Identification and Characterization of Novel Plant Adenylate Cyclases – The Arabidopsis Thaliana Potassium Uptake Permeases

Al-Younis, Inas

05 1900

Adenylyl Cyclases (ACs) catalyze the formation of the key universal second messenger adenosine 3’, 5’-cyclic monophosphate (cAMP) from adenosine 5’- triphosphate. Cyclic AMP participates in several signal transduction pathways and is present in bacteria and higher and lower eukaryotes including higher plants. Previous studies in plants have shown a role for cAMP in signal transduction during e.g. the cell cycle, elongation of the pollen tube and stimulation of protein kinase activity. More recently cAMP has been shown to play a role in stress responses. Interestingly, cAMP has also been shown to regulate ion transport in plant cells. Here we used a similar strategy that led to the discovery of the first guanylyl cyclase in plants that was based on the alignment of conserved and functionally assigned amino acids in the catalytic centre of annotated nucleotide cyclases from lower and higher eukaryotes, to identify a novel candidate ACs in Arabidopsis (Arabidopsis thaliana K+ Uptake 5 and 7). ATKUP5 and 7 are homologous to K+ uptake permeases (KUPs) from bacteria and high-affinity K+ transporters (HAKs) from fungi. The AC activity was investigated by recombinantly expressing the ATKUP5 and 7 AC domain in vitro and by complementation of an E. coli AC mutant (cyaA). Furthermore, ATKUP5 was tested for its ability to functionally complement a yeast mutant deficient in Trk1 and Trk2 high affinity potassium uptake transporters. Site-mutagenesis in the AC domain was used to test the effect of both functions in each other. Furthermore, ATKUP5 was characterized electrophysiologically in HEK-293 cells to characterize the nature of this transporter. The localization of the ATKUP5 in Arabidopsis was examined using a Green Fluorescent Protein (GFP) fusion with the ATKUP5 to determine whether ATKUP5 is expressed at the plasma or tonoplast membrane. Arabiodpsis thaliana of the wild type, overexpressing ATKUP5 and atkup5 mutant lines were used to examine phenotypic differences.

Adenylyl Cyclase

Arabidopsis Thaliana

ATKUP5

potassium transporter

signal transduction

cAMP

Cyclic di-AMP homeostasis and osmoregulation in Listeria monocytogenes

Gibhardt, Johannes

31 March 2020

No description available.

570

Listeria monocytogenes

c-di-AMP

osmoregulation

diadenylate cyclase

potassium transporter

cdaA

cdaR

glmM

disA

regulation

Biologie (PPN619462639)

Transports de Na+ et K+ chez le riz : caractérisation de transporteurs et co-transporteurs de Na+ et K+ de la famille HKT / K+ and Na+ transports in rice : characterization of Na+ and K+ transporters and co-transporters of the HKT family

