Study on the Structure and Function of Suppressor of K+ Transport Growth Defect (SKD1) Protein from Mesembryanthemum crystallinum using Bioinformatics

Kuo, Yu-Mei

23 July 2004

SKD1 (suppressor of potassium transport growth defect) belongs to the AAA-ATPase family and is one of the class E VPS (vacuolar protein sorting) proteins. The ATPase activity-deficient form of SKD1 leads the perturbation of mechanism transport through endosomes and lysosomes, however, the molecular mechanism behind the action of SKD1 is poorly understood. In this study, it is identified that VPS4_YEAST (Saccharomyces cerevisiae) is the homology protein of mcSKD1 (Mesembryanthemum crystallinum SKD1) employing sequence profile analysis. The full-length mcSKD1 protein possesses MIT, AAA-ATPase, and NACHT domains of VPS4_YEAST. It is investigated that VPS4_YEAST (NACHT domain) interacts to BRO1_YEAST (HEAT repeat), BRO1_YEAST (HEAT repeat) to AIP1_YEAST (WD40 repeat), AIP1_YEAST (WD40 repeat) to ABP1_YEAST (ADF domain), ABP1_YEAST (ADF domain) to ARP2_YEAST (ACTIN domain), respectively, from yeast two-hybrid system via protein-protein interaction. These proteins employ the function of cytoskeleton structural proteins in cells. Hence, mcSKD1 protein may involve the mechanisms of potassium ion uptake and salt tolerance via the function of cytoskeleton structural proteins.

Mesembryanthemum crystallinum

Bioinformatics

structure-function

Suppressor of K+ Transport Growth Defect

Experiments to modify grape juice potassium content and wine quality on granite derived soils near Paardenberg

Agenbach, G.

12 1900

Thesis (MScAgric (Soil Science))--University of Stellenbosch, 2006. / High potassium content in grape juice and wine are associated with low quality red wine in warm wine producing countries. In an attempt to reduce the potassium content of juice, must and wine, a field experiment was laid out on the farms Meerlus and Kersfontein in the Paardeberg area near Wellington in 1998 on granite derived soils to investigate the effect of canopy management and fertiliser applications on berry K accumulation and wine quality. Four fertiliser applications, three canopy treatments and a MgSO4 foliar spray were studied. The three fertiliser treatments being: none (control), CaSO4, Ca(OH)2, and MgSO4 applications. The canopy treatments were: thin to two shoots per bearer, tip, vertical shoot positioning (VSP) and the removal of yellow leaves and lateral shoots (canopy 1), thin to three shoots per bearer, top after véraison and VSP (canopy 2) and VSP with top after véraison (canopy 3/control). Magnesium sulfate sprays were applied at véraison for two seasons (1999/00 and 2000/01). Seasonal effects produced the most significant differences in this experiment. Canopy treatments did not affect juice K concentration at harvest. Canopy 1 and 2 produced significantly lower wine pH values at Kersfontein. Fertiliser treatments had no effect on juice K concentration nor did it affect wine quality. Magnesium sulphate foliar sprays did not affect juice K concentration at harvest but significantly lowered juice and wine pH, improved wine colour density and total phenolic content. It appears for this experiment that soil K content before véraison, shoot growth at and after véraison and water stress after véraison were the main factors determining juice K concentration at harvest.

Grapevine

Vitis viniferal

Berry potassium

Potassium uptake

K transport

Dissertations -- Soil science

Theses -- Soil science

Analysis of molecular mechanisms involved in exchange of nutrients between the fungus and the host plant within the ectomycorrhizal symbiosis / Analyse des mécanismes moléculaires responsables des échanges de solutés nutritifs entre le champignon et l'arbre dans la symbiose ectomycorhizienne

