Xylem, phloem, and transpiration flows in developing sweet cherry fruit

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Martin Brüggenwirth
  • Andreas Winkler
  • Moritz Knoche

Research Organisations

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Details

Original languageEnglish
Pages (from-to)1821-1830
Number of pages10
JournalTrees - Structure and Function
Volume30
Issue number5
Early online date2 Jun 2016
Publication statusPublished - 1 Oct 2016

Abstract

Key message: Flow in the phloem increased in developing sweet cherry, whereas xylem flow continuously decreased resulting in a fruit water potential that was independent from the tree at fruit maturity. Abstract: Rain cracking of sweet cherry fruit is associated with water uptake through the skin, but probably also through the vasculature of the pedicel. The aim of this study was to quantify the xylem, phloem, and transpiration contributions to the overall water balance of developing sweet cherry fruit. Using linear variable displacement transducers, changes in fruit diameter were monitored in untreated control fruit, fruit whose pedicels had been steam-girdled, and fruit whose pedicels had been cut through (these fruits were detached, but remained in situ in the canopy). Fruit volume changes with time were inferred from the measured diameter changes. Pedicel xylem and phloem sap-flow rates, and fruit transpiration rates, were inferred from fruit volume changes. Daily phloem flows were low during stage II (phase of pit development), but markedly increased in stage III (phase of cell enlargement in flesh). Xylem flows exceeded phloem flows in stage II, but decreased continuously in stage III to nearly zero at harvest. Transpiration flow essentially mirrored xylem flow in stage II, but exceeded xylem flow in stage III. Transpiration flow was closely related to the water vapour pressure deficit. Phloem flow was linearly related to the increase in fruit dry mass per-unit time. The data reveal a decrease in xylem sap flow throughout stage III resulting in a water-potential isolation of the mature fruit from the tree. Such isolation would prevent uncontrolled osmotic uptake of xylem water by the sugary flesh and a putative backflow in the xylem from fruit to tree.

Keywords

    Fruit cracking, Fruit growth, Prunus avium, Vapour pressure deficit, Water relations

ASJC Scopus subject areas

  • Agricultural and Biological Sciences(all)
  • Forestry
  • Biochemistry, Genetics and Molecular Biology(all)
  • Physiology
  • Environmental Science(all)
  • Ecology
  • Agricultural and Biological Sciences(all)
  • Plant Science

Cite this

Xylem, phloem, and transpiration flows in developing sweet cherry fruit. / Brüggenwirth, Martin; Winkler, Andreas; Knoche, Moritz.
In: Trees - Structure and Function, Vol. 30, No. 5, 01.10.2016, p. 1821-1830.

Research output: Contribution to journalArticleResearchpeer review

Brüggenwirth M, Winkler A, Knoche M. Xylem, phloem, and transpiration flows in developing sweet cherry fruit. Trees - Structure and Function. 2016 Oct 1;30(5):1821-1830. Epub 2016 Jun 2. doi: 10.1007/s00468-016-1415-4
Brüggenwirth, Martin ; Winkler, Andreas ; Knoche, Moritz. / Xylem, phloem, and transpiration flows in developing sweet cherry fruit. In: Trees - Structure and Function. 2016 ; Vol. 30, No. 5. pp. 1821-1830.
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abstract = "Key message: Flow in the phloem increased in developing sweet cherry, whereas xylem flow continuously decreased resulting in a fruit water potential that was independent from the tree at fruit maturity. Abstract: Rain cracking of sweet cherry fruit is associated with water uptake through the skin, but probably also through the vasculature of the pedicel. The aim of this study was to quantify the xylem, phloem, and transpiration contributions to the overall water balance of developing sweet cherry fruit. Using linear variable displacement transducers, changes in fruit diameter were monitored in untreated control fruit, fruit whose pedicels had been steam-girdled, and fruit whose pedicels had been cut through (these fruits were detached, but remained in situ in the canopy). Fruit volume changes with time were inferred from the measured diameter changes. Pedicel xylem and phloem sap-flow rates, and fruit transpiration rates, were inferred from fruit volume changes. Daily phloem flows were low during stage II (phase of pit development), but markedly increased in stage III (phase of cell enlargement in flesh). Xylem flows exceeded phloem flows in stage II, but decreased continuously in stage III to nearly zero at harvest. Transpiration flow essentially mirrored xylem flow in stage II, but exceeded xylem flow in stage III. Transpiration flow was closely related to the water vapour pressure deficit. Phloem flow was linearly related to the increase in fruit dry mass per-unit time. The data reveal a decrease in xylem sap flow throughout stage III resulting in a water-potential isolation of the mature fruit from the tree. Such isolation would prevent uncontrolled osmotic uptake of xylem water by the sugary flesh and a putative backflow in the xylem from fruit to tree.",
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AU - Brüggenwirth, Martin

