Maize/peanut intercropping increases photosynthetic characteristics, 13C-photosynthate distribution, and grain yield of summer maize

doi:10.1016/S2095-3119(19)62616-X

Journal of Integrative Agriculture

2019, Vol. 18

Issue (10): 2219-2229 DOI: 10.1016/S2095-3119(19)62616-X

Crop Science

Advanced Online Publication | Current Issue | Archive | Adv Search

Maize/peanut intercropping increases photosynthetic characteristics, ¹³C-photosynthate distribution, and grain yield of summer maize

LI Yan-hong^{1, 2*}, SHI De-yang^{1, 3*}, LI Guang-hao¹, ZHAO Bin¹, ZHANG Ji-wang¹, LIU Peng¹, REN Bai-zhao¹, DONG Shu-ting¹

¹ State Key Laboratory of Crop Biology/College of Agronomy, Shandong Agricultural University, Tai’an 271018, P.R.China
² Soil Fertilizer Station of Yantai Agricultural Technology Promotion Center, Yantai 264000, P.R.China
³ Institute of Maize and Oil Crops, Yantai Academy of Agricultural Sciences, Yantai 265500, P.R.China

Abstract
References

Download: PDF in ScienceDirect
Export: BibTeX | EndNote (RIS)

Abstract

Intercropping is used widely by smallholder farmers in developing countries to increase land productivity and profitability. We conducted a maize/peanut intercropping experiment in the 2015 and 2016 growing seasons in Shandong, China. Treatments included sole maize (SM), sole peanut (SP), and an intercrop consisting of four rows of maize and six rows of peanut (IM and IP). The results showed that the intercropping system had yield advantages based on the land equivalent ratio (LER) values of 1.15 and 1.16 in the two years, respectively. Averaged over the two years, the yield of maize in the intercropping was increased by 61.05% compared to that in SM, while the pod yield of peanut was decreased by 31.80% compared to SP. Maize was the superior competitor when intercropped with peanut, and its productivity dominated the yield of the intercropping system in our study. The increased yield was due to a higher kernel number per ear (KNE). Intercropping increased the light transmission ratio (LTR) of the ear layer in the maize canopy, the active photosynthetic duration (APD), and the harvest index (HI) compared to SM. In addition, intercropping promoted the ratio of dry matter accumulation after silking and the distribution of ¹³C-photosynthates to grain compared to SM. In conclusion, maize/peanut intercropping demonstrated the potential to improve the light condition of maize, achieving enhanced photosynthetic characteristics that improved female spike differentiation, reduced barrenness, and increased KNE. Moreover, dry matter accumulation and 13C-photosynthates distribution to grain of intercropped maize were improved, and a higher grain yield was ultimately obtained.

Keywords: maize intercropping peanut land equivalent ratio (LER) net photosynthetic rate (Pn) ¹³C-photosynthates distribution

Received: 19 July 2018 Accepted:

Fund: We acknowledge the financial support of the National Key Research and Development Program of China (2017YFD0301001), the National Natural Science Foundation of China (31301274 and 31171497), funds from the Shandong “Double Tops” Program, China (SYL2017XTTD14), and the Open Project of State Key Laboratory of Crop Biology in Shandong Agricultural University, China (2018KF10).

Corresponding Authors: Correspondence DONG Shu-ting E-mail: stdong@sdau.edu.cn

About author: * These authors contributed equally to this study.

	Service
	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS

	Articles by authors
	LI Yan-hong
	SHI De-yang
	LI Guang-hao
	ZHAO Bin
	ZHANG Ji-wang
	LIU Peng
	REN Bai-zhao
	DONG Shu-ting

Cite this article:

LI Yan-hong, SHI De-yang, LI Guang-hao, ZHAO Bin, ZHANG Ji-wang, LIU Peng, REN Bai-zhao, DONG Shu-ting. 2019. Maize/peanut intercropping increases photosynthetic characteristics, ¹³C-photosynthate distribution, and grain yield of summer maize. Journal of Integrative Agriculture, 18(10): 2219-2229.

