Studies on membrane-bound peptidases and a sugar transporter in the hyperthermophilic archaeon Thermococcus kodakaraensis / 超好熱始原菌サーモコッカス コダカラエンシスの膜結合型ペプチダーゼ及び糖トランスポーターに関する研究 / チョウ コウネツ シゲンキン サーモコッカス コダカラエンシス ノ マク ケツゴウガタ ペプチダーゼ オヨビ トウ トランスポーター ニ カンスル ケンキュウ

Matsumi, Rie

24 March 2008

Kyoto University (京都大学) / 0048 / 新制・論文博士 / 博士(工学) / 乙第12200号 / 論工博第3989号 / 新制||工||1438(附属図書館) / 26272 / UT51-2008-C970 / (主査)教授 今中 忠行, 教授 青山 安宏, 教授 森 泰生 / 学位規則第4条第2項該当

Hyperthermophilic

archaea

Thermococcus kodakaraensis

membrane-bound peptidase

sugar transporter

gene disruption system

500

Characterization of activation tagged potato (Solanum tuberosum L.) mutants

Aulakh, Sukhwinder Singh

02 November 2012

Generation and characterization of activation tagged potato mutants could aid in functional genomic studies. Morphological and molecular studies were conducted to compare potato cv. Bintje, its two mutants, underperformer (up), and nikku generated using the activation tagging vector pSKI074, and nikku revertant plants. Mutant up exhibited a dwarf phenotype (plant height 42 cm vs. 73 cm in cv. Bintje), abundant axillary shoot growth (3.1 shoots/plant compared to 0.7 shoots/plant in cv. Bintje; in vitro plants), greater tuber yield, altered tuber traits and early senescence compared to wild-type Bintje under in vitro conditions. Under in vivo conditions, the dwarf and early senescence phenotypes of the mutant were consistent, but the tuber yield of up was less (250 g/plant compared to 610 g/plant in wild-type Bintje) and had fewer axillary shoots compared to wild-type (1.9 shoots/plant in up vs. 4.7 shoots/plant in Bintje). Mutant nikku plants exhibited an extremely dwarf phenotype (plant height 2 cm in nikku vs. 6 cm in Bintje), had small hyponastic leaves, were rootless, and infrequently produced small tubers when compared to cv. Bintje. The overall nikku phenotype was suggestive of a constitutive stress response, which was further supported by the higher expression levels of several stress-responsive genes in nikku. The nikku revertant plants exhibited near normal stem elongation, larger leaves and consistent rooting, and it was a case of partial reversion. Southern blot analyses indicated the presence of single T-DNA insertions on chromosome 10 in the up and on chromosome 12 in the nikku mutant. The reversion in the nikku plants was not associated with the loss of enhancer copies from the original nikku mutant. Reverse transcriptase PCR analyses indicated transcriptional activation/repression of several genes in the up and nikku mutants, suggesting pleiotropic effects. In revertant, the expression levels of several genes which were differentially regulated in the nikku mutant were similar to Bintje. The gene immediately flanking the right border of the T-DNA insertion, which encoded a novel BTB/POZ (Broad complex, Tramtrac, Bric a brac; also known as Pox virus and Zinc finger) domain-containing protein, was highly up-regulated in the up mutant. This protein domain plays an important role in several important developmental, transcriptional and regulatory pathways. The mRNA-seq analyses resulted in 1,632 genes that were differentially expressed between mutant up and Bintje and the total number of up-regulated genes (661) were less than the number of genes down-regulated (971 genes) in the up mutant. Further analyses indicated that a variety of biological processes including decreased cell division, cell cycle activity, and abiotic stress responses were modified in the up mutant. In the nikku mutant, two potato genes, encoding an Acyl-CoA N-acyltransferases (NAT) superfamily protein, and a predicted major facilitator superfamily protein (MFS) were identified and overexpression lines Bintje/35S::NAT1 and Bintje/35S::PMT1 were created for recapitulation of the nikku mutant phenotype. Methylated DNA-PCR between the nikku and the revertant indicated a change in methylation status of the 35S enhancers, suggesting that the nikku revertant phenotype may be associated with some epigenetic modification. / Ph. D.

