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Caracterização genômica e funcional da Β-N-Acetilglicosaminidases de Metarhizium anisopliaeOliveira, Eder Silva de January 2016 (has links)
A degradação de quitina é importante para o remodelamento da parede celular em fungos filamentosos e crucial para o rompimento da cutícula de hospedeiros artrópodes durante a infecção de fungos entomopatogênicos. Além disso a quitina é uma importante fonte nutricional. Para que a quitina possa ser eficientemente utilizada, a atividade de b-Nacetilglicosaminidases (NAGases) deve estar presente. Após a ação de quitinases sobre a quitina, gerando dímeros de N-acetilglicosamina (GlcNAc)2, NAGases hidrolisam suas ligações β-1-4 produzindo GlcNAc livre. Fungos filamentosos possuem, em média, 15 a 25 quitinases, mas somente duas NAGases, o que leva a questões sobre a real importância destas enzimas. Em escala genômica, foram identificadas no fungo entomopatogênico Metarhizium anisopliae duas NAGases da família GH20 (MaNAG1 e MaNAG2) e duas NAGases da família GH3 (MaNAG3 e MaNAG4) das glicosil hidrolases. Análises filogenéticas sugerem subsequentes duplicações ocorrendo principalmente no clado de MaNAG2, resultando na presença de ortólogos em um amplo espectro de ascomicetos com diferentes estilos de vida. MaNAG1 agrupou majoritariamente com espécies entomopatogênicas. MaNAG3 e MaNAG4 apresentaram alta similaridade de sequências e conservação de domínios com NAGases GH3 de bactérias O perfil transcricional dos genes das NAGases GH20 e GH3 foi avaliado por qPCR, em oito diferentes condições de cultivo, representando diferentes estágios de desenvolvimento ou diferentes estados nutricionais. As NAGases apresentaram perfis de transcrição diferenciais em resposta às diferentes condições, indicando a ausência de um padrão de regulação gênica em comum. Os perfis de expressão variáveis também sugerem que elas não devem possuir funções totalmente redundantes. Ensaios de transcrição relativa mostraram a indução da expressão de MaNAG1, MaNAG2 e MaNAG4 por quitina 1%, enquanto MaNAG3 foi induzida em meio suplementado com GlcNAc 0,25%. As relações evolutivas de MaNAG3 e MaNAG4 e a regulação de suas expressões por substratos quitinosos são a primeira evidência do envolvimento de NAGases GH3 em processos celulares fisiológicos em ascomicetos, apontando para sua potencial relevância na diferenciação celular durante o ciclo de vida de M. anisopliae. Com o objetivo de avançar no estudo funcional das NAGases de M. anisopliae, foram gerados vetores para a construção de mutantes nulos para os quatro genes de NAGases e linhagens transformantes foram obtidas utilizando-se a metodologia de transformação de fungos mediada por Agrobacterium tumefaciens. / Chitin degradation is important for filamentous fungi cell wall remodeling and, in entomopathogenic fungi, this process is pivotal for breaching the arthropod host cuticles during infection. Chitin is an important nutrient and to be efficiently used, β-Nacetylglucosaminidases (NAGases) activity must be present. After chitinase action on chitin generating N-acetylglucosamine dimers (GlcNAc)2, NAGases hydrolyze theirs β-1-4 linkages producing free GlcNAc. Filamentous fungi have between 15 to 25 chitinases, but only two NAGases; then, questions arise about the actual importance of these enzymes. On a genomic scale, were identified in the entomopathogenic fungus Metarhizium anisopliae two GH20 NAGases (MaNAG1 and MaNAG2) and two GH3 NAGases (MaNAG3 and MaNAG4) from glycoside hydrolases. Phylogenetic analysis suggested subsequent duplications occurring mainly in MaNAG2 clade, resulting in ortholog clusters in several ascomycetes with a broad range life style. MaNAG1 clusters mostly with entomopathogenic species clades. MaNAG3 and MaNAG4 showed high sequence similarity and domain conservation with bacterial GH3 NAGases Transcriptional profiles of GH20 and GH3 NAGase genes were evaluated by qPCR from eight culture conditions, representing different stages of development and different nutritional states. NAGases showed differential transcript profiles in response to different conditions, indicating an absence of a common gene regulation pattern. The variable expression profiles also suggest they may not have totally redundant roles. Relative transcription assays showed MaNAG1, MaNAG2 and MaNAG4 expression induction by chitin 1%, while MaNAG3 was induced in medium supplemented with GlcNAc 0.25%. Evolutionary relationships of MaNAG3 and MaNAG4 and their expression regulated by chitinous substrates are the first evidence of GH3 NAGases involvement in physiological cell process in entomopathogenic fungi, therefore, pointing to potential relevance on cell differentiation during M. anisopliae life cycle. In order to proceed on functional studies of M. anisopliae NAGases, vectors were constructed to produce knockout mutants for four NAGases genes and transformant strains were obtained by using fungi transformation mediated by Agrobacterium tumefaciens.
