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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Etude du système de sécrétion de type VI chez Escherichia coli entéro-agrégatif : Caractérisation d'un sous complexe d'ancrage membranaires

Aschtgen, Marie-Stéphanie 16 December 2011 (has links)
Bacterial pathogenesis relies on a subset of mechanisms including adhesion to various matrices, antibiotic resistance, defence and action against surrounding microorganisms, and secretion of virulence factors. Among the secretion systems, the recently identified Type VI secretion system (T6SS) has been shown to be involved in both virulence against eukaryotic cells and inter-bacterial warfare. T6SS are composed of a minimum of 13 proteins called "core components". It is believe to form a macromolecular system that spans the envelope to assemble an extracellular structure composed of the Hcp protein with a trimer of VgrG located at the tip. This model has been built following in silico and structural analyses demonstrating the link between several T6SS subunits and bacteriophage T4 baseplate and tail elements. Other T6SS subunits include membrane proteins. Using enteroaggregative Escherichia coli as a bacterial model, the aim of my work is to understand how this system assembles in the cell envelope. I recently showed that four of these membrane proteins, SciP, SciS, SciN and SciZ make contact to form a complex [1]. These four subunits are critical components of the T6SS. I then delineated the interaction network, demonstrating that SciZ interacts with SciP, and that SciS interacts with both SciP and SciN. Further characterization of these subunits showed that SciN is a lipoprotein associated with the outer membrane [2, 4], whereas SciP and SciS are inner membrane proteins anchored through a single and three transmembrane segments respectively. SciZ is a polytopic inner membrane protein carrying a peptidoglycan-binding motif within its periplasmic domain. Mutagenesis and peptidoglycan binding experiments demonstrated that SciZ anchors the T6SS to the cell wall [1, 3]. Overall, we have identified and characterized a trans-envelope complex anchored in both membrane and to the peptidoglycan layer. / Bacterial pathogenesis relies on a subset of mechanisms including adhesion to various matrices, antibiotic resistance, defence and action against surrounding microorganisms, and secretion of virulence factors. Among the secretion systems, the recently identified Type VI secretion system (T6SS) has been shown to be involved in both virulence against eukaryotic cells and inter-bacterial warfare. T6SS are composed of a minimum of 13 proteins called "core components". It is believe to form a macromolecular system that spans the envelope to assemble an extracellular structure composed of the Hcp protein with a trimer of VgrG located at the tip. This model has been built following in silico and structural analyses demonstrating the link between several T6SS subunits and bacteriophage T4 baseplate and tail elements. Other T6SS subunits include membrane proteins. Using enteroaggregative Escherichia coli as a bacterial model, the aim of my work is to understand how this system assembles in the cell envelope. I recently showed that four of these membrane proteins, SciP, SciS, SciN and SciZ make contact to form a complex [1]. These four subunits are critical components of the T6SS. I then delineated the interaction network, demonstrating that SciZ interacts with SciP, and that SciS interacts with both SciP and SciN. Further characterization of these subunits showed that SciN is a lipoprotein associated with the outer membrane [2, 4], whereas SciP and SciS are inner membrane proteins anchored through a single and three transmembrane segments respectively. SciZ is a polytopic inner membrane protein carrying a peptidoglycan-binding motif within its periplasmic domain. Mutagenesis and peptidoglycan binding experiments demonstrated that SciZ anchors the T6SS to the cell wall [1, 3]. Overall, we have identified and characterized a trans-envelope complex anchored in both membrane and to the peptidoglycan layer.
22

Caracterização genotípica e fenotípica de mutantes não aderentes de Escherichia coli enteropatogênica atípica do sorotipo O125ac:H6. / Genotypic and phenotypic characterization of nonadherent mutants of atypical enteropathogenic Escherichia coli of serotype 0125ac:H6.

