Abstract
Herein, we sought to explore the contribution of cellulose biosynthesis to the shape and morphogenesis of hexagonal seed coat cells in Arabidopsis (Arabidopsis thaliana). Consistent with seed preferential expression of CELLULOSE SYNTHASE9 (CESA9), null mutations in CESA9 caused no change in cellulose content in leaves or stems, but caused a 25% reduction in seeds. Compositional studies of cesa9 seeds uncovered substantial proportional increases in cell wall neutral sugars and in several monomers of cell wall-associated polyesters. Despite these metabolic compensations, cesa9 seeds were permeable to tetrazolium salt, implying that cellulose biosynthesis, via CESA9, is required for correct barrier function of the seed coat. A syndrome of depleted radial wall, altered seed coat cell size, shape, and internal angle uniformity was quantified using scanning electron micrographs in cesa9 epidermal cells. By contrast, morphological defects were absent in cesa9 embryos, visually inspected from torpedo to bent cotyledon, consistent with no reduction in postgermination radical or hypocotyl elongation. These data implied that CESA9 was seed coat specific or functionally redundant in other tissues. Assessment of sections from glutaraldehyde fixed wild-type and cesa9 mature seeds supported results of scanning electron micrographs and quantitatively showed depletion of secondary cell wall synthesis in the radial cell wall. Herein, we show a nonredundant role for CESA9 in secondary cell wall biosynthesis in radial cell walls of epidermal seed coats and document its importance for cell morphogenesis and barrier function of the seed coat.
Highlights
We sought to explore the contribution of cellulose biosynthesis to the shape and morphogenesis of hexagonal seed coat cells in Arabidopsis (Arabidopsis thaliana)
Analysis of developing seed by both scanning electron microscopy (SEM) and sectioning showed that the radial wall was present during early developmental stages in cesa9 (Fig. 4) but failed to show secondary cell wall thickening relative to wild type during the latter stages of development (Fig. 4)
Careful examination of cross-sectioned seed coat cells stained with toluidine blue showed that the secondary cell wall of wild-type cells extended up the entire radial wall whereas in cesa9 the secondary radial wall was less developed
Summary
We sought to explore the contribution of cellulose biosynthesis to the shape and morphogenesis of hexagonal seed coat cells in Arabidopsis (Arabidopsis thaliana). Morphological defects were absent in cesa embryos, visually inspected from torpedo to bent cotyledon, consistent with no reduction in postgermination radical or hypocotyl elongation These data implied that CESA9 was seed coat specific or functionally redundant in other tissues. The formation of the secondary cell wall includes reinforcement of the radial wall that assists in forming the unique hexagonal shapes of testa epidermal cells. This radial wall must inherently possess substantial biomechanical strength. The overarching goal of this study sought to explore cellulose deposition in the uniquely hexagonally shaped epidermal seed coat (testa) cells. With no change observed in embryogenesis, these results inferred intriguing cell type specificity for cellulose biosynthesis in the seed
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