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Procedures for genetic modification of Miscanthus x giganteus, a biomass cropArpan, Anjali 13 May 2022 (has links) (PDF)
Development of genetic improvement procedures for the bioenergy crop, Miscanthus × giganteus (M×g; triploid), are desired for trait improvement. Agrobacterium tumefaciens has been used in other Miscanthus spp. for genetic improvement, but not in M×g, nor have more than a few genes been introduced at a given time. Transformation procedures for M×g were developed; studies included use of A.tumefaciens (strain LBA4404) and A. rhizogenes (strain A4) for introduction of seven genes isolated (by other researchers) from Sorghum bicolor involved in sorgoleone biosynthesis (an allelopathic compound), and selectable marker gene neomycin phosphotransferase II. Procedural development included generation of embryogenic calli from immature inflorescences, attempts to minimize generation of phenolics by these tissues, transformation procedures for both Agrobacterium spp., selection of transgenic tissues, and tissue screenings via polymerase chain reaction to identify putative transgenic tissues/plants. Although four M×g putative transgenic plants were generated, none were proven to be transgenic.
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Intrication des signalisations opine, quorum-sensing et GABA chez le phytopathogène Agrobacterium tumefaciens : conséquences sur la colonisation de l’hôte et la dissémination des gènes plasmidiques / Interlink between opine, quorum-sensing and GABA signaling in the phytopathogen Agrobacterium tumefaciens : impact on host colonization and dissemination of plasmidsLang, Julien 06 December 2013 (has links)
Les opines sont des molécules produites dans les cellules végétales transformées par l’ADN-T d’A. tumefaciens. Ces opines peuvent être utilisées comme nutriments par le phytopathogène et certaines d’entre elles agissent comme signaux moléculaires contrôlant la dissémination du plasmide de virulence Ti via la signalisation quorum-sensing. Le présent travail vise à une compréhension élargie du rôle des opines au cours des interactions A. tumefaciens-plantes hôtes. En se basant d’abord sur des analyses transcriptomiques, le régulon AccR d’A. tumefaciens C58, contrôlé par les opines agrocinopines, a été défini : celui-ci inclut des fonctions associées (i) à l’assimilation des agrocinopines, (ii) à l’assimilation de la nopaline, (iii) à la signalisation quorum-sensing et la conjugaison du plasmide Ti, (iv) à la conjugaison du plasmide At. La corrélation entre la co-régulation des conjugaisons des plasmides Ti et At et le co-transfert des deux réplicons a en outre été mise en évidence. Dans un second temps, associant des approches de génétique fonctionnelle à des travaux collaboratifs en biologie structurale, l’avantage sélectif conféré par les opines nopaline et octopine à A. tumefaciens au sein des tumeurs végétales a été quantifié. Les bases moléculaires sous-jacentes à cet avantage sélectif, notamment celles associées à la perception et l’importation des deux opines dans le cytoplasme bactérien, ont été décrites. Enfin, en combinant des approches de métabolomique et de génétique inverse avec des tests de conjugaison in planta, les effets opposés de la signalisation GABA d’une part et des signalisations opine et quorum-sensing d’autre part sur la dissémination du plasmide Ti ont été démontrés. En conclusion, nos résultats révèlent l’intrication des signalisations opine, quorum-sensing et GABA au cours de l’interaction A. tumefaciens-plantes hôtes. Ils soulignent en particulier les impacts de cette intrication sur la colonisation de l’hôte ainsi que sur la dissémination des gènes de virulence et d’adaptation à l’environnement tumeur portés par les plasmides Ti et At. / Opines are produced in plant cells transformed with the A. tumefaciens T-DNA. These opines can be used as nutrients by the phytopathogen and some of them act as signaling molecules controlling Ti plasmid dissemination through quorum-sensing. The present study aims at an enlarged understanding of the roles of opines during A. tumefaciens/plant host interactions. First, based on transcriptomic investigations, the agrocinopine-controled AccR regulon from A. tumefaciens C58 was thoroughly characterized. This one includes functions associated with (i) agrocinopines assimilation, (ii) nopaline assimilation, (iii) quorum-sensing and Ti plasmid conjugation, (iv) At plasmid conjugation. Moreover our analysis showed that co-regulation of Ti and At plasmid conjugations correlated with the co-transfer of the two replicons. In a second step using functional genetic and structural biology we quantified the selective advantage conferred to colonizing A. tumefaciens populations by the assimilation of the opines nopaline and octopine. The molecular basis which underlies this selective advantage, especially regarding the sensing and import of the two opines within the bacterial cytoplasm, were also described. Finally combining metabolomics and reverse genetic with in planta conjugation assays we demonstrated the opposite effects of GABA and opine/quorum-sensing signaling on the dissemination of Ti plasmids. In conclusion our results reveal the interlink between opine, quorum-sensing and GABA signaling during A. tumefaciens/plant host interactions. They noticeably highlight the impact of this interlink on host colonization and the dissemination of Ti and At plasmid genes which are critical for the virulence and the adaption of the bacteria to the tumor lifestyle.