Ruiz, Renato de Mello 03 April 2009 (has links)
O sorotipo O125ac:H6 compreende amostras de Escherichia coli enteropatogênica atípicas que apresentam o padrão de adesão agregativa (AA) em células HEp-2. A construção de um banco de mutantes da amostra protótipo Ec292/84 com o transposon TnphoA gerou quatro mutantes não aderentes. O objetivo deste estudo foi a caracterização genotípica e fenotípica desses mutantes. As regiões adjacentes à inserção do TnphoA no mutante Ec2921/84::01 foram amplificadas, clonadas e seqüenciadas, revelando que a inserção do TnphoA ocorreu no gene secD, parte do sistema de secreção de proteínas do tipo 2 (SST2). O perfil de proteínas de membrana externa (OMP) dos mutantes, em comparação com a amostra selvagem, revelou a ausência de proteínas de 21 e 30 kDa nos mutantes. Um antissoro obtido contra o extrato de OMP da amostra protótipo inibiu o padrão AA e reconheceu a proteína de 30 kDa em immunoblottings com extratos de OMP. Esses dados indicam que esta proteína está envolvida no estabelecimento do padrão AA de E. coli O125ac:H6 e que essa proteína é transportada através do SST2. / The serotype O125ac:H6 comprises atypical Enteropathogenic Escherichia coli strains that express the aggregative adherence (AA) pattern to HEp-2 cells. We obtained four nonadherent mutants using TnphoA insertion in the Ec292/84 strain. The aim of this study was the genetic and phenotypic characterization of these mutants. The genetic analysis of the mutants revealed that the insertion of TnphoA ocurred in the secD gene, part of the bacterial type 2 secretion system (T2SS). The mutant outer membrane proteins (OMP) profile, in comparison to the prototype strain, demonstrated the lack of expression of proteins of 21 and 30 kDa in the mutant profile. An antiserum raised against the OMP extract of the prototype strain, in addition to inhibit the AA pattern, recognized the 30 kDa protein in immunoblotting assays with OMP extract. These data indicate this OMP is involved in the establishment of the AA pattern presented by the atypical EPEC strains of the O125ac:H6 serotype, and that this protein is transported via the T2SS.
23

Regulation of the Pseudomonas aeruginosa type III secretion system by cyclic-di-GMP

Bailin, Adam 01 May 2017 (has links)
Pseudomonas aeruginosa is a gram-negative pathogen that causes opportunistic infections in immunocompromised individuals. Whereas clinical isolates from acute infections are characterized by host cell cytotoxicity and motility, isolates from chronic infections are characterized by biofilm formation and persistence. The type III secretion system (T3SS) causes cytotoxicity by injecting effectors into host cells. T3SS gene expression is activated by ExsA, an AraC family transcriptional regulator. Transcription of exsA is controlled by two promoters, PexsC and PexsA, which are regulated by ExsA and the cAMP-Vfr system, respectively. Additional global regulatory systems also influence T3SS including the second messenger signaling molecule c-di-GMP and the RsmAYZ regulatory system. c-di-GMP signaling increases biofilm production and decreases acute virulence factor expression. A previous study found that c-di-GMP alters cAMP levels and affect cAMP-Vfr signaling. Other studies found that c-di-GMP signaling alters expression of the small non-coding regulatory RNAs, rsmY and rsmZ. The RsmAYZ post-transcriptional regulatory system regulates ExsA translation. We hypothesize that c-di-GMP regulates T3SS expression by altering exsA transcription through the cAMP-Vfr dependent PexsA promoter. Overexpression of YfiN, a c-di-GMP synthase, decreases T3SS reporter activity in PA103 and requires a functional GGDEF active site for full inhibition. Inhibition by YfiN does not require rsmYZ. YfiN expression decreases cAMP-Vfr signaling and coordinately inhibits PexsA-lacZ reporter activity. Consistent with the proposed model, YfiN expression in a vfr mutant does not further decrease T3SS reporter activity. These data indicate that the YfiN alters T3SS expression through transcriptional control of the cAMP-Vfr dependent PexsA promoter.
24

