Abstract
ABSTRACTPlant cell expansion is a dynamic process that is physically constrained by the deposition of new cell wall components. During tip growth, new cell wall materials are delivered at a restricted plasma membrane domain which results in a highly polarized expansion within that specified domain. Previous studies demonstrated that this process requires the activities of members of theCellulose Synthase-Like D (CSLD)subfamily of cell wall synthases. CSLD3 displays β-1,4 glucan synthase activity, but whether other members of CSLD subfamily share this conserved biochemical activity, and whether CSLD proteins form higher-order complexes to perform β-1,4 glucan synthase activities have not been determined. Here, we use genetic methods to demonstrate that CSLD2 and CSLD3 functions are interchangeable during root hair elongation and cell plate formation, while CSLD5 provides a unique and irreplaceable function in the formation of cell plates. Importantly, genetic analysis with inactivated versions of CSLD3 show that, unlike CESA proteins, CSLDs do not require the simultaneous presence of different isoforms to perform catalytic cell wall synthase activities.In vitrobiochemical activity experiments confirmed that CSLD2, CSLD3, and CSLD5 proteins displayed β-1,4 glucan synthases activities. Taken together, these results indicated that while all three vegetatively expressed CSLD proteins possess conserved β-1,4 glucan synthase activities, that CSLD5 has a more complicated and specialized role during cell plate formation.
Publisher
Cold Spring Harbor Laboratory
Cited by
1 articles.
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1. Structure and growth of plant cell walls;Nature Reviews Molecular Cell Biology;2023-12-15