wal M A, Koshi H, Ikeda T. 2006. Radiation interception and use by maize/peanut intercrop canopy. Agricultural and Forest Meteorology, 139, 74–83.
Banik P, Sharma R C. 2009. Yield and resource utilization efficiency in baby corn-legume-intercropping system in the eastern plateau of India. Journal of Sustainable Agriculture, 33, 379–395.
Black C, Ong C. 2000. Utilization of light and water in tropical agriculture. Agricultural and Forest Meteorology, 104, 25–47.
Coll L, Cerrudo A, Monzon J P, Andrade F H. 2012. Capture and use of water and radiation in summer intercrops in the south-east Pampas of Argentina. Field Crops Research, 134, 105–113.
Cui L, Yang W Y, Huang N, Liu J, Wang Y L, Wang X H, Liu Y, Yan S. 2015. Effects of maize plant types on dry matter accumulation characteristics and yield of soybean in maize-soybean intercropping systems. Chinese Journal of Applied Ecology, 26, 2414–2420. (in Chinese)
Feike T, Doluschitz R, Chen Q, Graeff-Hninger S, Claupein W. 2012. How to overcome the slow death of intercropping in the North China Plain. Sustainability, 4, 2550–2565.
Finch S, Collier R H. 2012. The influence of host and non-host companion plants on the behaviour of pest insects in field crops. Entomologia Experimentalis et Applicata, 142, 87–96.
Gao Y L, Sun Z X, Bai W, Feng L S, Cai Q, Feng C, Zhang Z. 2016. Spatial distribution characteristics of root system and the yield in maize-peanut intercropping system. Journal of Maize Sciences, 24, 79–87. (in Chinese)
Hugar H Y, Palled Y B. 2008. Effect of intercropped vegetables on maize and associated weeds in maize-vegetable intercropping systems. Karnataka Journal of Agricultural Sciences, 21, 159–161.
Jia S F, Dong S T, Wang K J, Zhang J W, Li C F. 2007. Effect of shading on grain quality at different stages from flowering to maturity in maize. Acta Agronomica Sinica, 33, 1960–1967. (in Chinese)
Jiao N Y, Chen M C, Ning T Y, Li Z J. 2007. Effects of maize intercropping with peanut on dry matter accumulation and distribution of maize. Journal of Anhui Agricultural Sciences, 35, 11782–11783. (in Chinese)
Jiao N Y, Zhao C, Ning T Y, Hou L T, Fu G Z, Li Z J, Chen M C. 2008. Effects of maize-peanut intercropping on economic yield and light response of photosynthesis. Chinese Journal of Applied Ecology, 19, 981–985. (in Chinese)
Li L, Li S M, Sun J H, Zhou L L, Bao X G, Zhang H G, Zhang F S. 2007. Diversity enhances agricultural productivity via rhizosphere phosphorus facilitation on phosphorus-deficient soils. Proceedings of the National Academy of Sciences of the United States of America, 104, 11192–11196.
Li L, Sun J H, Zhang F S, Li X L, Yang S C, Rengel Z. 2001. Wheat/maize or wheat/soybean strip intercropping. I. Yield advantage and interspecific interactions on nutrients. Field Crops Research, 71, 123–137.
Li L, Sun J, Zhang F, Guo T, Bao X, Smith F A, Smith S E. 2006. Root distribution and interactions between intercropped species. Oecologia, 147, 280–290.
Li L, Zhang L Z, Zhang F Z. 2013. Crop mixtures and the mechanisms of overyielding. In: Levin S A, ed., Encyclopedia of Biodiversity. 2nd ed. vol. 2. Academic Press, Waltham, MA, USA. pp. 382–395.
