Effects of De- and Rehydration on Food-conducting Cells in the Moss Polytrichum formosum: A Cytological Study

doi:10.1093/aob/mcl092

AOBPreview originally published online on May 30, 2006
Annals of Botany 2006 98(1):67-76; doi:10.1093/aob/mcl092

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Effects of De- and Rehydration on Food-conducting Cells in the Moss Polytrichum formosum: A Cytological Study

SILVIA PRESSEL¹^,*, ROBERTO LIGRONE² and JEFFREY G. DUCKETT¹

¹ School of Biological Sciences, Queen Mary University of London, Mile End Road, London E1 4NS, UK and ² Dipartimento di Scienze ambientali, Seconda Università di Napoli, via A. Vivaldi 43, 81100 Caserta, Italy

^* For correspondence. E-mail s.pressel{at}qmul.ac.uk

Received: 9 November 2005 Returned for revision: 16 December 2005 Accepted: 21 March 2006 Published electronically: 30 May 2006

• Background and Aims Moss food-conducting cells (leptoidsand specialized parenchyma cells) have a highly distinctivecytology characterized by a polarized cytoplasmic organizationand longitudinal alignment of plastids, mitochondria, endoplasmicreticulum and vesicles along endoplasmic microtubules. Previousstudies on the desiccation biology of mosses have focused almostexclusively on photosynthetic tissues; the effects of desiccationon food-conducting cells are unknown. Reported here is a cytologicalstudy of the effects of de- and rehydration on food-conductingcells in the desiccation-tolerant moss Polytrichum formosumaimed at exploring whether the remarkable subcellular organizationof these cells is related to the ability of mosses to survivedesiccation.

• Methods Shoots of Polytrichum formosum were dehydratedunder natural conditions and prepared for transmission and scanningelectron microscopy using both standard and anhydrous chemicalfixation protocols. Replicate samples were then fixed at intervalsover a 24-h period following rehydration in either water orin a 10 µM solution of the microtubule-disrupting drugoryzalin.

• Key Results Desiccation causes dramatic changes; theendoplasmic microtubules disappear; the nucleus, mitochondriaand plastids become rounded and the longitudinal alignment ofthe organelles is lost, though cytoplasmic polarity is in partretained. Prominent stacks of endoplasmic reticulum, typicalof the hydrated condition, are replaced with membranous tubulesarranged at right angles to the main cellular axis. The internalcytoplasm becomes filled with small vacuoles and the plasmalemmaforms labyrinthine tubular extensions outlining newly depositedingrowths of cell wall material. Whereas plasmodesmata in meristematiccells at the shoot apex and in stem parenchyma cells appearto be unaffected by dehydration, those in leptoids become pluggedwith electron-opaque material. Starch deposits in parenchymacells adjoining leptoids are depleted in desiccated plants.Rehydration sees complete reestablishment over a 12- to 24-hperiod of the cytology seen in the control plants. Oryzalineffectively prevents leptoid recovery.

• Conclusions The results point to a key role of the microtubularcytoskeleton in the rapid re-establishment of the elaboratecytoplasmic architecture of leptoids during rehydration. Thereassembly of the endoplasmic microtubule system appears todictate the time frame for the recovery process. The failureof leptoids to recover normal cytology in the presence of oryzalinfurther underlines the key role of the microtubules in the controlof leptoid cytological organization.

Key words: Bryophytes, desiccation-tolerance, microtubules, oryzalin, plasmodesmata, Polytrichum formosum, rehydration, vascular tissue

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