The role of porcine reproductive and respiratory syndrome (PRRS) virus structural and non-structural proteins in virus pathogenesis.

Porcine reproductive and respiratory syndrome (PRRS) is an economically devastating viral disease affecting the swine industry worldwide. The etiological agent, PRRS virus (PRRSV), possesses a RNA viral genome with nine open reading frames (ORFs). The ORF1a and ORF1b replicase-associated genes encode the polyproteins pp1a and pp1ab, respectively. The pp1a is processed in nine non-structural proteins (nsps): nsp1a, nsp1b, and nsp2 to nsp8. Proteolytic cleavage of pp1ab generates products nsp9 to nsp12. The proteolytic pp1a cleavage products process and cleave pp1a and pp1ab into nsp products. The nsp9 to nsp12 are involved in virus genome transcription and replication. The 30 end of the viral genome encodes four minor and three major structural proteins. The GP2a, GP3 and GP4 (encoded by ORF2a, 3 and 4), are glycosylated membrane associated minor structural proteins. The fourth minor structural protein, the E protein (encoded by ORF2b), is an unglycosylated membrane associated protein. The viral envelope contains two major structural proteins: a glycosylated major envelope protein GP5 (encoded by ORF5) and an unglycosylated membrane M protein (encoded by ORF6). The third major structural protein is the nucleocapsid N protein (encoded by ORF7). All PRRSV non-structural and structural proteins are essential for virus replication, and PRRSV infectivity is relatively intolerant to subtle changes within the structural proteins. PRRSV virulence is multigenic and resides in both the non-structural and structural viral proteins. This review discusses the molecular characteristics, biological and immunological functions of the PRRSV structural and nsps and their involvement in the virus pathogenesis.

FosteraTM PRRS modified live vaccine efficacy against a Canadian heterologous virulent field strain of porcine reproductive and respiratory syndrome virus (PRRSV).

Vaccination is a useful option to control infection with porcine reproductive and respiratory syndrome virus (PRRSV), and several modified live-PRRSV vaccines have been developed. These vaccines have shown some efficacy in reducing the incidence and severity of clinical disease as well as the duration of viremia and virus shedding but have failed to provide sterilizing immunity. The efficacy of modified live-virus (MLV) vaccines is greater against a homologous strain compared with heterologous PRRSV strains. The objective of this study was to evaluate the efficacy of Fostera PRRS MLV vaccine in protecting against challenge with a heterologous field strain widely circulating in the swine herds of eastern Canada. Forty-six piglets were divided into 4 groups: nonvaccinated-nonchallenged; nonvaccinated-challenged; vaccinated-challenged; and vaccinated-nonchallenged. The animals were vaccinated at 23 d of age with Fostera PRRS and challenged 23 d later with a heterologous field strain of PRRSV (FMV12-1425619). Overall, the vaccine showed some beneficial effects in the challenged animals by reducing the severity of clinical signs and the viral load. A significant difference between nonvaccinated and vaccinated animals was detected for some parameters starting 11 to 13 d after challenge, which suggested that the cell-mediated immune response or other delayed responses could be more important than pre-existing PRRSV antibodies in vaccinated animals within the context of protection against heterologous strains.

Análise do risco da ocorrência da síndrome reprodutiva e respiratória dos suínos(PRRS) em granjas de suínos tecnificadas do Estado de São Paulo: estudo do perfil descritivo da situação atual

Pós-graduação em Medicina Veterinária - FMVZ

Frequency of PRRS live vaccine virus (European and North American genotype) in vaccinated and non-vaccinated pigs submitted for respiratory tract diagnostics in North-Western Germany

The frequency of PRRSV corresponding to live vaccines and wild-type was determined in 902 pigs from North-Western Germany submitted for post-mortem examination. Overall, 18.5% of the samples were positive for the EU wild-type virus. EU genotype vaccine virus was detected in 1.3% and the NA genotype vaccine virus in 8.9% of all samples. The detection of the EU vaccine was significantly higher in pigs vaccinated with the corresponding vaccine (OR=9.4). Pigs vaccinated with NA genotype had significantly higher detection chances for the corresponding vaccine virus when compared to non-vaccinated animals (OR=3.34) animals, however, NA vaccine was also frequently detected in non-vaccinated pigs. Concluding, the dynamics of NA genotype vaccine and EU wild-type virus corresponds with studies on PRRSV spread in endemically infected herds. The potential of spontaneous spread of the NA genotype vaccine should be considered in the planning of eradication programs.