AU - Winkler, Andreas

AU - Knoche, Moritz

N1 - Funding Information: This research was funded in part by a grant from the Deutsche Forschungsgemeinschaft and by the Deutscher Akademischer Austauschdienst. We thank Marlene Ayala, Roman Toro, Rodrigo Belmar, and Claudio Vial for their support in Chile, Peter Braun for the design of the fruit diameter gauges, Dieter Reese for constructing and manufacturing the fruit diameter gauges, Simon Sitzenstock, Peter Grimm-Wetzel, and Marcel Pastwa for technical support, and Sandy Lang for helpful discussion and very useful comments on an earlier version of this manuscript.

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N2 - Key message: Flow in the phloem increased in developing sweet cherry, whereas xylem flow continuously decreased resulting in a fruit water potential that was independent from the tree at fruit maturity. Abstract: Rain cracking of sweet cherry fruit is associated with water uptake through the skin, but probably also through the vasculature of the pedicel. The aim of this study was to quantify the xylem, phloem, and transpiration contributions to the overall water balance of developing sweet cherry fruit. Using linear variable displacement transducers, changes in fruit diameter were monitored in untreated control fruit, fruit whose pedicels had been steam-girdled, and fruit whose pedicels had been cut through (these fruits were detached, but remained in situ in the canopy). Fruit volume changes with time were inferred from the measured diameter changes. Pedicel xylem and phloem sap-flow rates, and fruit transpiration rates, were inferred from fruit volume changes. Daily phloem flows were low during stage II (phase of pit development), but markedly increased in stage III (phase of cell enlargement in flesh). Xylem flows exceeded phloem flows in stage II, but decreased continuously in stage III to nearly zero at harvest. Transpiration flow essentially mirrored xylem flow in stage II, but exceeded xylem flow in stage III. Transpiration flow was closely related to the water vapour pressure deficit. Phloem flow was linearly related to the increase in fruit dry mass per-unit time. The data reveal a decrease in xylem sap flow throughout stage III resulting in a water-potential isolation of the mature fruit from the tree. Such isolation would prevent uncontrolled osmotic uptake of xylem water by the sugary flesh and a putative backflow in the xylem from fruit to tree.

AB - Key message: Flow in the phloem increased in developing sweet cherry, whereas xylem flow continuously decreased resulting in a fruit water potential that was independent from the tree at fruit maturity. Abstract: Rain cracking of sweet cherry fruit is associated with water uptake through the skin, but probably also through the vasculature of the pedicel. The aim of this study was to quantify the xylem, phloem, and transpiration contributions to the overall water balance of developing sweet cherry fruit. Using linear variable displacement transducers, changes in fruit diameter were monitored in untreated control fruit, fruit whose pedicels had been steam-girdled, and fruit whose pedicels had been cut through (these fruits were detached, but remained in situ in the canopy). Fruit volume changes with time were inferred from the measured diameter changes. Pedicel xylem and phloem sap-flow rates, and fruit transpiration rates, were inferred from fruit volume changes. Daily phloem flows were low during stage II (phase of pit development), but markedly increased in stage III (phase of cell enlargement in flesh). Xylem flows exceeded phloem flows in stage II, but decreased continuously in stage III to nearly zero at harvest. Transpiration flow essentially mirrored xylem flow in stage II, but exceeded xylem flow in stage III. Transpiration flow was closely related to the water vapour pressure deficit. Phloem flow was linearly related to the increase in fruit dry mass per-unit time. The data reveal a decrease in xylem sap flow throughout stage III resulting in a water-potential isolation of the mature fruit from the tree. Such isolation would prevent uncontrolled osmotic uptake of xylem water by the sugary flesh and a putative backflow in the xylem from fruit to tree.

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KW - Prunus avium

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