@article{2882, abstract = {Gravitropic bending of plant organs is mediated by an asymmetric signaling of the plant hormone auxin between the upper and lower side of the respective organ. Here, we show that also another plant hormone, gibberellic acid (GA), shows asymmetric action during gravitropic responses. Immunodetection using an antibody against GA and monitoring GA signaling output by downstream degradation of DELLA proteins revealed an asymmetric GA distribution and response with the maximum at the lower side of gravistimulated roots. Genetic or pharmacological manipulation of GA levels or response affects gravity-mediated auxin redistribution and root bending response. The higher GA levels at the lower side of the root correlate with increased amounts of PIN-FORMED2 (PIN2) auxin transporter at the plasma membrane. The observed increase in PIN2 stability is caused by a specific GA effect on trafficking of PIN proteins to lytic vacuoles that presumably occurs downstream of brefeldin A-sensitive endosomes. Our results suggest that asymmetric auxin distribution instructive for gravity-induced differential growth is consolidated by the asymmetric action of GA that stabilizes the PIN-dependent auxin stream along the lower side of gravistimulated roots.}, author = {Löfke, Christian and Zwiewka, Marta and Heilmann, Ingo and Van Montagu, Marc and Teichmann, Thomas and Friml, Jirí}, journal = {PNAS}, number = {9}, pages = {3627 -- 3632}, publisher = {National Academy of Sciences}, title = {{Asymmetric gibberellin signaling regulates vacuolar trafficking of PIN auxin transporters during root gravitropism}}, doi = {10.1073/pnas.1300107110}, volume = {110}, year = {2013}, } @article{2883, abstract = {Plant architecture is influenced by the polar, cell-to-cell transport of auxin that is primarily provided and regulated by plasma membrane efflux catalysts of the PIN-FORMED and B family of ABC transporter (ABCB) classes. The latter were shown to require the functionality of the FK506 binding protein42 TWISTED DWARF1 (TWD1), although underlying mechanisms are unclear. By genetic manipulation of TWD1 expression, we show here that TWD1 affects shootward root auxin reflux and, thus, downstream developmental traits, such as epidermal twisting and gravitropism of the root. Using immunological assays, we demonstrate a predominant lateral, mainly outward-facing, plasma membrane location for TWD1 in the root epidermis characterized by the lateral marker ABC transporter G36/PLEIOTROPIC DRUG-RESISTANCE8/PENETRATION3. At these epidermal plasma membrane domains, TWD1 colocalizes with nonpolar ABCB1. In planta bioluminescence resonance energy transfer analysis was used to verify specific ABC transporter B1 (ABCB1)-TWD1 interaction. Our data support a model in which TWD1 promotes lateral ABCB-mediated auxin efflux via protein-protein interaction at the plasma membrane, minimizing reflux from the root apoplast into the cytoplasm.}, author = {Wang, Bangjun and Bailly, Aurélien and Zwiewk, Marta and Henrichs, Sina and Azzarello, Elisa and Mancuso, Stefano and Maeshima, Masayoshi and Friml, Jirí and Schulz, Alexander and Geisler, Markus}, journal = {Plant Cell}, number = {1}, pages = {202 -- 214}, publisher = {American Society of Plant Biologists}, title = {{Arabidopsis TWISTED DWARF1 functionally interacts with auxin exporter ABCB1 on the root plasma membrane}}, doi = {10.1105/tpc.112.105999}, volume = {25}, year = {2013}, } @article{2919, abstract = {The distribution of the phytohormone auxin regulates many aspects of plant development including growth response to gravity. Gravitropic root curvature involves coordinated and asymmetric cell elongation between the lower and upper side of the root, mediated by differential cellular auxin levels. The asymmetry in the auxin distribution is established and maintained by a spatio-temporal regulation of the PIN-FORMED (PIN) auxin transporter activity. We provide novel insights into the complex regulation of PIN abundance and activity during root gravitropism. We show that PIN2 turnover is differentially regulated on the upper and lower side of gravistimulated roots by distinct but partially overlapping auxin feedback mechanisms. In addition to regulating transcription and clathrin-mediated internalization, auxin also controls PIN abundance at the plasma membrane by promoting their vacuolar targeting and degradation. This effect of elevated auxin levels requires the activity of SKP-Cullin-F-box TIR1/AFB (SCF TIR1/AFB)-dependent pathway. Importantly, also suboptimal auxin levels mediate PIN degradation utilizing the same signalling pathway. These feedback mechanisms are functionally important during gravitropic response and ensure fine-tuning of auxin fluxes for maintaining as well as terminating asymmetric growth.