Evaluating perspectives for PRRS virus elimination from pig dense areas with a risk factor based herd index

Porcine reproductive and respiratory syndrome virus (PRRSV) is wide-spread in pig populations globally. In many regions of Europe with intensive pig production and high herd densities, the virus is endemic and can cause disease and production losses. This fuels discussion about the feasibility and sustainability of virus elimination from larger geographic regions. The implementation of a program aiming at virus elimination for areas with high pig density is unprecedented and its potential success is unknown. The objective of this work was to approach pig population data with a simple method that could support assessing the feasibility of a sustainable regional PRRSV elimination. Based on known risk factors such as pig herd structure and neighborhood conditions, an index characterizing individual herds' potential for endemic virus circulation and reinfection was designed. This index was subsequently used to compare data of all pig herds in two regions with different pig- and herd-densities in Lower Saxony (North-West Germany) where PRRSV is endemic. Distribution of the indexed herds was displayed using GIS. Clusters of high herd index densities forming potential risk hot spots were identified which could represent key target areas for surveillance and biosecurity measures under a control program aimed at virus elimination. In an additional step, for the study region with the higher pig density (2463 pigs/km(2) farmland), the potential distribution of PRRSV-free and non-free herds during the implementation of a national control program aiming at national virus elimination was modeled. Complex herd and trade network structures suggest that PRRSV elimination in regions with intensive pig farming like that of middle Europe would have to involve legal regulation and be accompanied by important trade and animal movement restrictions. The proposed methodology of risk index mapping could be adapted to areas varying in size, herd structure and density. Interpreted in the regional context, this could help to classify the density of risk and to accordingly target resources and measures for elimination.

Valutazione della risposta immunitaria cellulare e fenotipizzazione linfocitaria nel suino in corso di infezione naturale da virus della PRRS (“Porcine Reproductive and Respiratory Syndrome”) e dopo stimolazione di PBMC (“Peripheral Blood Mononuclear Cells”) in vitro con Peptide Killer (KP)