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Structures et spécificités de Protéines Périplasmiques de Fixation pour les mannityl-opines chez Agrobacterium tumefaciens. / Structures and specificity of Periplasmic Binding Proteins toward mannityl-opines in Agrobacterium tumefaciens.Marty, Loic 16 September 2016 (has links)
L’agent pathogène Agrobacterium tumefaciens induit, chez les plantes, le développement de tumeurs dans lesquelles il prolifère, en intégrant un fragment de son plasmide Ti de virulence dans le génome de son hôte. Les tissus transformés synthétisent des composés originaux, appelés opines, qui sont utilisés comme nutriments spécifiques par la bactérie. Une vingtaine d’opines sont connues à ce jour, et chacune d’elle peut être métabolisée par des souches d’Agrobacterium tumefaciens possédant les gènes de transport et de catabolisme qui lui sont associés, ce qui apparait comme un avantage compétitif dans la colonisation de la tumeur. La présence de ces gènes dépend du type de plasmide Ti que la souche pathogène possède.Agrobacterium tumefaciens B6 possède un pTi de type octopine, qui porte les gènes de métabolisme des mannityl-opines, qui sont la mannopine, l’acide mannopinique, l’agropine et l’acide agropinique. La mannopine et l’acide mannopinique sont synthétisés par la même enzyme, et ont pour précurseurs respectivement la désoxy-fructosyl-glutamine (DFG) et le désoxy-fructosyl-glutamate (DFGA), tous deux opines de la famille de la chrysopine. La DFG est aussi un composé d’Amadori répandu et assimilable par de nombreux organismes. La mannopine sert de précurseur pour la synthèse de l’agropine. Enfin, la mannopine, l’acide mannopinique et l’agropine peuvent toutes trois se lactamiser spontanément en acide agropinique.Malgré la similarité chimique de ces quatre opines, chacune est transportée par une protéine périplasmique de fixation (PBP) associée à un transporteur ATP-binding Cassette (ABC) différent. La PBP sélectionne et fixe une opine pour l’apporter au transporteur ABC, qui permet le passage de l’opine dans le cytoplasme grâce à l’hydrolyse de deux molécules d’ATP. La spécificité du transporteur entier est déterminée par la PBP.Des études génétiques chez des souches possédant un pTi de type octopine ont montré que le système PBP-transporteur ABC AgaABCD est spécifique de l’acide agropinique, AgtABCD spécifique de l’agropine, MoaABCD spécifique de l’acide mannopinique et que MotABCD transporte la mannopine et également l’acide mannopinique. Chez la souche C58, qui ne possède pas un pTi de type octopine, le système de transport SocAB, codé par des gènes situés sur le plasmide cryptique At, transporte la DFG comme nutriment, et semble aussi capable d’importer la mannopine.Mon travail de thèse a permis, dans un premier temps, de caractériser les fortes affinités et la spécificité des PBP AgaA et AgtB pour l’acide agropinique, de la PBP MoaA pour l’acide mannopinique et de la PBP SocA pour la DFG, mais aussi la non spécificité de MotA pour la mannopine, l’acide mannopinique et la DFG, ce qui remet en question les affinités précédemment décrites pour AgtB et SocA. Dans un deuxième temps, ce travail a apporté les bases moléculaires et structurales des complexes PBP-mannityl-opines, complexes jamais caractérisés auparavant. Enfin, dans un troisième temps, la structure de la PBP AttC chez la souche C58, annotée comme mannopine-like, a été déterminée, et les expériences d’interaction ont montré qu’elle n’interagit avec aucune mannityl-opine, ce qui conduit à une révision de son annotation.Mes travaux apportent un éclairage nouveau sur l’import des mannityl-opines chez Agrobacterium tumefaciens. Le fait qu’aucun des transporteurs étudié ne permette l’import de l’agropine laisse penser qu’il existe une autre PBP ou un autre système de transport encore inconnu assurant cette fonction, ouvrant la voie vers de nouvelles études sur les pTi de type octopine et agropine. / Agrobacterium tumefaciens pathogenic agent confers the development of tumors in plants, in which it proliferates, integrating a fragment of its virulence Ti plasmid into its host genome. Transformed tissues synthesize original compounds, called opines, used as specific nutrients by the bacterium. More than twenty opines are known so far, and each one of them can be metabolized by A. tumefaciens strains possessing its associated transport and catabolism genes, which appears as a competitive advantage in the tumor colonization. The presence of these genes relies on the Ti plasmid type a pathogenic strain possesses. A. tumefaciens B6 possesses an octopine-type pTi, which harbors the metabolism genes of the mannityl-opines, which are mannopine, mannopinic acid, agropine and agropinic acid. Mannopine and mannopinic acid are synthesized by the same enzyme, and their precursors are deoxy-fructosyl-glutamine (DFG) and deoxy-fructosyl-glutamate (DFGA) respectively, both opines of the chrysopine family. DFG is also a wide-spread Amadori compound which can be uptaken by numerous organisms. Mannopine is a precursor for agropine synthesis. Finally, mannopine, mannopinic acid and agropine can spontaneously lactamize into agropinic acid.Despite the chemical similarity of these four opines, each one is transported by a different periplasmic binding protein (PBP) associated with an ATP-binding cassette (ABC) transporter. The PBP selects and binds one opine to bring it to the ABC transporter, which allows the passage of the opine to the cytoplasm due to two ATP molecules hydrolysis. The whole transporter specificity is determined by the PBP.Genetic studies in strains possessing an octopine-type pTi showed that AgaABCD PBP-ABC transporter system is specific to agropinic acid, AgtABCD to agropine, MoaABCD to mannopinic acid and that MotABCD transports mannopine and also mannopinic acid. In C58 strain, which do not possess an octopine-type pTi, SocAB transport system, coded by genes located on the cryptic pAt plasmid, allows the transport of DFG as a nutrient, and seems able to import mannopine too.My thesis work allowed, first, to characterize the strong affinities and the specificity of PBPs AgaA and AgtB to agropinic acid, PBP MoaA to mannopinic acid and PBP SocA to DFG, and also MotA unspecificity toward mannopine, mannopinique acid and DFG, which leads to a revision of the previously described affinities of AgtB and SocA. Secondly, this work brought molecular and structural basis of PBP-mannityl-opine complexes, never described before. Finally, the structure of PBP AttC, annotated as a mannopine binding-like protein in C58, was determined, and interactions experiments showed that it binds no mannityl-opines, leading to a revision of its annotation.My work sheds light on the mannityl-opines importation in Agrobacterium tumefaciens. The fact that none of the studied transport system allows agropine import lets think that there is another unknown PBP or another unknown whole transport system assuming this role, opening new ways to new studies about octopine- and agropine-type pTis.
