Marie-Noëlle Mévélec

The MIC3 Gene of Toxoplasma gondii Is a Novel Potent Vaccine Candidate against Toxoplasmosis

ABSTRACT Infection with the intracellular protozoan parasite Toxoplasma gondii causes serious public health problems and is of great economic importance worldwide. The micronemal protein MIC3, which is a potent adhesin of T. gondii, could be a significant candidate vaccine against toxoplasmosis. In this study, all CBA/J mice intramuscularly vaccinated with a plasmid encoding the immature form of the MIC3 protein (pMIC3i) produced specific anti-MIC3 immunoglobulin G (IgG) antibodies, and their sera displayed high antibody titers. This response was increased by the coadministration of a plasmid encoding the granulocyte-macrophage colony-stimulating factor (pGM-CSF). Similarly, a specific and significant cellular immune response was obtained in mice immunized with pMIC3i, and this response was markedly enhanced by pGM-CSF coadministration. The cellular immune response was associated with the production of gamma interferon IFN-γ and interleukin-2 (IL-2), indicating that this was a Th1-type response. This was confirmed by the production of large amounts of IgG2a. Mice immunized with pMIC3i displayed significant protection against an oral challenge with T. gondii 76K cysts, exhibiting fewer brain cysts than did the control mice. Coadministration of pGM-CSF enhanced this protection. In conclusion, this study describes the design of a potent DNA vaccine encoding the novel T. gondii target antigen, MIC3 protein, that elicits a strong specific immune response as well as providing effective protection against T. gondii infection. In the attempt to achieve complete protection against toxoplasmosis, MIC3 is a good candidate vaccine which could be combined with other relevant and previously described candidates, such as SAG1 and GRA4.

Induction of protective immunity against toxoplasmosis in mice by DNA immunization with a plasmid encoding Toxoplasma gondii GRA4 gene

GRA4 is a dense granule protein of Toxoplasma gondii that is a candidate for vaccination against this parasite. We have inserted the entire coding sequence of GRA4 into an eukaryotic expression vector to determine whether DNA immunization can elicit protective immune response to T. gondii. Susceptible C57BL/6 mice were then vaccinated intramuscularly with GRA4 DNA and orally challenged with a lethal dose of 76 K T. gondii strain cysts. Immunization with pGRA4 resulted in a 62% survival of C57BL/6 infected mice. Mice immunized with GRA4 DNA developed high levels of serum anti-GRA4 immunoglobulin G antibodies as well as a cellular immune response, as assessed by splenocyte proliferation, in response to recombinant GRA4 protein restimulation in vitro. The cellular immune response was associated with IFN-gamma and IL-10 synthesis, suggesting a modulated Th1-type response. Splenocyte proliferation was strongly enhanced and protection slightly higher by inoculation with GRA4 DNA combined with a granulocyte-macrophage colony-stimulating factor expressing vector. This is the first report that demonstrates the establishment of a DNA vaccine-induced protective immunity against the acute phase of T. gondii infection.

Molecular cloning of GRA4, a Toxoplasma gondii dense granule protein, recognized by mucosal IgA antibodies

Clones which were selected from a Toxoplasma gondii expression library with the immune serum from a T. gondii-infected rabbit, were further screened using milk and intestinal secretions from mice which had been orally infected with T. gondii cysts. The gene products of several clones reacted strongly with milk IgA and weakly with intestinal IgA. Three of these clones (5.1, 36.1, 37.4) were shown to encode a dense granule protein of 40 kDa (GRA4). The GRA4 protein co-migrates with one of the T. gondii antigens recognized by mucosal IgA. The complete nucleotide sequence of GRA4 has been obtained by cloning genomic T. gondii BamHI fragments containing the 37.4 DNA insert. The coding sequence contains no intron. The deduced amino acid sequence indicates a proline rich (12%) product with an internal hydrophobic region of 19 amino acids and a potential site of N-glycosylation. The primary translation product with a theoretical size of 36,260 Da contains a putative N-terminal signal sequence of 20 amino acids but no apparent glycolipid anchor sequence. Quantitation of the GRA4 gene and Southern blot analysis suggested that the GRA4 gene is single copy. GRA4 gene is translated in tachyzoites to yield a single mRNA species of about 1900 bases.

Nasal immunization of mice with Cryptosporidium parvum DNA induces systemic and intestinal immune responses

DNA immunization offers a novel approach to inducing humoral and cellular immunity against infectious pathogens. We examined whether such an approach could be used against cryptosporiodiosis, an intestinal disease caused by the protozoan parasite Cryptosporidium parvum. This infection is a major problem for young ruminants and immunosuppressed individuals in whom cryptosporidiosis causes life‐threatening symptoms. The life cycle of C. parvum takes place in the enterocytes of the intestinal epithelium. We therefore focused our attention on a route of immunization that might induce a mucosal immunoglobulin (Ig)A response. Eight‐week‐old BALB/c mice were immunized intranasally with DNA encoding a 15‐kDa C. parvum sporozoite antigen (CP15‐DNA) cloned onto the plasmid pcDNA3. CP15‐DNA‐immunized mice developed specific and longlasting production of anti‐CP15 Ig A in intestinal secretions and specific IgG in sera 3 months and 1 year after the first DNA inoculation. CP15‐DNA‐immunized mice also developed an antigen‐specific T lymphocyte proliferative response in both spleen and mesenteric lymph nodes. Control mice that received the pcDNA3 plasmid alone did not develop specific humoral and cellular responses. These results indicate that plasmid DNA may provide a powerful means of eliciting intestinal humoral and cellular responses to C. parvum infections in mammals.

