Differences in leaf physiological and morphological traits between Camellia japonica and Camellia reticulata

doi:10.1016/j.pld.2020.01.002

Abstract

Abstract: Plants of the genus Camellia are widely cultivated throughout the world as ornamentals because of their bright and large flowers. The widely cultivated varieties are mainly derived from the mutant lines and hybrid progenies of Camellia japonica Linn. and Camellia reticulata Lindl. While their geographical distributions and environmental adaptabilities are significantly different, no systematic comparison has been conducted between these two species. To investigate differences in how these plants have adapted to their environments, we measured photosynthesis and 20 leaf functional traits of C. japonica and C. reticulata grown under the same conditions. Compared with C. japonica, C. reticulata showed higher values for light saturation point, light-saturated photosynthetic rate, leaf dry mass per unit area and stomatal area, but lower values for apparent quantum efficiency, leaf size, stomatal density and leaf nitrogen content per unit mass. Stomatal area was positively correlated with light-saturated photosynthetic rate and light saturation point, but negatively correlated with stomatal density. The differences between C. reticulata and C. japonica were mainly reflected in their adaptations to light intensity and leaf morphological traits. C. reticulata is better adapted to high light intensity than C. japonica. This difference is related to the two species’ differing life forms. Thus, leaf morphological traits have played an important role in the light adaptation of C. reticulata and C. japonica, and might be first noticed and selected during the breeding process. These findings will contribute to the cultivation of camellia plants.

Key words: Camellia, Light adaptation, Leaf traits, Ornamental plant, Photosynthesis

Ji-Hua Wang, Yan-Fei Cai, Shi-Feng Li, Shi-Bao Zhang. Differences in leaf physiological and morphological traits between Camellia japonica and Camellia reticulata[J]. Plant Diversity, 2020, 42(03): 181-188.

