Functional characterization of AtTPK3 potassium channel of Arabidopsis thaliana

My Ph.D. project has focused on the characterization of TPK3, a putative channel selective for potassium (K+) with a predicted chloroplast localization in higher plants, from biochemical, physiological and electrophysiological point of view. This protein belongs to the TPK channel family (from Tandem-Pore K+ channels) and displays amino acid sequence homology with another K+ channel studied in our laboratory, called SynK (Zanetti et al., 2010). SynK shows thylakoid localization in Cyanobacteria. The SynK channel has been shown to be critical for photosynthetic performances in Cyanobacteria, given the photosensitive phenotype displayed by the mutants lacking the SynK protein. Given the homology, we hypothesized that similarly, TPK3 might be involved in the regulation of photosynthetic processes in higher plants. So far, no information is available about the properties of TPK3, nor about its physiological roles, neither about its possible involvement in photosynthesis; the work presented in this thesis had the aim of clarifying some important aspects of the functions of TPK3. Following subcellular localization studies carried out using biochemistry and confocal microscopy techniques, the TPK3 channel was expressed in E. coli cells for subsequent electrophysiological characterization in a planar lipid bilayer setup in order to prove its function as K+ channel. The unavailability of commercial mutants for tpk3 gene required setting up of a silencing procedure via RNA interference of the messenger for the protein, in order to analyze the possible physiological roles of TPK3. The resulting silenced plants have been studied under different growth conditions to determine changes in physiology of the plants including their photosynthetic parameters. In parallel with the TPK3 project, the most important part of my Ph.D., I also followed two other major areas of research: one concerning the study of the functions of two members of plant Glutamate Receptors (GluRs) and the other one concerning the characterization of the plant homologous of the recently identified MCU (Mitochondrial Calcium Uniporter) of mammals. This thesis also includes a manuscript (Checchetto et al., 2012) to which I contributed with the heterologous expression of a calcium-activated K+ channel, SynCaK, of Cyanobacteria

Dissecting stimulus-specific Ca2+ signals in amyloplasts and chloroplasts of Arabidopsis thaliana cell suspension cultures

Calcium is used by plants as an intracellular messenger in the detection of and response to a plethora of environmental stimuli and contributes to a fine-tuned internal regulation. Interest in the role of different subcellular compartments in Ca(2+) homeostasis and signalling has been growing in recent years. This work has evaluated the potential participation of non-green plastids and chloroplasts in the plant Ca(2+) signalling network using heterotrophic and autotrophic cell suspension cultures from Arabidopsis thaliana plant lines stably expressing the bioluminescent Ca(2+) reporter aequorin targeted to the plastid stroma. Our results indicate that both amyloplasts and chloroplasts are involved in transient Ca(2+) increases in the plastid stroma induced by several environmental stimuli, suggesting that these two functional types of plastids are endowed with similar mechanisms for handling Ca(2+). A comparison of the Ca(2+) trace kinetics recorded in parallel in the plastid stroma, the surface of the outer membrane of the plastid envelope, and the cytosol indicated that plastids play an essential role in switching off different cytosolic Ca(2+) signals. Interestingly, a transient stromal Ca(2+) signal in response to the light-to-dark transition was observed in chloroplasts, but not amyloplasts. Moreover, significant differences in the amplitude of specific plastidial Ca(2+) changes emerged when the photosynthetic metabolism of chloroplasts was reactivated by light. In summary, our work highlights differences between non-green plastids and chloroplasts in terms of Ca(2+) dynamics in response to environmental stimuli

Experimental study on coalescer efficiency for liquid-liquid separation

The global community acknowledges water demand and accessibility as major challenges impacting human well-being. Forward Osmosis (FO) desalination coupled with concentrate solar power might represent a promising solution to combine water production with renewable sources. This work assesses the performance of a liquid-liquid separator (coalescer), an important component of the FO process, when using a polymeric thermo-responsive draw agent (PAGB2000). Experimental characterization of the coalescer is carried out for different regeneration temperatures (from 50 to 80 °C), residence time, draw concentration (from 0.30 to 0.60) and metal meshes. The separation efficiency of the coalescer can be as high as 95% for high residence time and regeneration temperatures (> 70 °C). Eventually, an analytical expression of the coalescer efficiency as function of the main operating parameters is proposed both to support desalination plant design and to enable understanding its applicability beyond its original context

