Global ETD Search

1	Iron regulation in Burkholderia cepacia and Burkholderia pseudomallei Lowe, Carolyn Ann January 2001 (has links) No description available. 579 Virulence mechanisms
2	Understanding the Resistance and Virulence Mechanisms of Staphylococcus Epidermidis Triggered During Skin Disinfection, Blood Production and Storage Alabdullatif, Meshari 07 January 2019 (has links) Bacterial contamination of platelet concentrates (PCs) represents the highest post-transfusion infectious risk. The skin flora bacterium Staphylococcus epidermidis has been reported to be the predominant aerobic contaminant of PCs. The Ramirez' group has shown that S. epidermidis can form surface-attached bacterial aggregates known as biofilms, and can outcompete other coagulase-negative staphylococci, such as Staphylococcus capitis, in PCs. The ability of S. epidermidis to form biofilms has been linked to increased pathogenicity and missed detection during PC screening with an automated culture system (BacT/ALERT). This thesis aimed at investigating the proliferative advantage and resistance mechanisms displayed by S. epidermidis in the PC milieu. Furthermore, in an effort to enhance PC safety for transfusion patients, I studied the anti-biofilm properties of essential oils and antimicrobial peptides (AMPs). My studies aimed at improving PC safety by focussing on both the point of introduction of bacterial contaminants (blood collection), and the stage at which bacterial contaminants can form biofilms and proliferate (PC storage). S. epidermidis can be found in the skin of blood donors as biofilms, which are resistant to the blood donor skin disinfectant currently used by Canadian Blood Services, chlorhexidine-gluconate and isopropyl alcohol (CHG-IPA). Here, several plant-extracted essential oils were evaluated for their ability to enhance the anti-biofilm activity of CHG-IPA. Data revealed that the Lavandula multifida oil and its main component (linalool) greatly enhanced the activity of CHG-IPA against S. epidermidis biofilms. Furthermore, the ability of a combination of three synthetic AMPs to inhibit S. epidermidis biofilm formation during PC storage was assessed These results showed that the combination of AMPs could inhibit biofilm formation but was ineffective against pre-formed S. epidermidis biofilms. The accumulation associated protein (Aap) encoded by the aap gene, found in most S. epidermidis strains and absent in S. capitis, plays a role in biofilm formation. When S. epidermidis aap is transformed into S. capitis, this bacterium displayed increased biofilm formation and proliferated to higher concentrations compared to untransformed S. capitis and to a S. epidermidis aap deletion mutant. Based on these results, aap appears to play a role in providing S. epidermidis a proliferative advantage in PCs by enhancing biofilm formation. Lastly, the GraRS system and SepA were studied for their role in S. epidermidis resistance to platelet-derived AMPs using the synthetic AMP PD4 as a model molecule. Results indicate that the GraS mechanism is involved in resistance towards PD4. The work presented in my thesis provides further insights into why S. epidermidis has a proliferative advantage in the PC storage environment and allows for the proposal of alternative methods to enhance PC safety for transfusion patients. Staphylococcus epidermidis Resistance mechanisms Virulence mechanisms Skin disinfection Blood production
3	Investigation of Burkholderia cepacia Virulence Mykrantz, Hallie B. 22 April 2005 (has links) No description available. Biology, Microbiology Caenorhabditis elegans Burkholderia cepacia cystic fibrosis virulence mechanisms transposon mutagenesis lipase protease phospholipase C
