Pollen tubes exhibit regular periodic membrane trafficking events in the absence of apical extension

doi:10.1242/jcs.00468

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First published online 13 May 2003
doi: 10.1242/jcs.00468

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Journal of Cell Science 116, 2707-2719 (2003)
doi: 10.1242/jcs.00468

Research Article

Pollen tubes exhibit regular periodic membrane trafficking events in the absence of apical extension

Richard M. Parton^*, Sabine Fischer-Parton, Anthony J. Trewavas and Masaaki K. Watahiki

Institute of Cell and Molecular Biology, University of Edinburgh, Mayfield Road, Edinburgh EH9 3JU, UK

^* Author for correspondence (e-mail: richard.parton{at}ed.ac.uk)

Accepted 10 March 2003

The growing pollen tube provides an excellent single cell modelsystem in which to study the mechanisms determining growth regulation,polarity and periodic behaviour. Previously, using FM4-64, weidentified periodic movements within the apical vesicle accumulationthat were related to the period of oscillatory growth. Thissuggested a more complex interdependence between membrane traffic,apical extension and periodicity than previously thought. To investigatethis a comparison was made between normally growing and Brefeldin-A-treated,non-growing, tubes. Brefeldin-A treatment established an intriguing,stable yet dynamic system of membrane aggregations in the pollen tubetip that exhibited regular movements of material with a 5-7second period compared with the normal $~$ 30 second periodicityobserved in growing tubes. Heat treatment was found to reduceperiod length in both cases. After BFA treatment membrane wasdemonstrated to flow from the extreme pollen tube apex backthrough a distinct subapical Brefeldin-A-induced membrane accumulation. Theeffects of Brefeldin-A on the distribution of ER- and Golgi-targeted fluorescentproteins revealed that ER did not contribute directly to the systemof membrane aggregations while only certain compartments ofthe Golgi might be involved. The involvement of membrane derivedfrom the apical vesicle accumulation was strongly implicated.Calcium measurements revealed that Brefeldin-A abolished thetypical tip-focused calcium gradient associated with growthand there were no obvious periodic fluctuations in apical calcium associatedwith the continued periodic Brefeldin-A membrane aggregation associatedmovements. Our experiments reveal an underlying periodicityin the pollen tube that is independent of secretion, apicalextension and the oscillating tip-focused calcium gradient normallyassociated with growth, but requires an active actin cytoskeleton.

Key words: Oscillating growth, Pollen tube, Brefeldin A, Membrane trafficking

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