}, author = {Baster, Pawel and Robert, Stéphanie and Kleine Vehn, Jürgen and Vanneste, Steffen and Kania, Urszula and Grunewald, Wim and De Rybel, Bert and Beeckman, Tom and Friml, Jirí}, journal = {EMBO Journal}, number = {2}, pages = {260 -- 274}, publisher = {Wiley-Blackwell}, title = {{SCF^TIR1 AFB-auxin signalling regulates PIN vacuolar trafficking and auxin fluxes during root gravitropism}}, doi = {10.1038/emboj.2012.310}, volume = {32}, year = {2013}, } @article{10895, abstract = {Due to their sessile lifestyles, plants need to deal with the limitations and stresses imposed by the changing environment. Plants cope with these by a remarkable developmental flexibility, which is embedded in their strategy to survive. Plants can adjust their size, shape and number of organs, bend according to gravity and light, and regenerate tissues that were damaged, utilizing a coordinating, intercellular signal, the plant hormone, auxin. Another versatile signal is the cation, Ca2+, which is a crucial second messenger for many rapid cellular processes during responses to a wide range of endogenous and environmental signals, such as hormones, light, drought stress and others. Auxin is a good candidate for one of these Ca2+-activating signals. However, the role of auxin-induced Ca2+ signaling is poorly understood. Here, we will provide an overview of possible developmental and physiological roles, as well as mechanisms underlying the interconnection of Ca2+ and auxin signaling. }, author = {Vanneste, Steffen and Friml, Jiří}, issn = {2223-7747}, journal = {Plants}, keywords = {Plant Science, Ecology, Ecology, Evolution, Behavior and Systematics}, number = {4}, pages = {650--675}, publisher = {MDPI}, title = {{Calcium: The missing link in auxin action}}, doi = {10.3390/plants2040650}, volume = {2}, year = {2013}, } @article{2290, abstract = {The plant hormone indole-acetic acid (auxin) is essential for many aspects of plant development. Auxin-mediated growth regulation typically involves the establishment of an auxin concentration gradient mediated by polarly localized auxin transporters. The localization of auxin carriers and their amount at the plasma membrane are controlled by membrane trafficking processes such as secretion, endocytosis, and recycling. In contrast to endocytosis or recycling, how the secretory pathway mediates the localization of auxin carriers is not well understood. In this study we have used the differential cell elongation process during apical hook development to elucidate the mechanisms underlying the post-Golgi trafficking of auxin carriers in Arabidopsis. We show that differential cell elongation during apical hook development is defective in Arabidopsis mutant echidna (ech). ECH protein is required for the trans-Golgi network (TGN)-mediated trafficking of the auxin influx carrier AUX1 to the plasma membrane. In contrast, ech mutation only marginally perturbs the trafficking of the highly related auxin influx carrier LIKE-AUX1-3 or the auxin efflux carrier PIN-FORMED-3, both also involved in hook development. Electron tomography reveals that the trafficking defects in ech mutant are associated with the perturbation of secretory vesicle genesis from the TGN. Our results identify differential mechanisms for the post-Golgi trafficking of de novo-synthesized auxin carriers to plasma membrane from the TGN and reveal how trafficking of auxin influx carriers mediates the control of differential cell elongation in apical hook development.}, author = {Boutté, Yohann and Jonsson, Kristoffer and Mcfarlane, Heather and Johnson, Errin and Gendre, Delphine and Swarup, Ranjan and Friml, Jirí and Samuels, Lacey and Robert, Stéphanie and Bhalerao, Rishikesh}, journal = {PNAS}, number = {40}, pages = {16259 -- 16264}, publisher = {National Academy of Sciences}, title = {{ECHIDNA mediated post Golgi trafficking of auxin carriers for differential cell elongation}}, doi = {10.1073/pnas.1309057110}, volume = {110}, year = {2013}, } @article{507, abstract = {Fertilization in flowering plants requires the temporal and spatial coordination of many developmental processes, including pollen production, anther dehiscence, ovule production, and pollen tube elongation. However, it remains elusive as to how this coordination occurs during reproduction. Here, we present evidence that endocytosis, involving heterotetrameric adaptor protein complex 2 (AP-2), plays a crucial role in fertilization. An Arabidopsis thaliana mutant ap2m displays multiple defects in pollen production and viability, as well as elongation of staminal filaments and pollen tubes, all of which are pivotal processes needed for fertilization. Of these abnormalities, the defects in elongation of staminal filaments and pollen tubes were partially rescued by exogenous auxin. Moreover, DR5rev:GFP (for green fluorescent protein) expression was greatly reduced in filaments and anthers in ap2m mutant plants. At the cellular level, ap2m mutants displayed defects in both endocytosis of N-(3-triethylammonium-propyl)-4- (4-diethylaminophenylhexatrienyl) pyridinium dibromide, a lypophilic dye used as an endocytosis marker, and polar localization of auxin-efflux carrier PIN FORMED2 (PIN2) in the stamen filaments. Moreover, these defects were phenocopied by treatment with Tyrphostin A23, an inhibitor of endocytosis. Based on these results, we propose that AP-2-dependent endocytosis plays a crucial role in coordinating the multiple developmental aspects of male reproductive organs by modulating cellular auxin level through the regulation of the amount and polarity of PINs.