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Kelp forests are essential marine ecosystems increasingly compromised by human activities. Effective reforestation strategies are urgently needed, and the “green gravel” method is a viable tool already used in some European regions. This study aimed to assess the success of this method using the native Kelp species Laminaria ochroleuca on the Portuguese coastline. Cultures of green gravel were reared until the specimens reached a size of approximately 3 cm. The gravel was then deployed at selected sites in Peniche, Berlengas, and Cascais. Over an eight-month period, scientific scuba divers monitored the integration of Kelp, along with associated fish, invertebrate, and algae communities. Nutrient availability, temperature, water movement, substrate type, and Rugosity Index (RI) were also measured. The highest success rate was 12% in Consolação, with Elefante and Galos (Berlengas) reaching 7% and 4%, respectively. By the end of the monitoring period, Cascais had no remaining Kelp on green gravel. Present data suggest that higher success is dependent on less rugged and higher RI topography. Higher grazing pressure, rougher terrain, and unexpected sedimentation appear to be the main obstacles to deployment success. Solid knowledge (biologic and topographic) on the restoration site, starting restoration actions near already established Kelp forests, and significantly scaling up restoration efforts could substantially improve the success of the green gravel method in future reforestation campaigns.

The challenge of American tegumentary leishmaniasis (ATL) continues in Brazil, presenting a persistent public health issue despite initiatives aimed at public outreach, vector control and health education. To gain a deeper understanding of this disease, a study was conducted in an endemic region located in the northern region of the state of Minas Gerais, Brazil. The study monitored 30 resident patients diagnosed with ATL, using serum samples from 6 healthy individuals as controls. The localized cutaneous form of the disease was found to be predominant, with lesions appearing on various parts of the body and the majority of the affected individuals being male. The study found significantly higher levels of IgG anti- α -Gal antibodies in ATL-infected patients compared to healthy individuals. Treatment of 19 patients with meglumine antimoniate resulted in limited improvement in symptoms for most. Nonetheless, the study found that 12 patients who completed treatment with epithelialization of the lesions showed a significant decrease in IgG anti- α -Gal antibodies, indicating potential applications of this antibody in the diagnosis and monitoring of the disease. The study also identified Leishmania species in 7 analysed patients, revealing 6 cases infected by Leishmania braziliensis and 1 by L. infantum , with a significant difference in the anti- α -Gal responses. The findings of the study emphasize the urgent need for the development of human vaccines and innovative treatment strategies adapted to the diversity of Leishmania species causing cutaneous leishmaniasis and individual patient responses to improve the clinical management of ATL in Brazil and similar endemic regions.

B-cells mediate humoral adaptive immune response via the production of antibodies and cytokines, and by inducing T-cell activation. These functions can be attributed to distinct B-cell subpopulations. Infection with , the causative agent of Chagas disease, induces a polyclonal B-cell activation and lytic antibody production, critical for controlling parasitemia. Individuals within the chronic phase of Chagas disease may remain in an asymptomatic form (indeterminate), or develop severe cardiomyopathy (cardiac form) that can lead to death. Currently, there is no effective vaccine to prevent Chagas disease, and no treatment to halt the development of the cardiomyopathy once it is installed. The pathology associated with cardiac Chagas disease is a result of an inflammatory reaction. Thus, discovering characteristics of the host's immune response that favor the maintenance of favorable heart function may unveil important immunotherapeutic targets. Given the importance of B cells in antibody production and parasite control, we investigated derived antigenic fractions responsible for B-cell activation and whether frequencies and functional characteristics of B-cell subpopulations are associated with different clinical outcomes of human Chagas disease. We stimulated cells from indeterminate (I) and cardiac (C) Chagas patients, as well as non-infected individuals (NI), with -derived protein- (PRO), glycolipid- (GCL) and lipid (LIP)-enriched fractions and determined functional characteristics of B-cell subpopulations. Our results showed that the frequency of B-cells was similar amongst groups. PRO, but not GCL nor LIP, led to an increased frequency of B1 B-cells in I, but not C nor NI. Although stimulation with PRO induced higher TNF expression by B1 B-cells from C and I, as compared to NI, it induced expression of IL-10 in cells from I, but not C. Stimulation with PRO induced an increased frequency of the CD11b B1 B-cell subpopulation, which was associated with better cardiac function. Chagas patients displayed increased IgM production, and activation of gamma-delta T-cells, which have been associated with B1 B-cell function. Our data showed that PRO activates CD11b B1 B-cells, and that this activation is associated with a beneficial clinical status. These findings may have implications in designing new strategies focusing on B-cell activation to prevent Chagas disease cardiomyopathy.

Trypanosoma cruzi is the causative agent of the life-threatening Chagas disease, in which increased platelet aggregation related to myocarditis is observed. Platelet-activating factor (PAF) is a potent intercellular lipid mediator and second messenger that exerts its activity through a PAF-specific receptor (PAFR). Previous data from our group suggested that T. cruzi synthesizes a phospholipid with PAF-like activity. The structure of T. cruzi PAF-like molecule, however, remains elusive. Here, we have purified and structurally characterized the putative T. cruzi PAF-like molecule by electrospray ionization-tandem mass spectrometry (ESI-MS/MS). Our ESI-MS/MS data demonstrated that the T. cruzi PAF-like molecule is actually a lysophosphatidylcholine (LPC), namely sn-1 C18:1(delta 9)-LPC. Similar to PAF, the platelet-aggregating activity of C18:1-LPC was abrogated by the PAFR antagonist, WEB 2086. Other major LPC species, i.e., C16:0-, C18:0-, and C18:2-LPC, were also characterized in all T. cruzi stages. These LPC species, however, failed to induce platelet aggregation. Quantification of T. cruzi LPC species by ESI-MS revealed that intracellular amastigote and trypomastigote forms have much higher levels of C18:1-LPC than epimastigote and metacyclic trypomastigote forms. C18:1-LPC was also found to be secreted by the parasite in extracellular vesicles (EV) and an EV-free fraction. A three-dimensional model of PAFR was constructed and a molecular docking study was performed to predict the interactions between the PAFR model and PAF, and each LPC species. Molecular docking data suggested that, contrary to other LPC species analyzed, C18:1-LPC is predicted to interact with the PAFR model in a fashion similar to PAF. Taken together, our data indicate that T. cruzi synthesizes a bioactive C18:1-LPC, which aggregates platelets via PAFR. We propose that C18:1-LPC might be an important lipid mediator in the progression of Chagas disease and its biosynthesis could eventually be exploited as a potential target for new therapeutic interventions.