SUMMARY The Porcine Reproductive and Respiratory Syndrome (PRRS) virus is one of the most spread pathogens in swine herds all over the world and responsible for a reproductive and respiratory syndrome that causes severe heath and economical problems. This virus emerged in late 1980’s but although about 30 years have passed by, the knowledge about some essential facets related to the features of the virus (pathogenesis, immune response, and epidemiology) seems to be still incomplete. Taking into account that the development of modern vaccines is based on how innate and acquire immunity react, a more and more thorough knowledge on the immune system is needed, in terms of molecular modulation/regulation of the inflammatory and immune response upon PRRSV infection. The present doctoral thesis, which is divided into 3 different studies, is aimed to increase the knowledge about the interaction between the immune system and the PRRS virus upon natural infection. The objective of the first study entitled “Coordinated immune response of memory and cytotoxic T cells together with IFN-γ secreting cells after porcine reproductive and respiratory syndrome virus (PRRSV) natural infection in conventional pigs” was to evaluate the activation and modulation of the immune response in pigs naturally infected by PRRSV compared to an uninfected control group. The course of viremia was evaluated by PCR, the antibody titres by ELISA, the number of IFN-γ secreting cells (IFN- SC) by an ELISPOT assay and the immunophenotyping of some lymphocyte subsets (cytotoxic cells, memory T lymphocytes and cytotoxic T lymphocytes) by flow cytometry. The results showed that the activation of the cell-mediated immune response against PRRSV is delayed upon infection and that however the levels of IFN-γ SC and lymphocyte subsets subsequently increase over time. Furthermore, it was observed that the course of the different immune cell subsets is time-associated with the levels of PRRSV-specific IFN-γ SC and this can be interpreted based on the functional role that such lymphocyte subsets could have in the specific production/secretion of the immunostimulatory cytokine IFN-γ. In addition, these data support the hypothesis that the age of the animals upon the onset of infection or the diverse immunobiological features of the field isolate, as typically hypothesized during PRRSV infection, are critical conditions able to influence the qualitative and quantitative course of the cell-mediated immune response during PRRSV natural infection. The second study entitled “Immune response to PCV2 vaccination in PRRSV viremic piglets” was aimed to evaluate whether PRRSV could interfere with the activation of the immune response to PCV2 vaccination in pigs. In this trial, 200 pigs were divided into 2 groups: PCV2-vaccinated (at 4 weeks of age) and PCV2-unvaccinated (control group). Some piglets of both groups got infected by PRRSV, as determined by PRRSV viremia detection, so that 4 groups were defined as follows: PCV2 vaccinated - PRRSV viremic PCV2 vaccinated - PRRSV non viremic PCV2 unvaccinated - PRRSV viremic PCV2 unvaccinated - PRRSV non viremic The following parameters were evaluated in the 4 groups: number of PCV2-specific IFN-γ secreting cells, antibody titres by ELISA and IPMA. Based on the immunological data analysis, it can be deduced that: 1) The low levels of antibodies against PCV2 in the PCV2-vaccinated – PRRSV-viremic group at vaccination (4 weeks of age) could be related to a reduced colostrum intake influenced by PRRSV viremia. 2) Independently of the viremia status, serological data of the PCV2-vaccinated group by ELISA and IPMA does not show statistically different differences. Consequently, it can be be stated that, under the conditions of the study, PRRSV does not interfere with the antibody response induced by the PCV2 vaccine. 3) The cell-mediated immune response in terms of number of PCV2-specific IFN-γ secreting cells in the PCV2-vaccinated – PRRSV-viremic group seems to be compromised, as demonstrated by the reduction of the number of IFN-γ secreting cells after PCV2 vaccination, compared to the PCV2-vaccinated – PRRSV-non-viremic group. The data highlight and further support the inhibitory role of PRRSV on the development and activation of the immune response and highlight how a natural infection at early age can negatively influence the immune response to other pathogens/antigens. The third study entitled “Phenotypic modulation of porcine CD14+ monocytes, natural killer/natural killer T cells and CD8αβ+ T cell subsets by an antibody-derived killer peptide (KP)” was aimed to determine whether and how the killer peptide (KP) could modulate the immune response in terms of activation of specific lymphocyte subsets. This is a preliminary approach