Monitoring calcium handling by the plant endoplasmic reticulum with a low‐Ca 2+ ‐affinity targeted aequorin reporter

Precise measurements of dynamic changes in free Ca2+ concentration in the lumen of the plant endoplasmic reticulum (ER) have been lacking so far, despite increasing evidence for the contribution of this intracellular compartment to Ca2+ homeostasis and signalling in the plant cell. In the present study, we targeted an aequorin chimera with reduced Ca2+ affinity to the ER membrane and facing the ER lumen. To this aim, the cDNA for a low-Ca2+-affinity aequorin variant (AEQmut) was fused to the nucleotide sequence encoding a non-cleavable N-terminal ER signal peptide (fl2). The correct targeting of fl2-AEQmut was confirmed by immunocytochemical analyses in transgenic Arabidopsis thaliana (Arabidopsis) seedlings. An experimental protocol well-established in animal cells – consisting of ER Ca2+ depletion during photoprotein reconstitution followed by ER Ca2+ refilling – was applied to carry out ER Ca2+ measurements in planta. Rapid and transient increases of the ER luminal Ca2+ concentration ([Ca2+]ER) were recorded in response to different environmental stresses, displaying stimulus-specific Ca2+ signatures. The comparative analysis of ER and chloroplast Ca2+ dynamics indicates a complex interplay of these organelles in shaping cytosolic Ca2+ signals during signal transduction events. Our data highlight significant differences in basal [Ca2+]ER and Ca2+ handling by plant ER compared to the animal counterpart. The set-up of an ER-targeted aequorin chimera extends and complements the currently available toolkit of organelle-targeted Ca2+ indicators by adding a reporter that improves our quantitative understanding of Ca2+ homeostasis in the plant endomembrane system