4	Virulence mechanisms of pathogenic Yersinia : aspects of type III secretion and twin arginine translocation Lavander, Moa January 2005 (has links) <p>The pathogenic bacteria Yersinia pestis and Y. pseudotuberculosis are related to the degree where the former is considered a subspecies of the latter, and still they cause disease of little resemblance in humans. Y. pestis is the causative agent of lethal bubonic and pneumonic plague, while Y. pseudotuberculosis manifests itself as mild gastroenteritis. An important virulence determinant for these species is their ability to secrete and inject toxins (Yop effectors) into immune cells of the infected host, in a bacterium-cell contact dependent manner. This ability depends on the extensively studied type III secretion system, a highly complex multicomponent structure resembling a needle. The induction of Yop secretion is a strictly controlled event. The two structural type III secretion components YscU and YscP are here shown to play a crucial role in this process, which is suggested to require an YscP mediated conformational change of the C-terminus of YscU. Proteolytic cleavage of YscU within this domain is further revealed to be a prerequisite for functional Yop secretion. The needle subcomponent itself, YscF, is recognised as a regulatory element that controls the induction of Yop effectors and their polarised delivery into target cells. Potentially, the needle might act as a sensor that transmits the inducing signal (i.e. target cell contact) to activate the type III secretion system. Secondly a, for Yersinia, previously unexplored system, the Twin arginine translocation (Tat) pathway, is shown to be functional and absolutely required for virulence of Y. pseudotuberculosis. A range of putative Yersinia Tat substrates were predicted in silico, which together with the Tat system itself may be interesting targets for future development of antimicrobial treatments.</p> Molecular biology Yersinia pestis Yersinia pseudotuberculosis bacterial pathogenesis type III secretion twin arginine translocation virulence mechanisms YscU YscP YscF Molekylärbiologi Molecular biology Molekylärbiologi
5	Virulence mechanisms of pathogenic Yersinia : aspects of type III secretion and twin arginine translocation Lavander, Moa January 2005 (has links) The pathogenic bacteria Yersinia pestis and Y. pseudotuberculosis are related to the degree where the former is considered a subspecies of the latter, and still they cause disease of little resemblance in humans. Y. pestis is the causative agent of lethal bubonic and pneumonic plague, while Y. pseudotuberculosis manifests itself as mild gastroenteritis. An important virulence determinant for these species is their ability to secrete and inject toxins (Yop effectors) into immune cells of the infected host, in a bacterium-cell contact dependent manner. This ability depends on the extensively studied type III secretion system, a highly complex multicomponent structure resembling a needle. The induction of Yop secretion is a strictly controlled event. The two structural type III secretion components YscU and YscP are here shown to play a crucial role in this process, which is suggested to require an YscP mediated conformational change of the C-terminus of YscU. Proteolytic cleavage of YscU within this domain is further revealed to be a prerequisite for functional Yop secretion. The needle subcomponent itself, YscF, is recognised as a regulatory element that controls the induction of Yop effectors and their polarised delivery into target cells. Potentially, the needle might act as a sensor that transmits the inducing signal (i.e. target cell contact) to activate the type III secretion system. Secondly a, for Yersinia, previously unexplored system, the Twin arginine translocation (Tat) pathway, is shown to be functional and absolutely required for virulence of Y. pseudotuberculosis. A range of putative Yersinia Tat substrates were predicted in silico, which together with the Tat system itself may be interesting targets for future development of antimicrobial treatments. Molecular biology Yersinia pestis Yersinia pseudotuberculosis bacterial pathogenesis type III secretion twin arginine translocation virulence mechanisms YscU YscP YscF Molekylärbiologi Molecular biology Molekylärbiologi