Defining the interaction of ESXA and LCRF with Type III secretion system gene promoters

King, Jessica Marie 01 December 2013 (has links)
Transcription of the Pseudomonas aeruginosa type III secretion system is controlled by ExsA, a member of the AraC/XylS family of regulators. ExsA is comprised of an amino terminal domain that is involved in self-association and regulatory functions, and a carboxy-terminal domain that contains two helix-turn helix (HTH) DNA-binding motifs which contact promoter DNA. Previous work from our lab determined the function of the two independent ExsA domains and found that each ExsA-dependent promoter contains two adjacent binding sites for monomeric ExsA. The promoter-proximal site (binding site 1) consists of highly conserved GnC and TGnnA sequences that are individually recognized by the two HTH DNA-binding motifs of an ExsA monomer. Nevertheless, the details of how ExsA recognizes and binds to ExsA-dependent promoters were still unknown. In chapter II I show that the two ExsA monomers bind to promoter regions in a head-to-tail orientation and identify residues in the first HTH of ExsA that contact the GnC sequence. Likewise, residues located in the second HTH motif, which contribute to the recognition of the TGnnA sequence, were also identified. While the GnC and TGnnA sequences are important for binding to site 1, the promoter-distal binding sites (site 2) lack obvious similarity among themselves or with binding site 1. Site 2 in the PexsC promoter region contains a GnC sequence that is functionally equivalent to the GnC in site 1 and recognized by the first HTH motif of an ExsA monomer and the second HTH interacts with an adenine residue in binding site 2. A comparison of hybrid promoters composed of binding site 2 from one promoter fused to binding site 1 derived from another promoter indicates that ExsA-binding affinity, promoter strength, and the degree of promoter bending are properties that are largely determined by binding site 2. Through the course of the ExsA studies I observed that the amino acids that comprise the HTH motifs of ExsA are nearly identical to those in LcrF/VirF, the activators of T3SS gene expression in the pathogenic yersiniae. In chapter III I tested the hypothesis that ExsA/LcrF/VirF recognize a common nucleotide sequence. Here I report that Yersinia pestis LcrF binds to and activates transcription of ExsA-dependent promoters in P. aeruginosa, and that plasmid expressed ExsA complements a Y. pestis lcrF mutant for T3SS gene expression. Mutations that disrupt the ExsA consensus-binding sites in both P. aeruginosa and Y. pestis T3SS promoters prevent activation by ExsA and LcrF. All of the data combined demonstrate that ExsA and LcrF recognize a common nucleotide sequence. Nevertheless, the DNA binding properties of ExsA and LcrF are distinct. Whereas two ExsA monomers are sequentially recruited to the promoter region, LcrF binds to promoter DNA as a preformed dimer and has a higher capacity to bend DNA. An LcrF mutant defective for dimerization bound promoter DNA with properties similar to ExsA. Finally, I demonstrate that the activators of T3SS gene expression from Photorhabdus luminescens, Aeromonas hydrophila, and Vibrio parahaemolyticus are also sensitive to mutations that disrupt the ExsA-consensus binding site. Taken together, this work shows that ExsA binding and activation at T3SS gene promoters serves as a model system by which the DNA binding properties of other AraC family transcriptional activators can be predicted.
25

Histoire évolutive de Xanthomonas arboricola, espèce bactérienne composée de souches pathogènes et commensales / Evolutionary history of Xanthomonas arboricola, bacterial species composed of pathogenic and commensal strains