also aimed to subsequently evaluate such KP with a potential antivural role or as adjuvant. In this work, pig peripheral blood mononuclear cells (PBMC) were stimulated with three KP concentrations (10, 20 and 40 g/ml) for three time points (24, 48 and 72 hours). TIME POINTS (hours) KP CONCENTRATIONS (g/ml) 24 0-10-20-40 48 0-10-20-40 72 0-10-20-40 By using flow cytometry, the qualitative and quantitative modulation of the following immune subsets was evaluated upon KP stimulation: monocytes, natural killer (NK) cells, natural killer T (NKT) cells, and CD4+ and CD8α/β+ T lymphocyte subsets. Based on the data, it can be deduced that: 1) KP promotes a dose-dependent activation of monocytes, particularly after 24 hours of stimulation, by inducing a monocyte phenotypic and maturation shift mainly involved in sustaining the innate/inflammatory response. 2) KP induces a strong dose-dependent modulation of NK and NKT cells, characterized by an intense increase of the NKT cell fraction compared to NK cells, both subsets involved in the antibody-dependent cell cytotoxicity (ADCC). The increase is observed especially after 24 hours of stimulation. 3) KP promotes a significant activation of the cytotoxic T lymphocyte subset (CTL). 4) KP can modulate both the T helper and T cytotoxic phenotype, by inducing T helper cells to acquire the CD8α thus becoming doube positive cells (CD4+CD8+) and by inducing CTL (CD4-CD8+high) to acquire the double positive phenotype (CD4+CD8α+high). Therefore, KP may induce several effects on different immune cell subsets. For this reason, further research is needed aimed at characterizing each “effect” of KP and thus identifying the best use of the decapeptide for vaccination practice, therapeutic purposes or as vaccine adjuvant. RIASSUNTO Il virus della PRRS (Porcine Reproductive Respiratory Syndrome) è uno dei più diffusi agenti patogeni negli allevamenti suini di tutto il mondo, responsabile di una sindrome riproduttiva e respiratoria causa di gravi danni ad impatto sanitario ed economico. Questo virus è emerso attorno alla fine degli anni ’80 ma nonostante siano passati circa una trentina di anni, le conoscenze su alcuni punti essenziali che riguardano le caratteristiche del virus (patogenesi, risposta immunitaria, epidemiologia) appaiono ancora spesso incomplete. Considerando che lo sviluppo dei vaccini moderni è basato sui principi dell’immunità innata e acquisita è essenziale una sempre più completa conoscenza del sistema immunitario inteso come modulazione/regolazione molecolare della risposta infiammatoria e immunitaria in corso di tale infezione. Questo lavoro di tesi, suddiviso in tre diversi studi, ha l’intento di contribuire all’aumento delle informazioni riguardo l’interazione del sistema immunitario, con il virus della PRRS in condizioni di infezione naturale. L’obbiettivo del primo studio, intitolato “Associazione di cellule memoria, cellule citotossiche e cellule secernenti IFN- nella risposta immunitaria in corso di infezione naturale da Virus della Sindrome Riproduttiva e Respiratoria del Suino (PRRSV)” è stato di valutare l’attivazione e la modulazione della risposta immunitaria in suini naturalmente infetti da PRRSV rispetto ad un gruppo controllo non infetto. I parametri valutati sono stati la viremia mediante PCR, il titolo anticorpale mediante ELISA, il numero di cellule secernenti IFN- (IFN- SC) mediante tecnica ELISPOT e la fenotipizzazione di alcune sottopopolazioni linfocitarie (Cellule citotossiche, linfociti T memoria e linfociti T citotossici) mediante citofluorimetria a flusso. Dai risultati ottenuti è stato possibile osservare che l’attivazione della risposta immunitaria cellulo-mediata verso PRRSV appare ritardata durante l’infezione e che l’andamento, in termini di IFN- SC e dei cambiamenti delle sottopopolazioni linfocitarie, mostra comunque degli incrementi seppur successivi nel tempo. E’ stato inoltre osservato che gli andamenti delle diverse sottopopolazioni immunitarie cellulari appaiono temporalmente associati ai livelli di IFN- SC PRRSV-specifiche e ciò potrebbe essere interpretato sulla base del ruolo funzionale che tali sottopopolazioni linfocitarie potrebbero avere nella produzione/secrezione specifica della citochina immunoattivatrice IFN-. Questi dati inoltre supportano l’ipotesi che l’età degli animali alla comparsa dell’infezione o, come tipicamente ipotizzato nell’infezione da PRRSV, le differenti caratteristiche immunobiologiche dell’isolato di campo, sia condizioni critiche nell’ influenzare l’andamento qualitativo e quantitativo della risposta cellulo-mediata durante l’infezione naturale da PRRSV. Il secondo studio, dal titolo “Valutazione della risposta immunitaria nei confronti di una vaccinazione contro PCV2 in suini riscontrati PRRSV viremici e non