GCN5

Sugar transporter

revertant

methylation

Solanaceae

BTB/POZ domain

RNA-seq

Étude du transport des sucres dans les racines d'Arabidopsis thaliana au cours de son cycle de développement et en réponse à un stress osmotique / Sugar transport in roots of Arabidopsis thaliana during osmotic stress

Mainson, Dany

11 January 2013

Chez les plantes supérieures, la distribution des sucres entre organes sources et puits requiert l'activité de transporteurs membranaires de sucre. Les flux de sucre variant au cours du développement de la plante et en réponse à des stress, il est logique de penser que les transporteurs de sucres sont impliqués dans ces changements. Le but du travail était de suivre la répartition des sucres et l'expression des transporteurs correspondants dans les racines de la plante modèle Arabidopsis thaliana, en réponse à un stress osmotique. Afin de pouvoir récolter des racines, un système de culture en hydroponie a été mis en place. Après avoir vérifié l'homogénéité des plantes cultivées dans ce système, une étude de l'expression des gènes de transporteurs de sucre a été effectuée au cours du développement des plantes et de d'une journée (24h), en utilisant la technique de macroarray. Cette étude a révélé l'expression dans les racines de 3 transporteurs de saccharose (AtSUC1, AtSUC2 et AtSUC5), 2 transporteurs de polyols (AtPLT5 et AtPLT6) et 2 transporteurs d'hexoses (AtSTP7 et AtSTP13). Le suivi de la teneur en sucres solubles et en amidon ainsi que du transport à longue distance de [U-14C]-saccharose a permis d'émettre des hypothèses quant au rôle des transporteurs de sucres exprimés dans la racine. Afin de mimer un stress hydrique en hydroponie, un protocole d'application progressif d'un agent osmotique (polyéthylène glycol 6000) dans le milieu de culture a été élaboré. Ce système a permis de mettre en évidence que 5 des gènes de transporteurs de sucre identifiés dans la racine ont une expression qui varie dans ces conditions. Trois d'entre eux sont fortement réprimés : AtSUC1 / In plants, sugar allocation between source and sink organs is based on the activity of membrane transporters for sugars. As sugar fluxes are changing during development and in response to stress, sugar transporters are supposed to be involved in those changes. The aim of this work was to study sugar allocation and the corresponding transporters gene expression in the roots of the model plant Arabidopsis thaliana during an osmotic stress. In order to have access to the roots, an hydroponic culture system was developped. The homogeneity of the plants obtained with this system was checked and the expression of sugar tranporter genes was followed during development and during a 24h period was studied by a macro-array technique. The expression in the roots of the following genes was found: 3 sucrose transporters (AtSUC1, AtSUC2 and AtSUC5), 2 polyol transporters (AtPLT5 and AtPLT6) and 2 hexose transporters (AtSTP7 and AtSTP13). The sugar and starch content and the long distance of 14C-sucrose were measured and used to build some hypothesis on the role of sugar transporters in the roots. To mimick a water stress, an osmotic stress due to the progressive addition of Polyethylene-glycol was applied. This system demonstrated that 5 of the identified transporter genes display a change in expression: 3 are repressed (AtSUC1, AtSUC5 and AtPLT6) and 2 are over expressed (AtSUC2 and AtSTP13). Moreover, soluble sugar and starch accumulate in the leaves and 14C-sucrose transport to the roots is decreased in plants subjected to an osmotic stress. The respective role of transporters is discussed. The gene expression data were also confirmed with plants grown in rhizoboxes.

