Abstract
The pattern of electric signals accompanying compatible and incompatible pollination were studied in pistils of petunia (Petunia hybrida L.) and rape (Brassica napus L). Electric potential was recorded for 4–7 hours with non-polarizable Ag/AgCl electrodes implanted into the ovary and beneath the sigma. At the end of measurements, pistils were fixed and the growth of pollen tubes was analyzed under a fluorescent microscope.
Action potentials appeared in both species. In rape the potential dropped by 10 mV for few minutes after pollination regardless of the compatibility of the cross. In this species, during compatible pollination action potentials with amplitudes of 15–20 mV were recorded up to one hour after pollination. They were followed by a long lasting decrease of the potential by 10 to 50 mV. Contrary, after the self-incompatible pollination, action potentials were rare and of lower amplitudes and the potential gradually raised in comparison to the initial level. During the first hour after the compatible pollination of Petunia hybrida series of action potentials with amplitudes reaching 10–20 mV were recorded. At the time corresponding to the pollen tubes entrance to the transmitting tissue of the style, action potentials reaching up to 40 mV were followed by a steady decrease of the potential. The electric signals traveled along the style with velocity of 25 mm/s. Incompatible pollination in petunia resulted only in minor oscillation and gradual increase of the potential up to 100 mV in comparison to the initial level.
The present investigation demonstrated that each phase of pollen-stigma recognition events, germination and growth of pollen tubes within the style have its characteristic pattern of electric changes which was species specific and depended on compatibility of the cross.
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Abbreviations
- EP:
-
electric potential
- hAP:
-
hours after pollination
- AcP:
-
action potential
References
Arditti J. 1979. Aspects of the physiology of orchids. Adv. Bot. Res. 7: 421–655.
Bednarska E. 1992. Calcium uptake from the stigma by germinating pollen in Primula officinalis L. and Ruscus aculeatus L. Sex. Plant Rep. 4: 36–38.
Bednarska E. 1995. Localization of membrane-associated calcium in unpollinated and pollinated pistil of Petunia hybrida Hort. Acta Soc. Bot. Poloniae 64(1): 19–24.
Bednarska E., Butowt R. 1995. Calcium in pollen — pistil interaction in Petunia hybrida Hort. III. Localization of Ca2+ ions and ATPase in pollinated pistil. Folia Hist. Cytob. 33(2): 125–132.
Clarke A. E., Anderson M. A., Atkinson A., Bacic A., Ebert P. R., Jahnen W., Lush W. M., Mau S.-L., Woodward J. R. 1989. Recent developments in the molecular genetics and biology of self-incompatibility. Plant Mol. Biol. 13: 261–271.
Davies E., Zawadzki T., Witters D. 1991. Electrical activity and signal transmission in plants: How do plants know? In: Plant Signaling, plasma membrane and change of state. ed. by Penel C., Greppen H. Universite de Geneve, Geneva pp.119–137.
Deurenberg J. J. M. 1976 a. In vitro protein synthesis with polysomes from unpollinated, cross- and selfpollinated Petunia ovaries. Planta 128(1): 29–33.
Deurenberg J. J. M. 1976 b. Activation of protein synthesis in ovaries from Petunia hybrida after compatible and incompatible pollination. Acta Bot. Neerl. 25(3): 221–226.
Dickinson H. 1995. Dry stigmas, water and self incompatibility in Brassica. Sex. Plant Reprod. 8: 1–10.
Donk, Van der, J. A. W. M. 1974. Synthesis of RNA and protein as a function of time and type of pollen tubestyle interaction in Petunia hybrida L.. Molec. Genet. 134: 93–94.
Fromm J., Hajirezaei M., Wilke I. 1995. The biochemical response of electric signaling in the reproductive system of Hibiscus plants. Plant Physiol. 109: 375–384.
Gaude T., Dumas C. 1987. Molecular and cellular events of self-incompatibility. Int. Rev. Cytol. 107: 333–366.
Lenartowska M., Bednarska E., Butowt R. 1997. Ca2+ in the pistil of Petunia hybrida Hort. during growth of the pollen tube — cytochemical and radiographic studies. Acta Biol. Crac. ser. Bot. 39: 79–89.
Linskens H. F. 1973. Activation of the ovary. Caryologia. Suppl. 25: 27–41.
Linskens H. F., Spanjers A. W. 1973. Changes of the electric potential in the transmitting tissue of Petunia styles after cross- and self-pollination. Incompatibility Newsletter. 3: 81–85.
Lysikov V., Dukhovnyi A. I. 1966. Izmenenie biopotentsialov v generativnykh organakh kukuruzy. Tr. Kishinievsk. Sel’skokhoz. Inst. 45: 72–75.
Pickard B. G. 1973. Action potentials in higher plants. Bot. Rev. 39: 172–201.
Roberts K. 1992. Potential awareness of plants. Nature 360: 14–15.
Roggen H. P. J. R. 1967. Changes in enzyme activities during the progametic phase in Petunia hybrida. Acta Bot. Neerl. 16: 1–31.
Sinyukhin A. M., Britikov A. A. 1967. Action potentials in the reproductive systems of plants. Nature 215: 1287–1280.
Spanjers A. W. 1981. Bioelectric potential changes in the style of Lilium longiflorum Thumb. after self- and cross-pollination of the stigma. Planta. (153): 1–5.
Wędzony M., Filek M. 1996. Changes of electric potential in wheat pistils induced by pollination. Acta Soc. Bot. Poloniae 65(1–2): 97–100.
Wędzony M., Van Lammeren A. A. M. 1996. Pollen tube growth and early embryogenesis in wheat × maize crosses influenced by 2,4-D. Ann. Bot. 77: 639–649.
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Wędzony, M., Filek, M. Changes of electric potential in pistils of Petunia hybrida Hort. and Brassica napus L. during pollination. Acta Physiol Plant 20, 291–297 (1998). https://doi.org/10.1007/s11738-998-0061-x
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DOI: https://doi.org/10.1007/s11738-998-0061-x