Functional characterization of AtTPK3 potassium channel of Arabidopsis thaliana

My Ph.D. project has focused on the characterization of TPK3, a putative channel selective for potassium (K+) with a predicted chloroplast localization in higher plants, from biochemical, physiological and electrophysiological point of view. This protein belongs to the TPK channel family (from Tandem-Pore K+ channels) and displays amino acid sequence homology with another K+ channel studied in our laboratory, called SynK (Zanetti et al., 2010). SynK shows thylakoid localization in Cyanobacteria. The SynK channel has been shown to be critical for photosynthetic performances in Cyanobacteria, given the photosensitive phenotype displayed by the mutants lacking the SynK protein. Given the homology, we hypothesized that similarly, TPK3 might be involved in the regulation of photosynthetic processes in higher plants. So far, no information is available about the properties of TPK3, nor about its physiological roles, neither about its possible involvement in photosynthesis; the work presented in this thesis had the aim of clarifying some important aspects of the functions of TPK3. Following subcellular localization studies carried out using biochemistry and confocal microscopy techniques, the TPK3 channel was expressed in E. coli cells for subsequent electrophysiological characterization in a planar lipid bilayer setup in order to prove its function as K+ channel. The unavailability of commercial mutants for tpk3 gene required setting up of a silencing procedure via RNA interference of the messenger for the protein, in order to analyze the possible physiological roles of TPK3. The resulting silenced plants have been studied under different growth conditions to determine changes in physiology of the plants including their photosynthetic parameters. In parallel with the TPK3 project, the most important part of my Ph.D., I also followed two other major areas of research: one concerning the study of the functions of two members of plant Glutamate Receptors (GluRs) and the other one concerning the characterization of the plant homologous of the recently identified MCU (Mitochondrial Calcium Uniporter) of mammals. This thesis also includes a manuscript (Checchetto et al., 2012) to which I contributed with the heterologous expression of a calcium-activated K+ channel, SynCaK, of Cyanobacteria.Il mio progetto di dottorato si è focalizzato sulla caratterizzazione, dal punto di vista biochimico ed elettrofisiologico, di una proteina denominata TPK3 che è predetta di funzionare come canale selettiva per il potassio (K+) ed essere localizzata nei cloroplasti nelle piante superiori,. Questa proteina appartiene alla famiglia dei canali TPK (da Tandem-Pore K+ channels) e mostra omologia di sequenza a un altro canale del K+ studiato nello stesso nostro laboratorio, denominato SynK (Zanetti et al., 2010), a localizzazione tilacoidale ed appartenente al phylum dei Cianobatteri. È stato dimostrato in più esperimenti che il canale SynK è fondamentale per la regolazione della fotosintesi nei Cianobatteri, in considerazione del fenotipo fotosensibile mostrato dai mutanti per il gene synk. Visto la localizzazione predetta del TPK3, è stato ipotizzato in partenza che TPK3 potesse svolgere un ruolo simile nelle piante superiori. Finora nulla si conosceva sulle proprietà di TPK3, ne sui suoi ruoli fisiologici, ne su di un suo eventuale coinvolgimento nella fotosintesi nelle piante superiori; il lavoro contenuto nel progetto presentato ha cercato di chiarire alcuni aspetti salienti delle funzioni di TPK3. Dopo studi di localizzazione subcellulare condotti con tecniche di biochimica e microscopia confocale, il canale TPK3 è stato espresso in E. coli per la successiva caratterizzazione elettrofisiologica in bilayer lipidico planare allo scopo di determinare la sua funzione come canale di K+. L’assenza di mutanti commerciali per il gene tpk3 ha necessitato la messa a punto del suo silenziamento tramite RNA interference del messaggero per la proteina suddetta, al fine di analizzarne i possibili ruoli fisiologici. Le piante silenziate risultanti, sottoposte a differenti condizioni di crescita, sono state studiate in vari esperimenti atti a determinarne vari parametri inclusi quelli fotosintetici. Contemporaneamente allo studio del TPK3, quello di maggior rilievo nel mio dottorato, ho seguito anche altri due filoni di ricerca principali, riguardanti l’uno l’approfondimento delle funzioni di due membri dei Recettori di Glutammato vegetali (GluRs) e l’altro la caratterizzazione degli omologhi del recentemente identificato MCU (Mitochondrial Calcium Uniporter) di Mammiferi. Nella presente tesi è inoltre incluso un manoscritto (Checchetto et al., 2012) per il quale ho collaborato nell’espressione eterologa del canale di K+ calcio-dipendente (SynCaK) di Cianobatteri

Global spectroscopic analysis to study the regulation of the photosynthetic proton motive force: A critical reappraisal

International audienceIn natural variable environments, plants rapidly adjust photosynthesis for optimum balance between photochemistry and photoprotection. These adjustments mainly occur via changes in their proton motive force (pmf). Recent studies based on time resolved analysis of the Electro Chromic Signal (ECS) bandshift of photosynthetic pigments in the model plant Arabidopsis thaliana have suggested an active role of ion fluxes across the thylakoid membranes in the regulation of the pmf. Among the different channels and transporters possibly involved in this phenomenon, we previously identified the TPK3 potassium channel. Plants silenced for TPK3 expression displayed light stress signatures, with reduced Non Photochemical Quenching (NPQ) capacity and sustained anthocyanin accumulation, even at moderate intensities. In this work we re-examined the role of this protein in pmf regulation, starting from the observation that both TPK3 knock-down (TPK3 KD) and WT plants display enhanced anthocyanin accumulation in the light under certain growth conditions, especially in old leaves. We thus compared the pmf features of young "green" (without anthocyanins) and old "red" (with anthocyanins) leaves in both genotypes using a global fit analysis of the ECS. We found that the differences in the ECS profile measured between the two genotypes reflect not only differences in TPK3 expression level, but also a modified photosynthetic activity of stressed red leaves, which are present in a larger amounts in the TPK3 KD plants