Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (23): 4984-4995.doi: 10.3864/j.issn.0578-1752.2021.23.005

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY·AGRICULTURE INFORMATION TECHNOLOGY • Previous Articles     Next Articles

Effects of Elevated Atmospheric CO2 Concentration and Temperature on Photosynthetic Characteristics, Carbon and Nitrogen Metabolism in Flag Leaves and Yield of Winter Wheat in North China

ZONG YuZheng(),ZHANG HanQing,LI Ping,ZHANG DongSheng,LIN Wen,XUE JianFu,GAO ZhiQiang,HAO XingYu()   

  1. College of Agriculture, Shanxi Agricultural University, Taigu 030801, Shanxi
  • Received:2021-02-18 Accepted:2021-07-05 Online:2021-12-01 Published:2021-12-06
  • Contact: XingYu HAO E-mail:zongyuzheng@163.com;haoxingyu1976@126.com

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Abstract:

【Objective】This study was conducted to clarify the response and acclimation process of winter wheat under elevated carbon dioxide (CO2) concentration and rising temperature in North China, so as to provide the theory basis for wheat production under future climate change condition.【Method】Winter wheat (Triticum aestivum ‘Zhongke2011’) plants were subjected to elevated CO2 concentration (ambient concentration +200 μmol·mol-1) and rising temperature (ambient temperature +2℃) at open top climate chambers. The photosynthetic traits, carbon and nitrogen metabolism, biomass accumulation and yield formation of winter wheat in response to elevated CO2 concentration and rising temperature were investigated. 【Result】The rising temperature shorten the whole growth period and the time from florescence to harvest of this wheat cultivar. The net photosynthesis rate (Pn) was enhanced at booting stage by 24.7%, but was not obviously changed in elongation and filling stages. However, the leaf fiber content, soluble protein content and nitrate reductase activity in filling stage, and kernels per spike, thousand seed weight, biomass, and yield in harvest stage decreased by 23.0%. Elevated CO2 concentration increased Pn in the elongation and booting stage by 32.8% and 40.7%, respectively. Elevated CO2 concentration also increased leaf carbohydrate content in the filling stage and spike number per unit area, and improved yield by 26.1%, although which induced photosynthesis acclimation at the late growth stage. Moreover, elevated CO2 concentration increased the time from florescence to harvest of wheat plants for 2 days, and improved Pn by 25.54%, leaf soluble sugar content, fiber content, and starch content under rising temperature conditions. 【Conclusion】Elevated CO2 concentration could offset the negative impacts of rising temperature on biomass accumulation and yield of wheat plants by increasing the time from florescence to harvest, net photosynthesis rate and carbon metabolism.

Key words: elevated CO2 concentration, rising temperature, winter wheat, photosynthesis performance, yield, growth period

Table 1

The air temperature of wheat growing season in 2017-2018 and 2019-2020"

年份
Year		 处理
Treatment		 生长季平均温度
Mean temperature of growing season (℃)		 最高温度及出现日期
Maximum temperature and its date		 最低气温及出现日期
Minimum temperature and its date
最高温度
Maximum
temperature (℃)		 日平均温度
Mean daily temperature (℃)		 日期
Date
(M-D)		 最低温度
Minimum temperature (℃)		 日平均温度
Mean daily temperature (℃)		 日期
Date
(M-D)
2017-2018 CK 11.4 38.3 28.7 06-07 -11.9 0.2 02-04
EC 11.6 38.6 28.9 06-07 -11.3 -0.1 02-04
ET 13.5 40.5 30.9 06-07 -11.9 0.3 02-04
ECT 13.6 40.8 30.9 06-07 -11.8 0.2 02-04
2019-2020 CK 12.4 40.3 28.7 06-04 -10.9 -0.2 12-31
EC 12.4 40.5 28.9 06-04 -10.3 0.1 12-31
ET 14.1 42.4 30.9 06-04 -10.9 0.3 12-31
ECT 14 42.5 31.0 06-04 -9.9 0.3 12-31

Table 2

Effects of elevated CO2 and increased temperature on growth of wheat in two growing years"

