Pavement cells are a cell type found in the outmost epidermal layer of plants. The main purpose of these cells is to form a protective layer for the more specialized cells below.[1] The arrangement and undulating geometry of these cells are demonstrated to enhance the epidermal tear resistance by extending the path of cracks and hindering their progression along cell interfaces, thereby preserving the plant epidermal integrity.[2] This layer helps decrease water loss, maintain an internal temperature, keep the inner cells in place, and resist the intrusion of any outside material.[3] They also separate stomata apart from each other as stomata have at least one pavement cell between each other.[4]
They do not have a regular shape. Rather, their irregular shapes help them to interlock with each other like puzzle pieces to form a sturdy layer.[5] This irregular shape that each individual cell takes on can be influenced by the cytoskeleton and specific proteins.[6] As the leaf grows, the pavement cells will also grow, divide, and synthesize new vacuoles, plasma membrane parts, and cell wall components. A thick external cell wall influences the direction of growth by impeding expansion towards the outside of the cell and instead promote expansion parallel to the epidermis layer.[7] Data suggest that waviness of pavement cells may be initiated by buckling due to compressive mechanical stresses resulting from turgor and growth in confined space, with a feedback loop that solidifies and augments cell shapes resulting in local reinforcement of the cell wall.[8][9]
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References
- ^ Glover, B. J. (2000). "Differentiation in plant epidermal cells". Journal of Experimental Botany. 51 (344): 497–505. doi:10.1093/jexbot/51.344.497. PMID 10938806.
- ^ Bidhendi, Amir J.; Lampron, Olivier; Gosselin, Frédérick P.; Geitmann, Anja (December 2023). "Cell geometry regulates tissue fracture". Nature Communications. 14: 8275. doi:10.1038/s41467-023-44075-4. PMC 10719271.
- ^ Qian, P.; Hou, S.; Guo, G. (2009). "Molecular mechanisms controlling pavement cell shape in Arabidopsis leaves". Plant Cell Reports. 28 (8): 1147–1157. doi:10.1007/s00299-009-0729-8. PMID 19529941. S2CID 31893311.
- ^ Bird, S. M.; Gray, J. E. (2003). "Signals from the cuticle affect epidermal cell differentiation". New Phytologist. 157 (1): 9–27. doi:10.1046/j.1469-8137.2003.00543.x. PMID 33873705.
- ^ Glover, B. J. (2000). "Differentiation in plant epidermal cells". Journal of Experimental Botany. 51 (344): 497–505. doi:10.1093/jexbot/51.344.497. PMID 10938806.
- ^ Qian, P.; Hou, S.; Guo, G. (2009). "Molecular mechanisms controlling pavement cell shape in Arabidopsis leaves". Plant Cell Reports. 28 (8): 1147–1157. doi:10.1007/s00299-009-0729-8. PMID 19529941. S2CID 31893311.
- ^ Zhang, C.; Halsey, L. E.; Szymanski, D. B. (2011). "The development and geometry of shape change in Arabidopsis thaliana cotyledon pavement cells". BMC Plant Biology. 11 (11): 27. doi:10.1186/1471-2229-11-27. PMC 3042916. PMID 21284861.
- ^ Bidhendi, Amir J.; Altartouri, Bara; Gosselin, Frédérick P.; Geitmann, Anja (July 2019). "Mechanical stress initiates and sustains the morphogenesis of wavy leaf epidermal cells". Cell Reports. 28 (5): 1237–1250. doi:10.1016/j.celrep.2019.07.006. PMID 31365867.
- ^ Altartouri, Bara; Bidhendi, Amir J.; Tani, Tomomi; Suzuki, Johnny; Conrad, Christina; Chebli, Youssef; Liu, Na; Karunakaran, Chithra; Scarcelli, Giuliano; Geitmann, Anja (2019). "Pectin Chemistry and Cellulose Crystallinity Govern Pavement Cell Morphogenesis in a Multi-Step Mechanism". Plant Physiology. 181 (1): 127–141. doi:10.1104/pp.19.00303. ISSN 1532-2548. PMC 6716242. PMID 31363005.
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This page was last edited on 15 January 2024, at 06:31