Li M, Sun Z M, Li M M, Yu H Q, Jiang C J, Zhao X H, Zhao S L, Wang X G, Cao M J. 2013. Effect of maize-peanut intercropping on peanut growth, yield and quality. Journal of Nuclear Agricultural Sciences, 27, 0391–0397. (in Chinese)
Li Y Y, Yu C B, Cheng X, Li C J, Sun J H, Zhang F S. 2009. Intercropping alleviates the inhibitory effect of N fertilization on nodulation and symbiotic N2 fixation of faba bean. Plant and Soil, 323, 295–308.
Liu H, Zuo Q S, Liu J Y, Zhou J L, Ding L, Yang C. 2017. Effects of salt-ion content on dry matter accumulation and distribution, agronomic traits and quality of rapeseed. Chinese Agricultural Science Bulletin, 33, 19–23. (in Chinese)
Liu J, Tang F S, Zhang J, Zang X W, Dong W Z, Yi M L, Hao X. 2017. Current status and development trends of peanut production technology in China. Chinese Agricultural Science Bulletin, 33, 13–18. (in Chinese)
Liu T N, Gu L M, Dong S T, Zhang J W, Liu P, Zhao B. 2015. Optimum leaf removal increases canopy apparent photosynthesis, 13C-photosynthate distribution and grain yield of maize crops grown at high density. Field Crops Research, 170, 32–39.
Lv Y, Francis C, Wu P T, Chen X L, Zhao X N. 2014. Maize-soybean intercropping interactions above and below ground. Crop Science, 54, 914–922.
Meng W W, Gao H X, Zhang Z, Xia H Y, Liu L Y, Guo F, Li Z X, Wan S B. 2016. Effects of different maize/peanut intercropping modes on system yield and land equivalent ratio. Shandong Agricultural Sciences, 48, 32–36. (in Chinese)
Mpairwe D R, Sabiiti E N, Ummuna N N, Tegegne A, Osuji P. 2002. Effect of intercropping cereal crops with forage legumes and source of nutrients on cereal grain yield and fodder dry matter yields. African Crop Science Journal, 10, 81–97.
Mucherumuna M, Pypers P, Mugendi D, Kung’u J, Mugwe J, Merckx R, Vanlauwe B. 2010. A staggered maize legume intercrop arrangement robustly increases crop yields and economic returns in the highlands of central kenya. Field Crops Research, 115, 132–139.
Munz S, Graeff-Hönninger S, Lizaso J I, Chen Q, Claupein W. 2014. Modeling light availability for a subordinate crop within a strip-intercropping system. Field Crops Research, 155, 77–89.
Odhiambo J A, Vanlauwe B, Tabu I M, Kanampiu F, Khan Z. 2011. Effect of intercropping maize and soybeans on striga hermonthica parasitism and yield of maize. Archives of Phytopathology and Plant Protection, 44, 158–167.
Postma J, Lynch J P. 2012. Complementarity in root architecture for nutrient uptake in ancient maize/bean and maize/bean/squash polycultures. Annals of Botany, 110, 521–534.
Rao M R, Willey R W. 1980. Evaluation of yield stability in intercropping: Studies on Sorghum/Pigeonpea. Experimental Agriculture, 16, 105–116.
Ren B Z, Cui H Y, Camberato J J, Dong S T, Liu P, Zhao B, Zhang J W. 2016. Effects of shading on the photosynthetic characteristics and mesophyll cell ultrastructure of summer maize. The Science of Nature, 103, 67.
Saidou A, Janssen B H, Temminghoff E J M. 2003. Effects of soil properties, mulch and NPK fertilizer on maize yields and nutrient budgets on ferralitic soils in southern Benin. Agriculture Ecosystems and Environment, 94, 265–273.