viremici alla vaccinazione” ha avuto lo scopo di valutare se il virus della PRRS potesse andare ad interferire sull’attivazione della risposta immunitaria indotta da vaccinazione contro PCV2 nel suino. In questo lavoro sono stati arruolati 200 animali divisi in due gruppi, PCV2 Vaccinato (a 4 settimane di età) e PCV2 Non Vaccinato (controllo negativo). Alcuni suinetti di entrambi i gruppi, si sono naturalmente infettati con PRRSV, come determinato con l’analisi della viremia da PRRSV, per cui è stato possibile creare quattro sottogruppi, rispettivamente: PCV2 vaccinato - PRRSV viremico PCV2 vaccinato - PRRSV non viremico PCV2 non vaccinato - PRRSV viremico PCV2 non vaccinato - PRRSV non viremico Su questi quattro sottogruppi sono stati valutati i seguenti parametri: numero di cellule secernenti IFN- PCV2 specifiche, ed i titoli anticorpali mediante tecniche ELISA ed IPMA. Dall’analisi dei dati immunologici derivati dalle suddette tecniche è stato possibile dedurre che:  I bassi valori anticorpali nei confronti di PCV2 del gruppo Vaccinato PCV2-PRRSV viremico già al periodo della vaccinazione (4 settimane di età) potrebbero essere messi in relazione ad una ridotta assunzione di colostro legata allo stato di viremia da PRRSV  Indipendentemente dallo stato viremico, i dati sierologici del gruppo vaccinato PCV2 provenienti sia da ELISA sia da IPMA non mostrano differenze statisticamente significative. Di conseguenza è possibile affermare che in questo caso PRRSV non interferisce con la risposta anticorpale promossa dal vaccino PCV2.  La risposta immunitaria cellulo-mediata, intesa come numero di cellule secernenti IFN- PCV2 specifiche nel gruppo PCV2 vaccinato PRRS viremico sembra essere compromessa, come viene infatti dimostrato dalla diminuzione del numero di cellule secernenti IFN- dopo la vaccinazione contro PCV2, comparata con il gruppo PCV2 vaccinato- non viremico. I dati evidenziano ed ulteriormente sostengono il ruolo inibitorio del virus della PRRSV sullo sviluppo ed attivazione della risposta immunitaria e come un infezione naturale ad età precoci possa influenzare negativamente la risposta immunitaria ad altri patogeni/antigeni. Il terzo studio, intitolato “Modulazione fenotipica di: monociti CD14+, cellule natural killer (NK), T natural killer (NKT) e sottopopolazioni linfocitarie T CD4+ e CD8+ durante stimolazione con killer peptide (KP) nella specie suina” ha avuto come scopo quello di stabilire se e come il Peptide Killer (KP) potesse modulare la risposta immunitaria in termini di attivazione di specifiche sottopopolazioni linfocitarie. Si tratta di un approccio preliminare anche ai fini di successivamente valutare tale KP in un potenziale ruolo antivirale o come adiuvante. In questo lavoro, periferal blood mononuclear cells (PBMC) suine sono state stimolate con KP a tre diverse concentrazioni (10, 20 e 40 g/ml) per tre diversi tempi (24, 48 e 72 ore). TEMPI DI STIMOLAZIONE (ore) CONCENTRAZIONE DI KP (g/ml) 24 0-10-20-40 48 0-10-20-40 72 0-10-20-40 Mediante la citometria a flusso è stato dunque possibile analizzare il comportamento qualitativo e quantitativo di alcune sottopopolazioni linfocitarie sotto lo stimolo del KP, tra cui: monociti, cellule Natural Killer (NK), cellule T Natural Killer (NKT) e linfociti T CD4 e CD8+. Dai dati ottenuti è stato possibile dedurre che: 1) KP promuove un’attivazione dei monociti dose-dipendente in particolare dopo 24 ore di stimolazione, inducendo uno “shift” fenotipico e di maturazione monocitaria maggiormente coinvolto nel sostegno della risposta innata/infiammatoria. 2) KP induce una forte modulazione dose-dipendente di cellule NK e NKT con un forte aumento della frazione delle cellule NKT rispetto alle NK, sottopopolazioni entrambe coinvolte nella citotossicità cellulare mediata da anticorpi (ADCC). L’aumento è riscontrabile soprattutto dopo 24 ore di stimolazione. 3) KP promuove una significativa attivazione della sottopopolazione del linfociti T citotossici (CTL). 4) Per quanto riguarda la marcatura CD4+/CD8+ è stato dimostrato che KP ha la capacità di modulare sia il fenotipo T helper che T citotossico, inducendo le cellule T helper ad acquisire CD8 diventando quindi doppio positive (CD4+CD8+) ed inducendo il fenotipo CTL (CD4-CD8+high) ad acquisire il fenotipo doppio positivo (CD4+CD8α+high). Molti dunque potrebbero essere gli effetti che il decapeptide KP potrebbe esercitare sulle diverse sottopopolazioni del sistema immunitario, per questo motivo va evidenziata la necessità di impostare e attuare nuove ricerche che portino alla caratterizzazione di ciascuna “abilità” di KP e che conducano successivamente alla scoperta del migliore utilizzo che si possa fare del decapeptide sia dal punto di vista vaccinale, terapeutico oppure sotto forma di adiuvante vaccinale.

