Abstract
Maize is a low-temperature (LT)-sensitive plant and its physiological responses towards LT of temperate regions developed is an adaptive trait. To further our understanding about the response of maize to LT at the physiological and photosynthesis level, we conducted Infrared Gas Analysis (IRGA using LICOR6400-XT in 45-day-old grown two maize genotypes, one from temperate region (Gurez-Kashmir Himalayas), viz., Gurez local (Gz local), and another from tropics (Gujarat), viz., GM6. This study was carried out to evaluate the underlying physiological mechanisms in the two differentially temperature-tolerant maize genotypes. Net photosynthetic rate (A/PN), 18.253 in Gz local and 25.587 (µmol CO2 m−2 s−1) in GM6; leaf conductance (gs), 0.0102 in Gz local and 0.0566 (mmol H2O m−2 s−1) in GM6; transpiration rate (E), 0.5371 in Gz local and 2.9409 (mmol H2O m−2 s−1) in GM6; and water use efficiency (WUE), 33.9852 in Gz local and 8.7224 (µmol CO2 mmol H2O−1) in GM6, were recorded under ambient conditions. Also, photochemical efficiency of photosystem II (PSII) (Fv/Fm), 0.675 in Gz local and 0.705 in GM6; maximum photochemical efficiency (Fv′/Fm′), 0.310234 in Gz local and 0.401391 in GM6; photochemical quenching (qP), 0.2375 in Gz local and 0.2609 in GM6; non-photochemical quenching (NPQ), 2.0036 in Gz local and 1.1686 in GM6; effective yield of PSII (ФPSII), 0.0789 in Gz local and 0.099 in GM6; and electron transport rate (ETR), 55.3152 in Gz local and 68.112 in GM6, were also evaluated in addition to various response curves, like light intensities and temperature. We observed that light response curves show the saturation light intensity requirement of 1600 µmol for both the genotypes, whereas temperature response curves showed the optimum temperature requirement for Gz local as 20 °C and for GM6 it was found to be 35 °C. The results obtained for each individual parameter and other correlational studies indicate that IRGA forms a promising route for quick and reliable screening of various stress-tolerant valuable genotypes, forming the first study of its kind.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abuhay T, Farrant J (2013) Water relations, gas exchange characteristics and water use efficiency in maize and sorghum after exposure to and recovery from pre and post-flowering dehydration. Afr J Agric Res 8:6468–6478
Adamski JM, Rosa LMG, Menezes Peixoto CRd, Pinheiro CL, Fett JP, Sperotto RAJP (2020) Photosynthetic activity of indica rice sister lines with contrasting cold tolerance. Physiol Mol Biol Plants 20:1–10
Allen DJ, Ort DR (2001) Impacts of chilling temperatures on photosynthesis in warm-climate plants. Trends Plant Sci 6:36–42
Anjum SA, Wang LC, Farooq M, Hussain M, Xue LL, Zou CM (2011) Brassinolide application improves the drought tolerance in maize through modulation of enzymatic antioxidants and leaf gas exchange. J Agro Crop Sci 197:177–185
Avramova V, Nagel KA, AbdElgawad H, Bustos D, DuPlessis M, Fiorani F, Beemster GT (2016) Screening for drought tolerance of maize hybrids by multi-scale analysis of root and shoot traits at the seedling stage. J Exp Bot 67:2453–2466
Banerjee A, Roychoudhury AJP (2019) Cold stress and photosynthesis. Photosynth, Product Environ Stress 12:27–37
Bellasio C, Griffiths H (2014) Acclimation of C4 metabolism to low light in mature maize leaves could limit energetic losses during progressive shading in a crop canopy. J Exp Bot 65:3725–3736
Choi HG, Moon BY, Kang NJ (2016) Correlation between strawberry (Fragaria ananassa Duch) productivity and photosynthesis-related parameters under various growth conditions. Front Plant Sci 7:1607
Colom M, Vazzana C (2003) Photosynthesis and PSII functionality of drought-resistant and drought-sensitive weeping lovegrass plants. Environ Exp Bot 49:135–144
de Carvalho RC, Cunha A, da Silva, (2011) Photosynthesis by six Portuguese maize cultivars during drought stress and recovery. Acta Physiol Plant 33:359–374
Edmeades GO, Trevisan W, Prasanna BM, Campos H (2017) Tropical maize (Zea mays L.). In Genetic improvement of tropical crops, Springer, Cham pp. 57–109
Efeoğlu B, Ekmekçi Y, Çiçek N (2009) Physiological responses of three maize cultivars to drought stress and recovery. S Afr J Bot 75:34–42