Sen S, Smith M E, Setter T. 2016. Effects of low nitrogen on chlorophyll content and dry matter accumulation in maize. African Journal of Agricultural Research, 11, 1001–1007.
Shi J G, Cui H Y, Zhao B, Dong S T, Liu P, Zhang J W. 2013. Effect of light on yield and characteristics of grain-filling of summer maize from flowering to maturity. Scientia Agricultura Sinica, 46, 4427–4434. (in Chinese)
Snapp S S, Blacke M J, Gilbert R A, Beznerkerr R, Kanyamaphiri G Y. 2010. Biodiversity can support a greener revolution in Africa. Proceedings of the National Academy of Sciences of the United States of America, 107, 20840–20845.
Tollenaar M, Daynard T B. 1982. Effect of source-sink ratio on dry matter accumulation and leaf senescence of maize. Candian Journal of Plant Science, 62, 855–860.
Tong P Y. 1994. Achievements and perspectives of tillage and cropping systems in China. Cropping System and Cultivation Technology, 77, 1–5. (in Chinese)
Tsubo M, Walker S, Ogindo H O. 2005. A simulation model of cereal-legume intercropping system for semi-arid regions: II. Model application. Field Crops Research, 93, 23–33.
Wang X C, Wang H N, Li W, Bi S. 2016. Research on soil water and crop yield of alfalfa maize intercropping system at slope land in the hilly regions of Sichuan Province. Journal of Natural Science of Hunan Normal University, 36, 9–14. (in Chinese)
White P J, George T S, Gregory P J, Bengough A G, Hallett P D, McKenzie B M. 2013. Matching roots to their environment. Annals of Botany, 112, 207–222.
Willey R W. 1990. Resource use in intercropping systems. Agricultural Water Management, 17, 215–231.
Xu B C, Li F M, Shan L. 2008. Switchgrass and milkvetch intercropping under 2:1 row-replacement in semiarid region, northwest China: Aboveground biomass and water use efficiency. European Journal of Agronomy, 28, 485–492.
Yang C, Huang G, Chai Q, Luo Z X. 2011. Water use and yield of wheat/maize intercropping under alternate irrigation in the oasis field of northwest China. Field Crops Research, 124, 426–432.
Zhang F S, Li L. 2003. Using competitive and facilitative interactions in intercropping systems enhances crop productivity and nutrient-use efficiency. Plant and Soil, 248, 305–312.
Zhang G G, Zhang C Y, Yang Z B, Dong S T. 2013. Root distribution and N acquisition in an alfalfa and corn intercropping system. Journal of Agricultural Science, 5, 128–142.
Zhang Y K, Chen F J, Li L, Chen Y H, Liu B R, Zhou Y L, Yuan L X, Zhang F S, Mi G H. 2012. The role of maize in phosphorus uptake and productivity of maize/faba bean and maize/wheat intercropping systems. Science China (Life Sciences), 55, 993–1001.
Zhang Y Q, Yang H, Qi Z Y, Yuan L, Wang N, Jin C, Qiu Z G. 2011. Effect of light stress on the plant characters of maize inbred lines. Chinese Agricultural Science Bulletin, 27, 40–43. (in Chinese)
Zuo Y M, Zhong F S, Li X L, Cao Y P. 2000. Studies on the improvement in iron nutrition of peanut by intercropping with maize on a calcareous soil. Plant and Soil, 220, 13–25.