}, author = {Kim, Soo and Xu, Zheng and Song, Kyungyoung and Kim, Dae and Kang, Hyangju and Reichardt, Ilka and Sohn, Eun and Friml, Jirí and Juergens, Gerd and Hwang, Inhwan}, journal = {Plant Cell}, number = {8}, pages = {2970 -- 2985}, publisher = {American Society of Plant Biologists}, title = {{Adaptor protein complex 2-mediated endocytosis is crucial for male reproductive organ development in arabidopsis}}, doi = {10.1105/tpc.113.114264}, volume = {25}, year = {2013}, } @article{509, abstract = {Clathrin-mediated endocytosis (CME) regulates many aspects of plant development, including hormone signaling and responses to environmental stresses. Despite the importance of this process, the machinery that regulates CME in plants is largely unknown. In mammals, the heterotetrameric ADAPTOR PROTEIN COMPLEX-2 (AP-2) is required for the formation of clathrin-coated vesicles at the plasma membrane (PM). Although the existence of AP-2 has been predicted in Arabidopsis thaliana, the biochemistry and functionality of the complex is still uncharacterized. Here, we identified all the subunits of the Arabidopsis AP-2 by tandem affinity purification and found that one of the large AP-2 subunits, AP2A1, localized at the PM and interacted with clathrin. Furthermore, endocytosis of the leucine-rich repeat receptor kinase, BRASSINOSTEROID INSENSITIVE1 (BRI1), was shown to depend on AP-2. Knockdown of the two Arabidopsis AP2A genes or overexpression of a dominant-negative version of the medium AP-2 subunit, AP2M, impaired BRI1 endocytosis and enhanced the brassinosteroid signaling. Our data reveal that the CME machinery in Arabidopsis is evolutionarily conserved and that AP-2 functions in receptormediated endocytosis. }, author = {Di Rubbo, Simone and Irani, Niloufer and Kim, Soo and Xu, Zheng and Gadeyne, Astrid and Dejonghe, Wim and Vanhoutte, Isabelle and Persiau, Geert and Eeckhout, Dominique and Simon, Sibu and Song, Kyungyoung and Kleine Vehn, Jürgen and Friml, Jirí and De Jaeger, Geert and Van Damme, Daniël and Hwang, Inhwan and Russinova, Eugenia}, journal = {Plant Cell}, number = {8}, pages = {2986 -- 2997}, publisher = {American Society of Plant Biologists}, title = {{The clathrin adaptor complex AP-2 mediates endocytosis of brassinosteroid INSENSITIVE1 in arabidopsis}}, doi = {10.1105/tpc.113.114058}, volume = {25}, year = {2013}, } @article{511, abstract = {The native auxin, indole-3-acetic acid (IAA), is a major regulator of plant growth and development. Its nonuniform distribution between cells and tissues underlies the spatiotemporal coordination of many developmental events and responses to environmental stimuli. The regulation of auxin gradients and the formation of auxin maxima/minima most likely involve the regulation of both metabolic and transport processes. In this article, we have demonstrated that 2-oxindole-3-acetic acid (oxIAA) is a major primary IAA catabolite formed in Arabidopsis thaliana root tissues. OxIAA had little biological activity and was formed rapidly and irreversibly in response to increases in auxin levels. We further showed that there is cell type-specific regulation of oxIAA levels in the Arabidopsis root apex. We propose that oxIAA is an important element in the regulation of output from auxin gradients and, therefore, in the regulation of auxin homeostasis and response mechanisms.}, author = {Pěnčík, Aleš and Simonovik, Biljana and Petersson, Sara and Henyková, Eva and Simon, Sibu and Greenham, Kathleen and Zhang, Yi and Kowalczyk, Mariusz and Estelle, Mark and Zažímalová, Eva and Novák, Ondřej and Sandberg, Göran and Ljung, Karin}, journal = {Plant Cell}, number = {10}, pages = {3858 -- 3870}, publisher = {American Society of Plant Biologists}, title = {{Regulation of auxin homeostasis and gradients in Arabidopsis roots through the formation of the indole-3-acetic acid catabolite 2-oxindole-3-acetic acid}}, doi = {10.1105/tpc.113.114421}, volume = {25}, year = {2013}, } @article{516, abstract = {In plants, changes in local auxin concentrations can trigger a range of developmental processes as distinct tissues respond differently to the same auxin stimulus. However, little is known about how auxin is interpreted by individual cell types. We performed a transcriptomic analysis of responses to auxin within four distinct tissues of the Arabidopsis thaliana root and demonstrate that different cell types