6	Salmonella virulence factors and their role in intracellular parasitism Möst, Thomas 17 October 2014 (has links) Salmonella est un pathogène intracellulaire dont la virulence dépend de la fonction de deux systèmes de sécrétion du type trois (T3SS). Les T3SSs sont responsables pour la transduction de protéines effectrices dans le cytoplasme de la cellule hôte afin d'initier l'invasion de la cellule et de former la vie intracellulaire de Salmonella. Plusieurs effecteurs forment la SCV et induisent un réseau de tubules qui est impliqué dans la stabilisation de la SCV. Il consiste de trois différents genres de tubules. Nous avons pu montrer que les protéines effectrices SseF et SseG sont responsables pour la formation d'un genre de ces tubules, les LAMP-1 negative tubules (LNTs). Leur fonction est importante puisque des souches de Salmonella qui induisent que des LNTs et ne pas d'autres tubules sont apte de créer une SCV stable. Ceci améliore la réplication et virulence in vivo comparé à des souches qui ne peuvent pas induire des tubules. En utilisant les LNTs comme modèle, nous avons essayé de comprendre la contribution des tubules à la formation de la SCV et aussi leurs interaction avec les endosomes tardives et les lysosomes (LE/lys). Nous avons découvert une contribution essentielle de la petite GTPase Arl8B à la fusion de tubules avec les LE/lys. Ainsi, le knockdown d'Arl8B réduit la capacité de reproduction de Salmonella dans la cellule hôte. Nous avons pu démontrer qu'une interaction entre l'effecteur SifA et Arl8B est responsable pour ces observations. / Salmonella is an intracellular pathogen, whose virulence relies on the function of two type three secretion systems (T3SSs). The T3SSs are responsible for the delivery of effector proteins into the host cell cytoplasm in order to mediate invasion of the cell and to shape Salmonella's intracellular life.Salmonella's intracellular survival and replication depends on its niche, the Salmonella containing vacuole (SCV), a compartment that is derived from host plasma membrane. Several effectors shape the SCV and give rise to a tubular network, which is implicated in the SCV's stabilization and consists of three different kinds of tubules. We were able to show that the effector proteins SseF and SseG play in concert to form one kind of tubules, the recently discovered LAMP-1-negative tubules (LNTs). Their function is important to Salmonella, as strains having only LNTs but none of the other tubules are able to create a stable SCV, which leads to better replication and virulence in vivo compared to a strain that lacks in tubule formation. Starting from these LNTs as working model, we tried to understand the contribution of tubules to the formation of the SCV and their interactions with the late endosomal / lysosomal compartment (LE/lys). We deciphered the small GTPase Arl8B to play an essential role in the fusion of tubules with LE/lys. Thereby, the knockdown of Arl8B reduced Salmonella's capability to replicate within host cells. We were able to show that an interaction between the effector SifA and Arl8B was responsible for our observations. Salmonella Protéines effectrices Interaction pathogène - hôte Mechanismes de virulence Changements de proteome Salmonella Effector proteins Host - pathogen interaction Virulence mechanisms Proteomic changes 571
7	Identification and Characterization of a Burkholderia pseudomallei Factor H-Binding Protein Syed, Irum 11 July 2022 (has links) No description available. Biology Biomedical Research Experiments Health Sciences Immunology Microbiology Burkholderia Burkholderia pseudomallei melioidosis complement the complement system Factor H immune evasion virulence mechanisms