References

Aasamaa, K., Sõber, A., Rahi, M., 2001. Leaf anatomical characteristics associated with shoot hydraulic conductance, stomatal conductance and stomatal sensitivity to changes of leaf water status in temperate deciduous trees. Aust. J. Plant Physiol. 28, 765-774.
Aleric, K.M., Kirkman, L.K., 2005. Growth and photosynthetic responses of the federally endangered shrub, Lindera melissifolia (Lauraceae), to varied light environments. Am. J. Bot. 92, 682-689.
Barman, T.S., Baruah, U., Saikia, J.K., 2008. Irradiance influences tea leaf (Camellia sinensis L.) photosynthesis and transpiration. Photosynthetica 46, 618-621.
Beaulieu, J.M., Leitch, I.J., Patel, S., et al., 2008. Genome size is a stronger predictor of cell size and stomatal density in angiosperms. New Phytol. 179, 975-986.
Brodribb, T.J., Jordan, G.J., 2011. Water supply and demand remain balanced during leaf acclimation of Nothofagus cunninghamii trees. New Phytol. 192, 437-448.
Brodribb, T.J., Jordan, G.J., Carpenter, R.J., 2013. Unified changes in cell size permit coordinated leaf evolution. New Phytol. 199, 559-570.
Büssis, D., von Groll, U., Fisahn, J., et al., 2006. Stomatal aperture can compensate altered stomatal density in Arabidopsis thaliana at growth light conditions. Funct. Plant Biol. 33, 1037-1043.
Cai, Z.Q., Rijkers, T., Bongers, F., 2005. Photosynthetic acclimation to light changes in tropical monsoon forest woody species differing in adult stature. Tree Physiol. 25, 1023-1031.
Cai, Y.-F., Yang, Q.-Y., Li, S.-F., et al., 2017. The water-water cycle is a major electron sink in Camellia species when CO₂ assimilation is restricted. J. Photochem. Photobiol., B 168, 59-66.
Chazdon, R.L., 1988. Sunflecks and their importance to understorey plants. Adv. Ecol. Res. 18, 1-63.
Dai, Y., Shen, Z., Liu, Y., et al., 2009. Effects of shade treatments on the photosynthetic capacity, chlorophyll fluorescence, and chlorophyll content of Tetrastigma hemsleyanum Diels et Gilg. Environ. Exp. Bot. 65, 177-182.
Drake, P.L., Froend, R.H., Franks, P.J., 2012. Smaller, faster stomata: scaling of stomatal size, rate of response, and stomatal conductance. J. Exp. Bot. 64, 495-505.
Evans, J.R., Clarke, V.C., 2019. The nitrogen cost of photosynthesis. J. Exp. Bot. 70, 7-15.
Fetcher, N., Strain, B.R., Oberbauer, S.F., 1983. Effects of light regime on the growth, leaf morphology, and water relations of seedlings of two species of tropical trees. Oecologia 58, 314-319.
Fonseca, C.R., Overton, J.M., Collins, B., et al., 2000. Shifts in trait-combinations along rainfall and phosphorus gradients. J. Ecol. 88, 964-977.
Franks, P.J., Drake, P.L., Beerling, D.J., 2009. Plasticity in maximum stomatal conductance constrained by negative correlation between stomatal size and density: an analysis using Eucalyptus globulus. Plant Cell Environ. 32, 1737-1748.
Goldstein, G., Santiago, L.S., Campanello, P.I., et al., 2016. Facing shortage or excessive light: how tropical and subtropical trees adjust their photosynthetic behavior and life history traits to a dynamic forest environment. In:Goldstein, G., Santiago, L.S. (Eds.), Tropical Tree Physiology. Springer International Publishing, Switzerland, pp. 319-336.
Hamerlynck, E., Knapp, A.K., 1996. Photosynthetic and stomatal responses to high temperature and light in two oaks at the western limit of their range. Tree Physiol. 16, 557-565.
He, P., Wright, I.J., Zhu, S., et al., 2019. Leaf mechanical strength and photosynthetic capacity vary independently across 57 subtropical forest species with contrasting light requirements. New Phytol. 223, 607-618.
Hikosaka, K., Terashima, I., 1995. A model of the acclimation of photosynthesis in the leaves of C₃ plants to sun and shade with respect to nitrogen use. Plant Cell Environ. 18, 605-618.
Hjelm, U., Ögren, E., 2004. Photosynthetic responses to short-term and long-term light variation in Pinus Sylvestris and Salix dasyclados. Trees 18, 622-629.
Inskeep, W.P., Bloom, P.R., 1985. Extinction coefficients of chlorophyll a and b in N,N-dimethylformamide and 80% acetone. Plant Physiol. 77, 483-485.
Jensen, R.G., 2004. Activation of Rubisco controls CO₂ assimilation in light: a perspective on its discovery. Photosynth. Res. 82, 187-193.
Kim, S.J., Yu, D.J., Kim, T.-C., et al., 2011. Growth and photosynthetic characteristics of blueberry (Vaccinium corymbosum cv. Bluecrop) under various shade levels. Sci. Hortic. 129, 486-492.
Krüger, G.H.J., Tsimilli-Michael, M., Strasser, R.J., 1997. Light stress provokes plastic and elastic modifications in structure and function of photosystem Ⅱ in camellia leaves. Physiol. Plantarum 101, 265-277.
Li, P.-R., Liu, Y.-Z., Zhai, M., et al., 2016a. Recent advances in Camellia japonica L. J. Plant Genet. Resour. 17, 1022-1030.
Li, S., Zhang, Y.-J., Sack, L., et al., 2013. The heterogeneity and spatial patterning of structure and physiology across the leaf surface in giant leaves of Alocasia macrorrhiza. PloS One 8, e66016.
Li, X., Liu, X., Li, C., et al., 2019. Growth and antioxidant physiology effects of Camellia azalea seedlings under different light conditions. Chin. J. Top. Crops 40, 688-692.
