Abstract
Transpiration, xylem water potential and water channel activity were studied in developing stolons and leaves of strawberry (Fragaria × ananassa Duch.) subjected to drought or flooding, together with morphological studies of their stomata and other surface structures. Stolons had 0.12 stomata mm−2 and a transpiration rate of 0.6 mmol H2O m−2 s−1, while the leaves had 300 stomata mm−2 and a transpiration rate of 5.6 mmol H2O m−2 s−1. Midday water potentials of stolons were always less negative than in leaves enabling nutrient ion and water transport via or to the strawberry stolons. Drought stress, but not flooding, decreased stolon and leaf water potential from −0.7 to −1 MPa and from −1 to −2 MPa, respectively, with a concomitant reduction in stomatal conductance from 75 to 30 mmol H2O m−2 s−1. However, leaf water potentials remained unchanged after flooding. Similarly, membrane vesicles derived from stolons of flooded strawberry plants showed no change in water channel activity. In these stolons, turgor may be preserved by maintaining root pressure, an electrochemical and ion gradient and xylem differentiation, assuming water channels remain open. By contrast, water channel activity was reduced in stolons of drought stressed strawberry plants. In every case, the effect of flooding on water relations of strawberry stolons and leaves was less pronounced than that of drought which cannot be explained by increased ABA. Stomatal closure under drought could be attributed to increased delivery of ABA from roots to the leaves. However, stomata closed more rapidly in leaves of flooded strawberry despite ABA delivery from the roots in the xylem to the leaves being strongly depressed. This stomatal closure under flooding may be due to release of stress ethylene. In the relative absence of stomata from the stolons, cellular (apoplastic) water transport in strawberry stolons was primarily driven by water channel activity with a gradient from the tip of the stolon to the base, concomitant with xylem differentiation and decreased water transport potential from the stolon tip to its base. Reduced water potential in the stolons under drought are discussed with respect to reduced putative water channel activity.
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References
Atkinson C.J. 2002. Strawberry stolons: a life-line for resource sharing and communication. Horticulture Research International, Annual Report for 2001-2002, HRI, Wellesbourne, p. 44.
Blanke M.M. 1990. Guidelines for reporting fruit respiration studies. Gartenbauwissenschaft 55: 282.
Blanke M.M. 1991. Wie sieht ein Erdbeerblatt unter dem Mikroskop aus? Erwerbsobstbau 33: 79–81.
Blanke M.M. 1993. Wie sehen die Blütenknospen der Erdbeere unter dem Mikroskop aus? Erwerbsobstbau 35: 9–12.
Blanke M.M. 2003. Photosynthesis of strawberry fruit. Proceedings of the Fourth Intrenational Strawberry Symposium, Tampere. Acta Horticulturae 567: 373–376.
Blanke M.M. and Cooke D.T. 2000. Respiration and plasma membrane ATPase in strawberry stolons. Plant Growth Regul. 30: 163–170.
Blanke M.M. and Leyhe A. 1988. Cuticular transpiration of the cap and berry of grape. J. Plant Physiol. 132: 250–253.
Blanke M.M., Höfer M. and Pring R. 1994. Stomata and structure of tetraploid apple leaves cultured in vitro. Ann. Botany 73: 651–654.
Deyton D.E., Sams C.E. and Cummins J.C. 1991. Strawberry growth and photosynthetic responses to paclobutrazol. HortScience 26: 1178–1180.
Goodwin P.B. and Gordon A. 1972. The gibberellin-like substances and growth inhibitors in developing strawberry leaves. J. Expt. Bot. 23: 970–979.
Jiang M. and Lenz F. 1993. Das Verhalten von Erdbeerpflanzen bei stauender Näasse. Erwerbsobstbau 33: 112–115.
Leather G.R. and Frank J.R. 1985. Translocation of glyphosate in strawberry stolons. HortScience 20: 70–71.
Sruamsiri P. and Lenz F. 1986. Photosynthese und stomatäares Verhalten bei Erdbeeren (Fragaria xananassa Duch.). VI. Einfluss von Wassermangel. Gartenbauwissenschaft 51: 84–92.
Steudle E. and Clarkson D.T. 1999. Diurnal variations of hydraulic conductivity and root pressure are related to the expression of putative aquaporins in the roots of Lotus japonicus. Planta 210: 50–60.
Steudle E. and Henzler T. 1995. Water channels in plants: do basic concepts of water transport change? J. Expt. Bot. 46: 1067–1076.
Turner N.C. and Long M.J. 1980. Errors arising from rapid water loss in the measurement of leaf water potential by the pressure chamber technique. Aus. J. Plant Physiol. 7: 527–537.
Wibbe M.L. and Blanke M.M. 1997. Effects of fruiting and drought or flooding on carbon balance of apple trees. Photosynthetica 33: 269–275.
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Blanke, M.M., Cooke, D.T. Effects of flooding and drought on stomatal activity, transpiration, photosynthesis, water potential and water channel activity in strawberry stolons and leaves. Plant Growth Regulation 42, 153–160 (2004). https://doi.org/10.1023/B:GROW.0000017489.21970.d4
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DOI: https://doi.org/10.1023/B:GROW.0000017489.21970.d4