The North China Plain (NCP) is a severe water shortage region, especially during the wheat growing season. Understanding the response of grain yield and water availability in winter wheat cultivars (Triticum aestivum L.) is important to adjust planting structure under groundwater reducible exploitation in rainfed dry years of NCP. Field experiments were conducted at the Luancheng Agroecosystem Experiment Station of the Chinese Academy of Sciences, Hebei, China. Two different drought resistant winter wheat cultivars (Jinmai47 and Shiluan02-1) were grown under rainfed conditions during four years of 2010-2011, 2011-2012, 2012-2013 and 2013-2014. Grain yield and its components, aboveground biomass (AB), dry matter accumulation translocation efficiency, water consumption, water use efficiency at field scale, and photosynthetic characteristics were measured. The results showed that Jinmai47 rapidly accumulated AB by higher tiller and photosynthetic potential comparing with those of Shiluan02-1. Its grain yield was 16.49% higher than that of the drought-sensitive winter wheat variety Shiluan02-1 during the four rainfed years. However, the dry matter remobilization efficiency (DMRE) and contribution of dry matter remobilization from heading stage to maturity stage to grain (CDMRE) of Shiluan02-1 was higher than those of Jinmai47. The average water use efficiency at grain yield level (WUEy), WUE at aboveground biomass level (WUEab), and WUE at grain yield under rainy conditions (WUEr) of Jinmai47 were 11.08%, 16.41%, and 17.21% higher than those of Shiluan02-1. There was a significant difference in the WUEab and WUEr between the two wheat cultivars. The two wheat varieties under drought condition have different growing strategies. Jinmai47 has more tiller number, earlier vigor, and higher AB than Shiluan02-1, helping it to adapt to the fluctuations in the environment.
Keywords: winter wheat cultivar, grain yield, rainy treatment, water use efficiency, dry year
DOI: 10.25165/j.ijabe.20181105.4344

Citation: Dong B D, Yang H, Qiao Y Z, Zhang M M, Wang Y K, Jin L L, et al. Different growing strategies of two winter wheat cultivars under rainfed conditions during dry years in North China Plain. Int J Agric & Biol Eng, 2018; 11(5): 150–159.

winter wheat cultivar, grain yield, rainy treatment, water use efficiency, dry year

Tari F T. The effects of different deficit irrigation strategies on yield, quality, and water-use efficiencies of wheat under semi-arid conditions. Agric. Water Manage, 2016; 167: 1–10.

Zhang K, Zeng Z H, Zhao J, Wang X Q, Zhou J, Xu H S, et al. Impact analysis of reduce the extraction of groundwater on wheat production in North China Plain. J Agric. Sci. Technol, 2016; 18(5): 111–117. (in Chinese)

Wang Y, Xi W, Wang Z, Wang B, Xu X, Han M, et al. Contribution of ear photosynthesis to grain yield under rainfed and irrigation conditions for winter wheat cultivars in the past 30 years in North China Plain. J. Integ. Agric, 2016; 15(10): 2247–2256.

Zhang Z, Zhou X B, Chen Y H. Effects of irrigation and precision planting patterns on photosynthetic product of wheat. Agron. J, 2016; 108(6): 2322–2328.

Dong B, Shi L, Shi C, Qiao Y, Liu M, Zhang Z. Grain yield and water use efficiency of two types of winter wheat cultivars under different water regimes. Agric. Water Manage, 2011; 99(1): 103–110.

Mei X R, Zhong X L, Vadez V, Liu X Y. Improving water use efficiency of wheat crop varieties in the North China Plain. J. Integr. Agric, 2013; 12(7): 1243–1250.

Xia J, Liu M Y, Jia S F. Water security problem in North China: Research and perspective. Pedosphere, 2005; 15(5): 563–575.

Sun H, Shen Y, Yu Q, Gerald N, Zhang Y, Liu C, et al. Effect of precipitation change on water balance and WUE of the winter wheat-summer maize rotation in the North China Plain. Agric. Water Manage, 2010; 97(8): 1139–1145.

Wang X, Li X B, Xin L. Impact of the shrinking winter wheat sown area on agricultural water consumption in the Hebei Plain. J. Geogr. Sci, 2014; 24(2): 313–330.

Chen S Y, Zhang X Y, Shao L W, Sun H Y, Niu J F. A comparative study of yield, cost-benefit and water use efficiency between monoculture of spring maize and double crops of wheat-maize under rain-fed condition in the North China Plain. Chin. J. Eco-Agric, 2015; 23(5): 535543. (in Chinese)

Wang Y, Zhang Y, Zhang R, Li J, Zhang M, Zhou S, et al. Reduced irrigation increases the water use efficiency and productivity of winter wheat-summer maize rotation on the North China Plain. Sci. Total Environ, 2018; 618: 112–120.

Farquhar G D, Richards R A. Isotopic composition of plant carbon correlates with water use efficiency of wheat. Aust. J. Plant Physiol, 1984; 11: 539–552.

Shan L, Deng X P, Zhang S Q. Advance in biological water-saving research: Challenge and perspectives. Sci. Found. China, 2006; 2: 66–71.

Dong B D, Zhang Z B, Liu M Y, Zhang Y Z, Li Q, Shi L, et al. Water use characteristics of different wheat varieties and their responses to different irrigation schedulings. Trans. Chin. Soc. Agric. Eng, 2007; 23(9): 27–33. (in Chinese)

Zhang X, Chen S, Sun H, Wang Y, Shao L. Water use efficiency and associated traits in winter wheat cultivars in the North China Plain. Agric. Water Manage, 2010; 97(8): 1117–1125.