年份
Year		 处理
Treatment		 播种期
Sowing date (M-D)		 出苗时间
Emergence (d)		 开花时间
Flowering date (d)		 成熟期
Mature date (d)		 开花到成熟时间
The days from flowering to ripening (d)
2017-2018 CK 10-25 9 180 219 39
EC 10-25 9 176 216 40
ET 10-25 8 174 209 35
ECT 10-25 8 171 208 37
2019-2020 CK 10-27 9 185 225 40
EC 10-27 9 183 223 40
ET 10-27 8 177 213 36
ECT 10-27 8 174 212 38

Fig. 1

Effects of elevated CO2 and increased temperature on net photosynthetic rate (Pn) and stomatal conductance (Gs) of wheat CK: Ambient CO2 concentration, ambient temperature; EC: Ambient concentration +200 μmol·mol-1; ET: Ambient temperature +2℃; ECT: Ambient concentration +200 μmol·mol-1, ambient temperature +2℃. P<0.05, significant difference; P<0.01, extremely significant difference. The same as below"

Table 3

Effects of elevated CO2 and increased temperature on leaf response parameters under different illumination levels of wheat at filling stage"

处理
Treatment		 光饱和点
Light saturation point
(LSP) (μmol·m-2·s-1)		 光补偿点
Light compensation point (LCP) (μmol·m-2·s-1)		 最大净光合速率
Maximum net photosynthetic rate (Pnmax) (μmol·m-2·s-1)		 暗呼吸速率
Dark respiration rate (Rd)
(μmol·m-2·s-1)
CK 2235.92±508.20ab 12.83±0.07ab 18.28±1.35b 1.01±0.14a
EC 2554.62±146.51a 10.47±5.17ab 22.07±0.58a 0.88±0.41a
ET 1475.33±118.13b 4.19±0.52b 19.99±0.28ab 0.42±0.05a
ECT 1481±150.09b 15.76±0.97a 22.59±0.61a 1.14±0.11a
P-value PT 0.01 0.54 0.21 0.49
PCO2 0.58 0.01 0.00 0.23
PT×CO2 0.59 0.03 0.48 0.09

Table 4

Effects of elevated CO2 and increased temperature on A-Ci curves of wheat at filling stage"

处理
Treatment		 饱和胞间CO2浓度
Saturated intercellular CO2 concentration (Cisat) (μmol·mol-1)		 CO2补偿点
CO2 compensation point (Γ)
(μmol·mol-1)		 最大光合能力
Photosynthetic capacity (Amax) (μmol·m-2·s-1)		 光呼吸速率
Photorespiration rate (Rp)
(μmol·m-2·s-1)
CK 772.78±70.01a 62.15±2.32a 42.64±3.2a 14.79±1.35a
EC 717.73±12.78b 65.41±3.44a 35.45±4.00ab 14.33±1.43a
ET 821.97±10.71a 68.47±4.28a 36.49±2.31ab 13.19±0.63a
ECT 842.16±14.57a 59.12±11.37a 30.64±1.92b 10.75±1.64a
P-value PT 0.00 0.99 0.10 0.08
PCO2 0.13 0.64 0.05 0.30
PT×CO2 0.01 0.35 0.82 0.47

Table 5

Effects of elevated CO2 and increased temperature on Vc.max and Jmax of wheat at filling stage"

处理
Treatment		 最大羧化速率
Maximum carboxylation rate (Vc.max) (μmol·m-2·s-1)		 最大电子传递速率
Maximum electron transport rate (Jmax) (μmol·m-2·s -1)		 Jmax/Vc.max
CK 102.50±6.05a 103.78±9.45a 0.99±0.04b
EC 102.63±8.49a 104.00±5.60a 0.98±0.03b
ET 71.47±6.15b 60.43±6.58b 1.19±0.03a
ECT 52.52±4.70b 44.83±3.67b 1.17±0.03a
P-value PT 0.00 0.00 0.00
PCO2 0.18 0.28 0.65
PT×CO2 0.18 0.26 0.90

Table 6

Effects of elevated CO2 and increased temperature on the cytochrome at wheat at filling stage"