[1]	WANG Xing-long, ZHU Yu-peng, YAN Ye, HOU Jia-min, WANG Hai-jiang, LUO Ning, WEI Dan, MENG Qing-feng, WANG Pu. Irrigation mitigates the heat impacts on photosynthesis during grain filling in maize [J]. >Journal of Integrative Agriculture, 2023, 22(8): 2370-2383.
[2]	Tiago SILVA, Ying NIU, Tyler TOWLES, Sebe BROWN, Graham P. HEAD, Wade WALKER, Fangneng HUANG. *Selection, effective dominance, and completeness of Cry1A.105/Cry2Ab2 dual-protein resistance in Helicoverpa zea* (Boddie) (Lepidoptera: Noctuidae)**[J]. >Journal of Integrative Agriculture, 2023, 22(7): 2151-2161.
[3]	FAN Ting-lu, LI Shang-zhong, ZHAO Gang, WANG Shu-ying, ZHANG Jian-jun, WANG Lei, DANG Yi, CHENG Wan-li. Response of dryland crops to climate change and drought-resistant and water-suitable planting technology: A case of spring maize[J]. >Journal of Integrative Agriculture, 2023, 22(7): 2067-2079.
[4]	ZHANG Miao-miao, DANG Peng-fei, LI Yü-ze, QIN Xiao-liang, Kadambot-H. M. SIDDIQUE. Better tillage selection before ridge–furrow film mulching can facilitate root proliferation, increase nitrogen accumulation, translocation, grain yield of maize in a semiarid area[J]. >Journal of Integrative Agriculture, 2023, 22(6): 1658-1670.
[5]	WANG Peng, WANG Cheng-dong, WANG Xiao-lin, WU Yuan-hua, ZHANG Yan, SUN Yan-guo, SHI Yi, MI Guo-hua. Increasing nitrogen absorption and assimilation ability under mixed NO₃^– and NH₄⁺ supply is a driver to promote growth of maize seedlings[J]. >Journal of Integrative Agriculture, 2023, 22(6): 1896-1908.
[6]	ZHANG Chong, WANG Dan-dan, ZHAO Yong-jian, XIAO Yu-lin, CHEN Huan-xuan, LIU He-pu, FENG Li-yuan, YU Chang-hao, JU Xiao-tang. Significant reduction of ammonia emissions while increasing crop yields using the 4R nutrient stewardship in an intensive cropping system[J]. >Journal of Integrative Agriculture, 2023, 22(6): 1883-1895.
[7]	SONG Chao-yu, ZHANG Fan, LI Jian-sheng, XIE Jin-yi, YANG Chen, ZHOU Hang, ZHANG Jun-xiong. Detection of maize tassels for UAV remote sensing image with an improved YOLOX Model[J]. >Journal of Integrative Agriculture, 2023, 22(6): 1671-1683.
[8]	WANG Jin-bin, XIE Jun-hong, LI Ling-ling, ADINGO Samuel. Review on the fully mulched ridge–furrow system for sustainable maize production on the semi-arid Loess Plateau[J]. >Journal of Integrative Agriculture, 2023, 22(5): 1277-1290.
[9]	ZHAO Hai-liang, QIN Yao, XIAO Zi-yi, SUN Qin, GONG Dian-ming, QIU Fa-zhan. Revealing the process of storage protein rebalancing in high quality protein maize by proteomic and transcriptomic[J]. >Journal of Integrative Agriculture, 2023, 22(5): 1308-1323.
[10]	ZHANG Bing-chao, HU Han, GUO Zheng-yu, GONG Shuai, SHEN Si, LIAO Shu-hua, WANG Xin, ZHOU Shun-li, ZHANG Zhong-dong. Plastic-film-side seeding, as an alternative to traditional film mulching, improves yield stability and income in maize production in semi-arid regions[J]. >Journal of Integrative Agriculture, 2023, 22(4): 1021-1034.
[11]	SHI Wen-xuan, ZHANG Qian, LI Lan-tao, TAN Jin-fang, XIE Ruo-han, WANG Yi-lun. Hole fertilization in the root zone facilitates maize yield and nitrogen utilization by mitigating potential N loss and improving mineral N accumulation[J]. >Journal of Integrative Agriculture, 2023, 22(4): 1184-1198.
[12]	GAO Xing, LI Yong-xiang, YANG Ming-tao, LI Chun-hui, SONG Yan-chun, WANG Tian-yu, LI Yu, SHI Yun-su. Changes in grain-filling characteristics of single-cross maize hybrids released in China from 1964 to 2014[J]. >Journal of Integrative Agriculture, 2023, 22(3): 691-700.
[13]	XU Xiao-hui, LI Wen-lan, YANG Shu-ke, ZHU Xiang-zhen, SUN Hong-wei, LI Fan, LU Xing-bo, CUI Jin-jie. Identification, evolution, expression and protein interaction analysis of genes encoding B-box zinc-finger proteins in maize[J]. >Journal of Integrative Agriculture, 2023, 22(2): 371-388.
[14]	Irshad AHMAD, Maksat BATYRBEK, Khushnuma IKRAM, Shakeel AHMAD, Muhammad KAMRAN, Misbah, Raham Sher KHAN, HOU Fu-jiang, HAN Qing-fang. *Nitrogen management improves lodging resistance and production in maize (Zea* mays L.) at a high plant density** [J]. >Journal of Integrative Agriculture, 2023, 22(2): 417-433.
[15]	CHEN Zhe, REN Wei, YI Xia, LI Qiang, CAI Hong-guang, Farhan ALI, YUAN Li-xing, MI Guo-hua, PAN Qing-chun, CHEN Fan-jun. *Local nitrogen application increases maize post-silking nitrogen uptake of responsive genotypes via* enhanced deep root growth**[J]. >Journal of Integrative Agriculture, 2023, 22(1): 235-250.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed

Cite this article:

About JIA

Editorial board

For authors