Fageria NK, Baligar VC, Clark R (2006) Physiology of crop production. CRC Press
Feng L, Raza MA, Li Z, Chen Y, Khalid MHB (2019) The influence of light intensity and leaf movement on photosynthesis characteristics and carbon balance of soybean. Front Plant Sci 9:1952
Fracheboud Y, Haldimann P, Leipner J, Stamp P (1999) Chlorophyll fluorescence as a selection tool for cold tolerance of photosynthesis in maize (Zea mays L.). J Exp Bot. 50:1533–1540
Gallé A, Flexas J (2010) Gas-exchange and chlorophyll fluorescence measurements in grapevine leaves in the field. In: Methodologies and Results in Grapevine Research. Springer, pp 107–121
Grzybowski M, Adamczyk J, Jończyk M, Sobkowiak A, Szczepanik J, Frankiewicz K, Sowiński P (2019) Increased photosensitivity at early growth as a possible mechanism of maize adaptation to cold. springs J Exp Bot 70:2887–2904
Guidi L, Lo Piccolo E, Landi M (2019) Chlorophyll fluorescence, photoinhibition and abiotic stress: does it make any difference the fact to be a C3 or C4 species? Front Plant Sci 10:174
Hajihashemi S, Noedoost F, Geuns J, Djalovic I, Siddique K (2018) Effect of cold stress on photosynthetic traits, carbohydrates, morphology, and anatomy in nine cultivars of Stevia rebaudiana. Front Plant Sci 9:1430
Hatfield JL, Dold C (2019) Water-use efficiency: advances and challenges in a changing climate. Front Plant Sci 10
Kasajima I, Ebana K, Yamamoto T, Takahara K, Yano M, Kawai-Yamada M, Uchimiya H (2011) Molecular distinction in genetic regulation of nonphotochemical quenching in rice. Proc Natl Acad Sci 108:13835–13840
Knapp AK, Medina E (1999) Success of C4 photosynthesis in the field: lessons from communities dominated by C4 plants. Plant Biol C4:251–283
Krall JP, Edwards GE (1992) Relationship between photosystem II activity and CO2 fixation in leaves. Physiol Plant 86:180–187
Lee JE et al (2015) Simulations of chlorophyll fluorescence incorporated into the C ommunity L and Model version 4. Global Change Biol 21:3469–3477
Leipner J, Fracheboud Y, Stamp P (1999) Effect of growing season on the photosynthetic apparatus and leaf antioxidative defenses in two maize genotypes of different chilling tolerance. Environ Exp Bot 42:129–139
Liu M, Qi H, Zhang Z, Song Z, Kou T, Zhang W, Yu J (2012) Response of photosynthesis and chlorophyll fluorescence to drought stress in two maize cultivars. Afrc J Agr Res 7:4750–4759
Long SP, Bernacchi C (2003) Gas exchange measurements, what can they tell us about the underlying limitations to photosynthesis? Procedures and sources of error. J Exp Bot 54:2393–2401
Lu T, Yu H, Li Q, Chai L, Jiang W (2019) Improving plant growth and alleviating photosynthetic inhibition and oxidative stress from low-light stress with exogenous GR24 in tomato (Solanum lycopersicum L) seedlings. Front Plant Sci. https://doi.org/10.3389/fpls.2019.00490
Mangani R, Tesfamariam EH, Bellocchi G, Hassen AJS (2018) Growth, development, leaf gaseous exchange, and grain yield response of maize cultivars to drought and flooding stress. Sustainability. 10:3492
Mauchamp A, Méthy M (2004) Submergence-induced damage of photosynthetic apparatus in Phragmites australis. Environ Exp Bot 51:227–235
Maxwell K, Johnson G (2000) Chlorophyll fluorescence: a practical guide. J Exp Bot 51:659–668
Piao S, Ciais P, Friedlingstein P, Peylin P, Reichstein M, Luyssaert S, Margolis H, Fang J, Barr A, Chenn A, Grelle A (2008) Net carbon dioxide losses of northern ecosystems in response to autumn warming. Nature 451:49–52
Prioul J, Chartier P (1977) Partitioning of transfer and carboxylation components of intracellular resistance to photosynthetic CO2 fixation: a critical analysis of the methods used. Ann Bot 41:789–800
Ramazan S and John R (2020) Climate Change Impacts and Mitigation; Abiotic Stress Impressions and Tolerance: A Perspective from Kashmir Himalayas. Proc Indian Natn Sci Acad 1139–1156
Ribeiro RV, Machado EC, Oliveira RF (2006) Temperature response of photosynthesis and its interaction with light intensity in sweet orange leaf discs under non-photorespiratory condition. Ciencia e Agrotechnologia 30:670–678
Ribeiro RV, Machado EC, Oliveira RF (2004) Growth-and leaf-temperature effects on photosynthesis of sweet orange seedlings infected with Xylella fastidiosa. Plant Pathol 53:334–340
