Effects of elevated atmospheric CO2 concentration on nonstructural carbohydrates and grain quality of maize

doi:10.13287/j.1001-9332.202301.010

Abstract

Abstract: We used open-top chambers (OTCs) to simulate the conditions of elevated atmospheric CO₂ concentration at the Changwu State Key Agro-Ecological Experimental Station of the Loess Plateau. There were three treatments, CK (maize grown under field conditions with natural atmospheric CO₂ concentration), OTC (maize grown in the open-top chamber under natural atmospheric CO₂ concentration), and OTC_e (maize grown in the open-top chamber under elevated atmospheric CO₂ concentration of 700 μmol·mol^-1).We explored the responses of non-structural carbohydrate (NSC) and grain quality (soluble sugar, starch and crude protein) of spring maize to elevated CO₂ at different growth stages, aiming to provide scientific basis for revealing the adaptation mechanism of maize to elevated CO₂. The results showed that the effects of elevated CO₂ on NSC content and accumulation in maize varied across organs and growth periods. Elevated CO₂ promoted the activation and redistribution of NSC in leaves, stems and roots during reproductive growth period, and significantly increased the amount of NSC conversion to the grains (ATM_NSC), as well as the conversion rate to the grains (AR_NSC) and the contribution to the grains (AC_NSC) in leaves, stems and roots. Compared with CK, the warming effect of OTC inhibited the activation and redistribution of NSC in stems and roots, but promoted the activation and redistribution of NSC in leaves, significantly increased the ATM_NSC, AR_NSC, and AC_NSC of maize leaves. Elevated CO₂ did not affect the contents of soluble sugar, starch, and crude protein in maize grains.

Key words: elevated CO₂ concentration, NSC content, maize, open-top chamber.

LI Chang-xin, YAN Qi, NI Li-li, ZHANG Shu-xin, WANG Li-mei. Effects of elevated atmospheric CO₂ concentration on nonstructural carbohydrates and grain quality of maize[J]. Chinese Journal of Applied Ecology, 2023, 34(1): 123-130.