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Mode de vie d'Agrobacterium tumefaciens dans la tumeur / Lifestyle of Agrobacterium tumefaciens in the tumorGonzález Mula, Almudena 08 June 2017 (has links)
Le phytopathogène Agrobacterium tumefaciens est l'agent causal de la maladie appelée galle du collet, et est capable d'infecter plus de 90 familles de plantes dicotylédones. Cette ∝-protéobactérie appartient à la famille Rhizobiaceae. A. tumefaciens est un complexe de différentes espèces regroupées en 10 génomovars (G1 à G8 et G13). A. tumefaciens C58 appartient au groupe du G8. Son génome est constitué de 4 réplicons : 1 chromosome circulaire, 1 chromosome linéaire et des 2 plasmides dispensables : pAt (pour A.tumefaciens) et pTi (pour Tumor inducing, qui est requis pour la virulence). Pour explorer de nouveaux aspects du mode de vie d’A. tumefaciens, et en particulier l'interaction entre la bactérie et sa plante hôte, deux approches différentes ont été utilisées pour identifier, caractériser et analyser les gènes qui pourraient jouer un rôle dans l'adaptation des bactéries à la tumeur. Une expérience de l'évolution par des passages en série de trois souches différentes de l'agent pathogène sur la plante hôte Solanum lycopersicum a été effectuée afin de clarifier la dynamique évolutive du génome au cours de l'infection. Parallèlement, une étude de différents transcriptomes (in planta et in vitro) a été réalisée et étudiée pour élucider des gènes bactériens candidats impliqués dans l'interaction de la bactérie avec la plante et divers composés produits dans la tumeur. Ce travail tente de donner une vue plus générale du processus d'adaptation de la bactérie à la niche écologique qui est la tumeur. / Agrobacterium tumefaciens is the causal agent of the plant disease called crowngall, and it’s able to infect more than 90 families of dicotyledonous plants. It is an α-Proteobacterium and belongs to the Rhizobiaceae family. A. tumefaciens is a complex of different species grouped in 10 genomovars (G1 to G8, and G13). A. tumefaciens C58 belongs to the G8 group. Its genome consists in 4 replicons: 1 chromosome circular, 1 chromosome linear and 2 dispensable plasmids: pAt (for A. tumefaciens) and pTi (for Tumor inducing), which is required for virulence. To explore new aspects of the A. tumefaciens lifestyle, and in particular the interaction between the bacteria and its plant host, two different approaches have been used to identify, characterize and analyze genes that could play a role in the adaptation of the bacteria to tumor lifestyle. An evolution experiment by serial passages of three different strains of thepathogen on the host plant Solanum lycopersicum has been carried out to clarify the evolutionary dynamics of the genome during the course of infection. In parallel, a study of different transcriptomes (in planta and in vitro) was performed and studied to elucidate bacterial candidate genes involved in the interaction of the bacteria with the plant and various compounds produced in the tumor. This work attempts to give a more general view of the process of adaptation of the bacteria to the ecological niche that is the tumor.
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Development of an Agrobacterium vitis transformation system for grapevineJoubert, Dirk Albert, 1973- 03 1900 (has links)
Thesis (MSc)--University of Stellenbosch, 2000. / ENGLISH ABSTRACT: Agrobacterium tumefaciens-mediated transformation technology has been used in a
variety of applications throughout the fields of cellular and molecular plant biology as well
as plant physiology. Research is conducted in order to extend this application range and
overcome some of the intrinsic limitations of the Agrobacterium transformation system.
Predominantly, these limitations can be attributed to the host range specificity of
A. tumefaciens, as well as adverse effects induced on explant tissue by active plant
defence mechanisms, triggered by the plant-pathogen-interaction. Typically, this active
defence mechanism culminates in the hypersensitive response (HR), characterised by
localised cell death and necrosis.
Not all Agrobacterium species, however, share the same host range and some have
evolved the ability to infect plant species not normally considered hosts of A. tumefaciens.
This host range specificity can be exploited to extend the application of existing
Agrobacterium transformation systems. In an attempt to establish an efficient
transformation system for Vitis vinifera which, has proven very difficult to transform with
A. tumefaciens, indigenous A. vitis strains have been evaluated as possible host-specific
transformation agents. Strains of Agrobacterium vitis should be suitable for this type of
endeavour, since they have evolved several unique characteristics directly linked to the
infection of their hosts. These include the ability to utilise, tartrate, a host abundant carbon
source, as well as the production of an acid polygalacturonase that could play a role
during the infection process. The proposition that the evolution of A. vitis is a fairly recent
event is also confirmed by the relatively little divergence observed between A. tumefaciens
and A. vitis.
