Mucosal Heterologous Prime/Boost Vaccination Induces Polyfunctional Systemic Immunity, Improving Protection Against Trypanosoma cruzi

Albertí, A.; Bivona, Augusto E.; Matos, Marina N.; Cerny, Natacha; Schulze, Kai; Weißmann, Sebastian; Ebensen, Thomas; González, Germán; Morales, Celina; Cardoso, Alejandro C.; Cazorla, Silvia I.; Guzmán, Carlos A.; Malchiodi, Emilio L.

doi:10.3389/fimmu.2020.00128

Cited by 21 publications

(20 citation statements)

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“…In the last few years, a better understanding of the protective immune responses that can effectively arrest T. cruzi survival in mammalian host provides the fundamentals for a rational design of a prophylactic and therapeutic vaccine against Chagas disease ( 22 ). Anti- T. cruzi strategies had been focused on targeting specific metabolic biochemical pathways or parasite-specific enzymes, as well as noninvasive immunization routes ( 23 , 24 ). Most of these strategies need potent adjuvant to obtain the desirable response to improve vaccine efficacy ( 43 ).…”

Section: Discussionmentioning

confidence: 99%

“…In our laboratory, we took advantage of attenuated Salmonella enterica serovar Typhimurium aroA that can be administered orally and is easily produced, facilitating its implementation in vaccination campaigns. We have previously demonstrated the efficacy of this transport system as prophylactic vaccines to T. cruzi infection ( 19 , 21 , 24 , 50 , 51 ). Based on these promising results, we have evaluated the therapeutic effect of Salmonella as a DNA delivery system of Cz upon the coadministration with GM-CSF as adjuvant with good performance ( 25 ).…”

Section: Discussionmentioning

confidence: 99%

“…Cz stimulates potent humoral and cellular immune responses during infection ( 18 ). Additionally, Cz has been reported as an efficient prophylactic vaccine as both protein and DNA vaccine, in different administration routes and coupled with several adjuvants ( 19 – 24 ). In addition, we had encouraging results using a therapeutic Cz DNA-based vaccine that has been able to decrease parasitemia, inflammatory cell infiltrate, and tissue damage in murine models of T. cruzi infection ( 25 ).…”

Section: Introductionmentioning

confidence: 99%

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Cruzipain and Its Physiological Inhibitor, Chagasin, as a DNA-Based Therapeutic Vaccine Against Trypanosoma cruzi

et al. 2020

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Chagas disease caused by the protozoan parasite Trypanosoma cruzi is endemic in 21 Latin American countries and the southern United States and now is spreading into several other countries due to migration. Despite the efforts to control the vector throughout the Americas, currently, there are almost seven million infected people worldwide, causing ~10,000 deaths per year, and 70 million people at risk to acquire the infection. Chagas disease treatment is restricted only to two parasiticidal drugs, benznidazole and nifurtimox, which are effective during the acute and early infections but have not been found to be as effective in chronic infection. No prophylactic or therapeutic vaccine for human use has been communicated at this moment. Here, we evaluate in a mouse model a therapeutic DNA vaccine combining Cruzipain (Cz), a T. cruzi cysteine protease that proved to be protective in several settings, and Chagasin (Chg), which is the natural Cz inhibitor. The DNAs of both antigens, as well as a plasmid encoding GM-CSF as adjuvant, were orally administrated and delivered by an attenuated Salmonella strain to treat mice during the acute phase of T. cruzi infection. The bicomponent vaccine based on Salmonella carrying Cz and Chg (SChg+SCz) was able to improve the protection obtained by each antigen as monocomponent therapeutic vaccine and significantly increased the titers of antigen- and parasite-specific antibodies. More importantly, the bicomponent vaccine triggered a robust cellular response with interferon gamma (IFN-γ) secretion that rapidly reduced the parasitemia during the acute phase and decreased the tissue damage in the chronic stage of the infection, suggesting it could be an effective tool to ameliorate the pathology associated to Chagas disease.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Cruzipain and Its Physiological Inhibitor, Chagasin, as a DNA-Based Therapeutic Vaccine Against Trypanosoma cruzi

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“…For this purpose, after the last immunization animals were challenged with 3 × 10 5 blood trypomastigotes of the less virulent K98 clone (from CA-I strain) by intraperitoneal injection. Parasitemias were recorded weekly during the acute phase (19,35).…”

Section: Challenge With T Cruzi Bloodstream Trypomastigotesmentioning

confidence: 99%

“…described that the N-terminal domain of Cz (Nt-Cz) displayed the highest protective role during immunization, bypassing ineffective responses towards the C-terminal domain (17). In previous work from our laboratory, an engineered chimeric immunogen named Traspain was designed containing Nt-Cz as one of the key parasitic molecules, with very promising results (18,19).…”