Sassi, Ali

12 December 2011

Un prélèvement efficace de K+ à partir du sol est essentiel au développement des végétaux. Sur un sol riche en NaCl, le maintien d'un prélèvement sélectif et efficace de K+ à partir du sol et le contrôle de l'exportation de Na+ par la racine vers les feuilles constituent des fonctions essentielles pour la survie de la plante. Chez les plantes, les transporteurs HKT (High-affinity K+ Transporters) sont classés en deux sous-familles sur des bases phylogénétiques et de sélectivité ionique. Les membres de la sous-famille 1 transportent sélectivement Na+. Plusieurs d'entre eux ont été identifiés comme des acteurs majeurs de l'adaptation des plantes aux fortes salinités du sol en prévenant l'accumulation de Na+ dans les parties aériennes. Les membres de la sous-famille 2 co-transportent Na+ et K+. Leur rôle dans la plante, notamment dans le transport de K+, est encore mal compris. Je me suis intéressé à différents systèmes de transports de K+ et Na+, appartenant essentiellement à la famille HKT chez le riz. La caractérisation que j'ai effectuée a fait appel à plusieurs approches : électrophysiologie (voltage-clamp après expression en ovocyte de xénope), biologie cellulaire, génétique inverse et PCR en temps réel. L'analyse de l'expression par RT-PCR en temps réel de toute la famille HKT (4 membres dans chacune des deux sous-familles) a montré que ces transporteurs sont différemment exprimés au niveau des racines et des feuilles, et que leur niveau de transcrits est fortement et differentiellement régulé en conditions de stress salin ou osmotique et en présence d'hormones, ce qui suggère que ces différents systèmes jouent des rôles propres et diversifiés dans la plante. L'analyse plus détaillée d'OsHKT2;4, a montré par expression hétérologue dans l'ovocyte de xénope que ce système possède des propriétés fonctionnelles originales: il transporte sélectivement K+ à faibles concentrations de Na+, mais co-transporte Na+ et K+ à fortes concentrations de Na+ (>10 mM). L'analyse de l'expression d'OsHKT2;4 a révélé que ce transporteur est surexprimé en condition de carence en K+ et de stress salin, suggérant qu'OsHKT2;4 pourrait jouer un rôle important dans le transport de K+ dans ces deux conditions. Enfin, un patron d'expression nouveau pour un transporteur HKT a été révélé par l'analyse de plantes transgéniques exprimant le promoteur d'OsHKT2;4 fusionné aux gènes rapporteurs GUS ou GFP : en plus d'une localisation classique dans les tissus conducteurs, une forte expression est observée dans les stomates des gaines et des limbes foliaires, suggérant un rôle dans l'osmocontractilité de ces cellules.Mots clés: Oryza sativa, transport de potassium, transporteur HKT, Na+-K+ co-transporteur, électrophysiologie, ovocyte de xénope, localisation tissulaire, PCR quantitative, stress salin / Efficient uptake of K+ from the soil solution is essential for plant development. When plants are grown on a soil rich in NaCl, the maintenance of an efficient and selective uptake of K+ and the control of Na+ export from roots to shoots are crucial for plant survival. In plants, transporters belonging to the HKT (Highaffinity K+ Transport) family have been sorted in two subfamilies based on phylogenetic grounds and functional properties. Subfamily 1 members transport selectively Na+. Several of them have been shown to play major roles in plant adaptation to salt stress by preventing excessive accumulation of Na+ in shoots. Subfamily 2 members are thought to co-transport Na+ and K+, at least when expressed in heterologous systems. Their roles in planta, especially their potential role in K+ transport, are still largely unknown. I have been interested in different K+ and/or Na+ transport systems in rice, mostly belonging to the HKT family. For their characterization, different approaches have been used: electrophysiology (two-electrode voltage-clamp after expression in Xenopus oocytes), cell biology, reverse genetics and real-time PCR. Realtime RT-PCR analyses on the whole family of rice HKT transporters (4 members in both subfamilies) showed that the expression level in roots and leaves of these different systems is variable, and is differentially regulated by salt and osmotic stresses as well as by hormonal treatments, which suggests that these transporters have diverse and differentiated functions in the plant. A detailed analysis of OsHKT2;4 revealed original functional properties: this HKT transporter was indeed shown to be K+-selectively in the presence of low external Na+, but to switch to Na+ and K+ co-transport mode at high (>10 mM) Na+ concentrations. Expression analysis of OsHKT2;4 showed that this transporter is overexpressed upon salt stress and K+ shortage, which suggests that it could play an important role in K+ transport in these two conditions. At last, a new expression pattern for an HKT transporter was evidenced through the analysis of transgenic rice plants expressing OsHKT2;4 promoter fused to the GUS or GFP reporter genes: in addition to a classical localization in vascular tissues, expression of OsHKT2;4 was observed in stomata, suggesting a role for OsHKT2;4 in osmotic regulation in these cells

Oryza sativa

Transport de potassium

Transporteur HKT

Électrophysiologie

Stress salin

Ovocyte de xénope

Oryza sativa

Potassium transporter

HKT transporter

Electrophysiology

Salt stress

Xenopus oocytes

Real-time PCR