Immune regulation and function of the NOD-like receptors NLRC5 and NLRP3

AbstractThe vertebrate immune system is composed of the innate and the adaptive branches. Innate immune cells represent the first line of defense and detect pathogens through pattern recognition receptors (PRRs), detecting evolutionary conserved pathogen- and danger- associated molecular patterns. Engagement of these receptors initiates the inflammatory response, but also instructs antigen-specific adaptive immune cells. NOD-like receptors (NLRs) are an important group of PRRs, leading to the production of inflammatory mediators and favoring antigen presentation to Τ lymphocytes through the regulation of major histocompatibility complex (MHC) molecules.In this work we focused our attention on selected NOD-like receptors (NLRs) and their role at the interface between innate and adaptive immunity. First, we describe a new regulatory mechanism controlling IL-1 production. Our results indicate that type I interferons (IFNs) block NLRP1 and NLRP3 inflammasome activity and interfere with LPS-driven proIL-Ια and -β induction. As type I IFNs are produced upon viral infections, these anti-inflammatory effects of type I IFN could be relevant in the context of superinfections, but could also help explaining the efficacy of IFN-β in multiple sclerosis treatment.The second project addresses the role of a novel NLR family member, called NLRC5. The function of this NLR is still matter of debate, as it has been proposed as both an inhibitor and an activator of different inflammatory pathways. We found that the expression of this protein is restricted to immune cells and is positively regulated by IFNs. We generated Nlrc5-deficient mice and found that this NLR plays an essential role in Τ, NKT and, NK lymphocytes, in which it drives the expression of MHC class I molecules. Accordingly, we could show that CD8+ Τ cell-mediated killing of target lymphocytes lacking NLRC5 is strongly impaired. Moreover, NLRC5 expression was found to be low in many lymphoid- derived tumor cell lines, a mechanism that could be exploited by tumors to escape immunosurveillance.Finally, we found NLRC5 to be involved in the production of IL-10 by CD4+ Τ cells, as Nlrc5- deficient Τ lymphocytes produced less of this cytokine upon TCR triggering. In line with these observations, Mrc5-deficient CD4+ Τ cells expanded more than control cells when transferred into lymphopenic hosts and led to a more rapid appearance of colitis symptoms. Therefore, our work gives novel insights on the function of NLRC5 by using knockout mice, and strongly supports the idea that NLRs direct not only innate, but also adaptive immune responses.

