Spelling suggestions: "subject:"auxin transport"" "subject:"yuxin transport""
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Transport auxinu v řasách / Auxin transport in algaeSkokan, Roman January 2014 (has links)
Phytohormone auxin plays an important role in regulating plant development. Directional (polar) cell-to-cell auxin transport creates auxin gradients within plant tissues, which trigger a specific developmental response. The vast majority of available data concerns angiosperms. Lower land plants have been much less explored in this regard, but the important auxin-related mechanisms (including polar auxin transport) are already present in mosses. To uncover the origins of auxin action, one must focus on green algae, especially of clade Streptophyta, which are the direct ancestors of all land plants. In this study, the possible effects of auxins, both native and synthetic, were investigated on two algae: basal, unicellular Chlorella lobophora and advanced, filamentous Spirogyra sp. The latter received comparably more attention, since it belongs to a clade now acknowledged as a sister group to land plants. Chlorella lobophora culture growth was irresponsive to synthetic auxin NAA. The average Spirogyra sp. cell length was, however, changed by auxins at high concentrations. By conducting accumulation assays of radioactively labelled auxins and HPLC analysis, auxin metabolism and transport was investigated in Spirogyra sp. This alga was able to metabolize the plant-native IAA, but not synthetic auxins...
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Etude moléculaire et fonctionnelle du rôle des isoprénoïdes cytosoliques (dolichol et stérol) au cours du développement chez Arabidopsis thaliana / Molecular and functional studies of the role of two cytosolic isoprenoids (dolichol and sterol) in the development of Arabidopsis thalianaJadid, Nurul 02 July 2013 (has links)
Les isoprénoïdes constituent une vaste famille de constituants cellulaires synthétisés chez la plupart des organismes vivants. Chez les plantes, la biosynthèse des isoprénoïdes est réalisée dans trois compartiments : le plaste, le cytoplasme-réticulum endoplasmique et la mitochondrie. Nous avons orienté nos travaux vers l'étude moléculaire et fonctionnelle du rôle de 2 types d'isoprénoïdes cytosoliques (dolichols et stérols) au cours du développement chez les plantes. Pour mener à bien notre étude, nous avons créé des lignées mutantes « knockdown » via la technique de !'ARN interférence (RNAi) et caractérisé des mutant~d'insertion T-DNAs « knockout » pour les gènes d'intérêt chez Arabidopsis.Dans le premier chapitre, nous montrons que les isoprénoïdes sont impliqués de façon indirecte dans la Nglycosylation de protéines via le Dolichol-P-Mannose (Dol-P-Man) dont la synthèse est catalysée par la dolichol phosphate mannose synthase (DPMS). Nous démontrons que chez les plantes, la DPMS est organisée en un complexe hétéromérique localisé dans le réticulum endoplasmique (RE) qui comprend 3 sous unités DPMS1, DPMS2 et DPMS3 codées par 3 gènes. Seule DPMS1 possède une activité catalytique. Les lignées DPMS 1-RNAi et dpms 1 présentent une hypo N-glycosylation des protéines, une forte chlorose et une inhibition de la croissance racinaire. Ces traits sont associés à une hypersensibilité à l'ammonium et à une induction de la« unfolded protein response »au niveau du RE. L'ensemble de ces données montrent que les gènes DPMS jouent un rôle important dans la N-glycosylation des protéines et le développement des plantes.Dans le deuxième chapitre, nous avons porté notre attention sur le rôle des intermédiaires de biosynthèse des stérols («SBls») dans la régulation du développement des plantes en choisissant comme cible ERG28,une protéine impliquée dans le complexe enzymatique de déméthylation en C-4 des stérols « SC4DM ». Nous montrons que ERG28 est localisée dans le RE et assemble 3 enzymes du complexe« SC4DM », la«sterol 4a-methyl oxidase ». la « 4a-carboxysterol-C3-dehydrogenase/C4-decarboxylase » et la « sterone ketoreductase ». Nous démontrons que la perte de fonction de ERG28 dans les lignées ERG28-RNAi eterg28 se traduit par des phénotypes caractéristiques d'une inhibition du transport polaire de l'auxine« PAT»(différenciation d'inflorescence de type «PIN», perte de dominance apicale, fusion des feuilles et inhibition du développement racinaire ... ). Ces phénotypes sont corrélés à l'accumulation de méthylène-cycloartanol-4-carboxy-4-méthyl (MCCM), un« SBI »qui inhibe de façon spécifique le« PAT». Ces données mettent en évidence un nouveau type d'interaction entre l'auxine et les stérols. / Isoprenoids represent important cell constituents synthesized in many living organisms. ln plants, isoprenoid biogenesis occurs in three compartments : plastids, the endoplasmic reticulum-cytosol and mitochondrie.We focused on the molecular and functional studies of the role of Iwo cytosolic isoprenoids ( dolichol andsterol) in the development of plants. The key Io our strategy is the targeted silencing of specific Arabidopsis genes using the RNAi technology (knockdown) and the identification of T-DNA insertion mutants (knockout). ln the first chapter, we show that isoprenoids are involved indirectly in protein N-glycosylation via Dolichol P-Mannose derived from dolichol phosphate mannose synthase (DPMS). We demonstrate that plant DPMSis organized as a heteromeric enzyme complex localized in the endoplasmic reticulum (ER) and consists of DPMS1 acting as the catalytic core and two interacting subunits DPMS2 and DPMS3. The DPMS1-RNAiand dpms1 lines display an altered N-glycosylation pattern and exhibit extensive chlorosis, strong inhibition of root growth and hypersensitivity to ammonium. These phenotypic defects are associated with an «unfolded protein response» in the ER. These data demonstrate that the DPMS genes are essential for the protein N-glycome and plant development. ln the second chapter, we focused on the potentiel roles of sterol biosynthetic intermediates (SBls) in plant development using ERG28 protein, a component of the sterol C-4 demethylation (SC4DM) complex, as a target. We demonstrate that ERG28 is localized in ER and tethers 3 enzymes, sterol 4alpha-methyl oxidase, 4alpha carboxysterol-C3-dehydrogenase/C4- decarboxylase and sterone ketoreductase. We show that the Arabidopsis ERG28-RNAi and erg28 lines develop the hallmarks of altered polar auxin transport (PAT) including the differentiation of pin-like inflorescences, the loss of apical dominance, leaf fusion and inhibition root growth. The observed phenotypes correlate with the accumulation of methylene-cycloartanol-4-carboxy-4-methyl, a cryptic SBI. Our data provide a new level of interaction between sterols and auxin.