Li, X., Yang, Y., Yang, S., et al., 2016b. Comparative proteomics analyses of intraspecific differences in the response of Stipa purpurea to drought. Plant Divers. 38, 101-117.
Liu, D., Zhao, S., Zhang, Z., et al., 2003. Photosynthesis of different cultivars of Camellia japonica L. in greenhouse. Acta Hortic. Sin. 30, 65-68.
Mantovani, A., 1999. Leaf morpho-physiology and distribution of epiphytic aroids along a vertical gradient in a Brazilian rain forest. Selbyana 20, 241-249.
Mao, L.Z., Lu, H.F., Wang, Q., et al., 2007. Comparative photosynthesis characteristics of Calycanthus chinensis and Chimonanthus praecox. Photosynthetica 45, 601-605.
Ming, T.-L., 2000. Monograph of the Genus Camellia. Yunnan Science and Technology Press, Kunming, China.
Murphy, M.R.C., Jordan, G.J., Brodribb, T.J., 2012. Differential leaf expansion can enable hydraulic acclimation to sun and shade. Plant Cell Environ. 35, 1407-1418.
Niinemets, Ü., Kull, K., 1994. Leaf weight per area and leaf size of 85 Estonian woody species in relation to shade tolerance and light availability. For. Ecol. Manag. 70, 1-10.
Niinemets, U., 2007. Photosynthesis and resource distribution through plant canopies. Plant Cell Environ. 30, 1052-1071.
Ogburn, R.M., Edwards, E.J., 2013. Repeated origin of three-dimensional leaf venation releases constraints on the evolution of succulence in plants. Curr. Biol. 23, 722-726.
Pandey, S., Kushwaha, R., 2005. Leaf anatomy and photosynthetic acclimation in Valeriana jatamansi grown under high and low irradiance. Photosynthetica 43, 85-90.
Poorter, L., 1999. Growth responses of 15 rain-forest tree species to a light gradient:the relative importance of morphological and physiological traits. Funct. Ecol. 13, 396-410.
Poorter, L., Bongers, F., Sterck, F.J., et al., 2005. Beyond the regeneration phase:differentiation of heightelight trajectories among tropical tree species. J. Ecol. 93, 256-267.
Prioul, J.L., 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.
Rozendaal, D.M.A., Hurtado, V.H., Poorter, L., 2006. Plasticity in leaf traits of 38 tropical tree species in response to light; relationships with light demand and adult stature. Funct. Ecol. 20, 207-216.
Sack, L., Grubb, P.J., Marañón, T., 2003. The functional morphology of juvenile plants tolerant of strong summer drought in shaded forest understories in southern Spain. Plant Ecol. 168, 139-163.
Sack, L., Frole, K., 2006. Leaf structural diversity is related to hydraulic capacity in tropical rain forest trees. Ecology 87, 483-491.
Sack, L., Scoffoni, C., 2013. Leaf venation: structure, function, development, evolution, ecology and applications in the past, present and future. New Phytol. 198, 983-1000.
Schuler, M.L., Sedelnikova, O.V., Walker, B.J., et al., 2018. SHORTROOT-mediated increase in stomatal density has no impact on photosynthetic efficiency. Plant Physiol. 176, 757-772.
Scoffoni, C., Kunkle, J., Pasquet-Kok, J., et al., 2015. Light-induced plasticity in leaf hydraulics, venation, anatomy, and gas exchange in ecologically diverse Hawaiian lobeliads. New Phytol. 207, 43-58.
Stewart, J.J., Polutchko, S.K., Adams Ⅲ, W.W., et al., 2017. Acclimation of Swedish and Italian ecotypes of Arabidopsis thaliana to light intensity. Photosynth. Res. 134, 215-229.
Tanaka, Y., Sugano, S.S., Shimada, T., et al., 2013. Enhancement of leaf photosynthetic capacity through increased stomatal density in Arabidopsis. New Phytol. 198, 757-764.
Thomas, S.C., Bazzaz, F.A., 1999. Asymptotic height as a predictor of photosynthetic characteristics in Malaysian rain forest trees. Ecology 80, 1607-1622.
Vogel, S., 2009. Leaves in the lowest and highest winds: temperature, force and shape. New Phytol. 183, 13-26.
Wu, C.A., Campbell, D.R., 2006. Environmental stressors differentially affect leaf ecophysiological responses in two Ipomopsis species and their hybrids. Oecologia 148, 202-212.
Xiong, D., Douthe, C., Flexas, J., 2018. Differential coordination of stomatal conductance, mesophyll conductance, and leaf hydraulic conductance in response to changing light across species. Plant Cell Environ. 41, 436-450.
Yang, Y.-J., Chang, W., Hu, H., 2011. The photosynthetic characteristics of three horticultural cultivars of Camellia reticulate. North. Horti. 21, 65-69.
Yang, G.-Y., Wang, B.-Y., He, H., et al., 2015. Drought resistance potential of different ploidy of Camellia reticulata from leaf anatomic traits view. Southwest China J. Agric. Sci. 28, 2714-2719.
Yu, D., 1985. A historical review and future development of Camellia reticulata in Yunnan. Acta Hortic. Sin. 12, 131-136.
Zhang, S.-B., Zhou, Z.-K., Hu, H., et al., 2005. Photosynthetic performances of Quercus pannosa vary with altitude in the Hengduan Mountains, southwest China. For. Ecol. Manag. 212, 291-301.
Zhang, S.-B., Hu, H., Xu, K., et al., 2006. Photosynthetic performances of five Cypripedium species after transplanting. Photosynthetica 44, 425-432.
Zhang, S.-B., Guan, Z.-J., Sun, M., et al., 2012. Evolutionary association of stomatal traits with leaf vein density in Paphiopedilum, Orchidaceae. PloS One 7, e40080.
Zhang, W., Huang, W., Zhang, S.-B., 2017. The study of a determinate growth orchid highlights the role of new leaf production in photosynthetic light acclimation. Plant Ecol. 218, 997-1008.