Innate receptors for adaptive immunity.

Pattern recognition receptors (PRRs) are commonly known as sensor proteins crucial for the early detection of microbial or host-derived stress signals by innate immune cells. Interestingly, some PRRs are also expressed and functional in cells of the adaptive immune system. These receptors provide lymphocytes with innate sensing abilities; for example, B cells express Toll-like receptors, which are important for the humoral response. Strikingly, certain other NOD-like receptors are not only highly expressed in adaptive immune cells, but also exert functions related specifically to adaptive immune system pathways, such as regulating antigen presentation. In this review, we will focus particularly on the current understanding of PRR functions intrinsic to B and T lymphocytes; a developing aspect of PRR biology.

Bacterial flagellin elicits innate immune defenses and cardiac dysfunction in vivo

Résumé Les agents pathogènes responsables d'infection entraînent chez l'hôte deux types de réponses immunes, la première, non spécifique, dite immunité innée, la seconde, spécifique à l'agent concerné, dite immunité adaptative. L'immunité innée, qui représente la première ligne de défense contre les pathogènes, est liée à la reconnaissance par les cellules de l'hôte de structures moléculaires propres aux micro-organismes (« Pathogen-Associated Molecular Patterns », PAMPs), grâce à des récepteurs membranaires et cytoplasmiques (« Pattern Recognition Receptors », PRRs) identifiant de manière spécifique ces motifs moléculaires. Les récepteurs membranaires impliqués dans ce processus sont dénommés toll-like récepteurs, ou TLRS. Lorsqu'ils sont activés par leur ligand spécifique, ces récepteurs activent des voies de signalisation intracellulaires initiant la réponse inflammatoire non spécifique et visant à éradiquer l'agent pathogène. Les deux voies de signalisation impliquées dans ce processus sont la voie des « Mitogen-Activated Protein Kinases » (MAPKs) et celle du « Nuclear Factor kappaB » (NF-κB), dont l'activation entraîne in fine l'expression de protéines de l'inflammation dénommées cytokines, ainsi que certaines enzymes produisant divers autres médiateurs inflammatoires. Dans certaines situations, cette réponse immune peut être amplifiée de manière inadéquate, entraînant chez l'hôte une réaction inflammatoire systémique exagérée, appelée sepsis. Le sepsis peut se compliquer de dysfonctions d'organes multiples (sepsis sévère), et dans sa forme la plus grave, d'un collapsus cardiovasculaire, définissant le choc septique. La défaillance circulatoire du choc septique touche les vaisseaux sanguins d'une part, le coeur d'autre part, réalisant un tableau de «dysfonction cardiaque septique », dont on connaît mal les mécanismes pathogéniques. Les bactéries à Gram négatif peuvent déclencher de tels phénomènes, notamment en libérant de l'endotoxine, qui active les voies de l'immunité innée par son interaction avec un toll récepteur, le TLR4. Outre l'endotoxine, la plupart des bactéries à Gram négatif relâchent également dans leur environnement une protéine, la flagelline, qui est le constituant majeur du flagelle bactérien, organelle assurant la mobilité de ces micro-organismes. Des données récentes ont indiqué que la flagelline active, dans certaines cellules, les voies de l'immunité innée en se liant au récepteur TLRS. On ne connaît toutefois pas les conséquences de l'interaction flagelline-TLRS sur le développement de l'inflammation et des dysfonctions d'organes au cours du sepsis. Nous avons par conséquent élaboré le présent travail en formulant l'hypothèse que la flagelline pourrait déclencher une telle inflammation et représenter ainsi un médiateur potentiel de la dysfonction d'organes au cours du sepsis à Gram négatif, en nous intéressant plus particulièrement àl'inflammation et à la dysfonction cardiaque. Dans la première partie de ce travail, nous avons étudié les effets de la flagelline sur l'activation du NF-κB et des MAPKs, et sur l'expression de cytokines inflammatoires au niveau du myocarde in vitro (cardiomyocytes en culture) et in vivo (injection de flagelline recombinante à des souris). Nous avons observé tout d'abord que le récepteur TLRS est fortement exprimé au niveau du myocarde. Nous avons ensuite démontré que la flagelline active la voie du NF-κB et des MAP kinases (p38 et JNK), stimule la production de cytokines et de chemokines inflammatoires in vitro et in vivo, et entraîne l'activation de polynucléaires neutrophiles dans le tissu cardiaque in vivo. Finalement, au plan fonctionnel, nous avons pu montrer que la flagelline entraîne une dilatation et une réduction aiguë de la contractilité du ventricule gauche chez la souris, reproduisant les caractéristiques de la dysfonction cardiaque septique. Dans la deuxième partie, nous avons déterminé la distribution du récepteur TLRS dans les autres organes majeurs de la souris (poumon, foie, intestin et rein}, et avons caractérisé dans ces organes l'effet de la flagelline sur l'activation du NF-κB et des MAPKs, l'expression de cytokines, et l'induction de l'apoptose. Nous avons démontré que le TLRS est exprimé de façon constitutive dans ces organes, et que l'injection de flagelline y déclenche les cascades de l'immunité innée et de processus apoptotiques. Finalement, nous avons également déterminé que la flagelline entraîne une augmentation significative de multiples cytokines dans le plasma une à six heures après son injection. En résumé, nos données démontrent que la flagelline bactérienne (a) entraîne une inflammation et une dysfonction importantes du myocarde et (b) active de manière très significative les mécanismes d'immunité innée dans les principaux organes et entraîne une réponse inflammatoire systémique. Par conséquent, la flagelline peut représenter un médiateur puissant de l'inflammation et de la dysfonction d'organes, notamment du coeur, au cours du choc septique déclenché par les bactéries à Gram négatif. Summary Pathogenic microorganisms trigger two kinds of immune responses in the host. The first one is immediate and non-specific and is termed innate immunity, whereas the second one, specifically targeted at the invading agent, is termed adaptative immunity. Innate immunity, which represents the first line of defense against invading pathogens, confers the host the ability to recognize molecular structures common to many microbial pathogens, ("Pathogen-Associated Molecular Patterns", PAMPs), through cytosolic or membrane-associated receptors ("Pattern Recognition Receptors", PRRs), the latter being represented by a family of receptors termed "toll-like receptors or TLRs". Once activated by the binding of their specific ligand, these receptors activate intracellular signaling pathways, which initiate the non-specific inflammatory response aimed at eradicating the pathogens. The two pathways implicated in this process are the mitogen-activated protein kinases (MAPK) and the nuclear factor kappa B (NF-κB) signaling pathways, whose activation elicit in fine the expression of inflammatory proteins termed cytokines, as well as various enzymes producing a wealth of additional inflammatory mediators. In some circumstances, the innate immune response can become amplified and dysregulated, triggering an overwhelming systemic inflammatory response in the host, identified as sepsis. Sepsis can be associated with multiple organ dysfunction (severe sepsis), and in its most severe form, with cardiovascular collapse, defming septic shock. The cardiovascular failure associated with septic shock affects blood vessels as well as the heart, resulting in a particular form of acute heart failure termed "septic cardiac dysfunction ", whose pathogenic mechanisms remain partly undefined. Gram-negative bacteria can initiate such phenomena, notably by releasing lipopolysaccharide (LPS), which activates innate immune signaling by interacting with its specific toll receptor, the TLR4. Besides LPS, most Gram-negative bacteria also release flagellin into their environment, which is the main structural protein of the bacterial flagellum, an appendage extending from the outer bacterial membrane, responsible for the motility of the microorganism. Recent data indicated that flagellin activate immune responses upon binding to its receptor, TLRS, in various cell types. However, the role of flagellin/TLRS interaction in the development of inflammation and organ dysfunction during sepsis is not known. Therefore, we designed the present work to address the hypothesis that flagellin might trigger such inflammatory responses and thus represent a potential mediator of organ dysfunction during Gram-negative sepsis, with a particular emphasis on cardiac inflammation and contractile dysfunction. In the first part of this work, we investigated the effects of flagellin on NF-κB and MAPK activation and the generation of pro-inflammatory mediators within the heart in vitro (cultured cardiomyocytes) and in vivo (injection of recombinant flagellin into mice). We first observed that TLRS protein is strongly expressed by the myocardium. We then demonstrated that flagellin activates NF-κB and MAP kinases (p38 and JNK), upregulates the transcription of pro-inflammatory cytokines and chemokines in vitro and in vivo, and stimulates the activation of polymorphonuclear neutrophils within the heart in vivo. Finally, we demonstrated that flagellin triggers acute cardiac dilation, and a significant reduction of left ventricular contractility, mimicking characteristics of clinical septic cardiac dysfunction. In the second part, we determined the TLRS distribution in other mice major organs (lung, liver, gut and kidney) and we characterized in these organs the effects of flagellin on NF-κB and MAPK activation, on the expression of pro-inflammatory çytokines, and on the induction of apoptosis. We demonstrated that TLRS protein is constitutively expressed and that flagellin activates prototypical innate immune responses and pro-apoptotic pathways in all these organs. Finally, we also observed that flagellin induces a significant increase of multiple cytokines in the plasma from 1 to 6 hours after its intravenous administration. Altogether, these data provide evidence that bacterial flagellin (a) triggers an important inflammatory response and an acute dysfunction of the myocardium, and (b) significantly activates the mechanisms of innate immunity in most major organs and elicits a systemic inflammatory response. In consequence, flagellin may represent a potent mediator of inflammation and multiple organ failure, notably cardiac dysfunction, during Gram-negative septic shock.