8	Caracterização do potencial patogênico de linhagens de Yersinia enterocolitica-like / Characterization of the pathogenic potential of Yersinia enterocolitica-like strains Imori, Priscilla Fernanda Martins 04 April 2016 (has links) Dentre as 18 espécies do gênero Yersinia, as espécies Y. enterocolitica, Y. pseudotuberculosis e Y. pestis foram extensivamente caracterizadas em diversos aspectos como ecologia, epidemiologia e mecanismos de patogenicidade. Sete das 15 espécies restantes (Y. aldovae, Y. bercovieri, Y. frederiksenii, Y. intermedia, Y. kristensenii, Y. mollaretii e Y. rohdei), usualmente conhecidas como Y. enterocolitica-like, até o momento, não tiveram seu potencial patogênico caracterizado e são, geralmente, consideradas não-patogênicas. Entretanto, dados da literatura sugerem que algumas dessas espécies possam causar doença. Esses dados estimularam o surgimento de questões sobre os mecanismos pelos quais as espécies de Y. enterocolitica-like possam interagir com as células do hospedeiros e causar doenças. Esse projeto teve como principal objetivo caracterizar o potencial patogênico de linhagens de Y. enterocolitica-like, especificamente das espécies Y. frederiksenii, Y. kristensenii e Y. intermedia. No presente trabalho, o potencial patogênico de 118 linhagens de Y. enterocolitica-like (50 Y. frederiksenii, 55 Y. intermedia e 13 Y. kristensenii) foi avaliado pela pesquisa da presença dos genes relacionados à virulência ail, fepA, fepD, fes, hreP, myfA, tccC, ystA, ystB e virF por PCR. Além disso, a habilidade de algumas linhagens de Yersinia de aderir e invadir células Caco-2 e HEp-2 após diferentes períodos de incubação, bem como, de sobreviver no interior de macrófagos humanos U937 foi testada. Aspectos morfológicos da adesão bacteriana foram visualizados por microscopia eletrônica. Finalmente, a presença de possíveis novos mecanismos de virulência foi avaliada a partir do sequenciamento de RNA de uma linhagem de Y. enterocolitica-like. As linhagens estudadas apresentaram os seguintes genes: Y. frederiksenii, fepA (44%), fes (44%) e ystB (18%); Y. intermedia, ail (53%), fepA (35%), fepD (2%), fes (97%), hreP (2%), ystB (2%) e tccC (35%); e Y. kristensenii, ail (62%), ystB (23%), fepA (77%), fepD (54%), fes (54%) e hreP (54%). De modo geral, as linhagens de Y. enterocolitica-like tiveram a habilidade de aderir e invadir células Caco-2 e HEp-2 inferior à da linhagem altamente patogênica Y. enterocolitica 8081. Contudo, Y. kristensenii FCF 410 e Y. frederiksenii FCF 461 apresentaram elevado potencial de invasão a células Caco-2 após cinco dias de pré-incubação, os quais foram 45 e 7,2 vezes maiores do que o controle Y. enterocolitica 8081, respectivamente, porém, o gene ail não foi detectado nessas linhagens. O ensaio de sobrevivência em macrófagos humanos U937 ii mostrou que as linhagens de Y. frederiksenii FCF 461 (40,0%) e Y. frederiksenii FCF 379 (24,6%) tiveram porcentagens de sobrevivência superior à de Y. enterocolitica 8081 (13,4%). Todavia, linhagens de Y. intermedia e Y. kristensenii apresentaram uma capacidade reduzida de sobreviver em macrófagos. A microscopia eletrônica de varredura mostrou as bactérias em contato com a filipódia celular. As bactérias foram distribuídas tanto individualmente quanto em pequenos aglomerados. Portanto, podemos concluir que a presença dos genes relacionados à virulência encontrados nas Y. enterocolitica-like estudadas indicou o possível potencial patogênico de algumas dessas linhagens. Os ensaios de adesão e invasão a células de mamíferos sugerem que a patogenicidade de Y. kristensenii e Y. frederiksenii possa ser linhagem-dependente. O ensaio de sobrevivência em macrófagos humanos U937 evidenciou o potencial patogênico de algumas linhagens de Y. frederiksenii. Em conjunto, os resultados obtidos sugerem a existência de mecanismos de virulência alternativos aos mecanismos clássicos descritos para Y. enterocolitica patogênica. Contudo, a presença de possíveis novos mecanismos de virulência não pode ser verificada, uma vez que a plataforma 454 GS Junior (Roche) não se mostrou adequada para a realização de sequenciamento de RNA de amostras provenientes de interações com células devido à baixa cobertura obtida. / Among the 18 species of the Yersinia genus, Y. enterocolitica, Y. pseudotuberculosis and Y. pestis were extensively characterized in