References

[1] IPCC. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, 2013
[2] Wang W, Cai C, He J, et al. Yield, dry matter distribution and photosynthetic characteristics of rice under elevated CO₂ and increased temperature conditions. Field Crops Research, 2020, 248: 107605
[3] 潘庆民, 韩兴国, 白永飞, 等. 植物非结构性贮藏碳水化合物的生理生态学研究进展. 植物学通报, 2002, 19(1): 30-38
[4] 郑云普, 王贺新, 娄鑫, 等. 木本植物非结构性碳水化合物变化及其影响因子研究进展. 应用生态学报, 2014, 25(4): 1188-1196
[5] 赵江涛, 李晓峰, 李航, 等. 可溶性糖在高等植物代谢调节中的生理作用. 安徽农业科学, 2006, 34(24): 6423-6425, 6427
[6] 宋练, 蔡创, 朱春梧. CO₂升高对粮食作物影响的研究进展. 农业环境科学学报, 2020, 39(4): 786-796
[7] Hatfield JL, Boote KJ, Kimball BA, et al. Climate impacts on agriculture: Implications for crop production. Agronomy Journal, 2011, 103: 351-370
[8] 马剑, 张钰. 分期追施氮肥对玉米营养器官中非结构性碳水化合物积累转运及产量的影响. 玉米科学, 2019, 27(2): 155-160
[9] 田青兰, 波刘, 钟晓媛, 等. 不同播栽方式下杂交籼稻非结构性碳水化合物与枝梗和颖花形成及产量性状的关系. 中国农业科学, 2016, 49(1): 35-53
[10] 柴如山, 牛耀芳, 朱丽青, 等. 大气 CO₂浓度升高对农产品品质影响的研究进展. 应用生态学报, 2011, 22(10): 2765-2775
[11] Ingram JSI, Gregory PJ, Izac AM. The role of agronomic research in climate change and food security policy. Agriculture, Ecosystems & Environment, 2008, 126: 4-12
[12] 郭艳亮, 王晓琳, 张晓媛, 等. 田间条件下模拟CO₂浓度升高开顶式气室的改进及其效果. 农业环境科学学报, 2017, 36(6): 1034-1043
[13] 高俊凤. 植物生理学实验指导. 北京: 高等教育出版社, 2006
[14] 何照范. 粮油籽粒品质及其分析技术. 北京: 中国农业出版社, 1985
[15] Fu G, Shen ZX, Sun W, et al. A meta-analysis of the effects of experimental warming on plant physiology and growth on the Tibetan Plateau. Journal of Plant Growth Regulation, 2015, 34: 57-65
[16] Yang Y, Wang G, Yang L, et al. Effects of drought and warming on biomass, nutrient allocation, and oxidative stress in Abies fabri in Eastern Tibetan Plateau. Journal of Plant Growth Regulation, 2013, 32: 298-306
[17] Brueggemann N, Gessler A, Kayler Z, et al. Carbon allocation and carbon isotope fluxes in the plant-soil-atmosphere continuum: A review. Biogeosciences, 2011, 8: 3457-3489
[18] 庞晓瑜, 雷静品, 王奥, 等. 亚高山草甸植物群落对气候变化的响应. 西北植物学报, 2016, 36(8): 1678-1686
[19] 周宁. 大气CO₂浓度和温度升高对茎鞘非结构性碳水化合物的影响. 农业与技术, 2020, 40(14): 45-48
[20] 范玉洁, 姜慧敏, 温祥珍, 等. 长期高温与增施CO₂对番茄叶片光合作用及淀粉含量的影响. 山西农业科学, 2022, 50(1): 41-45
[21] 孙啸震, 张黎妮, 戴艳娇, 等. 花铃期增温对棉花干物重累积的影响及其生理机制. 作物学报, 2012, 38(4): 683-690
[22] Du Y, Lu R, Xia J. Impacts of global environmental change drivers on non-structural carbohydrates in terrestrial plants. Functional Ecology, 2020, 34: 1525-1536
[23] Li W, Hartmann H, Adams HD, et al. The sweet side of global change: Dynamic responses of non-structural carbohydrates to drought, elevated CO₂ and nitrogen fertilization in tree species. Tree Physiology, 2018, 38: 1706-1723
[24] Zheng Y, Li F, Hao L, et al. Elevated CO₂concentration induces photosynthetic down-regulation with changes in leaf structure, non-structural carbohydrates and nitrogen content of soybean. BMC Plant Biology, 2019, 19: 255
[25] 韩文军, 廖飞勇, 何平. 大气二氧化碳浓度倍增对闽楠光合性状的影响. 中南林学院学报, 2003, 23(2): 62-65
[26] 曹培培, 杨凯, 吕春华, 等. 不同CO₂浓度和N肥水平对粳稻茎鞘非结构性碳水化合物含量与积累的影响. 生态学杂志, 2020, 39(5): 1474-1483
[27] Griffin KL, Winner WE, Strain BR. Construction cost of loblolly and ponderosa pine leaves grown with varying carbon and nitrogen availability. Plant, Cell and Environment, 1996, 19: 729-739
[28] 王建波. 三江平原小叶章湿地碳特征对模拟CO₂升高和氮沉降的响应. 博士论文. 长春: 东北师范大学, 2013
[29] 李青超, 张远彬, 王开运, 等. 大气CO₂浓度升高对亚高山红桦碳水化合物含量与分配的影响. 西北林学院学报, 2008, 23(1): 1-5
[30] Breda N, Huc R, Granier A, et al. Temperate forest trees and stands under severe drought: A review of ecophysiological responses, adaptation processes and long-term consequences. Annals of Forest Science, 2006, 63: 625-644
[31] 王睿照. 非结构性碳水化合物对气候变化响应研究进展. 辽宁林业科技, 2021(2): 55-56
[32] 李豫婷. 不同株型冬小麦光合碳代谢及产量对高CO₂浓度的响应差异及机理研究. 博士论文. 北京: 中国农业科学院, 2019
[33] Hogy P, Fangmeier A. Effects of elevated atmospheric CO₂ on grain quality of wheat. Journal of Cereal Science, 2008, 48: 580-591
[34] 柴如山, 牛耀芳, 朱丽青, 等. 大气CO₂浓度升高对农产品品质影响的研究进展. 应用生态学报, 2011, 22(10): 2765-2775
[35] Wu DX, Wang GX, Bai YF, et al. Effects of elevated CO₂ concentration on growth, water use, yield and grain quality of wheat under two soil water levels. Agriculture, Ecosystems & Environment, 2004, 104: 493-507
[36] Idso SB, Idso KE. Effects of atmospheric CO₂ enrichment on plant constituents related to animal and human health. Environmental and Experimental Botany, 2001, 45: 179-199
[37] 牛玺朝, 户少武, 杨阳, 等. 大气CO₂浓度增高对不同水稻品种稻米品质的影响. 中国生态农业学报, 2021, 29(3): 509-519
[38] Ziska LH, Namuco O, Moya T, et al. Growth and yield response of field-grown tropical rice to increasing carbon dioxide and air temperature. Agronomy Journal, 1997, 89: 45-53
[39] 哈蓉, 马亚平, 曹兵, 等. 模拟 CO₂浓度升高对宁夏枸杞营养生长与果实品质的影响. 林业科学, 2019, 55(6): 28-36
[40] 谢立勇, 马占云, 韩雪, 等. CO₂浓度与温度增高对水稻品质的影响. 东北农业大学学报, 2009, 40(3): 1-6
[41] 王晓琳. 旱作覆膜玉米生物学过程对大气CO₂浓度升高的响应. 硕士论文. 杨凌: 西北农林科技大学, 2017

Effects of elevated atmospheric CO₂ concentration on nonstructural carbohydrates and grain quality of maize

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