In this study, a selection of A. vitis strains were evaluated in screenings designed to
accentuate desirable traits in strains such as good infectivity of grapevine material
(presumably an indicator of an efficient mechanism of gene transfer to be exploited in an
engineered transformation system) as well as a favourable reaction (causing no necrosis)
on grapevine somatic embryos. Two strains produced large tumours on grapevine cuttings
and caused little necrosis on the somatic embryos. Significant variation in infectivity as
well as callus necrosis was observed between the strains as well as in a genotype-specific
manner on the host material. This genotypic-specific effect of either host or pathogen could be an indication of the degree of specialisation developed by plant pathogens to
infect specific hosts. On the basis of these results, it was possible to select an A. vitis
strain for further biochemical and genetic characterisation.
Simple biochemical analysis classified the strain as an octopine strain. DNA-DNA
hybridisation techniques combined with a plasmid walking technique resulted in the partial
characterisation of the T-DNA of the selected A. vitis strain. A partial restriction enzyme
map of the T-DNA was constructed and the T-DNA and flanking areas were cloned.
Significant differences, most notably, the absence of a TB-area as well as the absence of
the agrocinopine (aes) gene from the 5' area of the T-DNA, were observed. Partial
sequencing data indicated the presence of at least four conserved T-DNA genes located
on the TA-DNA, as well as the presence of three bacterial insertion (IS-)elements flanking
the region. Two of these IS elements, both related to the IS 110 family of IS elements have
not yet been reported in A. vitis. In fact, these two elements seem to be the 5' and 3' ends
of a disrupted element and could therefore have played an evolutionary role in the
development of this strain.
This study provides fundamental background for the development of a more efficient
transformation system specific for grapevine, exploiting same of-the unique characteristics
of one of its pathogens, A. vitis. / AFRIKAANSE OPSOMMING: Agrobacterium tumefaciens-gebaseerde transformasiesisteme word in "n wye reeks van
toepassings in die velde van sellulêre- en molekulêre plantbiologie asook plantfisiologie
aangewend. Navorsing word voortdurend onderneem om die inherente beperkinge van
die Agrobacterium-transformasiesisteem te oorkom en sodoende die toepassingsveld van
die sisteem verder te verbreed. Die beperkinge tipies aan dié sisteem kan hoofsaaklik
toegeskryf word aan die gasheerspesifisteit van A. tumeteciens, asook die negatiewe
reaksies op eksplantmateriaal wat deur die plant se aktiewe verdedigingsmeganisme,
soos ontlok deur die plant-patogeen interaksie, veroorsaak word. Hierdie aktiewe
verdedigingsmeganisme lei gewoonlik tot In hipersensitiewe respons (HR) in die plant, wat
deur gelokaliseerde selafsterwing en nekrose gekenmerk word.
Alle Agrobacterium-spesies het egter nie almal dieselfde gasheerreeks nie en sommige
rasse het as gevolg van evolusionêre ontwikkelings die vermoë verkry om plantspesies
wat normaalweg buite die gasheerreeks van A. tumefaciens val, te infekteer. Hierdie tipe
gasheerspesifisiteit kan uitgebuit word om die toepassingsmoontlikhede van bestaande
Agrobacterium-transformasiesisteme te verbreed. In In poging om In effektiewe
transformasiesisteem vir Vitis vinifera, In moeilik transformeerbare gewas, te ontwikkel, is
inheemse rasse van Agrobacterium vitis ondersoek as moontlike gasheerspesifieke
transformasie-agente. Rasse van A. vitis behoort uiters geskik te wees vir so "n
toepassing, aangesien hulle verskeie unieke eienskappe, wat direk aan die infeksie van
die gasheer gekoppel is, vertoon. Van hierdie eienskappe is onder meer die vermoë om
tartraat, In koolstofbron volop in druifplante, te benut. A. vitis produseer verder ook In suur
poligalaktorunase wat vermoedelik In rol in die infeksieproses speel. Die voorstel dat die
evolusionêre ontwikkeling van A. vitis In redelike onlangse gebeurtenis is, word onderskryf
deur die betreklike homogenisiteit met A. tumefaciens.
In hierdie studie is "n groep A. vitis-rasse met behulp van siftingsprosedures wat
daarop gemik is om gesogte eienskappe in rasse uit te wys, beoordeel. Die vermoë om
druifplantmateriaal te infekteer (wat vermoedelik "n aanwyser van "n effektiewe meganisme
van geenoordraging is wat in "n gemanipuleerde transformasiesisteem benut kan word),
sowel as 'n gunstige reaksie (d.w.s geen nekrose) op druifplant somatiese embrio's is van
die gesogte eienskappe waarvoor gesoek word. Twee rasse het groot tumors op druifplant-stingelsegmente veroorsaak terwyl hulle bykans geen weefselskade op
somatiese embrio's geïnduseer het nie. Betekenisvolle verskille in infektiwiteit en in
kallusnekrose is tussen die rasse sowel as in 'n genotipe-spesifieke-verhouding
waargeneem. Hierdie genotipe-spesifieke effek, kenmerkend van óf die gasheer óf die
patogeen, kan aanduidend wees van die vlak van spesialisasie wat heers by die infeksie
van spesifieke gashere. Na aanleiding van bogenoemde resultate was dit moontlik om 'n
A. vitis-ras te selekteer wat verder aan biochemiese en genetiese analises onderwerp kon
word.
Eenvoudige biochemiese analises het dit moontlik gemaak om die ras as oktopien te
klassifiseer. DNA-DNA hibridisasietegnieke gekombineerd met 'n unieke plasmiedwandeltegniek
het gelei tot die gedeeltelike karakterisering van die geselekteerde A. vitisras.
