Brassinosteroids (BRs) are plant steroid hormones that control many aspects of plant growth and development. BRs are perceived at the cell-surface by the plasma membrane-localized receptor complex composed of the receptor kinase BRI1 and its co-receptor BAK1. Here we show that BRI1 is post-translationally modified by K63 polyubiquitin chains in vivo. Artificially ubiquitinated BRI1 is recognized at the trans-Golgi Network/Early Endosomes (TGN/EE) and rapidly routed for vacuolar degradation. Mass spectrometry analyses identified residue K866 as an in vivo ubiquitination target in BRI1 involved in the negative regulation of BRI1. Model prediction revealed several redundant ubiquitination sites required for the endosomal sorting and vacuolar targeting of BRI1. Using total internal reflection fluorescence microscopy (TIRF), we also uncovered a role for BRI1 ubiquitination in promoting internalization from the cell-surface. Finally, we demonstrate that the control of BRI1 protein dynamics by ubiquitination is a fundamental control mechanism for BR responses in plants. Altogether, our results identify K63-linked polyubiquitin chain formation as a dual targeting signal for BRI1 internalization and sorting along the endocytic pathway, and highlight its role in hormonally controlled plant development.
In plants, clathrin mediated endocytosis (CME) represents the major route for cargo internalisation from the cell surface. It has been assumed to operate in an evolutionary conserved manner as in yeast and animals. Here we report characterisation of ultrastructure, dynamics and mechanisms of plant CME as allowed by our advancement in electron microscopy and quantitative live imaging techniques. Arabidopsis CME appears to follow the constant curvature model and the bona fide CME population generates vesicles of a predominantly hexagonal-basket type; larger and with faster kinetics than in other models. Contrary to the existing paradigm, actin is dispensable for CME events at the plasma membrane but plays a unique role in collecting endocytic vesicles, sorting of internalised cargos and directional endosome movement that itself actively promote CME events. Internalized vesicles display a strongly delayed and sequential uncoating. These unique features highlight the independent evolution of the plant CME mechanism during the autonomous rise of multicellularity in eukaryotes.
The polybiquitination of proteins can take on different topologies depending on the residue from ubiquitin involved in the chain formation. Although the role of lysine-48 (K48) polyubiquitination in proteasome-mediated degradation is fairly well characterized, much less is understood about the other types of ubiquitin chains and proteasome-independent functions. To overcome this, we developed a K63 polyubiquitin-specific sensor-based approach to track and isolate K63 polyubiquitinated proteins in plants.Proteins carrying K63 polyubiquitin chains were found to be enriched in diverse membrane compartments as well as in nuclear foci. Using liquid chromatography-tandem mass spectrometry, we identified over 100 proteins from Arabidopsis (Arabidopsis thaliana) that are modified with K63 polyubiquitin chains. The K63 ubiquitinome contains critical factors involved in a wide variety of biological processes, including transport, metabolism, protein trafficking, and protein translation. Comparison of the proteins found in this study with previously published nonresolutive ubiquitinomes identified about 70 proteins as ubiquitinated and specifically modified with K63-linked chains. To extend our knowledge about K63 polyubiquitination, we compared the K63 ubiquitinome with K63 ubiquitination networks based on the Arabidopsis interactome. Altogether, this work increases our resolution of the cellular and biological roles associated with this poorly characterized posttranslational modification and provides a unique insight into the networks of K63 polyubiquitination in plants.
No abstract
Endocytosis is a key process in the internalization of extracellular materials and plasma membrane proteins, such as receptors and transporters, thereby controlling many aspects of cell signaling and cellular homeostasis. Endocytosis in plants has an essential role not only for basic cellular functions but also for growth and development, nutrient delivery, toxin avoidance, and pathogen defense. The precise mechanisms of endocytosis in plants remain quite elusive. The lack of direct visualization and examination of single events of endocytosis has greatly hampered our ability to precisely monitor the cell surface lifetime and the recruitment profile of proteins driving endocytosis or endocytosed cargos in plants. Here, we discuss the necessity to systematically implement total internal reflection fluorescence microcopy (TIRF) in the Plant Cell Biology community and present reliable protocols for high spatial and temporal imaging of endocytosis in plants using clathrin-mediated endocytosis as a test case, since it represents the major route for internalization of cell-surface proteins in plants. We developed a robust method to directly visualize cell surface proteins using TIRF microscopy combined to a high throughput, automated and unbiased analysis pipeline to determine the temporal recruitment profile of proteins to single sites of endocytosis, using the departure of clathrin as a physiological reference for scission. Using this ‘departure assay’, we assessed the recruitment of two different AP-2 subunits, alpha and mu, to the sites of endocytosis and found that AP2A1 was recruited in concert with clathrin, while AP2M was not. This validated approach therefore offers a powerful solution to better characterize the plant endocytic machinery and the dynamics of one’s favorite cargo protein.
The phytohormone auxin and its directional transport through tissues are intensively studied. However, a mechanistic understanding of auxin-mediated feedback on endocytosis and polar distribution of PIN auxin transporters remains limited due to contradictory observations and interpretations. Here, we used state-of-the-art methods to reexamine the auxin effects on PIN endocytic trafficking. We used high auxin concentrations or longer treatments versus lower concentrations and shorter treatments of natural (IAA) and synthetic (NAA) auxins to distinguish between specific and nonspecific effects. Longer treatments of both auxins interfere with Brefeldin A-mediated intracellular PIN2 accumulation and also with general aggregation of endomembrane compartments. NAA treatment decreased the internalization of the endocytic tracer dye, FM4-64; however, NAA treatment also affected the number, distribution, and compartment identity of the early endosome/trans-Golgi network (EE/TGN), rendering the FM4-64 endocytic assays at high NAA concentrations unreliable. To circumvent these nonspecific effects of NAA and IAA affecting the endomembrane system, we opted for alternative approaches visualizing the endocytic events directly at the plasma membrane (PM). Using Total Internal Reflection Fluorescence (TIRF) microscopy, we saw no significant effects of IAA or NAA treatments on the incidence and dynamics of clathrin foci, implying that these treatments do not affect the overall endocytosis rate. However, both NAA and IAA at low concentrations rapidly and specifically promoted endocytosis of photo-converted PIN2 from the PM. These analyses identify a specific effect of NAA and IAA on PIN2 endocytosis, thus contributing to its polarity maintenance and furthermore illustrate that high auxin levels have nonspecific effects on trafficking and endomembrane compartments.
Availability of the essential macronutrient nitrogen in soil plays a critical role in plant growth, development, and impacts agricultural productivity. Plants have evolved different strategies for sensing and responding to heterogeneous nitrogen distribution. Modulation of root system architecture, including primary root growth and branching, is among the most essential plant adaptions to ensure adequate nitrogen acquisition. However, the immediate molecular pathways coordinating the adjustment of root growth in response to distinct nitrogen sources, such as nitrate or ammonium, are poorly understood. Here, we show that growth as manifested by cell division and elongation is synchronized by coordinated auxin flux between two adjacent outer tissue layers of the root. This coordination is achieved by nitratedependent dephosphorylation of the PIN2 auxin efflux carrier at a previously uncharacterized phosphorylation site, leading to subsequent PIN2 lateralization and thereby regulating auxin flow between adjacent tissues. A dynamic computer model based on our experimental data successfully recapitulates experimental observations. Our study provides mechanistic insights broadening our understanding of root growth mechanisms in dynamic environments.
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