different subjects as ecology, epidemiology and pathogenicity mechanisms. Seven among the remaining 15 species (Y. aldovae, Y. bercovieri, Y. frederiksenii, Y. intermedia, Y. kristensenii, Y. mollaretii and Y. rohdei), often called Y. enterocolitica-like have not their pathogenic potential characterized and are usually considered to be nonpathogenic. However, literature data suggest that some of these species can cause diseases. These data stimulate the upsurge of questions about the mechanisms of which Y. enterocolitica-like species may interact with host cells and cause diseases. The main objective of this preject was to characterize the pathogenic potential of Y. enterocolitica-like strains, specifically of the species Y. frederiksenii, Y. kristensenii and Y. intermedia. This work evaluated the pathogenic potential of 118 Y. enterocolitica-like strains (50 Y. frederiksenii, 55 Y. intermedia and 13 Y. kristensenii) searching for the presence of the virulence-related genes ail, fepA, fepD, fes, hreP, myfA, tccC, ystA, ystB and virF by PCR. Besides, Yersinia strains ability of adhesion and invasion to Caco-2 and HEp-2 cells after different pre-incubation periods, and its survival within human macrophages U937 were tested. Morphologic aspects of bacterial adhesion were observed by scanning electronic microscopy. Finally, the presence of new possible virulence mechanisms was evaluated through RNA sequencing of one Y. enterocolitica-like strain. The studied strains showed the following genes: Y. frederiksenii, fepA (44%), fes (44%) and ystB (18%); Y. intermedia, ail (53%), fepA (35%), fepD (2%), fes (97%), hreP (2%), ystB (2%) and tccC (35%); and Y. kristensenii, ail (62%), ystB (23%), fepA (77%), fepD (54%), fes (54%) and hreP (54%). Usually Y. enterocolitica-like strains presented less ability of adhere and invade Caco-2 and HEp-2 cells than the highly pathogenic strain Y. enterocolitica 8081. On the other hand, Y. kristensenii FCF 410 and Y. frederiksenii FCF 461 showed high potential of invasion in Caco-2 cells after 5 days of pre-incubation, which were 45 and 7.2 times higher than the control Y. enterocolitica 8081 respectively, but ail gene was not found in these strains. Survival assay in human macrophages U937 showed that Y. frederiksenii FCF 461 (40.0%) and Y. frederiksenii FCF 379 (24.6%) strains presented survival percentages higher than Y. enterocolitica 8081 (13.4%). However, Y. intermedia and Y. iv kristensenii strains showed a reduced capability of surviving in macrophages. Scanning electron microscopy showed bacteria at the surface in contact with the cellular filopodia. The bacteria were distributed either individually or in small clumps. Therefore, it may be concluded that the presence of virulence-related genes in some of the Y. enterocolitica-like strains indicated their possible pathogenic potential. Mammal cells adhesion and invasion assays suggest that the pathogenicity of Y. kristensenii and Y. frederiksenii may be strain-dependent. Human macrophages U937 surviving assay highlighted the pathogenic potential of some Y. frederiksenii strains. Together, the results suggest the existence of alternative virulence mechanisms other than the classical mechanisms described for pathogenic Y. enterocolitica. However, we could not verify the presence of possible new virulence mechanisms because 454 GS Junior (Roche) platform was not suitable for RNA sequencing of strains from cells interaction due its low coverage obtained. adesão e invasão celular cell adhesion and invasion assays electron microscopy and RNA-seq genes de virulência microscopia eletrônica e RNA-seq new virulence mechanisms novos marcadores de virulência pathogenic potential potencial patogênico surviving within human macrophages virulence-related genes Yersinia enterocolitica-like Yersinia enterocolitica-like