Fulvia R, Jaleh G, Sylvie M, Loredana M, Anna M, Franz-Werner B. Constitutive differences in water use efficiency between two durum wheat cultivars. Field Crops Res, 2012; 125: 49–60.

Nagy E, Lantos C, Pauk J. Selection of drought tolerant and sensitive genotypes from wheat DH population. Acta Physiol. Plant, 2017; 39(12): 261.

Levitt J. Responses of plants to environmental stresses. Water, radiation, salt and other stresses: New York: Academic Press, 2015; pp. 93–128.

Tomar R, Tiwari S, Vinod N B K, Chand S, Deshmukh R. Molecular and morpho-agronomical characterization of root architecture at seedling and reproductive stages for drought tolerance in wheat. PLoS One, 2016; 11(6): e0156528. doi: 10.1371/journal.pone.0156528.

Xu C, Tao H, Tian B, Gao Y B, Ren J H, Wang P. Limited-irrigation improves water use efficiency and soil reservoir capacity through regulating root and canopy growth of winter wheat. Field Crops Res, 2016; 196: 268–275.

Panigrahi B, Panda S N, Raghuwanshi N S. Potato yield and water-use-efficiency under furrow irrigation. Irrigation Science, 2001; 20(4): 155–163.

Wu Q H, Wang G L, Lin W J, Zhang F W. Estimating groundwater recharge of Taihang Mountain Piedmont in Luancheng County, Hebei Province, China. Geol. Sci. Technol. Inf, 2012; 31(2): 99–105. (in Chinese)

Chu P, Zhang Y, Yu Z, Guo Z, Shi Y. Winter wheat grain yield, water use, biomass accumulation and remobilization under tillage in the North China Plain. Field Crops Res, 2016; 193: 43–53.

Sun H, Shao L, Chen S, Wang Y, Zhang X. Effect of sowing time and rate on crop growth and radiation use efficiency of winter wheat in the North China Plain. Int. J. Plant Prod, 2013; 7(1): 117–138.

Wen H Q, Zhang L S, Li S H, Hou L S, Yao X L, Yao H L, et al. Analysis of yield forming factors of wheat in arid land in Shanxi. J. Shanxi Agric.Sci, 2001; 29(1): 5–10. (in Chinese)

Austin R B, Ford M A, Morgan C L. Genetic improvement in the yield of winter wheat; a further evaluation. J. Agric. Sci, 1989; 112(3): 295–301.

Shearman V J, Sylvester-Bradley R, Scott R K, Foulkes M J. Physiological progress associated with wheat yield progress in the UK. Crop Sci, 2005; 45: 175–185.

Zhou T, Xu K W, Liu W G, Zhang C C, Chen Y X, Yang W Y. More aboveground biomass, phosphorus accumulation and remobilization contribution to high productivity of intercropping wheat. Int. J. Plant Prod, 2017; 11(3): 407–424.

Renolds M, Foulkes M J, Slafer G A, Berry P, Parry M A J, Snape J W, et al. Raising yield potential in wheat. J. Exp. Bot, 2009; 60: 1899–1918.

Renolds M P, van Ginkel M, Ribaut J M. Avenues for genetic modification of radiation use efficiency in wheat. J. Exp. Bot, 2000; 51: 459–473.

Koutroubas S D, Papakosta D K, Doitsinis A. Cultivar and seasonal effects on the contribution of pre-anthesis assimilates to safflower yield. Field Crops Res, 2004; 90(2): 263–274.

Lu D, Lu F, Pan J, Cui Z, Zou C, Chen X, et al. The effects of cultivar and nitrogen management on wheat yield and nitrogen use efficiency in the North China Plain. Field Crops Res, 2015; 171: 157–164.

Yao H, Zhang Y, Yi X, Zuo W, Lei Z, Sui L, et al. Characters in light-response curves of canopy photosynthetic use efficiency of light and N in responses to plant density in field-grown cotton. Field Crops Res, 2017; 203: 192–200.

Deng X P, Shan L, Zhang H, Turner N C. Improving agricultural water use efficiency in arid and semiarid areas of China. Agric. Water Manage, 2006; 80(13): 23–40.

Agrawal M K, Panda S N, Panigrahi B. Modeling water balance parameters for rainfed rice. Journal of Irrigation and Drainage Engineering, 2004; 130(2): 129–139.

Dong B D, Liu M Y, Shao H B, Li Q Q, Shi L, Du F, et al. Investigation on the relationship between leaf water use efficiency and physio-biochemical traits of winter wheat under rained condition. Colloids Surf. B Biointerfaces, 2008; 62(2): 280–287.

Sun C Y, Dong W Q, Liu M Y, Dong B D. Research progression on water use efficiency and its difference mechanism of different crop varieties. Chin. Agric. Sci. Bull, 2009; 25(12): 117–121. (in Chinese)

Sheng C F. Growth tediousness as an explanation over-compensation of crops for insect feeding. J. Appl. Ecol, 1990; 1(1): 26–30. (in Chinese)

Wang J, Li P, Cheng Z, Asfa B, Lv G, Zhu Y, et al. Plant ideotype and growth redundancy in dryland wheats. Acta Ecol. Sin, 2015; 35(8): 2428–2467. (in Chinese)

Hao L N, Su X L, Singh V P. Cropping pattern optimization considering uncertainty of water availability and water saving potential. Int J Agric & Biol Eng, 2018; 11(1): 178–186.