Riva-Roveda L, Escale B, Giauffret C, Périlleux C (2016) Maize plants can enter a standby mode to cope with chilling stress. BMC Plant Biol 16:212
Shangguan Z, Shao M, Dyckmans J (2000) Effects of nitrogen nutrition and water deficit on net photosynthetic rate and chlorophyll fluorescence in winter wheat. J Plant Physiol 156:46–51
Sharma DK, Andersen SB, Ottosen CO, Rosenqvist E (2015) Wheat cultivars selected for high Fv/Fm under heat stress maintain high photosynthesis, total chlorophyll, stomatal conductance, transpiration and dry matter. Physiol Plant 153:284–298
Siddique M, Hamid A, Islam M (1999) Drought stress effects on photosynthetic rate and leaf gas exchange of wheat. Bot Bull Acad Sinica 40:141–145
Song Y, Chen Q, Ci D, Shao X, Zhang D (2014) Effects of high temperature on photosynthesis and related gene expression in poplar. BMC Plant Biol 14:111
Tollenaar M, Lee EA (2006) Dissection of physiological processes underlying grain yield in maize by examining genetic improvement and heterosis. Maydica 21:51–399
Tosens T, Niinemets U, Vislap V, Eichelmann H, Castro Diez P (2012) Developmental changes in mesophyll diffusion conductance and photosynthetic capacity under different light and water availabilities in Populus tremula: how structure constrains function. Plant Cell Environ 35:839–856
Wang J, Huang H, Jia S, Zhong X, Li F, Zhang K, Shi Z (2017) Photosynthesis and chlorophyll fluorescence reaction to different shade stresses of weak light sensitive maize. Pak J Bot 49:1681–1688
Wei MJGMH (1999) A quick new method for determining light response curves of photosynthesis under field light conditions. Chinese Bull Bot 6:24
Wen-feng Z, Xin-juan W, Meng Y, Wan-rong G, Zheng-jin X, Jing LJ (2013) Influence of low-temperature stress on photosynthetic traits in maize seedlings. J Northeast Agr Univ 20:1–5
Wimalasekera R (2019) Effect of Light Intensity on Photosynthesis. Phot Produc Environ Stress 2:65–73
Xu CC, Jeon YA, Lee CH (1999) Relative contributions of photochemical and non-photochemical routes to excitation energy dissipation in rice and barley illuminated at a chilling temperature. Physiol Plant 107:447–453
Xu Q, Ma X, Lv T, Bai M, Wang Z, Niu J (2020) Effects of water stress on fluorescence parameters and photosynthetic characteristics of drip irrigation in rice. Water 12:289
Yan W, Hunt L (1999) An equation for modelling the temperature response of plants using only the cardinal temperatures. Annal Bot 84:607–614
Yang Y, Yi X, Prasad P (2009) Response of photosynthesis and chlorophyll fluorescence quenching to leaf dichotocarpism in Ligustrum vicaryi, an ornamental herb. Photosynthetica 47:137–140
Yang Z, Sinclair TR, Zhu M, Messina CD, Cooper M, Hammer GL (2012) Temperature effect on transpiration response of maize plants to vapour pressure deficit. Environ Exp Bot 78:157–162
Ying J, Lee E, Tollenaar M (2000) Response of maize leaf photosynthesis to low temperature during the grain-filling period. Field Crops Res 68:87–96
Zhang P, Zhang Z, Li B, Zhang H, Hu J, Zhao J (2020) Photosynthetic rate prediction model of newborn leaves verified by core fluorescence parameters. Sci Rep 10:1–11
Zhang J, Liu J, Yang C, Du S, Yang W (2016) Photosynthetic performance of soybean plants to water deficit under high and low light intensity. S Afr J Bot 105:279–287
Zhao X, Chen T, Feng B, Zhang C, Peng S (2017) Non-photochemical quenching plays a key role in light acclimation of rice plants differing in leaf color. Front Plant Sci 7:1968
Zheng YP, Li RQ, Guo LL, Hao LH, Zhou HR (2018) Temperature responses of photosynthesis and respiration of maize (Zea mays) plants to experimental warming. Russ J Plant Physiol 65:524–531
Acknowledgements
The authors acknowledge financial support from Council for Scientific and Industrial Research (CSIR) through the sanction no.38 (1459) 18/EMR II.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Ramazan, S., Bhat, H.A., Zargar, M.A. et al. Combined gas exchange characteristics, chlorophyll fluorescence and response curves as selection traits for temperature tolerance in maize genotypes. Photosynth Res 150, 213–225 (2021). https://doi.org/10.1007/s11120-021-00829-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11120-021-00829-z