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Emily K. Dixon, Bernadine C. Strik, and David R. Bryla

relationships in ‘Titan’ red raspberry Acta Hort. 352 151 157 Fernandez, G.C. Pritts, M.P. 1994 Growth, carbon acquisition, and source-sink relationships in ‘Titan’ red raspberry J. Amer. Soc. Hort. Sci. 119 1163 1168 Fernandez, G.E. Pritts, M.P. 1996 Carbon

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Yue Wen, Shu-chai Su, Ting-ting Jia, and Xiang-nan Wang

photosynthesis rate ( Proietti et al., 2000 ) and chlorophyll fluorescence parameters ( Wen et al., 2018a ). Furthermore, various leaves have different source–sink relationships, resulting in differences in assimilate partitioning and carbon contributions to

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Ben-Hong Wu, Ning Niu, Ji-Hu Li, and Shao-Hua Li

Source-sink relationships (mainly leaves vs. reproductive organs) play an important role in fruit growth and quality with respect to fruit size, color, and chemical composition. Grape is a species well suited for exploring the mechanisms that govern

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ZhaoSen Xie, Charles F. Forney, WenPing Xu, and ShiPing Wang

organization based on source-sink relationship: New findings on developmental, biochemical and molecular responses to environment 263 280 Roubelakis-Angelakis K.A. Molecular biology & biotechnology of grapevine Kluwer Academic Publishers

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C. Yang, D.Y. Jiao, Z.Q. Cai, H.D. Gong, and G.Y. Li

( Fig. 6 ), contrasting with our previous results of P. volubilis plants in response to light intensity, water, fertilization, and planting density ( Cai, 2011 ; Jiao et al., 2012 ; Yang et al., 2014 ). PGRs are known to enhance the source–sink

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Sydney Lykins, Katlynn Scammon, Brian T. Lawrence, and Juan Carlos Melgar

351 Evans, J.R. Santiago, L.S. 2014 PrometheusWiki gold leaf protocol: Gas exchange using LI-COR 6400 Funct. Plant Biol. 41 223 226 doi: 10.1071/FP10900 10.1071/FP10900 Fernandez, G. Pritts, M. 1994 Growth, carbon acquisition, and source–sink

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Maren J. Mochizuki, Oleg Daugovish, Miguel H. Ahumada, Shawn Ashkan, and Carol J. Lovatt

-round production in greenhouses Acta Hort. 626 219 223 Daugovish, O. Larson, K.D. 2009 Strawberry production with protected culture in southern California ISHS Acta Hort. 842 163 166 Fernandez, G.E. Pritts, M.P. 1994 Growth, carbon acquisition, and source-sink

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Han Xu, Cuihua Bai, Wei Wang, Changmin Zhou, Luwei Zhu, and Lixian Yao

pathways Nature 517 7534 1515 1521 Engels, C. Kirkby, E. White, P. 2012 Mineral nutrition, yield and source-sink relationships, p. 85–133. In: P. Marschner (ed.). Marschner’s mineral nutrition of higher plants. 3rd ed. Elsevier Academic Press, San Diego, CA

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Ya-Ching Chuang and Yao-Chien Alex Chang

). Total carbohydrates in the rose ( Rosa hybrids L.) corolla decrease with time, but not as much as in the leaves; and the decrease in the corolla is more pronounced when leaves on cut flowers were removed, suggesting a source-sink relationship from

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Yansheng Li, Ming Du, Qiuying Zhang, Guanghua Wang, Jian Jin, Stephen Herbert, and Xiaobing Liu

transported from synthesizing (source) organs to sink organs where it is stored ( Lemoine, 2000 ), and any reduced type of source organs would influence sucrose accumulation. Furthermore, sucrose is a signal molecule for regulating the source-sink relationship