TY - JOUR AB - Flowers have a species-specific functional life span that determines the time window in which pollination, fertilization and seed set can occur. The stigma tissue plays a key role in flower receptivity by intercepting pollen and initiating pollen tube growth toward the ovary. In this article, we show that a developmentally controlled cell death programme terminates the functional life span of stigma cells in Arabidopsis. We identified the leaf senescence regulator ORESARA1 (also known as ANAC092) and the previously uncharacterized KIRA1 (also known as ANAC074) as partially redundant transcription factors that modulate stigma longevity by controlling the expression of programmed cell death-associated genes. KIRA1 expression is sufficient to induce cell death and terminate floral receptivity, whereas lack of both KIRA1 and ORESARA1 substantially increases stigma life span. Surprisingly, the extension of stigma longevity is accompanied by only a moderate extension of flower receptivity, suggesting that additional processes participate in the control of the flower's receptive life span. AU - Gao, Zhen AU - Daneva, Anna AU - Salanenka, Yuliya AU - Van Durme, Matthias AU - Huysmans, Marlies AU - Lin, Zongcheng AU - De Winter, Freya AU - Vanneste, Steffen AU - Karimi, Mansour AU - Van De Velde, Jan AU - Vandepoele, Klaas AU - Van De Walle, Davy AU - Dewettinck, Koen AU - Lambrecht, Bart AU - Nowack, Moritz ID - 280 IS - 6 JF - Nature Plants TI - KIRA1 and ORESARA1 terminate flower receptivity by promoting cell death in the stigma of Arabidopsis VL - 4 ER - TY - JOUR AB - The angiosperm seed is composed of three genetically distinct tissues: the diploid embryo that originates from the fertilized egg cell, the triploid endosperm that is produced from the fertilized central cell, and the maternal sporophytic integuments that develop into the seed coat1. At the onset of embryo development in Arabidopsis thaliana, the zygote divides asymmetrically, producing a small apical embryonic cell and a larger basal cell that connects the embryo to the maternal tissue2. The coordinated and synchronous development of the embryo and the surrounding integuments, and the alignment of their growth axes, suggest communication between maternal tissues and the embryo. In contrast to animals, however, where a network of maternal factors that direct embryo patterning have been identified3,4, only a few maternal mutations have been described to affect embryo development in plants5–7. Early embryo patterning in Arabidopsis requires accumulation of the phytohormone auxin in the apical cell by directed transport from the suspensor8–10. However, the origin of this auxin has remained obscure. Here we investigate the source of auxin for early embryogenesis and provide evidence that the mother plant coordinates seed development by supplying auxin to the early embryo from the integuments of the ovule. We show that auxin response increases in ovules after fertilization, due to upregulated auxin biosynthesis in the integuments, and this maternally produced auxin is required for correct embryo development. AU - Robert, Hélène AU - Park, Chulmin AU - Gutièrrez, Carla AU - Wójcikowska, Barbara AU - Pěnčík, Aleš AU - Novák, Ondřej AU - Chen, Junyi AU - Grunewald, Wim AU - Dresselhaus, Thomas AU - Friml, Jirí AU - Laux, Thomas ID - 158 IS - 8 JF - Nature Plants TI - Maternal auxin supply contributes to early embryo patterning in Arabidopsis VL - 4 ER - TY - JOUR AB - AtNHX5 and AtNHX6 are endosomal Na+,K+/H+ antiporters that are critical for growth and development in Arabidopsis, but the mechanism behind their action remains unknown. Here, we report that AtNHX5 and AtNHX6, functioning as H+ leak, control auxin homeostasis and auxin-mediated development. We found that nhx5 nhx6 exhibited growth variations of auxin-related defects. We further showed that nhx5 nhx6 was affected in auxin homeostasis. Genetic analysis showed that AtNHX5 and AtNHX6 were required for the function of the ER-localized auxin transporter PIN5. Although AtNHX5 and AtNHX6 were co-localized with PIN5 at ER, they did not interact directly. Instead, the conserved acidic residues in AtNHX5 and AtNHX6, which are essential for exchange activity, were required for PIN5 function. AtNHX5 and AtNHX6 regulated the pH in ER. Overall, AtNHX5 and AtNHX6 may regulate auxin transport across the ER via the pH gradient created by their transport activity. H+-leak pathway provides a fine-tuning mechanism that controls cellular auxin fluxes. AU - Fan, Ligang AU - Zhao, Lei AU - Hu, Wei AU - Li, Weina AU - Novák, Ondřej AU - Strnad, Miroslav AU - Simon, Sibu AU - Friml, Jirí AU - Shen, Jinbo AU - Jiang, Liwen AU - Qiu, Quan ID - 462 JF - Plant, Cell and Environment TI - NHX antiporters regulate the pH of endoplasmic reticulum and auxin-mediated development VL - 41 ER - TY - JOUR AB - The phytohormone auxin is the information carrier in a plethora of developmental and physiological processes in plants(1). It has been firmly established that canonical, nuclear auxin signalling acts through regulation of gene transcription(2). Here, we combined microfluidics, live imaging, genetic engineering and computational modelling to reanalyse the classical case of root growth inhibition(3) by auxin. We show that Arabidopsis roots react to addition and removal of auxin by extremely rapid adaptation of growth rate. This process requires intracellular auxin perception but not transcriptional reprogramming. The formation of the canonical TIR1/AFB-Aux/IAA co-receptor complex is required for the growth regulation, hinting to a novel, non-transcriptional branch of this signalling pathway. Our results challenge the current understanding of root growth regulation by auxin and suggest another, presumably non-transcriptional, signalling output of the canonical auxin pathway. AU - Fendrych, Matyas AU - Akhmanova, Maria AU - Merrin, Jack AU - Glanc, Matous AU - Hagihara, Shinya AU - Takahashi, Koji AU - Uchida, Naoyuki AU - Torii, Keiko U AU - Friml, Jirí ID - 192 IS - 7 JF - Nature Plants TI - Rapid and reversible root growth inhibition by TIR1 auxin signalling VL - 4 ER - TY - JOUR AB - The intercellular transport of auxin is driven by PIN-formed (PIN) auxin efflux carriers. PINs are localized at the plasma membrane (PM) and on constitutively recycling endomembrane vesicles. Therefore, PINs can mediate auxin transport either by direct translocation across the PM or by pumping auxin into secretory vesicles (SVs), leading to its secretory release upon fusion with the PM. Which of these two mechanisms dominates is a matter of debate. Here, we addressed the issue with a mathematical modeling approach. We demonstrate that the efficiency of secretory transport depends on SV size, half-life of PINs on the PM, pH, exocytosis frequency and PIN density. 3D structured illumination microscopy (SIM) was used to determine PIN density on the PM. Combining this data with published values of the other parameters, we show that the transport activity of PINs in SVs would have to be at least 1000× greater than on the PM in order to produce a comparable macroscopic auxin transport. If both transport mechanisms operated simultaneously and PINs were equally active on SVs and PM, the contribution of secretion to the total auxin flux would be negligible. In conclusion, while secretory vesicle-mediated transport of auxin is an intriguing and theoretically possible model, it is unlikely to be a major mechanism of auxin transport inplanta. AU - Hille, Sander AU - Akhmanova, Maria AU - Glanc, Matous AU - Johnson, Alexander J AU - Friml, Jirí ID - 14 IS - 11 JF - International Journal of Molecular Sciences TI - Relative contribution of PIN-containing secretory vesicles and plasma membrane PINs to the directed auxin transport: Theoretical estimation VL - 19 ER -