9	Caracterização do potencial patogênico de linhagens de Yersinia enterocolitica-like / Characterization of the pathogenic potential of Yersinia enterocolitica-like strains Priscilla Fernanda Martins Imori 04 April 2016 (has links) Dentre as 18 espécies do gênero Yersinia, as espécies Y. enterocolitica, Y. pseudotuberculosis e Y. pestis foram extensivamente caracterizadas em diversos aspectos como ecologia, epidemiologia e mecanismos de patogenicidade. Sete das 15 espécies restantes (Y. aldovae, Y. bercovieri, Y. frederiksenii, Y. intermedia, Y. kristensenii, Y. mollaretii e Y. rohdei), usualmente conhecidas como Y. enterocolitica-like, até o momento, não tiveram seu potencial patogênico caracterizado e são, geralmente, consideradas não-patogênicas. Entretanto, dados da literatura sugerem que algumas dessas espécies possam causar doença. Esses dados estimularam o surgimento de questões sobre os mecanismos pelos quais as espécies de Y. enterocolitica-like possam interagir com as células do hospedeiros e causar doenças. Esse projeto teve como principal objetivo caracterizar o potencial patogênico de linhagens de Y. enterocolitica-like, especificamente das espécies Y. frederiksenii, Y. kristensenii e Y. intermedia. No presente trabalho, o potencial patogênico de 118 linhagens de Y. enterocolitica-like (50 Y. frederiksenii, 55 Y. intermedia e 13 Y. kristensenii) foi avaliado pela pesquisa da presença dos genes relacionados à virulência ail, fepA, fepD, fes, hreP, myfA, tccC, ystA, ystB e virF por PCR. Além disso, a habilidade de algumas linhagens de Yersinia de aderir e invadir células Caco-2 e HEp-2 após diferentes períodos de incubação, bem como, de sobreviver no interior de macrófagos humanos U937 foi testada. Aspectos morfológicos da adesão bacteriana foram visualizados por microscopia eletrônica. Finalmente, a presença de possíveis novos mecanismos de virulência foi avaliada a partir do sequenciamento de RNA de uma linhagem de Y. enterocolitica-like. As linhagens estudadas apresentaram os seguintes genes: Y. frederiksenii, fepA (44%), fes (44%) e ystB (18%); Y. intermedia, ail (53%), fepA (35%), fepD (2%), fes (97%), hreP (2%), ystB (2%) e tccC (35%); e Y. kristensenii, ail (62%), ystB (23%), fepA (77%), fepD (54%), fes (54%) e hreP (54%). De modo geral, as linhagens de Y. enterocolitica-like tiveram a habilidade de aderir e invadir células Caco-2 e HEp-2 inferior à da linhagem altamente patogênica Y. enterocolitica 8081. Contudo, Y. kristensenii FCF 410 e Y. frederiksenii FCF 461 apresentaram elevado potencial de invasão a células Caco-2 após cinco dias de pré-incubação, os quais foram 45 e 7,2 vezes maiores do que o controle Y. enterocolitica 8081, respectivamente, porém, o gene ail não foi detectado nessas linhagens. O ensaio de sobrevivência em macrófagos humanos U937 ii mostrou que as linhagens de Y. frederiksenii FCF 461 (40,0%) e Y. frederiksenii FCF 379 (24,6%) tiveram porcentagens de sobrevivência superior à de Y. enterocolitica 8081 (13,4%). Todavia, linhagens de Y. intermedia e Y. kristensenii apresentaram uma capacidade reduzida de sobreviver em macrófagos. A microscopia eletrônica de varredura mostrou as bactérias em contato com a filipódia celular. As bactérias foram distribuídas tanto individualmente quanto em pequenos aglomerados. Portanto, podemos concluir que a presença dos genes relacionados à virulência encontrados nas Y. enterocolitica-like estudadas indicou o possível potencial patogênico de algumas dessas linhagens. Os ensaios de adesão e invasão a células de mamíferos sugerem que a patogenicidade de Y. kristensenii e Y. frederiksenii possa ser linhagem-dependente. O ensaio de sobrevivência em macrófagos humanos U937 evidenciou o potencial patogênico de algumas linhagens de Y. frederiksenii. Em conjunto, os resultados obtidos sugerem a existência de mecanismos de virulência alternativos aos mecanismos clássicos descritos para Y. enterocolitica patogênica. Contudo, a presença de possíveis novos mecanismos de virulência não pode ser verificada, uma vez que a plataforma 454 GS Junior (Roche) não se mostrou adequada para a realização de sequenciamento de RNA de amostras provenientes de interações com células devido à baixa cobertura