Expression of non-TLR pattern recognition receptors in the spleen of BALB/c mice infected with Plasmodium yoelii and Plasmodium chabaudi chabaudi AS

The spleen plays a crucial role in the development of immunity to malaria, but the role of pattern recognition receptors (PRRs) in splenic effector cells during malaria infection is poorly understood. In the present study, we analysed the expression of selected PRRs in splenic effector cells from BALB/c mice infected with the lethal and non-lethal Plasmodium yoelii strains 17XL and 17X, respectively, and the non-lethal Plasmodium chabaudi chabaudi AS strain. The results of these experiments showed fewer significant changes in the expression of PRRs in AS-infected mice than in 17X and 17XL-infected mice. Mannose receptor C type 2 (MRC2) expression increased with parasitemia, whereas Toll-like receptors and sialoadhesin (Sn) decreased in mice infected with P. chabaudi AS. In contrast, MRC type 1 (MRC1), MRC2 and EGF-like module containing mucin-like hormone receptor-like sequence 1 (F4/80) expression decreased with parasitemia in mice infected with 17X, whereas MRC1 an MRC2 increased and F4/80 decreased in mice infected with 17XL. Furthermore, macrophage receptor with collagenous structure and CD68 declined rapidly after initial parasitemia. SIGNR1 and Sn expression demonstrated minor variations in the spleens of mice infected with either strain. Notably, macrophage scavenger receptor (Msr1) and dendritic cell-associated C-type lectin 2 expression increased at both the transcript and protein levels in 17XL-infected mice with 50% parasitemia. Furthermore, the increased lethality of 17X infection in Msr1 -/- mice demonstrated a protective role for Msr1. Our results suggest a dual role for these receptors in parasite clearance and protection in 17X infection and lethality in 17XL infection.

Surface assembly of poly(I:C) on PEGylated microspheres to shield from adverse interactions with fibroblasts.

By expressing an array of pattern recognition receptors (PRRs), fibroblasts play an important role in stimulating and modulating the response of the innate immune system. The TLR3 ligand polyriboinosinic acid-polyribocytidylic acid, poly(I:C), a mimic of viral dsRNA, is a vaccine adjuvant candidate to activate professional antigen presenting cells (APCs). However, owing to its ligation with extracellular TLR3 on fibroblasts, subcutaneously administered poly(I:C) bears danger towards autoimmunity. It is thus in the interest of its clinical safety to deliver poly(I:C) in such a way that its activation of professional APCs is as efficacious as possible, whereas its interference with non-immune cells such as fibroblasts is controlled or even avoided. Complementary to our previous work with monocyte-derived dendritic cells (MoDCs), here we sought to control the delivery of poly(I:C) surface-assembled on microspheres to human foreskin fibroblasts (HFFs). Negatively charged polystyrene (PS) microspheres were equipped with a poly(ethylene glycol) (PEG) corona through electrostatically driven coatings with a series of polycationic poly(L-lysine)-graft-poly(ethylene glycol) copolymers, PLL-g-PEG, of varying grafting ratios g from 2.2 up to 22.7. Stable surface assembly of poly(I:C) was achieved by incubation of polymer-coated microspheres with aqueous poly(I:C) solutions. Notably, recognition of both surface-assembled and free poly(I:C) by extracellular TLR3 on HFFs halted their phagocytic activity. Ligation of surface-assembled poly(I:C) with extracellular TLR3 on HFFs could be controlled by tuning the grafting ratio g and thus the chain density of the PEG corona. When assembled on PLL-5.7-PEG-coated microspheres, poly(I:C) was blocked from triggering class I MHC molecule expression on HFFs. Secretion of interleukin (IL)-6 by HFFs after exposure to surface-assembled poly(I:C) was distinctly lower as compared to free poly(I:C). Overall, surface assembly of poly(I:C) may have potential to contribute to the clinical safety of this vaccine adjuvant candidate.