一个新的胼胝质功能:参与蕨类植物气孔复合体的分化和功能。
A new callose function: involvement in differentiation and function of fern stomatal complexes.
机构信息
Department of Botany, Faculty of Biology, University of Athens, Athens, Greece.
出版信息
Plant Signal Behav. 2010 Nov;5(11):1359-64. doi: 10.4161/psb.5.11.12959. Epub 2010 Nov 1.
Abstract
Callose in polypodiaceous ferns performs multiple roles during stomatal development and function. This highly dynamic (1→3)-β-D-glucan, in cooperation with the cytoskeleton, is involved in: (a) stomatal pore formation, (b) deposition of local GC wall thickenings, and (c) the mechanism of stomatal pore opening and closure. This behavior of callose, among others, probably relies on the particular mechanical properties as well as on the ability to form and degrade rapidly, to create a scaffold or to serve as a matrix for deposition of other cell wall materials, and to produce fibrillar deposits in the periclinal GC walls, radially arranged around the stomatal pore. The local callose deposition in closing stomata is an immediate response of the external periclinal GC walls experiencing strong mechanical forces induced by the neighboring cells. The radial callose fibrils transiently co-exist with radial cellulose microfibrils and, like the latter, seem to be oriented via cortical MTs.
摘要
在石松类蕨类植物中,胼胝质在气孔发育和功能中发挥多种作用。这种高度动态的(1→3)-β-D-葡聚糖与细胞骨架合作,参与:(a)气孔孔形成,(b)局部 GC 壁加厚的沉积,以及(c)气孔孔开口和关闭的机制。胼胝质的这种行为,除其他外,可能依赖于特定的机械特性以及快速形成和降解的能力,以创建支架或作为其他细胞壁材料沉积的基质,并在沿气孔孔径向排列的周壁 GC 中产生纤维状沉积物。在关闭气孔时局部胼胝质的沉积是外部周壁 GC 对相邻细胞施加的强烈机械力的即时反应。径向的胼胝质原纤维与径向纤维素微纤维暂时共存,并且与后者一样,似乎通过皮质 MT 定向。
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