The main purpose of this research is to provide a theoretical foundation for the screening of drought-resistant soybean varieties and to establish an efficient method to detect the PSII actual photochemical quantum yields efficiently. Three soybean varieties were compared in this experiment after 15 d when they were planted in a greenhouse. These varieties were then exposed to light drought stress (LD) and serious drought stress (SD) conditions. With five times’ measurement, chlorophyll fluorescence and soil-plant analysis development considered as the main basis for this study. Several parameters in SD conditions significantly reduced, such as net photosynthetic rates (Pn), stomatal conductance (Gs), PSII primary light energy conversion efficiency (Fv/FM), PSII actual photochemical quantum yields [Y(II)], photochemical quenching coefficient (qP) and non-photochemical quenching coefficient (qN). The soybeans in the seedling stage adapted to the inhibitory effect of drought stress on photosynthesis through stomatal limitation. Under serious drought stress, non-stomatal limitation damaged the plant photosynthetic system. The amplitudes of Pn and Y(II) of drought-resistant Qihuang 35 were lower than those of the two other varieties. Based on the data of this study, a new method had been developed to detect Y (II) which reflected the photosynthetic capacity of plant, R=0.85989, u=0.048803 when using multiple linear regression, and R=0.84285, u=0.054739 when using partial least square regression.
Keywords: soybean seedling, drought stress, photosynthetic parameters, chlorophyll fluorescence parameters, chlorophyll fluorescence images
DOI: 10.25165/j.ijabe.20181102.3390

Citation: Wang W S, Wang C, Pan D Y, Zhang Y K, Luo B, Ji J W. Effects of drought stress on photosynthesis and chlorophyll fluorescence images of soybean (Glycine max) seedlings. Int J Agric & Biol Eng, 2018; 11(2): 196–201.

soybean seedling, drought stress, photosynthetic parameters, chlorophyll fluorescence parameters, chlorophyll fluorescence images

Wang W F, Peng C H, Kneeshawdaniel D, Larocqueguy R, Luo Z. Drought-induced tree mortality: ecological consequences, causes, and modeling. Environ. Rev., 2012; 20(2): 109–121.

Allen C D, Macalady A K, Chenchouni H, Bachelet D, Mcdowell N, Vennetier M, et al. A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. For. Ecol. Manage., 2010; 259(4): 660–684.

Cheeseman J. 7 – Food security in the face of salinity, drought, climate change, and population growth. Halophytes for Food Security in Dry Lands, 2016; pp.111–123.

Pew Research Center. The future of world religions: population growth projections, 2010-2050. Washington, DC: Pew Research Center, 2015.

Shao G, Huang D, Cheng X, Cui J, Zhang Z. Path analysis of sap flow of tomato under rain shelters in response to drought stress. Int. J. Agric. & Biol. Eng., 2016; 9(2): 54–62.

Masuda T, Goldsmith P D. World soybean production: area harvested, yield, and long-term projections. Int. Food & Agribusiness Manage. Rev., 2009; 12(4): 233–236.

Panagopoulos Y, Gassman P W, Arritt R W, Herzmann D E, Campbell T D, Valcu A, et al. Impacts of climate change on hydrology, water quality and crop productivity in the Ohio-Tennessee River Basin. Int. J. Agric. & Biol. Eng., 2015; 8(3): 1–18.

Golldack D, Li C, Mohan H, Probst N. Tolerance to drought and salt stress in plants: Unraveling the signaling networks. Front. in Plant Sci., 2014; 5(2): 151.

Bollig C, Feller U. Impacts of drought stress on water relations and carbon assimilation in grassland species at different altitudes. Agric. Ecosyst. Environ., 2014; 188(188): 212–220

Zivcak M, Kalaji H M, Shao H B, Olsovska K, Brestic M. Photosynthetic proton and electron transport in wheat leaves under prolonged moderate drought stress. J. Photochem. Photobiol., 2014; 137(8): 107–115.

Singh S K, Raja R K. Regulation of photosynthesis, fluorescence, stomatal conductance and water-use efficiency of cowpea (Vigna unguiculata [L.] Walp.) under drought. J. Photochem. Photobiol. B, 2011; 105(1): 40–50.