Section: Introductionmentioning

confidence: 99%

Heterologous Chimeric Construct Comprising a Modified Bacterial Superantigen and a Cruzipain Domain Confers Protection Against Trypanosoma cruzi Infection

et al. 2020

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Chagas disease is an endemic chronic parasitosis in Latin America affecting more than 7 million people. Around 100 million people are currently at risk of acquiring the infection; however, no effective vaccine has been developed yet. Trypanosoma cruzi is the etiological agent of this parasitosis and as an intracellular protozoan it can reside within different tissues, mainly muscle cells, evading host immunity and allowing progression towards the chronic stage of the disease. Considering this intracellular parasitism triggers strong cellular immunity that, besides being necessary to limit infection, is not sufficient to eradicate the parasite from tissues, a differential immune response is required and new strategies for vaccines against Chagas disease need to be explored. In this work, we designed, cloned and expressed a chimeric molecule, named NCz-SEGN24A, comprising a parasite antigen, the N-terminal domain of the major cysteine protease of T. cruzi, cruzipain (Nt-Cz), and a non-toxic form of the staphylococcal superantigen (SAg) G, SEG, with the residue Asn24 mutated to Ala (N24A). The mutant SAg SEGN24A, retains its ability to trigger classical activation of macrophages without inducing T cell apoptosis. To evaluate, as a proof of concept, the immunogenicity and efficacy of the chimeric immunogen vs. its individual antigens, C3H mice were immunized intramuscularly with NCz-SEGN24A co-adjuvanted with CpG-ODN, or the recombinant proteins Nt-Cz plus SEGN24A with the same adjuvant. Vaccinated mice significantly produced Nt-Cz-specific IgG titers after immunization and developed higher IgG2a than IgG1 titers. Specific cell-mediated immunity was assessed by in-vivo DTH and significant responses were obtained. To assess protection, mice were challenged with trypomastigotes of T. cruzi. Both schemes reduced the parasite Antonoglou et al. Heterologous Immunogen Protects Against T. cruzi load throughout the acute phase, but only mice immunized with NCz-SEGN24A showed significant differences against control; moreover, these mice maintained 100% survival. These results encourage testing mutated superantigens fused to specific antigens as immune modulators against pathogens.

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The high identity of the Trypanosoma cruziGroup‐I of trans‐sialidases points them as promising vaccine immunogens

Pacini,

Perdomini,

Bulfoni Balbi

et al. 2023

Proteins

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Trans‐sialidase (TS) superfamily of proteins comprises eight subgroups, being the proteins of Group‐I (TS‐GI) promising immunogens in vaccine approaches against Trypanosoma cruzi. Strikingly, TS‐GI antigenic variability among parasite lineages and their influence on vaccine development has not been previously analyzed. Here, a search in GenBank detects 49 TS‐GI indexed sequences, whereas the main infecting human different parasite discrete typing units (DTU) are represented. In silico comparison among these sequences indicate that they share an identity above 92%. Moreover, the antigenic regions (T‐cell and B‐cell epitopes) are conserved in most sequences or present amino acid substitutions that scarcely may alter the antigenicity. Additionally, since the generic term TS is usually used to refer to different immunogens of this broad family, a further in silico analysis of the TS‐GI‐derived fragments tested in preclinical vaccines was done to determine the coverage and identity among them, showing that overall amino acid identity of vaccine immunogens is high, but the segment coverage varies widely. Accordingly, strong H‐2K, H‐2I, and B‐cell epitopes are dissimilarly represented among vaccine TS‐derived fragments depending on the extension of the TG‐GI sequence used. Moreover, bioinformatic analysis detected a set of 150 T‐cell strong epitopes among the DTU‐indexed sequences that strongly bind human HLA‐I supertypes. In all currently reported experimental vaccines based on TS‐GI fragments, mapping these 150 epitopes showed that they are moderately represented. However, despite vaccine epitopes do not present all the substitutions observed in the DTUs, these regions of the proteins are equally recognized by the same HLAs. Interestingly, the predictions regarding global and South American population coverage estimated in these 150 epitopes are similar to the estimations in experimental vaccines when the complete sequence of TS‐GI is used as an antigen. In silico prediction also shows that a number of these MHC‐I restricted T‐cell strong epitopes could be also cross‐recognized by HLA‐I supertypes and H‐2Kb or H‐2Kd backgrounds, indicating that these mice may be used to improve and facilitate the development of new TS‐based vaccines and suggesting an immunogenic and protective potential in humans. Further molecular docking analyses were performed to strengthen these results. Taken together, different strategies that would cover more or eventually fully of these T‐cell and also B‐cell epitopes to reach a high level of coverage are considered.

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Mucosal Heterologous Prime/Boost Vaccination Induces Polyfunctional Systemic Immunity, Improving Protection Against Trypanosoma cruzi

Cited by 21 publications

References 52 publications

Cruzipain and Its Physiological Inhibitor, Chagasin, as a DNA-Based Therapeutic Vaccine Against Trypanosoma cruzi

Cruzipain and Its Physiological Inhibitor, Chagasin, as a DNA-Based Therapeutic Vaccine Against Trypanosoma cruzi

Heterologous Chimeric Construct Comprising a Modified Bacterial Superantigen and a Cruzipain Domain Confers Protection Against Trypanosoma cruzi Infection

The high identity of the Trypanosoma cruziGroup‐I of trans‐sialidases points them as promising vaccine immunogens

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