Development of a reporter system for the analysis of xylophilus ampelinus type III secreted effectors

Nyembe, Nompumelelo Philile Praiseworth

January 2014

>Magister Scientiae - MSc / Xylophilus ampelinus, the causal agent of bacterial blight and canker of grapevines, has long been a threat to the table grape industry in the Western Cape, leading to severe economic losses due to the reduced productivity and shortened lifespan of infected grapevines. Very little is known about the genetic makeup of the organism, especially with regard to the factors that contribute to its pathogenicity. Generally, bacterial pathogens directly inject the effector proteins into host cells via Type III secretion system (T3SS). In the attempts to identify and characterize the T3 secreted effectors, different reporter plasmid systems have been used to study the secretion and translocation mechanisms the effectors employ during pathogenicity. The aim of the study was to generate a T3 reporter plasmid system for X. ampelinus that will allow the identification and classification of potential pathogenicity factors as members of the Type III secretion class of effectors. First, the avrBs1 family genes avrBs1 and avrA were identified and characterized. The two avirulence genes induced HR on Nicotiana tabacum leaves. Due to the relatedness of the X. ampelinus avr sequences to those of xanthomonads, and the fact that Xanthomonas avrBs1 has been successfully used in a number T3 effector studies, it was decided to construct an X. ampelinus T3 effector reporter vector based on the avrBs1 gene. The minimal segment of the X. ampelinus AvrBs1 protein C-terminus, sufficient for recognition inside host cells and also responsible for HR-induction was identified and characterized using Agrobacterium-mediated transient expression. The AvrBs157-413 HR-inducing domain was cloned in-frame with the 3x FLAG epitope, into a broad-host range vector. To test the reporter vector, the full length avrBs1 sequences of X. ampelinus and Xanthomonas campestris pv. campestris were cloned ahead of the 3x FLAG epitope and the constructs were transferred into XaΔavrBs1 knockout mutant to test for protein secretion. Furthermore, the reporter construct was tested for Type III protein translocation on Bs1 resistant pepper cultivar STAR 6657. Optimization of protein secretion and translocation assays is however required for the improved results. This might include the application of an alternative protein tag to identify candidate X. ampelinus T3SS effectors.

Vitis vinifera

Xylophilus ampelinus

Bacterial effectors

Synthesis and investigation of bacterial effector molecules

Albers, Michael Franz

January 2016

During infections, bacterial microorganisms initiate profound interactions with mammalian host cells. Usually defense mechanisms of the host destroy intruding bacteria in rapid manner. However, many bacterial pathogens have evolved in a way to avoid these mechanisms. By use of effector molecules, which can be small organic molecules or proteins with enzymatic activity, the host is manipulated on a molecular level. Effectors mediating post-translational modifications (PTMs) are employed by many pathogens to influence the biological activity of host proteins. In the presented thesis, two related PTMs are investigated in detail: Adenylylation, the covalent transfer of an adenosine monophosphate group from adenosine triphosphate onto proteins, and phosphocholination, the covalent transfer of a phosphocholine moiety onto proteins. Over the past years, enzymes mediating these modifications have been discovered in several pathogens, especially as a mechanism to influence the signaling of eukaryotic cells by adenylylating or phosphocholinating small GTPases. However, the development of reliable methods for the isolation and identification of adenylylated and phosphocholinated proteins remains a vehement challenge in this field of research. This thesis presents general procedures for the synthesis of peptides carrying adenylylated or phosphocholinated tyrosine, threonine and serine residues. From the resulting peptides, mono-selective polyclonal antibodies against adenylylated tyrosine and threonine have been raised. The antibodies were used as tools for proteomic research to isolate unknown substrates of adenylyl transferases from eukaryotic cells. Mass spectrometric fragmentation techniques have been investigated to ease the identification of adenylylated proteins. Furthermore, this work presents a new strategy to identify adenylylated proteins. Additionally, small effector molecules are involved in the regulation of infection mechanisms. In this work, the small molecule LAI-1 (Legionella autoinducer 1) from the pathogen Legionella pneumophila, the causative agent of the Legionnaire’s disease, was synthesised together with its amino-derivatives. LAI-1 showed are a clear pharmacological effect on the regulation of the life cycle of L. pneumophila, initiating transmissive traits like motility and virulence. Furthermore, LAI-1 was shown to have an effect on eukaryotic cells as well. Directed motility of the eukaryotic cells was significantly reduced and the cytoskeletal architecture was reorganised, probably by interfering with the small GTPase Cdc42.