In Gedeeltelike restriksie-ensiem (RE) kaart van die T-DNA kon gevolglik opgestel
word. Die T-DNA en die aangrensende gedeeltes is boonop gekloneer. Betekenisvolle
verskille, spesifiek die afwesigheid van In TB area, sowel as die afwesigheid van die
agrosinopien-sintasegeen (acs) aan die 51-kant van die T-DNA, is waargeneem.
Gedeeltelike basispaaropeenvolgingsdata het egter die teenwoordigheid van minstens vier
gekonserveerde T-DNA-gene, asook die teenwoordigheid van drie bakteriese
invoegingselemente (IS) aan weerskante van die area, geïdentifiseer. Twee van hierdie
elemente, wat beide homologie vertoon met die IS110 familie van IS elemente, is nog nie
vantevore in A. vitis aangetref nie. Dit wil boonop blyk of dié twee elemente die 51
- en 31
-
areas van In onderbroke element vorm, wat dus In moontlike aanduiding is van hul
potensiële rol in die evolusionêre ontwikkeling van die ras.
Hierdie studie verskaf basiese inligting wat daartoe kan lei dat 'n doeltreffender
transformasiesisteem spesifiek vir druifplante ontwikkel word deur van die unieke
kenmerke van een van sy patogene, A. vitis, uit te buit.
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Physiological Role of Fatty Acid Desaturation in Agrobacterium-induced Arabidopsis Crown Galls / Physiologische Rolle der Fettsäure-Desaturierung in der durch Agrobacterium ausgelösten Wurzelhalsgalle von ArabidopsisKlinkenberg, Jörn January 2011 (has links) (PDF)
Crown gall development is accompanied by hypoxia, drought and oxidative stress. These abiotic stress factors are known to have an impact on fatty acid (FA) desaturation. Thus, an alteration in the lipid profile of plant tumors was expected. A comprehensive lipid analysis of Arabidopsis thaliana crown galls induced by Agrobacterium tumefaciens showed an increase in the degree of FA desaturation. The poly unsaturated fatty acid (PUFA) linolenic acid (18:3) of endoplasmic reticulum (ER) derived phospholipids was especially affected. The increased levels of desaturated FAs were reflected by a strong induction of two genes encoding desaturases, FAD3 and SAD6. In contrast to FAD3, which encodes the ER membrane bound fatty acid desaturase enzyme that synthesizes 18:3 PUFAs in the ER, the function of SAD6 is unknown. The ability of SAD6 to complement the extreme dwarf growth phenotype of the ssi2-2 mutant allele suggests that SAD6 is a functional stearoyl-acyl-carrier-protein delta-9 desaturase (SAD) which catalyzes the first step in FA desaturation and forms stearic acid (18:1). Overexpression of the SAD6 gene in Arabidopsis (SAD6-OE) to a similar degree as in tumors resulted in a light-dependent chlorosis phenotype and caused a similar shift in the lipid profile towards unsaturated phospholipids. Posttranscriptional down-regulation of SAD6 overexpression by RNA reverted the chlorosis phenotype and the changes in the lipid profile, showing that SAD6 overexpression forms the unsaturated FA profile and the phenotype in SAD6-OE. The subcellular localization of the SAD6 protein in chloroplasts, which is obligatory for SAD function was demonstrated. SSI2, which encodes the major contributor to the 18:1 FA levels in Arabidopsis is down-regulated in crown galls pointing to a replacement of SSI2 function by SAD6 in the tumor. SAD6 transcripts were almost undetectable in Arabidopsis under normal growth condition, whereas under hypoxia the gene was strongly activated. In the tumor hypoxia most likely caused the very high transcription of SAD6. Hypoxia is known to limit FA desaturation and it is associated with an elevated reactive oxygen species (ROS) production which is detrimental for unsaturated FAs. Thus, up-regulation of SAD6 in the crown gall, most likely serves as an adaptive mechanism to activate desaturation under low oxygen concentrations and to maintain the levels of unsaturated FA under oxidative stress. The ER localized FAD3 most likely is responsible for the rise in 18:3 of the phospholipid class to cope with drought stress in crown galls. This hypothesis was supported by the loss of function mutant, fad3-2, which developed significantly smaller tumors as the wild type under low relative humidity.Taken together, this study suggests that the induction of SAD6 and FAD3 shapes the tumor lipid profile by increasing the levels of unsaturated FAs. Unsaturated fatty acids prepare the crown gall to cope with ongoing hypoxia, drought and oxidative stress during growth and development. / Die Physiologie der durch Agrobacterium tumefaciens hervorgerufenen Wurzelhalsgallen ist geprägt von Sauerstoffmangel, Trocken- und oxidativen Stress. Diese Stressfaktoren beeinflussen die Umwandlung gesättigter zu ungesättigten Fettsäuren (Desaturierung). Somit sind Änderungen im Lipidmuster des durch Agrobacterium tumefaciens ausgelösten Pflanzentumors wahrscheinlich. Eine umfassende Analyse des Wurzelhalsgallenlipidmusters ergab, dass der Anteil an ungesättigten Fettsäuren erhöht war. Am auffälligsten war vor allem die Erhöhung der mehrfach ungesättigten Fettsäure Linolensäure (18:3) in den mit dem endoplasmatischen Retikulum (ER) assoziierten Phospholipiden. Dieser Anstieg ging einher mit der stark erhöhten transkriptionellen Aktivität des FAD3-Gens, das eine membrangebundene Fettsäure-Desaturase kodiert, die Linolensäure (18:3) im ER