Centre for Plant Sciences, School of Biology, University of Leeds, Leeds, UK.
Plant Cell Environ. 2023 Feb;46(2):391-404. doi: 10.1111/pce.14510. Epub 2022 Dec 19.
Cell walls are essential for plant growth and development, providing support and protection from external environments. Callose is a glucan that accumulates in specialized cell wall microdomains including around intercellular pores called plasmodesmata. Despite representing a small percentage of the cell wall (~0.3% in the model plant Arabidopsis thaliana), callose accumulation regulates important biological processes such as phloem and pollen development, cell division, organ formation, responses to pathogenic invasion and to changes in nutrients and toxic metals in the soil. Callose accumulation modifies cell wall properties and restricts plasmodesmata aperture, affecting the transport of signaling proteins and RNA molecules that regulate plant developmental and environmental responses. Although the importance of callose, at and outside plasmodesmata cell walls, is widely recognized, the underlying mechanisms controlling changes in its synthesis and degradation are still unresolved. In this review, we explore the most recent literature addressing callose metabolism with a focus on the molecular factors affecting callose accumulation in response to mutualistic symbionts and pathogenic elicitors. We discuss commonalities in the signaling pathways, identify research gaps and highlight opportunities to target callose in the improvement of plant responses to beneficial versus pathogenic microbes.
细胞壁对于植物的生长和发育至关重要,为细胞提供支持和保护,使其免受外部环境的影响。胼胝质是一种葡聚糖,在包括细胞间孔(称为胞间连丝)周围的特定细胞壁微域中积累。尽管胼胝质仅占细胞壁的一小部分(在模式植物拟南芥中约占 0.3%),但其积累调节着重要的生物学过程,如韧皮部和花粉的发育、细胞分裂、器官形成、对病原体入侵以及对土壤中养分和有毒金属变化的反应。胼胝质的积累会改变细胞壁的性质并限制胞间连丝的孔径,从而影响调节植物发育和环境反应的信号蛋白和 RNA 分子的运输。尽管人们广泛认识到胼胝质在质膜和胞间连丝细胞壁中的重要性,但控制其合成和降解变化的潜在机制仍未解决。在这篇综述中,我们探讨了最近关于胼胝质代谢的文献,重点介绍了影响胼胝质积累的分子因素,以响应互利共生体和致病性激发子。我们讨论了信号通路的共性,确定了研究空白,并强调了在改善植物对有益和致病微生物的反应时靶向胼胝质的机会。