Merda, Déborah 29 November 2016 (has links)
Comprendre l’émergence des maladies dans les agroécosystèmes nécessite d’étudier l’histoire évolutive des populations bactériennes associées aux plantes. L’objectif de ce travail était de déterminer les évènements évolutifsconduisant à l’émergence des lignées pathogènes ou pathovars dans l’espèce Xanthomonas arboricola. Une analyse de génétique des populations a été menée sur un panel de souches phytopathogènes et commensales et complétée par l’inférence des gains et pertes de facteurs de virulence. Cette espèce possède une structure de population épidémique ; les clones épidémiques ont émergé suite à l’acquisition de facteurs de virulence à partir d’un fond recombinant de souches commensales. Une analyse de génomique des populations et la reconstruction de scénarios de divergence entre ces clones et le réseau de souches recombinantes, a montré la persistance d’un flux de gènes asymétrique entre ces deux groupes, dans le sens souches pathogènes vers souches commensales. Enfin, l’histoire évolutive du principal facteur de virulence des Xanthomonas, le système de sécrétion de type 3, a été retracée au sein du genre, et a montré que celui-ci avait été acquis ancestralement puis perdu dans certaines souches commensales. En conclusion, l’ancêtre commun de X. arboricola possédait des facteurs de virulence et au sein des souches commensales, certaines ont perdu ces facteurs, tandis que d’autres ont conservé le répertoire ancestral. Ces dernières diffèrent peu de certains agents pathogènes, et pourraient représenter un risque pour de nouvelles émergences. Des travaux de génomique fonctionnelle permettraient de valider ces hypothèses. / Deciphering the evolutionary history of bacterial populations associated to plants is necessary to understand diseaseemergence in agroecosystems. The aim of this study is to unveil the evolutionary events responsible for pathogeniclineages or pathovar emergences in Xanthomonas arboricola. This species is composed of both plant pathogenic andcommensal strains Population genetics analyses and gain and loss inferences of virulence factors showed that X. arboricola exhibits an epidemic population structure, within which epidemic clones emerged from a recombinogenic background population following virulence factor acquisition. Population genomics and inference of divergence scenarii between epidemic clones and the network of recombinant strains showed persistence of homologous recombination along divergence of these two groups, with an asymmetric gene flux from pathogenic strains to commensal ones. Finally, evolutionary history of the type three secretion system (T3SS), the main virulence factor in Xanthomonas genus, was studied at genus scale and showed that T3SS was ancestrally acquired and lost in commensal strains. Altogether these analyses allowed us to show that the common ancestor of X.arboricola had virulence factors, and that within commensal strains, some lost these virulence factors whereas others kept the ancestral repertoire. These latter strains have a similar repertoire to that of some pathogenic strains, and could represent a risk for new disease emergence. Functional genomics could allow us to validate these hypotheses.
26

Evolutionary Processes and Genome Dynamics in Host-Adapted Bacteria

Nystedt, Björn January 2009 (has links)
Many bacteria live in close association with other organisms such as plants and animals, with important implications for both health and disease. This thesis investigates bacteria that are well adapted to live inside an animal host, and describes the molecular evolutionary processes underlying host-adaptation, based on bacterial genome comparisons. Insect-transmitted bacteria of the genus Bartonella infect the red blood cells of mammals, and we investigate host adaptation and genome evolution in this genus. In Bartonella, many host-interaction systems are encoded in a highly variable chromosomal segment previously shown to be amplified and packaged into bacteriophage particles. Among all genes imported into the Bartonella ancestor, we identify the short gene cluster encoding these phage particles as the most evolutionary conserved, indicating a strong selective advantage and a role in niche adaptation. We also provide an overview of the remarkable evolutionary dynamics of type IV and type V secretion systems, including a detailed analysis of the type IV secretion system trw. Our results highlight the importance of recombination and gene conversion in the evolution of host-adaptation systems, and reveal how these mutational mechanisms result in strikingly different outcomes depending on the selective constraints. In the insect endosymbionts Buchnera and Blochmannia, we show that genes frameshifted at poly(A) tracts can remain functional due to transcriptional slippage. Selection against poly(A) tracts is very inefficient in these genomes compared to other bacteria, and we discuss why this can lead to increased rates of gene loss. Using the human pathogen Helicobacter pylori as a model, we provide a deeper understanding of why highly expressed genes evolve slowly. This thesis emphasizes the power of using complete genome sequences to study evolutionary processes. In particular, we argue that knowledge about the complex evolution of duplicated gene segments is crucial to understand host adaptation in bacteria.
27