synthetisiert. Darüber hinaus war ein weiteres funktionell unbekanntes Desaturase-Gen, SAD6, stark aktiviert. Das SAD6 Protein war in Chloroplasten lokalisiert und in der Lage den extremen Zwergwuchs-Phänotyp der ssi2-2 Mutante zum Wildtyp zu komplementieren. Damit wurde nahegelegt, dass SAD6, wie SSI2, eine funktionelle „delta-9 Stearoyl-Acyl-Carrier-Protein-Desaturase“ (SAD) ist. Die Überexpression des SAD6-Gens in Arabidopsis (SAD6-OE), vergleichbar der in Wurzelhalsgallen, führte zu einem Anstieg ungesättigter Phospholipide und einem lichtabhängigen chlorotischen Phänotyp. Eine posttranskriptionelle Reduzierung der SAD6 Überexpression durch RNAi revertierte den Chlorosephänotyp und die Veränderungen im Lipidprofil zum Phänotyp des Wildtyps. Da SSI2, welches das SAD-Enzym für die Ölsäure (18:1)-Produktion in Arabidopsis kodiert, in Wurzelhalsgallen stark herunterreguliert ist, übernimmt hier sehr wahrscheinlich SAD6 die Funktion von SSI2. Insbesondere deshalb, weil der im Tumor vorherrschende Sauerstoffmangel zu einer starken Aktivierung des SAD6-Gens führt. Die Produktion ungesättigter Fettsäuren wird unter hypoxischen Bedingungen limitiert, weshalb eine erhöhte Expression von SAD6 die reduzierte Synthese ungesättigter Fettsäuren kompensieren könnte. Hypoxie und vor allem die posthypoxische Phase führen zur Produktion reaktiver Sauerstoffspezies (ROS), die ungesättigte Fettsäuren peroxidieren, so dass das Hypoxie-sensitive SAD6-Gen darüber hinaus das Niveau ungesättigter Fettsäuren unter oxidativem Stress zu erhalten scheint. Die ER lokalisierte Desaturase FAD3 ist ursächlich für die spezifische Erhöhung von Linolensäure (18:3) in den ER assoziierten Phospholipiden und führt somit zu einer Anpassung an den Trockenstress im Tumor. Dies wird dadurch unterstützt, dass an fad3-2 Mutanten unter erhöhtem Trockenstress deutlich kleinere Tumore wachsen. Diese Studie hat gezeigt, dass die Induktion von SAD6 und FAD3 in der Wurzelhalsgalle mit einer erhöhten Produktion ungesättigter Fettsäuren einhergeht und somit die Entwicklung und das Wachstum von Wurzelhalsgallen unter Sauerstoffmangel, oxidativem Stress und Wasserverlust ermöglicht wird.
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Funktion des Lipidtransferproteins 2 (LTP2) und dessen Rolle bei der Bildung von durch Agrobacterium tumefaciens induzierten Wurzelhalsgallen an Arabidopsis thaliana / Function of lipid transfer protein 2 (ltp2) and its function in Agrobacterium tumefaciens induced crown gall development on Arabidopsis thalianaSaupe, Stefanie January 2014 (has links) (PDF)
In Tumoren an Arabidopsis thaliana, induziert über Agrobacterium tumefaciens (Stamm C58), ist von den 49 bekannten Lipidtransferproteinen (LTPs) nur die Expression von LTP2 stark erhöht (Deeken et al., 2006). Mutanten ohne LTP2-Transkripte (ltp2KO) entwickeln deutlich kleinere Tumore als der Wildtyp. Durch die permanenten Zellstreckungs- und Dehnungsprozesse besitzen Tumore keine intakte Epidermis (Efetova et al., 2007). Dies wiederum führt zum Verlust einer vollständigen Cuticula-Schicht, welche von der Epidermis produziert wird und dieser als Barriere zur Umwelt aufgelagert ist. Um den transpirationsbedingten Wasserverlust zu minimieren, werden in Tumoren langkettige Aliphaten in die äußeren Zellschichten eingelagert (Efetova et al., 2006). Ein ähnliches Szenario findet um Verwundungsareale statt (Kolattukudy et al., 2001). Die Gen-Expression von LTP2 wird nicht durch tumorinduzierende Agrobakterien ausgelöst. Faktoren wie Verwundung, sowie die Applikation des Trockenstress-Phytohormons Abscisinsäure (ABA) begünstigen die LTP2-Gen-Expression positiv. Außerdem ist der LTP2-Promotor in Gewebe aktiv, in welchem sekundäre Zellwandmodifikationen auftreten, sowie insbesondere in Abscissionsschichten von welkenden Organen. Ungerichtete Lipidanalysen der ltp2KO-Mutante im Vergleich zum Wildtyp zeigten nur signifikante Veränderungen in der Menge definierter Sphingolipide – obwohl bislang eine Beteiligung von LTP2 am Transfer von Phospholipiden postuliert wurde. Allerdings kann das LTP2-Protein, wie Protein-Lipid-Overlay-Analysen demonstrierten, weder komplexen Sphingolipide noch Sphingobasen binden. Neben Sphingobasen sind auch langkettige Fettsäuren Bestandteile von Sphingolipiden und diese sind wiederum Bindepartner von LTP2. Um eine eventuelle Beteiligung von LTP2 an der Bildung von Suberin von Tumoren zu zeigen, wurde dieses analysiert. Die GC-MS-Analysen des Tumor-Suberins haben jedoch veranschaulicht, dass durch das Fehlen von LTP2-Transkripten das Lipidmuster nicht beeinträchtigt wird. Eine Überexpression von LTP2 im gesamten Kormophyten war trotz drei unabhängiger experimenteller Ansätze nicht möglich. Daher wurde das Protein ektopisch in epidermalen Zellen exprimiert (CER5Prom::LTP2). Die Transgenen CER5Prom::LTP2 wiesen einige morphologische Besonderheiten auf, wie verminderte Oberflächenhydrophobizität, aberrante Blüten- und Blattmorphologien etc., die typisch für Wachsmutanten sind. GC-MS-Analysen der cuticulären Wachse dieser transgenen Pflanzen zeigten, einen erhöhten Gehalt an C24- und C26-Fettsäuren, wohingegen die korrespondierenden Aliphaten wie Aldehyde und Alkane dezimiert waren. Unterstützend zeigten Lokalisationsanalysen, dass das LTP2-Protein an/in der Plasmamembran assoziiert ist.