[1]	Jing-Qiu Feng, Ji-Hua Wang, Shi-Bao Zhang. Leaf physiological and anatomical responses of two sympatric Paphiopedilum species to temperature [J]. Plant Diversity, 2022, 44(01): 101-108.
[2]	Harue Abe, Hiroki Miura, Yoshitaka Motonaga. Quantitative classification of Camellia japonica and Camellia rusticana (Theaceae) based on leaf and flower morphology [J]. Plant Diversity, 2021, 43(03): 216-224.
[3]	Shuang Li, Shang-Li Liu, Si-Yu Pei, Man-Man Ning, Shao-Qing Tang. Genetic diversity and population structure of Camellia huana (Theaceae), a limestone species with narrow geographic range, based on chloroplast DNA sequence and microsatellite markers [J]. Plant Diversity, 2020, 42(05): 343-350.
[4]	Shibao Zhang, Yingjie Yang, Jiawei Li, Jiao Qin, Wei Zhang, Wei Huang, Hong Hu. Physiological diversity of orchids [J]. Plant Diversity, 2018, 40(04): 196-208.
[5]	LIU Hai-Yan-, YANG NAi-Kun-, JU Tian-Cai. Population Ecological Characteristics of the Rare and Endangered Plant Camellia rhytidophylla from Guizhou [J]. Plant Diversity, 2015, 37(06): 837-848.
[6]	LI Miao-Miao, MEEGAHAKUMBURA M. Kasun, YAN Li-Jun, LIU Jie, GAO Lian-Ming. Genetic Involvement of Camellia taliensis in the Domestication of C.sinensis var. assamica (Assimica Tea) Revealed by Nuclear Microsatellite Markers [J]. Plant Diversity, 2015, 37(01): 29-37.
[7]	TANG Ting, ZHENG Guo-Wei, LI Wei-Qi. The Thermotolerance and Repair Mechanism of Photosystem in Alpine Plant Arabis paniculata (Cruciferae)* [J]. Plant Diversity, 2015, 37(01): 46-54.
[8]	YANG Shi-Xiong, Nguyen Hieu, ZHAO Dong-Wei, SHUI Yu-Min. Rediscovery of Camellia tonkinensis (Theaceae) after More Than 100 Years [J]. Plant Diversity, 2014, 36(05): 585-589.
[9]	CHEN Ke, LIU Wen-Yao, LI Su, SONG Liang. Photosynthetic Characteristics of Three Epiphytic Lichens under Different Water Conditions [J]. Plant Diversity, 2014, 36(05): 603-610.
[10]	OUYANG-Fen, ZHENG Guo-Wei, LI Wei-Qi. Influence of Elevated CO2 Concentration and Nitrogen Source on Photosynthetic Traits in the Invasive Species Eupatorium adenophorum (Asteraceae) [J]. Plant Diversity, 2014, 36(05): 611-621.
[11]	WU Chun-Lan, HUANG Ya-Hui, LAI Xing-Fei, LAI Rong-Hui, ZHANG Min, ZHAO Wen-Xia, ZhAO Wen-Fang. Study on Quality Components of GABA Maoyecha Tea (Camellia ptilophylla)* [J]. Plant Diversity, 2014, 36(03): 411-418.
[12]	ZHANG Shi-Bao. Biomass Partitioning Affects the Growth of Pinus Species from Different Elevations [J]. Plant Diversity, 2014, 36(01): 47-55.
[13]	YANG Ting-, XU Kun-, YAN Ning-, LI Shu-Yun-, HU Hong. Photosynthetic Ecophysiology of Three Species of Genus Rhododendron [J]. Plant Diversity, 2013, 35(1): 17-25.
[14]	ZHU Li-Fang-, DONG Hong-Zhu-, YANG Shi-Xiong-, SHU Hong-Tao-, XU Min-, ZENG Shu-Fen-, YANG Chong-Ren-, ZHANG Ying-Jun. Chemical Compositions and Antioxidant Activity of Essential Oil from Green Tea Produced from Camellia taliensis (Theaceae) in Yuanjiang, Southwestern China [J]. Plant Diversity, 2012, 34(4): 409-.
[15]	ZHANG Shi-Bao-, ZHOU Zhe-Kun-, XIU Kun. Effects of Altitude on Photosynthetic Gas Exchange and the Associated Leaf Trait in an Alpine Oak, Quercus guyavifolia (Fagaceae) [J]. Plant Diversity, 2011, 33(2): 214-224.