Haider, Muhammad Zulqurnain

14 December 2011

La symbiose mycorhizienne entre les champignons du sol et les racines de la plupart des plantes constitue une relation à bénéfice réciproque et joue un rôle majeur dans la productivité des écosystèmes. Les récentes avancées dans le domaine ont abouties à l'identification et à la caractérisation fonctionnelle de nombreux systèmes de transport du partenaire fongique. Le travail présenté s'inscrit dans le cadre de développement d'outils permettant la localisation de gènes d'intérêts du champignon ectomycorhizien Hebeloma cylindrosporum et de leur caractérisation fonctionnelle. Les systèmes de transport candidats ont été identifiés au sein d'une banque EST du champignon et semblent impliqués dans les échanges de phosphate (Pi) et de potassium (K+) entre Hebeloma et la plante hôte Pinus pinaster. Une stratégie de fusion transcriptionnelle utilisant l'EGFP comme gène rapporteur a été développée pour permettre la localisation de deux transporteurs de phosphate, HcPT1 et HcPT2, d'un transporteur de potassium, HcTrk1, et d'un canal potassique de type Shaker, HcSKC1, dans les hyphes en culture pure et au sein de l'ectomycorhize. Les Agrotransformations de la souche h7 d'Hebeloma avec des vecteurs de fusion transcriptionnelle ont montré une expression mycélienne de l'EGFP sous contrôle des promoteurs de nos gènes d'intérêts. Sous contrôle des différents promoteurs, l'expression de l'EGFP apparait comme étant site-spécifique dans les hyphes différenciés des ectomycorhizes. Le promoteur du transporteur de Pi HcPT1 induit l'expression du gène rapporteur au niveau des hyphes extramatriciels et du manteau mycélien entourant la racine. De plus, son expression est stimulée en cas de carence en Pi, indiquant ainsi l'implication de ce transporteur dans la récupération du Pi du sol lorsque celui-ci devient limitant. Pour ce qui est du promoteur de HcTrk1, il permet l'expression de l'EGFP dans les hyphes extraracinaires et dans le manteau, tandis que celui de HcSKC1 permet son expression au niveau du réseau de Hartig et du manteau. Ceci indique, qu'ils semblent respectivement participer à la récupération du K+ du sol et à son excrétion vers la plante. Pour poursuivre la caractérisation fonctionnelle de nos systèmes de transport candidats, un second canal potassique, HcSKC2, a été isolé à partir de la souche h1 et exprimé dans des ovocytes de xénope. Tout comme HcSKC1, HcSKC2 n'a pas été actif en système d'expression hétérologue. Cependant, des fusions traductionnelles avec l'EGFP ont montré que la protéine HcSKC2 est bien dirigée à la membrane. En perspective, la caractérisation fonctionnelle de ce canal issue de la souche h7 récemment séquencée sera tentée. / The mycorrhizal symbiosis made it possible the first plants to conquest emerged lands and is a major biological phenomenon of terrestrial ecosystems. The fungal partner efficiently takes up nutritive ions from the soil solution and transfers them to the host plants in exchange for photosynthetates. However, despite the importance of this symbiosis on ecosystem productivity, our knowledge about molecular processes controlling this symbiotic interaction and solute transports at the membrane level is very scarce. The objective of the project aims at dissecting part of the molecular mechanisms required for a functional ectomycorrhizal symbiosis associated with most of the woody species from boreal and temperate forests, by focusing on K+ exchanges occurring through the continuum soil-hyphae-plant. The general aim of the project is to gain new insights into the molecular mechanisms responsible for the polarization and differentiation of the plasma membrane between the site of nutrient uptake and the site of efflux into the apoplastic space in the ectomycorrhizal root. The team "Canaux Ioniques – Ion channels" has obtained an EST library of the fungus Hebeloma cylindrosporum (1) and has identified and characterized a potassium transporter of the Trk family (2). Also a Shaker-type potassium cannel was identified within the EST library but it is not yet functionally characterized. A second transcript was found from this channel with a longer N-terminus compared to the first transcript isolated in the beginning. Also, a sugar transporter was identified among the ESTs that could participate in the absorption of sugars, coming from the host plant, by the fungus. The objective of the PhD thesis is the functional characterization of these fungal transport systems as well as their localization. The functional characterization of these candidate genes will be accomplished using heterologous expression systems (Xenopus oocytes, COS cells, complementation of yeast mutants) and by the means of electrophysiology. Localization of genes within the fungus being in symbiotic interaction with the host plant, the tree Pinus pinaster, will help to better understand the role of the transport systems. The differentiation of the fungus, when establishing symbiosis, into the specialized interfaces soil-fungus and fungal cell- host plant cell within the ectomycorrhiza (Hartig net) is probably accompanied by a specific expression of transport proteins and ion channels

