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Identification and Characterization of a Mutation Causing Stunted Growth in Arabidopsis that is Linked to Phosphate PerceptionShaikh, Mearaj Ahmed A J 12 1900 (has links)
Plant yield is an agronomic trait dependent on the transport of photosynthate from mature source leaves to sink tissues. Manipulating phloem transport may lead to increased yield, however in a previous study, Arabidopsis thaliana overexpressing sucrose transporter AtSUC2 in the phloem resulted in stunted growth and an apparent P-deficiency. In the course of further characterizing the phenotype and identifying the causative mutation, this research included 1) reverse genetics to test genes hypothesized to modulate carbon-phosphate interactions; 2) whole genome sequencing to identify all T-DNA insertions in plants displaying the phenotype; 3) genetic crosses and segregation analysis to isolate the causative mutation; and 4) transcriptomics to capture gene-expression profiles in plants displaying the phenotype. These phenotypes were traced to a T-DNA insertion located on chromosome 4. Transcriptomics by RNA-Seq and data analysis through bioinformatics pipelines suggest disruptions in metabolic and transport pathways that include phosphate, but do not support a direct role of well-established phosphate acquisition mechanisms. Gene At1G78690 is immediately downstream of the T-DNA insertion site and shows modestly increased expression relative to wild type plants. At1G78690 encodes O-acyl transferase, which is involved in processing N-acylphosphotidyl ethanolamine (NAPE) to N-acyl ethanolamine (NAE). Exogenous NAE application causes stunted growth in specific conditions. From the experiments described herein, At1G78690 emerges as the strongest candidate for causing the observed phenotypes.
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Manipulations of Sucrose/Proton Symporters and Proton-pumping Pyrophosphatase Lead to Enhanced Phloem Transport But Have Contrasting Effects on Plant BiomassKhadilkar, Aswad S 05 1900 (has links)
Delivery of photoassimilate, mainly sucrose (Suc) from photoautotrophic source leaves provides the substrate for the growth and maintenance of sink tissues such as roots, storage tissues, flowers and fruits, juvenile organs, and seeds. Phloem loading is the energized process of accumulating solute in the sieve element/companion cell complex of source leaf phloem to generate the hydrostatic pressure that drives long-distance transport. In many plants this is catalyzed by Suc/Proton (H+) symporters (SUTs) which are energized by the proton motive force (PMF). Overexpression of SUTs was tested as means to enhance phloem transport and plant productivity. Phloem specific overexpression of AtSUC2 in wild type (WT) tobacco resulted in enhanced Suc loading and transport, but against the hypothesis, plants were stunted and accumulated carbohydrates in the leaves, possibly due to lack of sufficient energy to support enhanced phloem transport. The energy for SUT mediated phloem loading is provided from the PMF, which is ultimately supplied by the oxidation of a small proportion of the loaded photoassimilates. It was previously shown that inorganic pyrophosphate (PPi) is necessary for this oxidation and overexpressing a proton-pumping pyrophosphatase (AVP1) enhanced both shoot and root growth, and augmented several energized processes like nutrient acquisition and stress responses. We propose that AVP1 localizes to the PM of phloem cells and uses PMF to synthesize PPi rather than hydrolyze it, and in doing so, maintains PPi levels for efficient Suc oxidation and ATP production. Enhanced ATP production in turn strengthens the PMF via plasma membrane (PM) ATPase, increasing phloem energization and phloem transport. Phloem-specific and constitutive AVP1 overexpressing lines showed increased growth and more efficiently moved carbohydrates to sink organs compared to WT. This suggested changes in metabolic flux but diagnostic metabolites of central metabolism did not show changes in steady state levels. This research focuses on fundamental aspects of carbon utilization and transport, and has a strong applied component, since increased H+-PPase activity enhances plant biomass, nutrient up-take capacities, and stress tolerance for as yet not fully characterized reasons.
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Sodium and calcium uptake, transport and allocation in Populus euphratica and Populus x canescens in response to salinity / Natrium und Kalzium Aufnahme, Transport und Allokation in Populus euphratica und Populus x canescens als Reaktion auf SalinitätHawighorst, Peter 14 December 2007 (has links)
No description available.
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Amino acid and glucose conjugates of a phenylpyrrole compound : synthesis, systemicity and biological properties / Conjugués entre un dérivé phénylpyrrolique et un aminocide ou le glucose : synthèse, systémie et propriétés biologiquesWu, Hanxiang 07 April 2017 (has links)
Le but de notre travail est de développer une stratégie de vectorisation pour conférer la mobilité phloémienne aux produits agrochimiques en appliquant le concept de prodrogue dans l'élaboration de composés phytopharmaceutiques. Le fenpiclonil, fongicide non systémique de la famille des phénylpyrroles, a été choisi comme composé parent modèle et modifié en l'associant à un acide alpha-aminé ou à un monosaccharide.La mobilité phloémienne des conjugués entre le fenpiclonil et les acides L ou D-glutamique ou le D-glucose (D-GFC) a été évaluée chez des plantules de ricin. Le test de systémie a montré que le L-aminoacide était nettement plus favorable à la mobilité phloémienne que l'acide D-aminé ou le D-glucose. Les résultats suggèrent que le conjugué fenpiclonil/L-aminoacide est reconnu et manipulé par un système de transport d'acide aminé stéréospécifique énergisé par la force proton-motrice. Des expériences complémentaires ont montré que le D-GFC était un inhibiteur puissant et sélectif de l'absorption du saccharose par les tissus foliaires et du chargement phloémien du saccharose. En raison de l'inhibition spécifique des transporteurs de saccharose (par exemple AtSUC2), le D-GFC peut être envisagé comme un nouvel outil en phloémologie.Enfin, nous avons exploré l'impact de la modification de structure de l'espaceur afin d'optimiser la stratégie de prodrogue. Après avoir introduit différentes structures d'espaceur entre le fenpiclonil et la fonction acide aminé, le conjugué qui contient un cycle triazole avec l'acide aminé comprenant la chaine la plus courte a montré la meilleure mobilité phloémienne et, par ailleurs, une systémie optimisée par rapport aux dérivés acides du fenpiclonil dans la gamme des valeurs de pH de l'apoplasme foliaire. / The purpose of our work is to develop a vectorization strategy to confer phloem mobility to agrochemicals by applying prodrug concept into agrochemical design. Fenpiclonil, a non-systemic fungicide from the phenylpyrrole family, was selected as a model parent compound and modified by associating it with an amino acid or a monosaccharide.The phloem mobility of L and D-glutamic acid and D-glucose fenpiclonil conjugates (D-GFC) was evaluated in Ricinus seedlings. The systemicity test showed that the L-amino acid promoiety was clearly more favorable to phloem mobility than D-amino acid or D-glucose. The results suggested that the transport of the L-amino acid conjugate is governed by a stereospecific amino acid carrier system energized by the proton motive force. Further investigation indicated that D-GFC was a potent and selective inhibitor of sucrose uptake by leaf tissues and sucrose phloem loading. Due to its specific inhibition of sucrose transporters (e.g. AtSUC2), D-GFC can be a candidate as a new tool in phloemology. Finally, we explored structural modifications of the spacer arm to optimize the prodrug strategy. Different structures of the spacer arm were introduced between fenpiclonil and the amino acid function. The conjugate which contains a triazole ring with the shortest amino acid chain showed the best phloem mobility and a better systemicity than fenpiclonil acidic derivatives within the pH range of the foliar apoplast.
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