show competence for discrete responses. The majority of auxin‐responsive genes displayed a spatial bias in their induction or repression. The novel data set was used to examine how auxin influences tissue‐specific transcriptional regulation of cell‐identity markers. Additionally, the data were used in combination with spatial expression maps of the root to plot a transcriptomic auxin‐response gradient across the apical and basal meristem. The readout revealed a strong correlation for thousands of genes between the relative response to auxin and expression along the longitudinal axis of the root. This data set and comparative analysis provide a transcriptome‐level spatial breakdown of the response to auxin within an organ where this hormone mediates many aspects of development.}, author = {Bargmann, Bastiaan and Vanneste, Steffen and Krouk, Gabriel and Nawy, Tal and Efroni, Idan and Shani, Eilon and Choe, Goh and Friml, Jirí and Bergmann, Dominique and Estelle, Mark and Birnbaum, Kenneth}, journal = {Molecular Systems Biology}, number = {1}, publisher = {Nature Publishing Group}, title = {{A map of cell type‐specific auxin responses}}, doi = {10.1038/msb.2013.40}, volume = {9}, year = {2013}, } @article{527, abstract = {The apical-basal axis of the early plant embryo determines the body plan of the adult organism. To establish a polarized embryonic axis, plants evolved a unique mechanism that involves directional, cell-to-cell transport of the growth regulator auxin. Auxin transport relies on PIN auxin transporters [1], whose polar subcellular localization determines the flow directionality. PIN-mediated auxin transport mediates the spatial and temporal activity of the auxin response machinery [2-7] that contributes to embryo patterning processes, including establishment of the apical (shoot) and basal (root) embryo poles [8]. However, little is known of upstream mechanisms guiding the (re)polarization of auxin fluxes during embryogenesis [9]. Here, we developed a model of plant embryogenesis that correctly generates emergent cell polarities and auxin-mediated sequential initiation of apical-basal axis of plant embryo. The model relies on two precisely localized auxin sources and a feedback between auxin and the polar, subcellular PIN transporter localization. Simulations reproduced PIN polarity and auxin distribution, as well as previously unknown polarization events during early embryogenesis. The spectrum of validated model predictions suggests that our model corresponds to a minimal mechanistic framework for initiation and orientation of the apical-basal axis to guide both embryonic and postembryonic plant development.}, author = {Wabnik, Krzysztof T and Robert, Hélène and Smith, Richard and Friml, Jirí}, journal = {Current Biology}, number = {24}, pages = {2513 -- 2518}, publisher = {Cell Press}, title = {{Modeling framework for the establishment of the apical-basal embryonic axis in plants}}, doi = {10.1016/j.cub.2013.10.038}, volume = {23}, year = {2013}, } @article{528, abstract = {Establishment of the embryonic axis foreshadows the main body axis of adults both in plants and in animals, but underlying mechanisms are considered distinct. Plants utilize directional, cell-to-cell transport of the growth hormone auxin [1, 2] to generate an asymmetric auxin response that specifies the embryonic apical-basal axis [3-6]. The auxin flow directionality depends on the polarized subcellular localization of PIN-FORMED (PIN) auxin transporters [7, 8]. It remains unknown which mechanisms and spatial cues guide cell polarization and axis orientation in early embryos. Herein, we provide conceptually novel insights into the formation of embryonic axis in Arabidopsis by identifying a crucial role of localized tryptophan-dependent auxin biosynthesis [9-12]. Local auxin production at the base of young embryos and the accompanying PIN7-mediated auxin flow toward the proembryo are required for the apical auxin response maximum and the specification of apical embryonic structures. Later in embryogenesis, the precisely timed onset of localized apical auxin biosynthesis mediates PIN1 polarization, basal auxin response maximum, and specification of the root pole. Thus, the tight spatiotemporal control of distinct local auxin sources provides a necessary, non-cell-autonomous trigger for the coordinated cell polarization and subsequent apical-basal axis orientation during embryogenesis and, presumably, also for other polarization events during postembryonic plant life [13, 14].}, author = {Robert, Hélène and Grones, Peter and Stepanova, Anna and Robles, Linda and Lokerse, Annemarie and Alonso, Jose and Weijers, Dolf and Friml, Jirí}, journal = {Current Biology}, number = {24}, pages = {2506 -- 2512}, publisher = {Cell Press}, title = {{Local auxin sources orient the apical basal axis in arabidopsis embryos}}, doi = {10.1016/j.cub.2013.09.039}, volume = {23}, year = {2013}, }