Symbiose

Hebeloma cylindrosporum

Fusion transcriptionnelle

Pinus pinaster

Agrotransformation

Symbiosis

Hebeloma cylindrosporum

Promoter-reporter expression

Pinus pinaster

Agrotransformation

Fungal Pi and K+ transport systems

Absorción de K+ en plantas con diferente tolerancia a la salinidad

Alemán Guillén, Fernando

26 November 2009

El trabajo realizado en la Tesis Doctoral llega a las siguientes conclusiones:1.- T. halophila muestra una relación en peso raíz/parte aérea mayor que A. thaliana, y esta diferencia se ve incrementada en condiciones de estrés salino, lo que podría suponer una ventaja para afrontarlo.2.- El estrés salino produce en A. thaliana mayores reducciones en la absorción y en las concentraciones internas de K+ que en T. halophila, a la vez que T. halophila presenta menor absorción de Na+ y transporte a la parte aérea que A. thaliana. Ambas circunstancias resultan en una mayor relación K+/Na+ en T. halophila, lo que puede suponer una mayor tolerancia a la salinidad.3.- El gen ThHAK5 codifica para un transportador que media un transporte de K+ de alta afinidad en levaduras similar al observado en las plantas de T. halophila lo que sugiere que este transportador juega un papel fundamental en la absorción de K+ en el rango de la alta afinidad en esta especie vegetal.4.- Aunque AtHAK5 y ThHAK5 presentan una gran homología de secuencia y unas características funcionales similares, la regulación de los genes que los codifican difieren en condiciones salinas. Así, la salinidad reduce en menor medida la inducción de ThHAK5 por ayuno de K+. En consecuencia, la absorción de K+ de alta afinidad está menos afectada por la presencia de NaCl en el medio externo en T. halophila.5.- La mutagénesis al azar permite encontrar aminoácidos importantes para la función de las proteínas y ésta ha permitido identificar dos versiones mutantes del transportador de K+ de alta afinidad AtHAK5 más eficientes, capaces de transportar K+ a concentraciones externas de Na+ muy elevadas (0.1 mM K+ y 800 mM Na+). / The work done in this Thesis provides some interesting conclusions:1.- Thellungiella halophila show a weight ratio root/shoot bigger than Arabidopsis thaliana, and this difference arise under salt stress, what might provide an effective mechanism of salt tolerance to T. halophila.2.- In A. thaliana, salt stress induces a bigger reduction of K+ uptake and tissue concentrations than in T. halophila, and at the same time T. halophila shows a reduced Na+ uptake and Na+ transport to the shoot. Both properties enable a higher ratio K+/Na+ in T. halophila which might be another mechanism of salt tolerance. 3.- The ThHAK5 gene isolated in this Thesis, encode a K+ transporter that mediates high affinity K+ transport in Saccharomyces cerevisiae similar to the observed in intact plants of T. halophila, which suggest a key role of this transporter in the high affinity range of concentrations.4.- Although AtHAK5 and ThHA5 shows high sequence homology and similar functional properties, gene regulation is different under salt stress. Thus, salinity reduces to a lesser extent the K+-starvation ThHAK5 induction. As a consequence, high affinity K+ uptake is less affected by NaCl in T. halophila. 5.- Random mutagenesis allows the identification of important aminoacids for protein function, and with this technique two more efficient mutant versions of AtHAK5 have been isolated. The evolved AtHAK5 mutant versions are able to transport K+ at high Na+ external concentrations (0.1 mM K+ and 800 mM Na+) in yeast.

Thellungiella halophila

K+ transport

gene expression

ThHAK5

mutagenesis

heterologous expression

AtHAK5

salinity

A. thaliana

Thellungiella halophila

sodium (Na+)

Potassium (K+)

expresión génica

gene expression

heterologous expression

ThHAK5

expresión heteróloga

AtHAK5

Arabidopsis thaliana

K+/Na+

K+ transport

transporte de K+

salinity

salinidad

Potassium

Potasio

K+/Na

Nutrición Vegetal

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