, Khera, TS, Doran, JW and Bronson, KF (2001) Managing crop residue with green manure, urea, and tillage in a rice-wheat rotation. Soil Science Society of America Journal 65, 820827.CrossRefGoogle Scholar
Bacon, CW, Wenger, R and Bullock, JF (1952) Chemical changes in tobacco during flue-curing. Industrial & Engineering Chemistry 44, 292296.Google Scholar
Bélanger, G, Walsh, JR, Richards, JE, Milburn, PH and Ziadi, N (2000) Comparison of three statistical models describing potato yield response to nitrogen fertilizer. Agronomy Journal 92, 902908.CrossRefGoogle Scholar
Broaddus, GM, York, JE and Moseley, JM (1965) Factors affecting the levels of nitrate nitrogen in cured tobacco leaves. Tobacco Science 9, 149157.Google Scholar
Brown, GW and Terrill, TR (1973) Effects of method of harvest on flue-cured tobacco part II. Chemical components 1. Agronomy Journal 65, 268273.CrossRefGoogle Scholar
Cerrato, ME and Blackmer, AM (1990) Comparison of models for describing; corn yield response to nitrogen fertilizer. Agronomy Journal 82, 138143.CrossRefGoogle Scholar
Collins, WK and Hawks, SN (1994) Principles of Flue-Cured Tobacco Production, 1st Edn edn, Raleigh, NC: North Carolina State University, pp. 2198.Google Scholar
Crafts-Brandner, SJ, Sutton, TG and Sims, JL (1987) Root system genotype and nitrogen fertility effects on physiological differences between Burley and flue-cured tobacco. II. Whole plant 1. Crop Science 27, 12191224.CrossRefGoogle Scholar
Crutchfield, JD and Grove, JH (2011) A New Cadmium reduction device for the microplate determination of nitrate in water, soil, plant tissue, and physiological fluids. Journal of AOAC International 94, 18961905.Google ScholarPubMed
Cui, ZY, Ruan, Z, Chen, FC, Zhang, L, Zheng, PF, Gao, M, Jin, BF and Zhang, LX (2016) Effects of nitrogen fertilizer application on nitrogen and potassium content, photosynthetic characteristics as well as enzyme activity of carbon and nitrogen metabolism and yield and quality of flue-cured tobacco in Southern Shanxi Province. Southwest China Journal of Agricultural Sciences 29, 628634.Google Scholar
Daliparthy, J, Barker, AV and Mondal, SS (1994) Potassium fractions with other nutrients in crops: a review focusing on the tropics. Journal of Plant Nutrition 17, 18591886.CrossRefGoogle Scholar
Dempster, DN, Jones, DL and Murphy, DV (2012) Clay and biochar amendments decreased inorganic but not dissolved organic nitrogen leaching in soil. Soil Research 50, 216221.CrossRefGoogle Scholar
Diacono, M, Rubino, P and Montemurro, F (2013) Precision nitrogen management of wheat. A review. Agronomy for Sustainable Development 33, 219241.CrossRefGoogle Scholar
Dinnes, DL, Karlen, DL, Jaynes, DB, Kaspar, TC, Hatfield, JL, Colvin, TS and Cambardella, CA (2002) Nitrogen management strategies to reduce nitrate leaching in tile-drained midwestern soils. Agronomy Journal 94, 153171.CrossRefGoogle Scholar
Dordas, CA and Sioulas, C (2008) Safflower yield, chlorophyll content, photosynthesis, and water use efficiency response to nitrogen fertilization under rainfed conditions. Industrial Crops and Products 27, 7585.CrossRefGoogle Scholar
Dwyer, LM, Anderson, AM, Ma, BL, Stewart, DW, Tollenaar, M and Gregorich, E (2013) Quantifying the nonlinearity in chlorophyll meter response to corn leaf nitrogen concentration. Canadian Journal of Plant Science 75, 179182.CrossRefGoogle Scholar
Elliot, JM and Court, WA (1978) The effects of applied nitrogen on certain properties of flue-cured tobacco and smoke characteristics of cigarettes. International Tobacco 22, 5458.Google Scholar
Evans, JR (1983) Nitrogen and photosynthesis in the flag leaf of wheat (Triticum aestivum L.). Plant Physiology 72, 297302.CrossRefGoogle Scholar
Golcz, A and Politycka, B (2009) Contents of chlorophyll and selected mineral components and the yield of common thyme (Thymus vulgaris L.) at differentiated nitrogen fertilization. Herba Polonica 55, 6975.Google Scholar
