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Leaf development and phloem transport in Cucurbita pepo: Carbon economy

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Summary

Net photosynthesis, dark respiration and growth for leaf 5 of Cucurbita pepo L. plants grown under controlled conditions were measured and the data used for an assessment of the changes in carbon balance during growth of the leaf through expansion to maturity. The blade is first capable of net CO2 fixation when ca. 8% expanded but the initial rapid growth during this period is sustained almost entirely through imported nutrients. When the growth rate starts to decline rapidly the net photosynthetic capacity of the blade begins to increase. This increase is accompanied by an expansion of the intercellular spaces and by decreasing dark respiration measured at night and in dark periods during the day. The blade becomes completely independent of phloem imported nutrients and begins to export excess photosynthate when the phase of rapid decrease in relative growth rate is almost complete at about 45% expansion. Maximum net photosynthesis of ca. 11 mg CO2 h-1 dm-2 is achieved at 70% expansion. The first detectable synthesis of the transport sugars stachyose and raffinose in the blade coincides with the beginning of intralaminar phloem transport from the tip to the base of the leaf. The synthesis of sucrose, the other major transport sugar, is detectable at all stages of leaf development.

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Author notes

  1. Robert Turgeon

    Present address: The Rockefeller University, 10021, New York, N.Y., USA

Authors and Affiliations

  1. Department of Biology, Carleton University, K1S 5B6, Ottawa, Ontario, Canada

    Robert Turgeon & J. A. Webb

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  1. Robert Turgeon
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  2. J. A. Webb
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Turgeon, R., Webb, J.A. Leaf development and phloem transport in Cucurbita pepo: Carbon economy. Planta 123, 53–62 (1975). https://doi.org/10.1007/BF00388060

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  • DOI: https://doi.org/10.1007/BF00388060

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