obtida. / Among the 18 species of the Yersinia genus, Y. enterocolitica, Y. pseudotuberculosis and Y. pestis were extensively characterized in different subjects as ecology, epidemiology and pathogenicity mechanisms. Seven among the remaining 15 species (Y. aldovae, Y. bercovieri, Y. frederiksenii, Y. intermedia, Y. kristensenii, Y. mollaretii and Y. rohdei), often called Y. enterocolitica-like have not their pathogenic potential characterized and are usually considered to be nonpathogenic. However, literature data suggest that some of these species can cause diseases. These data stimulate the upsurge of questions about the mechanisms of which Y. enterocolitica-like species may interact with host cells and cause diseases. The main objective of this preject was to characterize the pathogenic potential of Y. enterocolitica-like strains, specifically of the species Y. frederiksenii, Y. kristensenii and Y. intermedia. This work evaluated the pathogenic potential of 118 Y. enterocolitica-like strains (50 Y. frederiksenii, 55 Y. intermedia and 13 Y. kristensenii) searching for the presence of the virulence-related genes ail, fepA, fepD, fes, hreP, myfA, tccC, ystA, ystB and virF by PCR. Besides, Yersinia strains ability of adhesion and invasion to Caco-2 and HEp-2 cells after different pre-incubation periods, and its survival within human macrophages U937 were tested. Morphologic aspects of bacterial adhesion were observed by scanning electronic microscopy. Finally, the presence of new possible virulence mechanisms was evaluated through RNA sequencing of one Y. enterocolitica-like strain. The studied strains showed the following genes: Y. frederiksenii, fepA (44%), fes (44%) and ystB (18%); Y. intermedia, ail (53%), fepA (35%), fepD (2%), fes (97%), hreP (2%), ystB (2%) and tccC (35%); and Y. kristensenii, ail (62%), ystB (23%), fepA (77%), fepD (54%), fes (54%) and hreP (54%). Usually Y. enterocolitica-like strains presented less ability of adhere and invade Caco-2 and HEp-2 cells than the highly pathogenic strain Y. enterocolitica 8081. On the other hand, Y. kristensenii FCF 410 and Y. frederiksenii FCF 461 showed high potential of invasion in Caco-2 cells after 5 days of pre-incubation, which were 45 and 7.2 times higher than the control Y. enterocolitica 8081 respectively, but ail gene was not found in these strains. Survival assay in human macrophages U937 showed that Y. frederiksenii FCF 461 (40.0%) and Y. frederiksenii FCF 379 (24.6%) strains presented survival percentages higher than Y. enterocolitica 8081 (13.4%). However, Y. intermedia and Y. iv kristensenii strains showed a reduced capability of surviving in macrophages. Scanning electron microscopy showed bacteria at the surface in contact with the cellular filopodia. The bacteria were distributed either individually or in small clumps. Therefore, it may be concluded that the presence of virulence-related genes in some of the Y. enterocolitica-like strains indicated their possible pathogenic potential. Mammal cells adhesion and invasion assays suggest that the pathogenicity of Y. kristensenii and Y. frederiksenii may be strain-dependent. Human macrophages U937 surviving assay highlighted the pathogenic potential of some Y. frederiksenii strains. Together, the results suggest the existence of alternative virulence mechanisms other than the classical mechanisms described for pathogenic Y. enterocolitica. However, we could not verify the presence of possible new virulence mechanisms because 454 GS Junior (Roche) platform was not suitable for RNA sequencing of strains from cells interaction due its low coverage obtained. adesão e invasão celular genes de virulência microscopia eletrônica e RNA-seq novos marcadores de virulência potencial patogênico Yersinia enterocolitica-like cell adhesion and invasion assays electron microscopy and RNA-seq new virulence mechanisms pathogenic potential surviving within human macrophages virulence-related genes Yersinia enterocolitica-like

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