Gous, PJ, Terrill, TR and Kroontje, W (1971) Effects of soil fumigation and the form of nitrogen on the growth, yield, and value of tobacco grown on two soil types. I. Plant growth and yield 1. Agronomy Journal 63, 221224.CrossRefGoogle Scholar
Grant, CA, Derksen, DA, McLaren, DL and Irvine, RB (2011) Nitrogen fertilizer and urease inhibitor effects on canola seed quality in a one-pass seeding and fertilizing system. Field Crops Research 121, 201208.Google Scholar
Hajaji, AN and Gouia, H (2014) Photosynthesis sensitivity to NH4+-N change with nitrogen fertilizer type. Plant Soil and Environment 60, 274279.CrossRefGoogle Scholar
Jensen, MM, Lam, P, Revsbech, NP, Nagel, B, Gaye, B, Jetten, MS and Kuypers, MM (2011) Intensive nitrogen loss over the Omani shelf due to anammox coupled with dissimilatory nitrite reduction to ammonium. The ISME Journal 5, 1660.CrossRefGoogle Scholar
Karaivazoglou, NA, Tsotsolis, NC and Tsadilas, CD (2007) Influence of liming and form of nitrogen fertilizer on nutrient uptake, growth, yield, and quality of Virginia (flue-cured) tobacco. Field Crops Research 100, 5260.Google Scholar
Li, LY, Zou, XM, Huang, SQ, Huang, GQ and Liu, F (2007) Effects of different cultural practices on nicotine, agronomical and economic characters of flue-cured tobacco. Acta Agriculturae Jiangxi 3, 15.Google Scholar
Li, WQ, Chen, SH, Li, CJ and Ke, YQ (2012) Study on the relationship between polyphenols content and chemical index of flue-cured tobacco in different amount of applied nitrogen. Chinese Agricultural Science Bulletin 28, 282289.Google Scholar
Liu, HB, Li, ZH, Zhang, WL and Lin, B (2004) Study on N use efficiency of Chinese cabbage and nitrate leaching under open field cultivation. Plant Nutrition and Fertilizing Science 10, 286291.Google Scholar
Liu, J, Dai, LJ, Wang, Y and Rang, ZW (2017) The interaction effect of density and N application rate on the main chemical composition and agronomic traits of flue-cured tobacco. Crop Research 31, 152159.Google Scholar
Lu, XL, Zhou, JH, Lin, ZZ, Niu, LN and Nie, M (2013) Analysis on main chemical components of four flue-cured tobaccos in Qujing of Yunnan. Journal of Agriculture 3, 6770.Google Scholar
Lu, LM, Zeng, XM, Zhang, YH and Li, LQ (2017) Effects of nitrogen application on activities of Key enzymes and their gene expression in sugar metabolism in flue-cured tobacco. Chinese Tobacco Science 38, 8490.Google Scholar
Ma, XH, Liang, XF, Liu, GL, Shi, Y and Zhang, ZF (2016) Effect of nitrogen application rate and base and topdressing ratio on nitrogen utilization of flue-cured tobacco. Journal of Plant Nutrition and Fertilizer 22, 16551664.Google Scholar
MacKown, CT and Sutton, TG (1997) Recovery of fertilizer nitrogen applied to burley tobacco. Agronomy Journal 89, 183189.CrossRefGoogle Scholar
MacKown, CT and Sutton, TG (1998) Using early-season leaf traits to predict nitrogen sufficiency of Burley tobacco. Agronomy Journal 90, 2127.Google Scholar
Marchetti, R, Castelli, F and Contillo, R (2006) Nitrogen requirements for flue-cured tobacco. Agronomy Journal 98, 666674.CrossRefGoogle Scholar
Matsi, T, Papadopoulos, G, Stefanou, S, Kanellopoulos, G, Baharis, N and Barbyannis, N (2000) Effect of liming on the growth and composition of the tobacco varieties Katerini and VE9. CORESTA congress, Lisbon, Portugal.Google Scholar
Matt, P, Geiger, M, Walch-Liu, P, Engels, C, Krapp, A and Stitt, M (2001) The immediate cause of the diurnal changes of nitrogen metabolism in leaves of nitrate-replete tobacco: a major imbalance between the rate of nitrate reduction and the rates of nitrate uptake and ammonium metabolism during the first part of the light period. Plant, Cell & Environment 24, 177190.CrossRefGoogle Scholar
Miner, GS and Sims, JL (1983) Changing fertilization practices and utilization of added plant nutrients for efficient production of burley and flue-cured tobacco. Recent Advances in Tobacco Science 9, 476.Google Scholar