处理
Treatment		 叶绿素a
Chl a (mg·g-1 FW)		 叶绿素b
Chl b (mg·g-1 FW)		 叶绿素a+b
Chl a and Chl b (mg·g-1 FW)		 类胡萝卜素
Chl xc (mg·g-1 FW)
CK 2.44±0.14b 0.27±0.04b 2.71±0.18b 8.94±1.46a
EC 2.51±0.27bc 0.34±0.11b 2.85±0.38b 7.43±1.42a
ET 3.01±0.11a 0.63±0.00a 3.63±0.06a 4.78±2.75b
ECT 2.20±0.03c 0.32±0.04b 2.42±0.21c 7.89±0.71a
P-value PT 0.28 0.00 0.08 0.02
PCO2 0.01 0.02 0.01 0.17
PT×CO2 0.00 0.00 0.00 0.05

Table 7

Effects of elevated CO2 and increased temperature on the carbon and nitrogen metabolites of wheat at filling stage"

处理
Treatment		 可溶性总糖含量
Soluble sugar
content (mg·g-1 FW)		 淀粉含量
Starch content
(mg·g-1 FW)		 纤维素含量
Cellulose content
(mg·g-1 FW)		 可溶性蛋白
Soluble protein
(mg·g-1 FW)		 硝酸还原酶活性
Nitrate reductase activity (μg NO2-·g-1 FW·h-1)
CK 2.38±0.40d 0.13±0.02b 4.39±1.23a 15.47±2.83b 4.14±0.74a
EC 7.01±0.59a 0.23±0.09a 4.91±0.90a 21.15±1.18a 1.70±0.02b
ET 4.36±0.30c 0.13±0.01b 2.79±0.13b 10.80±1.63c 1.84±0.24b
ECT 5.99±0.72b 0.28±0.03a 3.16±0.99b 8.25±1.15d 1.98±0.34b
P-value PT 0.15 0.47 0.02 0.00 0.00
PCO2 0.00 0.00 0.51 0.22 0.00
PT×CO2 0.00 0.41 0.91 0.01 0.00

Table 8

Effects of elevated CO2 and increased temperature on the morphological index of wheat"

年份
Year		 处理
Treatment		 株高
Plant height (cm)		 穗长
Spike length (cm)		 茎粗
Stem-diameter (mm)		 节数
Internode number
2017-2018 CK 63.34±0.90ab 7.21±0.16a 3.419±0.072a 4.8±0.1a
EC 65.76±2.30a 7.64±0.26a 3.458±0.066a 4.9±0.0a
ET 60.41±0.29b 7.3±0.09a 3.418±0.059a 4.8±0.1a
ECT 62.83±1.55ab 7.52±0.13a 3.574±0.026a 4.7±0.1a
2019-2020 CK 66.19±2.32bc 9.81±0.20a 3.468±0.166a 5.9±0.1a
EC 71.26±1.16a 9.08±0.24b 3.520±0.102a 5.9±0.1a
ET 65.03±0.91c 8.49±0.20bc 3.096±0.114b 5.1±0.1b
ECT 70.53±1.02ab 8.25±0.18c 3.058±0.077b 5.1±0.1b
P-value Pyear 0.00 0.00 0.01 0.001
PT 0.07 0.00 0.01 0.01
PCO2 0.00 0.55 0.42 0.00
PT×CO2 0.91 0.61 0.91 0.01

Fig. 2

Effects of elevated CO2 and increased temperature on the biomass, yield and harvest index of wheat"

Table 9

Effects of elevated CO2 and increased temperature on the yield components of wheat"

年份 Year 处理 Treatment 单穗粒数 Grain number per spike 单位面积穗数 Spikes number (No./m2) 千粒重 1000-seed weight (g)
2017-2018 CK 22.7±1.7ab 327.1±9.8ab 45.44±1.84a
EC 25.3±1.2a 349.0±23.2a 44.45±0.66a
ET 21.1±1.0b 292.7±16.4b 43.68±0.74a
ECT 23.9±0.3ab 344.8±7.3a 44.55±0.66a
2019-2020 CK 45.0±1.4a 230.0±21.9c 43.53±1.12a
EC 46.3±6.7a 371.5±23.4a 38.39±4.00a
ET 37.2±4.4a 254.8±11.6bc 37.00±1.55a
ECT 39.8±2.1a 297.2±12.9b 36.32±0.64a
P-value Pyear 0.00 0.00 0.00
PT 0.03 0.08 0.05
PCO2 0.21 0.00 0.23
PT×CO2 0.83 0.16 0.21
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