bacterial effectors

organic synthesis

Legionella

PTM

peptide synthesis

nucleotide chemistry

Investigation of Wolbachia symbiosis in isopods and filarial nematodes by genomic and interactome studies / Étude des relations symbiotiques entre Wolbachia et les isopodes et nématodes par analyses génomiques et de l'intéractome

Geniez, Sandrine

27 September 2013

Les Wolbachia sont des alpha-proteobactéries présentes chez de nombreux arthropodes et nématodes filaires. Ces bactéries héritées maternellement induisent chez leurs hôtes des phénotypes allant du parasitisme au mutualisme, avec le long de ce continuum des phénotypes tels que la féminisation (F), l'incompatibilité cytoplasmique (IC) ou la mort des mâles. Wolbachia est ainsi un modèle particulièrement intéressant pour étudier les différents types de relations symbiotiques.Chez Brugia malayi, comme pour les autres nématodes filaires, Wolbachia vit en symbiose obligatoire avec son hôte. L'élimination de la bactérie par des traitements antibiotiques entraîne une perte de fertilité voire la mort du nématode. Chez l'isopode terrestre Armadillidium vulgare, Wolbachia induit la féminisation des mâles génétiques en femelles fonctionnelles entraînant des biais de sex-ratio vers les femelles dans la descendance.Pour comprendre les mécanismes impliqués dans ces deux symbioses, nous avons mis au point une nouvelle méthode de capture pour isoler l'ADN de Wolbachia et séquencer 8 souches de Wolbachia d'isopodes (F et IC). Une étude de génomique comparative a permis d'établir un premier pan-génome des bactéries du genre Wolbachia et d'identifier 2, 5 et 3 gènes présents seulement chez les souches mutualistes, féminisantes ou induisant la mort des mâles. L'expression des gènes potentiellement impliqués dans la féminisation ou le mutualisme a été étudiée au cours du développement de l'hôte. L'étude de l'interactome protéique bactérie-hôte a ensuite été initiée en utilisant comme appât des protéines bactériennes à domaines eucaryotes en vue d'identifier les cibles de Wolbachia chez l'hôte. / Bacteria of the genus Wolbachia are gram-negative alpha-proteobacteria present in many arthropods and filarial nematodes. These obligate intracellular bacteria are maternally inherited and induce a large number of phenotypes across the symbiosis continuum from mutualism to parasitism, including feminization (F), cytoplasmic incompatibility (CI) or male killing. Studying Wolbachia symbioses is therefore of particular interest in the investigation of symbiotic relationships.In Brugia malayi and other filarial nematodes, they are obligate leading to a loss of worm fertility, and eventual death upon their depletion with antibiotic. In arthropods, they rather are parasitic. In the isopod crustacean Armadillidium vulgare they cause feminization when present: genetic males develop as functional female leading to female biased sex-ratio progenies.In order to understand the molecular mechanisms of these two symbioses, we set up a new capture procedure to catch Wolbachia DNA and performed whole-genome sequencing on 8 Wolbachia strains, symbionts of isopods (F & CI). Comparative genomics led to the establishment of the Wolbachia pan-genome as well as the identification of phenotype related gene patterns. We identified 2, 5 and 3 genes that are only found in mutualist, feminizing and male killing strains, respectively. Expression of genes potentially involved in feminization and mutualism were also analyzed throughout host post-embryonic development. Host-symbiont interactome approach was then initiated by protein-protein interaction studies using bacterial proteins with eukaryote like motifs as bait in order to identify Wolbachia host targets involved in symbiosis.

Wolbachia

Symbiose

Séquençage de génomes bactériens

Ngs

Pan--Génome

Génomique comparative

Effecteurs bactériens

Interactome hôte/symbiote

Transcriptomique

Armadillidium vulgare

Crustacés isopodes

Féminisation

Brugia malayi

Nématodes

Mutualisme

Wolbachia

Symbiosis

Whole--Genome sequencings

Ngs

Pan--Genome

Comparative genomics

Bacterial effectors

Host--Symbiont interactome

Transcriptomics

Armadillidium vulgare

Isopod crustaceans

Feminization

Brugia malayi

Nematodes

Mutualism

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