Le couplage nitrate/proton au sein de l’échangeur AtClCa est essentiel à la physiologie de la plante en réponse aux fluctuations environnementales / Nitrate/proton coupling in AtClCa exchanger is required for plant physiology in response to environment fluctuations

Hodin, Julie

20 June 2018

Chez les plantes, le nitrate est un élément essentiel mais sa disponibilité dans le sol est fluctuante. Il est donc stocké dans la vacuole grâce à un échangeur nitrate/proton appelé AtClCa. La famille de protéines ClCs comporte à la fois des échangeurs mais aussi des canaux suggérés comme issus de l’évolution des échangeurs par une conversion mécanistique. Chez Arabidopsis thaliana, seuls des ClCs échangeurs assurent la gestion du nitrate. Deux glutamates très conservés, E203 et E270 dans AtClCa, sont essentiels pour le transport des protons chez les ClCs échangeurs. La mutation du résidu E203 en une alanine, un acide aminé non protonable (E203A) a permis de produire artificiellement une telle conversion mécanistique. Afin de mieux comprendre l’importance physiologique du mécanisme d’échange, une analyse a été conduite sur des plantes exprimant la forme mutée d’AtClCa pour ce glutamate. Chez ces plantes, le stockage vacuolaire est fortement réduit au profit d’une importante assimilation accroissant la teneur en protéines. En dépit de cela, elles présentent un défaut de production de biomasse résultant en grande partie d’une perturbation de l’homéostasie hydrique. Elles sont également plus sensibles aux stress hydrique et probablement azoté. La conservation d’un échangeur est donc requise pour croitre en dépit des fluctuations environnementales. En parallèle, la mutation E270A a été introduite en plante afin d’étudier son importance sur la physiologie d’Arabidopsis. Une analyse préliminaire de la biomasse et des contenus en nitrate et eau de plantes exprimant la forme mutée de ce glutamate est donc présentée dans la seconde partie de cette thèse. / Nitrate is a major element for plant but its availability is very fluctuant in soils. Then, it is stored in vacuoles thanks to a nitrate/proton exchanger named AtClCa. In ClCs, exchangers but also channels were identified, the latest were suggested to be evolved from exchanger in which a mechanistic switch happened. In Arabidopsis thaliana, only exchangers are involved in nitrate management. Two conserved glutamate, E203 and E270 in AtClCa, are essential for protons transport in ClCs exchangers. The mutation of E203 into an alanine, a non-protonable amino acid (E203A) artificially produces such a mechanistic switch. To better understand the physiological importance of this exchange mechanism, a study was conducted in plants expressing the mutated form of AtClCa for this glutamate. In those plants, the vacuolar storage is highly restricted whereas the assimilation is favoured and the protein content increased. Despite that, the biomass production is decreased mostly because of a hydric homeostasis disruption. Those plants are also more sensitive to hydric and probably nitrogenous stress. The exchanger conservation is then required for plant growth whatever the environmental fluctuations. In parallel, the mutation E270A was introduced in planta to study its physiological importance. A preliminary analysis of plant biomass and nitrate and water contents was then performed in plants expressing the E270A mutated form of AtClCa and the results are presented in the second part of the manuscript.

Transporteur de nitrate

Couplage

Physiologie moléculaire

Vacuole

Stockage

Échangeur

Résidus conservés

Vacuole

Gating

Nitrate transporter

Molecular physiology

Storage

Exchanger

Conserved residues

Exploring The Role Of The Highly Conserved Residues In Triosephosphate Isomerase

Samanta, Moumita

05 1900

This thesis discusses the structure-function studies on triosephosphate isomerase (TIM) from Plasmodium falciparum (Pf), directed towards understanding the roles of highly conserved residues by site derected mutagenesis. Chapter 1 provides an introductory overview to the relevant literature on triosephosphate isomerase. In addition, this Chapter provides an analysis of conserved residues in TIM, and amino acid diversity at specific positions in the structure using a dataset of 503 TIM sequences. Chapter 2 reports the work on the completely conserved residue, C126 in TIM, which is proximal to the active site. Five mutants, C126S, C126A, C126V, C126M and C126T have been characterized. Crystal structures of 3-phosphoglycolate (PGA) bound C126S mutant and the unliganded forms of the C126S and C126A mutants have been determined at a resolution of 1.7 Å to 2.1 Å. Kinetic studies reveal a ~5 fold drop in kcat for the C126S and C126A mutants, while a ~ 10 fold drop is observed for the other three mutants. All the mutants show reduced stability at lower concentration and higher temperature. Chapter 3 presents the kinetic and structural characterization for the E97Q and E97D mutants of Pf TIM. A 4000 fold reduction in kcat is observed for E97Q, 100 fold reduction for the E97D mutant, while a ~ 9000 fold drop in activity for the control mutant, E165A. A large conformational change for the critical K12 side chain is observed in the crystal structure of the E97Q mutant, while it remains unchanged in the E97D structure. The results are interpreted to invoke a direct role for E97 in the catalytic proton transfer cycle, eliminating the need to invoke the formation of the energetically unfavorable imidazolate anion at H95. Chapter 4 reports investigations with position 96 by the biochemical and structural characterization of single mutants, F96Y, F96A and the double mutants, F96S/S73A and F96S/L167V. F96Y showed ~100 fold drop in activity, F96A revealed ~10 fold drop in activity, while F96S/S73A showed 100 fold lower activity than that of the wild type enzyme. Interestingly, the double mutant F96S/L167V proved to be a partial pseudorevertant, showing 10 fold higher activity than the single mutant, F96S. Chapter 5 describes the cloning, and preliminary kinetic and biophysical characterization of the enzyme, Dm TIM. A survey of disease causing mutations in TIM and the relationship of these sites of mutation to the active site and the dimer interface of TIM is presented in this Chapter.

Triosephospate Isomerase - Residues

Conserved Residues in Reactions

Mutagenesis

Triosephosphate Isomerase - Cloning

Triosephosphate Isomerase - Structure

Drosophila melanogaster

Cys 126 Residue

Glutamic Acid 97 Residue

Biochemistry