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Cellulose assembles into helical bundles of uniform handedness in cell walls with abnormal pectin composition
SUMMARY Plant cells and organs grow into a remarkable diversity of shapes, as directed by cell walls composed primarily of polysaccharides such as cellulose and multiple structurally distinct pectins. The properties of the cell wall that allow for precise control of morphogenesis are distinct from t...
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Published in: | The Plant journal : for cell and molecular biology 2023-08, Vol.116 (3) |
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Main Authors: | , , , , , |
Format: | Article |
Language: | English |
Subjects: | |
Online Access: | Get full text |
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Summary: | SUMMARY
Plant cells and organs grow into a remarkable diversity of shapes, as directed by cell walls composed primarily of polysaccharides such as cellulose and multiple structurally distinct pectins. The properties of the cell wall that allow for precise control of morphogenesis are distinct from those of the individual polysaccharide components. For example, cellulose, the primary determinant of cell morphology, is a chiral macromolecule that can self‐assemble
in vitro
into larger‐scale structures of consistent chirality, and yet most plant cells do not display consistent chirality in their growth. One interesting exception is the
Arabidopsis thaliana rhm1
mutant, which has decreased levels of the pectin rhamnogalacturonan‐I and causes conical petal epidermal cells to grow with a left‐handed helical twist. Here, we show that in
rhm1
the cellulose is bundled into large macrofibrils, unlike the evenly distributed microfibrils of the wild type. This cellulose bundling becomes increasingly severe over time, consistent with cellulose being synthesized normally and then self‐associating into macrofibrils. We also show that in the wild type, cellulose is oriented transversely, whereas in
rhm1
mutants, the cellulose forms right‐handed helices that can account for the helical morphology of the petal cells. Our results indicate that when the composition of pectin is altered, cellulose can form cellular‐scale chiral structures
in vivo
, analogous to the helicoids formed
in vitro
by cellulose nano‐crystals. We propose that an important emergent property of the interplay between rhamnogalacturonan‐I and cellulose is to permit the assembly of nonbundled cellulose structures, providing plants flexibility to orient cellulose and direct morphogenesis. |
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ISSN: | 0960-7412 |