Data Entry: Please note that the research database will be replaced by UNIverse by the end of October 2023. Please enter your data into the system https://universe-intern.unibas.ch. Thanks

Login for users with Unibas email account...

Login for registered users without Unibas email account...

 
Demethylesterification of Cell Wall Pectins in Arabidopsis Plays a Role in Seed Germination
JournalArticle (Originalarbeit in einer wissenschaftlichen Zeitschrift)
 
ID 1541194
Author(s) Müller, Kerstin; Levesque-Tremblay, Gabriel; Bartels, Sebastian; Weitbrecht, Karin; Wormit, Alexandra; Usadel, Bjoern; Haughn, George; Kermode, Allison R
Author(s) at UniBasel Merker, Sebastian
Year 2013
Title Demethylesterification of Cell Wall Pectins in Arabidopsis Plays a Role in Seed Germination
Journal Plant physiology
Volume 161
Number 1
Pages / Article-Number 305-16
Abstract

The methylesterification status of cell wall homogalacturonans, mediated through the action of pectin methylesterases (PMEs), influences the biophysical properties of plant cell walls such as elasticity and porosity, important parameters for cell elongation and water uptake. The completion of seed germination requires cell wall extensibility changes in both the radicle itself and in the micropylar tissues surrounding the radicle. In wild-type seeds of Arabidopsis (Arabidopsis thaliana), PME activities peaked around the time of testa rupture but declined just before the completion of germination (endosperm weakening and rupture). We overexpressed an Arabidopsis PME inhibitor to investigate PME involvement in seed germination. Seeds of the resultant lines showed a denser methylesterification status of their cell wall homogalacturonans, but there were no changes in the neutral sugar and uronic acid composition of the cell walls. As compared with wild-type seeds, the PME activities of the overexpressing lines were greatly reduced throughout germination, and the low steady-state levels neither increased nor decreased. The most striking phenotype was a significantly faster rate of germination, which was not connected to altered testa rupture morphology but to alterations of the micropylar endosperm cells, evident by environmental scanning electron microscopy. The transgenic seeds also exhibited an apparent reduced sensitivity to abscisic acid with respect to its inhibitory effects on germination. We speculate that PME activity contributes to the temporal regulation of radicle emergence in endospermic seeds by altering the mechanical properties of the cell walls and thereby the balance between the two opposing forces of radicle elongation and mechanical resistance of the endosperm.

Publisher American Society of Plant Biologists
ISSN/ISBN 0032-0889
URL http://www.plantphysiol.org/content/161/1/305.abstract
edoc-URL http://edoc.unibas.ch/dok/A6083331
Full Text on edoc No
Digital Object Identifier DOI 10.1104/pp.112.205724
PubMed ID http://www.ncbi.nlm.nih.gov/pubmed/23129203
ISI-Number WOS:000312964000025
Document type (ISI) Journal Article
 
   

MCSS v5.8 PRO. 0.333 sec, queries - 0.000 sec ©Universität Basel  |  Impressum   |    
16/06/2024