Genome Evolution and Host Adaptation in Bartonella

Berglund, Eva Caroline January 2009 (has links)
Bacteria of the genus Bartonella infect the red blood cells of a wide range of wild and domestic mammals and are transmitted between hosts by blood-sucking insects. Although most Bartonella infections are asymptomatic, the genus contains several human pathogens. In this work, host adaptation and host switches in Bartonella have been studied from a genomic perspective, with special focus on the acquisition and evolution of genes involved in host interactions. As part of this study, the complete genome of B. grahamii isolated from a Swedish wood mouse was sequenced. A genus-wide comparison revealed that rodent-associated Bartonella species, which have rarely been associated with human disease, have the largest genomes and the largest number of host-adaptability genes. Analysis of known and putative genes for host interactions identified several families of autotransporters as horizontally transferred to the Bartonella ancestor, with a possible role both during early host adaptation and subsequent host shifts. In B. grahamii, the association of a gene transfer agent (GTA) and phage-derived run-off replication of a large genomic segment was demonstrated for the first time. Among all acquisitions to the Bartonella ancestor, the only well conserved gene clusters are those that encode the GTA and contain the origin of the run-off replication. This conservation, along with a high density of host-adaptability genes in the amplified region suggest that the GTA provides a strong selective advantage, possibly by increasing recombination frequencies of host-adaptability genes, thereby facilitating evasion of the host immune system and colonization of new hosts. B. grahamii displays stronger geographic pattern and higher recombination frequencies than the cat-associated B. henselae, probably caused by different lifestyles and/or population sizes of the hosts. The genomic diversity of B. grahamii is markedly lower in Europe and North America than in Asia, possibly an effect of reduced host variability in these areas following the latest ice age.
28

Identification of protein-protein interactions in the type two secretion system of <i>aeromonas hydrophila</i>

Zhong, Su 09 March 2009
The type II secretion system is used by many pathogenic and non-pathogenic bacteria for the extracellular secretion of enzymes and toxins. <i>Aeromonas hydrophila</i> is a Gram-negative pathogen that secretes proteins via the type II secretion system.<p> In the studies described here, a series of yeast two-hybrid assays was performed to identify protein-protein interactions in the type II secretion system of <i>A. hydrophila</i>. The periplasmic domains of ExeA and ExeB were assayed for interactions with the periplasmic domains of Exe A, B, C, D, K, L, M, and N. Interactions were observed for both ExeA and ExeB with the secretin ExeD in one orientation. In addition, a previously identified interaction between ExeC and ExeD was observed. In order to further examine and map these interactions, a series of eight two-codon insertion mutations in the amino terminal domain of ExeD was screened against the periplasmic domains of ExeA and ExeB. As a result, the interactions were verified and mapped to subdomains of the ExeD periplasmic domain. To positively identify the region of ExeD involved in the interactions with ExeA, B, C and D, deletion mutants of ExeD were constructed based on the two-codon insertion mutation mapping of subdomains of the ExeD periplasmic domain, and yeast two-hybrid assays were carried out. The results showed that a fragment of the periplasmic domain of ExeD, from amino acid residue 26 to 200 of ExeD, was involved in the interactions with ExeA, B and C. As an independent assay for interactions between ExeAB and the secretin, His-tagged derivatives of the periplasmic domains of ExeA and ExeB were constructed and co-purification on Ni-NTA agarose columns was used to test for interactions with untagged ExeD. These experiments confirmed the interaction between ExeA and ExeD, although there was background in the co-purification test.<p> These results provide support for the hypothesis that the ExeAB complex functions to organize the assembly of the secretin through interactions between both peptidoglycan and the secretin that result in its multimerization into the peptidoglycan and outer membrane layers of the envelope.
29