Arabidopsis thaliana

Racines

Hydroponie

Transporteur de sucres

Stress osmotique

Arabidopsis thaliana

Roots

Hydroponics

Sugar transporter

Osmotic stress

575.5

Transport processes in the arbuscular mycorrhizal symbiosis

Duensing, Nina

January 2013

The nutrient exchange between plant and fungus is the key element of the arbuscular mycorrhizal (AM) symbiosis. The fungus improves the plant’s uptake of mineral nutrients, mainly phosphate, and water, while the plant provides the fungus with photosynthetically assimilated carbohydrates. Still, the knowledge about the mechanisms of the nutrient exchange between the symbiotic partners is very limited. Therefore, transport processes of both, the plant and the fungal partner, are investigated in this study. In order to enhance the understanding of the molecular basis underlying this tight interaction between the roots of Medicago truncatula and the AM fungus Rhizophagus irregularis, genes involved in transport processes of both symbiotic partners are analysed here. The AM-specific regulation and cell-specific expression of potential transporter genes of M. truncatula that were found to be specifically regulated in arbuscule-containing cells and in non-arbusculated cells of mycorrhizal roots was confirmed. A model for the carbon allocation in mycorrhizal roots is suggested, in which carbohydrates are mobilized in non-arbusculated cells and symplastically provided to the arbuscule-containing cells. New insights into the mechanisms of the carbohydrate allocation were gained by the analysis of hexose/H+ symporter MtHxt1 which is regulated in distinct cells of mycorrhizal roots. Metabolite profiling of leaves and roots of a knock-out mutant, hxt1, showed that it indeed does have an impact on the carbohydrate balance in the course of the symbiosis throughout the whole plant, and on the interaction with the fungal partner. The primary metabolite profile of M. truncatula was shown to be altered significantly in response to mycorrhizal colonization. Additionally, molecular mechanisms determining the progress of the interaction in the fungal partner of the AM symbiosis were investigated. The R. irregularis transcriptome in planta and in extraradical tissues gave new insight into genes that are differentially expressed in these two fungal tissues. Over 3200 fungal transcripts with a significantly altered expression level in laser capture microdissection-collected arbuscules compared to extraradical tissues were identified. Among them, six previously unknown specifically regulated potential transporter genes were found. These are likely to play a role in the nutrient exchange between plant and fungus. While the substrates of three potential MFS transporters are as yet unknown, two potential sugar transporters are might play a role in the carbohydrate flow towards the fungal partner. In summary, this study provides new insights into transport processes between plant and fungus in the course of the AM symbiosis, analysing M. truncatula on the transcript and metabolite level, and provides a dataset of the R. irregularis transcriptome in planta, providing a high amount of new information for future works. / In der arbuskulären Mykorrhiza (AM) Symbiose werden die Wurzeln fast aller Landpflanzen von Pilzen der Abteilung Glomeromycota besiedelt. Der Pilz erleichtert der Pflanze die Aufnahme von Mineralien, hauptsächlich Phosphat, und Wasser. Im Gegenzug versorgt die Pflanze ihn mit Photoassimilaten. Trotz der zentralen Bedeutung der Austauschmechanismen zwischen Pilz und Pflanze ist nur wenig darüber bekannt. Um die molekularen Grundlagen der Interaktion zwischen den Wurzeln der Leguminose Medicago truncatula und dem arbuskulären Mykorrhizapilz Rhizophagus irregularis besser zu verstehen, werden hier die Transportprozesse, die zwischen den Symbiosepartnern ablaufen, näher untersucht. Die zellspezifische Regulation der Transkription potentieller M. truncatula Transporter Gene in arbuskelhaltigen und nicht-arbuskelhaltigen Zellen mykorrhizierter Wurzeln wird bestätigt. Ein Modell zur möglichen Verteilung von Kohlenhydraten in mykorrhizierten Wurzeln, nach dem Zucker in nicht-arbuskelhaltigen Zellen mobilisiert und symplastisch an arbuskelhaltige Zellen abgegeben werden, wird vorgestellt. Die Analyse eines Mykorrhiza-induzierten Hexose/H+ Symporter Gens, MtHxt1, liefert neue Einsichten in die Mechanismen der Kohlenhydratverteilung in mykorrhizierten Pflanzen. Metabolitanalysen von Wurzeln und Blättern einer knock-out Mutante dieses Gens zeigen dessen Einfluss auf den Kohlenhydrathaushalt der ganzen Pflanze und auf die Interaktion mit dem Pilz. Die Metabolitzusammensetzung von M. truncatula wird durch die Mykorrhiza Symbiose signifikant beeinflusst. Darüber hinaus werden durch Transkriptomanalysen die molekularen Grundlagen der AM Symbiose auf der Seite des Pilzes analysiert. Arbuskeln wurden mittels Laser Capture Mikrodissektion direkt aus mykorrhizierten Wurzeln isoliert. Über 3200 pilzliche Transkripte weisen in diesen Arbuskeln im Vergleich zu extraradikalen Geweben ein deutlich verändertes Expressionslevel auf. Unter diesen Transkripten sind auch sechs zuvor unbekannte Gene, die für potentielle Transporter codieren und mit großer Wahrscheinlichkeit eine Rolle im Nährstoffaustausch zwischen Pilz und Pflanze spielen. Während die Substrate von drei potentiellen MFS Transportern noch unbekannt sind, spielen zwei potentiellen Zuckertransporter möglicherweise eine Rolle im Transport von Kohlenhydraten in Richtung des Pilzes. Zusammengefasst bietet diese Arbeit neue Einsichten in Transportprozesse zwischen Pilz und Pflanze im Laufe der AM Symbiose. M. truncatula Transkript- und Metabolitlevel werden analysiert und die Transkriptomanalyse von R. irregularis liefert einen umfassenden Datensatz mit einer großen Menge an Informationen zu der noch unzureichend erforschten pilzlichen Seite der Symbiose für folgende Arbeiten.

arbuskuläre Mykorrhizasymbiose

Zuckertransporter

Medicago truncatula

Rhizophagus irregularis

Transkriptom Sequenzierung

arbuscular mycorrhizal symbiosis

sugar transporter

Medicago truncatula

Rhizophagus irregularis

transcriptome sequencing

Life sciences