Contrasting Effects of Cytoskeleton Disruption on Plasma Membrane Receptor Dynamics: Insights from Single-Molecule Analyses

Leander Rohr, Luiselotte Rausch, Klaus Harter, Sven zur Oven-Krockhaus
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Abstract

Traditional models such as the fluid mosaic model or the lipid raft hypothesis have shaped our understanding of plasma membrane (PM) organization. However, recent discoveries have extended these paradigms by pointing to the existence of micro- and nanodomains. Here, we investigated the role of the cytoskeleton in general and whether the picket fence model, established in animal cells, is transferable to the plant cell system. By using single-particle tracking photoactivated localization microscopy (sptPALM) in combination with genetically encoded enzymatic tools for the targeted disruption of the cytoskeleton, we studied the dynamics and nanoscale organization of a selection of PM receptor-like kinases (RLKs) and receptor-like proteins (RLPs). Our findings show that the disintegration of actin filaments leads to decreased diffusion, more restrictive motion patterns, and enlarged clusters, whereas the disintegration of microtubules results in increased diffusion, more unconstrained diffusive behavior, and decreased cluster sizes of the tested RLKs and RLPs. These results underscore the potential unique regulatory functions of cytoskeleton components in plants and suggest an altered mechanism compared to the picket fence model of the animal cell system. Our qualitative data can serve as the foundation for further investigations aimed at developing a comprehensive and refined model of protein dynamics and organization in plant cells.
细胞骨架破坏对质膜受体动力学的不同影响:单分子分析的启示
流体镶嵌模型或脂筏假说等传统模型塑造了我们对质膜(PM)组织的理解。然而,最近的发现扩展了这些模式,指出了微域和纳米域的存在。在这里,我们研究了细胞骨架的一般作用,以及在动物细胞中建立的篱笆模型是否可以移植到植物细胞系统中。通过使用单颗粒跟踪光激活定位显微镜(sptPALM)结合基因编码的酶工具有针对性地破坏细胞骨架,我们研究了部分 PM 受体样激酶(RLKs)和受体样蛋白(RLPs)的动态和纳米级组织。我们的研究结果表明,肌动蛋白丝的解体会导致扩散减少、运动模式更受限制以及集群增大,而微管的解体则会导致扩散增加、扩散行为更不受限制以及受测 RLKs 和 RLPs 的集群尺寸减小。这些结果突显了细胞骨架成分在植物中潜在的独特调控功能,并表明与动物细胞系统的篱笆模型相比,植物细胞骨架的机制发生了改变。我们的定性数据可作为进一步研究的基础,旨在建立一个全面、精细的植物细胞蛋白质动态和组织模型。
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