Colonization of cattle by non-O157 Shiga Toxin-producing <i>Escherichia coli</i> serotypes

Asper, David Jose 29 September 2009
Shiga toxin-producing <i>E. coli</i> (STEC) is an important food- and water-borne pathogen of humans, causing Hemorrhagic Colitis and Haemolytic Uremic Syndrome. Colonization of both cattle and human hosts is mediated through the action of effector molecules secreted via a type III secretion system (T3SS), which forms attaching and effacing lesions (A/E). The necessary effectors which form A/E by manipulation of host signalling and actin nucleation are present on a pathogenicity island called the Locus of Enterocyte Effacement (LEE).<p> It has been reported that vaccination of cattle with Type III-secreted proteins (T3SPs) from STEC O157 resulted in decreased shedding. In order to extend this to non-O157 STEC serotypes, we examined the serological cross-reactivity of T3SPs of serotypes O26:H11, O103:H2, O111:NM and O157:H7. Groups of cattle were vaccinated with T3SPs produced from each of the serotypes and the magnitude and specificity of the responses were measured resulting in limited cross reactivity. Overall, results suggest that vaccination of cattle with T3SPs as a means of reducing the risk of STEC transmission to humans will induce protection that is serotype specific.<p> To pursue the possibility of a cross-protective vaccine, we investigated the protective properties of a chimeric Tir protein against STEC serotypes. Several studies have reported that Tir is highly immunogenic and capable of producing high antibody titers. Potter and colleagues also demonstrated that the vaccination of cattle with ∆tir STEC O157 strain did not protect as well as the wildtype strain. We constructed thirty-mer peptides to the entire STEC O157 Tir protein, as well as to the intimin binding domain of the Tir protein from STEC serotype O26, O103 and O111. Using sera raised against STEC O157 and non-O157 T3SPs, we identified a number of immunogenic peptides containing epitopes unique to a particular serotype. Two different chimeric Tir proteins were constructed containing the STEC O157 Tir protein fused with six STEC non-O157 peptides with or without the Leukotoxin produced by <i>Mannheimia haemolytica</i>. However, the vaccination of mice with the chimeric protein did not protect against challenge with STEC O157 or STEC O111. These results suggest that to achieve cross protection against STEC serotypes using a recombinant protein vaccine, other immunogenic and protective antigens must also be included.<p> In order to identify other immunogenic and cross-protective antigens we cloned and expressed the genes coding for 66 effectors and purified each as histidine-tagged proteins. These included 37 LEE-encoded proteins and 29 non-LEE effectors. The serological response against each protein was measured by Western blot analysis and an enzyme-linked immunosorbent assay (ELISA) using sera from rabbits immunized with T3SPs from four STEC serotypes, experimentally infected cattle and human sera from 6 HUS patients. A total of 20 proteins were recognized by at least one of the STEC T3SP- vaccinated rabbits using Western blots. Sera from experimentally infected cattle and HUS patients were tested using an ELISA against each of the proteins. Tir, EspB, EspD, EspA and NleA were recognized by the majority of the samples tested. Overall, proteins such as Tir, EspB, EspD, NleA and EspA were highly immunogenic for both vaccinated and naturally infected subjects.<p> Based on the above results, two different mixtures of secreted proteins (5 proteins and 9 proteins) were used to vaccinate mice and test the level of shedding following challenge with STEC O157. Overall, the cocktail vaccine containing 9 immunogenic effectors including Tir, EspB, EspD, NleA and EspA was capable of reducing shedding as effectively as the current STEC T3SPs vaccine, Econiche®.
30

Role of Salmonella enterica subspecies enterica serovar Enteritidis pathogenicity island-2 in chickens