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Regulation of Plant Patterning by Polar Auxin TransportMarcos, Danielle 05 September 2012 (has links)
During embryogenesis and post-embryonic patterning, active transport of the phytohormone auxin, reflected in the expression of the Arabidopsis PIN family of auxin efflux mediators, generates local auxin distributions that are crucial for correct organ and tissue specification. Polar auxin transport routes have also long been postulated to regulate vein formation in the leaf. The molecular identification of PIN proteins has made it possible to investigate this hypothesis further by visualizing auxin transport routes in developing leaves.
In Arabidopsis leaf primordia, PIN1 is expressed before the earliest known markers of vascular identity, in domains that are gradually restricted to sites of vein formation. PIN1 polarity indicates that auxin is directed towards distinct “convergence points” (CPs) in the marginal epidermis, from which it defines the sites of major vein formation. Within incipient veins, PIN1 polarity indicates drainage of auxin into preexisting veins, such that veins connected at both ends display two divergent polarities. Local auxin application triggers the formation of ectopic CPs and new veins, demonstrating the sufficiency of auxin as a vein-specifying signal. However, not all PIN1-labeled auxin transport routes differentiate as veins: Minor veins are initially unstable, suggesting local competition for auxin transport. Expression of ATHB8, a marker of vascular cell selection, correlates with enhanced PIN1 expression domain (PED) stability and vascular differentiation. Auxin application and auxin transport inhibition reveal that both CP formation in the epidermis and subepidermal PED dynamics are auxin-dependent and self-organizing. Furthermore, normal auxin perception through the ARF-Aux/IAA signaling pathway is required for the restriction of PIN1-mediated auxin transport to narrow subepidermal domains.
ARF-Aux/IAA signaling is known to control auxin transport through the regulation of PIN1 dynamics, but the mechanism of this regulation is unclear. It is here shown that two redundantly acting AUXIN RESPONSE FACTOR (ARF) transcription factors, ARF5/MONOPTEROS (MP) and ARF7/NPH4, jointly regulate both PIN1 expression and localization during lateral root patterning in Arabidopsis, in part through the direct transcriptional activation of PIN1 by MP. Taken together, these results indicate that feedback between PIN-mediated auxin transport and ARF-Aux/IAA signaling regulates the patterning of root and shoot organs.
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Regulation of Plant Patterning by Polar Auxin TransportMarcos, Danielle 05 September 2012 (has links)
During embryogenesis and post-embryonic patterning, active transport of the phytohormone auxin, reflected in the expression of the Arabidopsis PIN family of auxin efflux mediators, generates local auxin distributions that are crucial for correct organ and tissue specification. Polar auxin transport routes have also long been postulated to regulate vein formation in the leaf. The molecular identification of PIN proteins has made it possible to investigate this hypothesis further by visualizing auxin transport routes in developing leaves.
In Arabidopsis leaf primordia, PIN1 is expressed before the earliest known markers of vascular identity, in domains that are gradually restricted to sites of vein formation. PIN1 polarity indicates that auxin is directed towards distinct “convergence points” (CPs) in the marginal epidermis, from which it defines the sites of major vein formation. Within incipient veins, PIN1 polarity indicates drainage of auxin into preexisting veins, such that veins connected at both ends display two divergent polarities. Local auxin application triggers the formation of ectopic CPs and new veins, demonstrating the sufficiency of auxin as a vein-specifying signal. However, not all PIN1-labeled auxin transport routes differentiate as veins: Minor veins are initially unstable, suggesting local competition for auxin transport. Expression of ATHB8, a marker of vascular cell selection, correlates with enhanced PIN1 expression domain (PED) stability and vascular differentiation. Auxin application and auxin transport inhibition reveal that both CP formation in the epidermis and subepidermal PED dynamics are auxin-dependent and self-organizing. Furthermore, normal auxin perception through the ARF-Aux/IAA signaling pathway is required for the restriction of PIN1-mediated auxin transport to narrow subepidermal domains.
ARF-Aux/IAA signaling is known to control auxin transport through the regulation of PIN1 dynamics, but the mechanism of this regulation is unclear. It is here shown that two redundantly acting AUXIN RESPONSE FACTOR (ARF) transcription factors, ARF5/MONOPTEROS (MP) and ARF7/NPH4, jointly regulate both PIN1 expression and localization during lateral root patterning in Arabidopsis, in part through the direct transcriptional activation of PIN1 by MP. Taken together, these results indicate that feedback between PIN-mediated auxin transport and ARF-Aux/IAA signaling regulates the patterning of root and shoot organs.
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