Parker, RG (2009) Evaluation of nitrogen sources and rates on yield and quality of modern flue-cured tobacco cultivars (PhD thesis). North Carolina State University, Raleigh, NC.Google Scholar
Paul, MJ and Pellny, TK (2003) Carbon metabolite feedback regulation of leaf photosynthesis and development. Journal of Experimental Botany 54, 539547.CrossRefGoogle ScholarPubMed
Pianezza, ML, Sellers, EM and Tyndale, RF (1998) Nicotine metabolism defect reduces smoking. Nature 393, 750.CrossRefGoogle ScholarPubMed
Qin, YQ, Li, CJ, Zhao, ZX, Wu, XP and Zhang, FS (2007) Effects of rates and methods of N application on growth and N uptake of flue-cured tobacco. Plant Nutrition and Fertilizer Science 13, 436442.Google Scholar
Rathier, TM and Frink, CR (1986) Efficiency of nitrogen fertilizer Use by shade tobacco improved by timed applications 1. Agronomy Journal 78, 459464.CrossRefGoogle Scholar
Riley, WJ, Ortiz-Monasterio, I and Matson, PA (2001) Nitrogen leaching and soil nitrate, nitrite, and ammonium levels under irrigated wheat in northern Mexico. Nutrient Cycling in Agroecosystems 61, 223236.CrossRefGoogle Scholar
Shi, HZ, Han, JF, Zhao, P and Yang, CY (1999) Studies on the dynamic changes in amylase and invertase activity in flue cured tobacco as affected by nitrogen level and source. Chinese Tobacco Science 3, 58.Google Scholar
Sinclair, TR and Horie, T (1989) Leaf nitrogen, photosynthesis, and crop radiation use efficiency: a review. Crop Science 29, 9098.CrossRefGoogle Scholar
Sisson, VA, Rufty, TW and Williamson, RE (1991) Nitrogen-use efficiency among flue-cured tobacco genotypes. Crop Science 31, 16151620.CrossRefGoogle Scholar
Standard of the People's Republic of China (1992) GB 2635–92 Flue-Cured Tobacco. Beijing, China: China Standard Press.Google Scholar
Standard of the People's Republic of China (2005) GB 5606.4-2005 Cigarettes Part 4: Technical Requirements for Sense Evaluation. Beijing, China: China Standard Press.Google Scholar
USDA (2014) Keys to Soil Taxonomy, 12th Edn. Washington DC: USDA.Google Scholar
Vann, MC, Fisher, LR, Jordan, DL, Smith, WD, Hardy, DH and Stewart, AM (2013) Potassium rate and application effect on flue-cured tobacco. Agronomy Journal 105, 304310.CrossRefGoogle Scholar
Walch-Liu, P, Neumann, G and Engels, C (2001) Response of shoot and root growth to supply of different nitrogen forms is not related to carbohydrate and nitrogen status of tobacco plants. Journal of Plant Nutrition and Soil Science 164, 97103.3.0.CO;2-Z>CrossRefGoogle Scholar
Walker, EK (1968 a) Correlations Among physical characteristics, and between physical and chemical characteristics, in cured leaves of flue-cured tobacco harvested at different stages of maturity. Tobocco Science 12, 8690.Google Scholar
Walker, EK (1968 b) Some chemical characteristics of the cured leaves of flue-cured tobacco relative to time of harvest, stalk position and chlorophyll content of the green leaves. Tobacco Science 12, 5865.Google Scholar
Weybrew, JA, Wan Ismail, WA and Long, RC (1983) The cultural management of flue-cured tobacco quality. Tobacco International 185, 8287.Google Scholar
Williams, LMK and Miner, GS (1982) Effect of urea on yield and quality of flue-cured tobacco 1. Agronomy Journal 74, 457462.CrossRefGoogle Scholar
Yang, WH, Weber, KA and Silver, WL (2012) Nitrogen loss from soil through anaerobic ammonium oxidation coupled to iron reduction. Nature Geoscience 5, 538541.CrossRefGoogle Scholar
Yang, H, Li, JW, Yang, JP, Wang, H, Zou, JL and He, JJ (2014) Effects of nitrogen application rate and leaf Age on the distribution pattern of leaf SPAD readings in the rice Canopy. Plos One 9, e88421.CrossRefGoogle ScholarPubMed
Zou, CM, Hu, XD, Huang, W, Zhao, GK, Yang, XB, Jin, Y, Gu, HG, Yan, F, Li, Y, Wu, Q and Xiong, KS (2019) Different yellowing degrees and the industrial utilization of flue-cured tobacco leaves. Scientia Agricola 76, 19.CrossRefGoogle Scholar