Somit kann die These aufgestellt werden, dass LTP2 langkettigen, unverzweigten Aliphaten (Fettsäuren) an der Grenzfläche Plasmamembran/Zellwand transferiert, die zur Versieglung und Festigung von Zellwänden benötigt werden. / Out of 49 known lipid transfer protein (LTP) only the expression of LTP2 is highly increased in tumors induced on Arabidopsis thaliana via Agrobacterium tumefaciens (strain C58; Deeken et al., 2006). Mutants with no LTP2 transcripts (ltp2KO) develop significantly smaller tumors than the wild-type. Due to the permanent cell stretch and elongation processes tumors do not possess an intact epidermal layer (Efetova et al., 2007). This leads to the loss of a complete cuticle layer, which is produced by the epidermis and builds up a barrier to the environment. To minimize the transpirational water loss, long-chain aliphatic compounds are incorperated into the outer cell layers of tumors (Deeken et al., 2006). The gene expression of LTP2 is not triggered by tumor-inducing agrobacteria. Instead, factors such as wounding and the application of the phytohormone abscisic acid (ABA) induce the LTP2 gene expression. In addition, the LTP2 promoter is highly active in tissue, in which secondary cell wall modifications occur, and in the abscission zone of wilting organs. Untargeted lipid analyzes of ltp2KO mutant in comparison to the wild type showed significant changes in the amount of defined sphingolipids only - although the involvement of LTP2 has been postulated for the transfer of phospholipids. However, the LTP2 protein, as protein-lipid overlay analysis demonstrated, binds neither complex sphingolipids nor sphingobases. Instead LCFAs, which are part of sphingolipids are binding partners of LTP2.
In order to show a possible involvement of LTP2 in the formation of tumor-suberin GC-MS analyzes were performed. These demonstrated that the composition of the lipid-pool is not altered in ltp2KO plants. Overexpression of LTP2 was not possible in spite of three independent experimental approaches. The protein was instead expressed ectopically in epidermal cells (CER5Prom::LTP2). The transgenes CER5Prom::LTP2 showed some morphological abnormities, such as reduced surface hydrophobicity, aberrant flowers and leaf morphologies, which are typical for wax mutants. GC-MS analyzes of the cuticular wax of those transgenic lines revealed an increased amount of C24- and C26- fatty acids. Furthermore LTP2 was localized at the plasma membrane.
Thus, this thesis proposes a role of LTP2 in the transfer of long chain, unbranched aliphatics (fatty acids), which are needed to seal up and strengthen cell walls at the interface plasma membrane and cell wall.
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Functional analyses of the roles of VirB4 and VirB5 during T-pilus assemblyYuan, Qing. Baron, Christian. January 1900 (has links)
Thesis (Ph.D.)--McMaster University, 2005. / Supervisor: Dr. Christian Baron. Includes bibliographical references (leaves 94-101).
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Silencing of Agrobacterium tumefaciens T-DNA oncogenes by cosuppressionLee, Hyewon 22 April 1999 (has links)
We have developed crown-gall resistant transgenic plants capable of suppressing Agrobacterium tumefaciens T-DNA oncogenes. Crown gall tumors result from overproduction of auxin and cytokinin in plant cells transformed by A. tumefaciens. High phytohormone levels result from expression of two auxin biosynthetic genes, tryptophan monooxygenase (iaaM) and indole acetamide hydrolase (iaaH), and isopentenyl transferase (ipt), which mediates cytokinin synthesis. Inactivation of ipt and either one of the two auxin biosynthesis genes prevents crown gall formation. To suppress T-DNA oncogene expression, we created transgenic tobacco that produce the corresponding untranslatable sense-strand RNAs. This phenomenon, called cosuppression, frequently blocks expression of transgenes in plants. Often, expression of an untranslatable sense-strand transgene elicits sequence-specific destruction of both the mutant mRNA and the corresponding wild-type mRNA.
Here we show that cosuppression can block expression of A. tumefaciens T-DNA oncogenes, resulting in plants that are resistant to gall induction by certain strains of A. tumefaciens. / Graduation date: 1999
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