Martinez-Ferri E, Zumaquero A, Ariza M T, Barceló A, Pliego M C. Non-destructive detection of white root rot disease in avocado rootstocks by leaf chlorophyll fluorescence. Plant Dis., 2015; 100(1): 49–58.

Mathur S. Chlorophyll a fluorescence study revealing effects of high salt stress on Photosystem II in wheat leaves. Plant Physiol. Biochem., 2010; 48(1): 16–20.

Baker N R. Chlorophyll fluorescence: a probe of photosynthesis in vivo. Plant Biol., 2008; 59(59): 89–113.

Qian W, Hong S, Li M Z, Wei Y. Development and application of crop monitoring system for detecting chlorophyll content of tomato seedlings. Int. J. Agric. & Biol. Eng., 2014; 7(2): 138–145.

Ghotbi-Ravandi A A, Shahbazi M, Shariati M, Mulo P. Effects of mild and severe drought stress on photosynthetic efficiency in tolerant and susceptible barley (hordeum vulgare L.) genotypes. J. Agron. & Crop Sci., 2015; 200(6): 403–415.

Farquhar G D, Sharkey T D. Stomatal conductance and photosynthesis. Annu. Rev. Plant Physiol., 1982; 33(1): 74–79.

Lu Q Q, Song X S, Yan D H. Effects of drought stress on photosynthetic physiological characteristics in soybean seeding. Chin. Agric. Bull., 2012; 28(9): 42–47. (in Chinese)

Guo S J, Yang K M, Huo J, Zhou Y H, Wang Y P. Influence of drought on leaf photosynthetic capacity and root growth of soybeans at grain filling stage. Chin. J. Appl. Ecol., 2015; 26(5): 1419–1425. (in Chinese)

Lawlor D W, Tezara W. Causes of decreased photosynthetic rate and metabolic capacity in water-deficient leaf cells: a critical evaluation of mechanisms and integration of processes. Ann. Bot., 2009; 103(4): 561–579.

Schreiber U, Schliwa U, Bilger W. Continuous recording of photochemical and non-photochemical chlorophyll fluorescence quenching with a new type of modulation fluorometer. Photosynth. Res., 1986; 10(1-2): 51–62.

Maxwell K, Johnson G N. Chlorophyll fluorescence - A practical guide. J. Exp. Bot., 2000; 51(345): 659–668.

Shahenshah, Isoda A. Effects of water stress on leaf temperature and chlorophyll fluorescence parameters in cotton and peanut. Plant Prod. Sci., 2015; 13(3): 269–278.

Galmés J, Pou A, Alsina M M, Tomàs M, Medrano H, Flexas J. Aquaporin expression in response to different water stress intensities and recovery in Richter-110 (Vitis, sp.): relationship with ecophysiological status. Planta, 2007; 226(3): 671–681.

Zhou S X, Medlyn B E, Prentice I C. Long-term water stress leads to acclimation of drought sensitivity of photosynthetic capacity in xeric but not riparian Eucalyptus species. Ann. Bot., 2016; 117(1): 133–144

Ivanov B, Edwards G. Influence of ascorbate and the Mehler peroxidase reaction on non-photochemical quenching of chlorophyll fluorescence in maize mesophyll chloroplasts. Planta, 2000; 210(5): 765–774.

Salvatori E, Fusaro L, Manes F. Chlorophyll fluorescence for phenotyping drought-stressed trees in a mixed deciduous forest. Ann. Bot. 2016; 6: 39–49.

Hou W, Sun A H, Chen H L, Yang F S, Pan J L, Guan M Y. Effects of chilling and high temperatures on photosynthesis and chlorophyll fluorescence in leaves of watermelon seedlings. Bio. Plantarum, 2016; 60(1): 148–154.

Atherton J, Nichol C J, Porcar-Castell A. Using spectral chlorophyll fluorescence and the photochemical reflectance index to predict physiological dynamics. Remote Sens. Environ., 2016; 176: 17–30.

Yang J, Gong W, Shi S, Du L, Sun J, Song S, et al. The effect of chlorophyll concentration of paddy rice on the fluorescence spectrum. Spectroscopy & Spectral Analysis, 2016; 36(10): 3410–3413.