Wisner, Amanda Lynn Stacy 02 August 2011
Salmonella enterica subspecies enterica serovar Enteritidis (S. Enteritidis) has been identified as a significant cause of salmonellosis in humans. Salmonella pathogenicity islands 1 and 2 (SPI-1 and SPI-2) each encode a specialized type III secretion system (T3SS) that enables Salmonella to manipulate host cells at various stages of the invasion/infection process. The SPI-2 T3SS has been identified as vital for survival and replication of S. Typhimurium and S. Enteritidis in mouse macrophages, as well as full virulence in mice. In order to test the ability of SE SPI-2 mutants to survive in vivo we used a chicken isolate of SE (Sal18). In one study, we orally co-challenged 35-day-old specific pathogen free (SPF) chickens with two bacterial strains per group. The control group received two versions of the wild-type (WT) strain Sal18: Sal18 attTn7::tet and Sal18 attTn7::cat, while the other two groups received the WT strain (Sal18 attTn7::tet) and one of two mutant strains (Sal18 attTn7::cat ÄspaSÄssaU or Sal18 ÄSPI-1ÄSPI-2::cat). From this study we conclude that S. Enteritidis deficient in the SPI-1 and SPI-2 systems are out-competed by the WT strain. In a second study, groups of SPF chickens were challenged at 1 week of age with four different strains; a WT strain and three other strains missing either one or both of the SPI-1 and SPI-2 regions. On days 1 and 2 post-challenge (PC) we observed a reduced systemic spread of the SPI-2 mutants, but by day 3 the mutants systemic distribution levels matched that of the WT strain. Based on these two studies, we conclude that the SPI-2 T3SS facilitates invasion and systemic spread of S. Enteritidis in chickens, but alternative mechanisms for these processes appear to exist. Several structural components of the T3SSs encoded by SPI-1 and SPI-2 are exposed to the hosts immune system prior to/during the infection/invasion process, making them potential vaccine candidates. Several of these candidates genes were cloned, the proteins overproduced, purified, and formulated as vaccines for use in further studies. SPI-2 T3SS proteins used for vaccine studies included the secretin, SsaC, the needle, SsaG, the filament, SseB, and a part of the translocon, SseD, as well as a number of effectors, SseI, SseL, SifA, and SifB. The first vaccine study involved vaccination of SPF chickens with SseB and SseD, followed by challenge with the WT S. Enteritidis strain Sal18. Additional studies evaluated whether hens vaccinated with SPI-2 T3SS structural or effector components could mount a significant humoral immune response (as measured by serum immunoglobulin Y [IgY] titres), whether these antibodies could be transferred to progeny (as measured by egg yolk IgY titres), and whether vaccinates and progeny of vaccinates could be protected against challenge with the WT S. Enteritidis strain Sal8. The results of our studies show that vaccinated chickens do produce high levels of SPI-2 T3SS specific serum IgY that they are able to transfer to their progeny. It was demonstrated that vaccinates and progeny of vaccinates had lower overall countable recovered SE per bird in most situations. In order to better identify the role of the SPI-2 T3SS in chickens, we used the well-known gentamicin protection assay with activated HD11 cells. HD11 cells are a macrophage-like chicken cell line that can be stimulated with phorbol 12-myristate 13-acetate (PMA) to exhibit more macrophage-like morphology and greater production of reactive oxygen species (ROS). Activated HD11 cells were infected with a WT S. Typhimurium strain, a SPI-2 mutant S. Typhimurium strain, a WT S. Enteritidis strain, a SPI-2 mutant S. Enteritidis strain, or a non-pathogenic Escherichia coli (E. coli) strain. SPI-2 mutant strains were found to survive as well as their parent strain at all time points post-infection (PI) up to 24 h PI, while the E. coli strain was no longer recoverable by 3 h PI. We can conclude from these observations that the SPI-2 T3SS is not important for survival of Salmonella in the activated macrophage-like HD11 cell line, and that Salmonella must employ other mechanisms for survival in this environment as E. coli is effectively eliminated.

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