Mic1-3 Knockout of Toxoplasma gondii Is a Successful Vaccine against Chronic and Congenital Toxoplasmosis in Mice

BACKGROUNDnWe evaluated a new vaccine, Mic1-3KO, against both chronic and congenital toxoplasmosis in mice. Mic1-3KO is a mutant strain of Toxoplasma gondii RH that lacks the mic1 and mic3 genes.nnnMETHODSnOF1 mice were vaccinated with Mic1-3KO tachyzoites and challenged orally with T. gondii (strain 76K). Immune responses and protection against chronic infection (cyst load in brain tissue) and congenital infection (maternofetal transmission, survival, body weight, and chronic infection in pups) were evaluated.nnnRESULTSnMic1-3KO induced a strong humoral and cellular T helper (Th) 1 response and conferred highly significant protection against chronic infection (>96% reduction in cysts in brain tissue). Fewer infected fetuses were observed in vaccinated dams that were infected during pregnancy than in nonvaccinated infected dams (4.6% vs. 33.3%). All pups born to vaccinated infected dams survived and had the same weight as those born to nonvaccinated uninfected dams. Furthermore, they had significantly fewer cysts in brain tissue (>91%) than pups from nonvaccinated infected dams. During pregnancy, protection against congenital disease was associated with a cellular Th1 response regulated by interleukin-10. One month after delivery, vaccinated infected dams had >96% fewer cysts in their brain tissue than nonvaccinated infected dams.nnnCONCLUSIONnMic1-3KO is an effective vaccine against chronic and congenital toxoplasmosis.

Protective Mucosal Th2 Immune Response against Toxoplasma gondii by Murine Mesenteric Lymph Node Dendritic Cells

ABSTRACT Toxoplasma gondii, an obligate intracellular parasite pathogen which initially invades the intestinal epithelium before disseminating throughout the body, may cause severe sequelae in fetuses and life-threatening neuropathy in immunocompromised patients. Immune protection is usually thought to be performed through a systemic Th1 response; considering the route of parasite entry it is important to study and characterize the local mucosal immune response to T. gondii. Despite considerable effort, Toxoplasma-targeted vaccines have proven to be elusive using conventional strategies. We report the use of mesenteric lymph node dendritic cells (MLNDCs) pulsed ex vivo with T. gondii antigens (TAg) as a novel investigation approach to vaccination against T. gondii-driven pathogenic processes. Using a murine model, we demonstrate in two genetically distinct mouse strains (C57BL/6 and CBA/J) that adoptively transferred TAg-pulsed MLNDCs elicit a mucosal Toxoplasma-specific Th2-biased immune response in vivo and confer strong protection against infection. We also observe that MLNDCs mostly traffic to the intestine where they enhance resistance by reduction in the mortality and in the number of brain cysts. Thus, ex vivo TAg-pulsed MLNDCs represent a powerful tool for the study of protective immunity to T. gondii, delivered through its natural route of entry. These findings might impact the design of vaccine strategies against other invasive microorganisms known to be delivered through digestive tract.

Targeted Delivery of Toxoplasma gondii Antigens to Dendritic Cells Promote Immunogenicity and Protective Efficiency against Toxoplasmosis

Toxoplasmosis is a major public health problem and the development of a human vaccine is of high priority. Efficient vaccination against Toxoplasma gondii requires both a mucosal and systemic Th1 immune response. Moreover, dendritic cells play a critical role in orchestrating the innate immune functions and driving specific adaptive immunity to T. gondii. In this study, we explore an original vaccination strategy that combines administration via mucosal and systemic routes of fusion proteins able to target the major T. gondii surface antigen SAG1 to DCs using an antibody fragment single-chain fragment variable (scFv) directed against DEC205 endocytic receptor. Our results show that SAG1 targeting to DCs by scFv via intranasal and subcutaneous administration improved protection against chronic T. gondii infection. A marked reduction in brain parasite burden is observed when compared with the intranasal or the subcutaneous route alone. DC targeting improved both local and systemic humoral and cellular immune responses and potentiated more specifically the Th1 response profile by more efficient production of IFN-γ, interleukin-2, IgG2a, and nasal IgA. This study provides evidence of the potential of DC targeting for the development of new vaccines against a range of Apicomplexa parasites.

VACCINATION CONTRE LA TOXOPLASMOSE CHEZ LES ANIMAUX DE RENTE

La toxoplasmose est une zoonose mondialement repandue. Chez lhomme, elle apparait apres lingestion de viandes insuffisamment cuites danimaux contamines. Chez le mouton et la chevre, elle est a lorigine de nombreux avortements. Une etude approfondie de sa seroprevalence chez les differentes especes animales peut permettre de mieux informer les consommateurs et ainsi de limiter les risques de transmission. La vaccination des animaux semble etre une alternative interessante puisquelle pourrait diminuer la transmission a lhomme mais egalement prevenir les avortements chez les brebis. Lutilisation dune souche naturelle de Toxoplasma gondii incomplete, presentant une virulence attenuee, a montre son efficacite dans la protection contre lavortement des brebis. Cependant, sa virulence nest pas bien controlee, et le risque de reversion vers la forme virulente existe. Les techniques de biologie moleculaire ont permis dobtenir des souches attenuees par la deletion de genes cibles, qui ne sont pas susceptibles de retrouver leur virulence dorigine. Lune delles, appelee Mic1-3KO, a montre son efficacite dans un modele murin contre la toxoplasmose chronique et congenitale. Elle est egalement efficace contre la toxoplasmose congenitale chez la brebis. Cette demarche vaccinale reste prometteuse. De plus, lutilisation du toxoplasme comme vecteur vaccinal reste une perspective interessante, puisque ce parasite est capable dexprimer des proteines etrangeres.