Paracoccidioidomycosis (PCM), caused by Paracoccidioides brasiliensis, is the most prevalent invasive fungal disease in South America. Systemic mycoses are the 10th most common cause of death among infectious diseases in Brazil and PCM is responsible for more than 50% of deaths due to fungal infections. PCM is typically treated with sulfonamides, amphotericin B or azoles, although complete eradication of the fungus may not occur and relapsing disease is frequently reported. A 15-mer peptide from the major diagnostic antigen gp43, named P10, can induce a strong T-CD4+ helper-1 immune response in mice. The TEPITOPE algorithm and experimental data have confirmed that most HLA-DR molecules can present P10, which suggests that P10 is a candidate antigen for a PCM vaccine. In the current work, the therapeutic efficacy of plasmid immunization with P10 and/or IL-12 inserts was tested in murine models of PCM. When given prior to or after infection with P. brasiliensis virulent Pb 18 isolate, plasmid-vaccination with P10 and/or IL-12 inserts successfully reduced the fungal burden in lungs of infected mice. In fact, intramuscular administration of a combination of plasmids expressing P10 and IL-12 given weekly for one month, followed by single injections every month for 3 months restored normal lung architecture and eradicated the fungus in mice that were infected one month prior to treatment. The data indicate that immunization with these plasmids is a powerful procedure for prevention and treatment of experimental PCM, with the perspective of being also effective in human patients.

[This corrects the article DOI: 10.3389/fimmu.2018.03015.].

•We report a peptide-based vaccine candidate for Chagas disease.•Use of immunoinformatics for selection of an immunogenic peptide.•Peptide comprises overlapping human and mouse B- and T-cell epitopes.•Peptide vaccine protects mice by priming both humoral and cellular immunity. Chagas disease, caused by Trypanosoma cruzi, is responsible for producing significant morbidity and mortality throughout Latin America. The disease has recently become a public health concern to nonendemic regions like the U.S. and Europe. Currently there are no fully effective drugs or vaccine available to treat the disease. The mucin-associated surface proteins (MASPs) are glycosylphosphatidylinositol (GPI)-anchored glycoproteins encoded by a multigene family with hundreds of members. MASPs are among the most abundant antigens found on the surface of the infective trypomastigote stage of T. cruzi, thus representing an attractive target for vaccine development. Here we used immunoinformatics to select a 20-mer peptide with several predicted overlapping B-cell, MHC-I, and MHC-II epitopes, from a MASP family member expressed on mammal-dwelling stages of T. cruzi. The synthetic MASP peptide conjugated to keyhole limpet hemocyanin (MASPpep-KLH) was tested in presence or not of an adjuvant (alum, Al) as a vaccine candidate in the C3H/HeNsd murine model of T. cruzi infection. In considerable contrast to the control groups receiving placebo, Al, or KLH alone or the group immunized with MASPpep-KLH/Al, the group immunized with MASPpep-KLH showed 86% survival rate after challenge with a highly lethal dose of trypomastigotes. As evaluated by quantitative real-time polymerase chain reaction, MASPpep-KLH-immunized animals had much lower parasite load in the heart, liver, and spleen than control animals. Moreover, protected animals produced trypanolytic, protective antibodies, and a cytokine profile conducive to resistance against parasite infection. Finally, in vivo depletion of either CD4+ or CD8+ T cells indicated that the latter are critical for protection in mice immunized with MASPpep-KLH. In summary, this new peptide-based vaccine with overlapping B- and T-cell epitopes is able to control T. cruzi infection in mice by priming both humoral and cellular immunity.

Chagas disease (ChD), caused by the hemoflagellate parasite Trypanosoma cruzi , affects six to seven million people in Latin America. Lately, it has become an emerging public health concern in nonendemic regions such as North America and Europe. There is no prophylactic or therapeutic vaccine as yet, and current chemotherapy is rather toxic and has limited efficacy in the chronic phase of the disease. The parasite surface is heavily coated by glycoproteins such as glycosylphosphatidylinositol (GPI)-anchored mucins (tGPI-mucins), which display highly immunogenic terminal nonreducing α-galactopyranosyl (α-Gal)-containing glycotopes that are entirely absent in humans. The immunodominant tGPI-mucin α-Gal glycotope, the trisaccharide Galα1,3Galβ1,4GlcNAc (Galα3LN), elicits high levels of protective T . cruzi -specific anti-α-Gal antibodies in ChD patients in both the acute and chronic phases. Although glycoconjugates are the major parasite glycocalyx antigens, they remain completely unexplored as potential ChD vaccine candidates. Here we investigate the efficacy of the T . cruzi immunodominant glycotope Galα3LN, covalently linked to a carrier protein (human serum albumin (HSA)), as a prophylactic vaccine candidate in the acute model of ChD, using the α1,3-galactosyltransferase-knockout (α1,3GalT-KO) mouse, which mimics the human immunoresponse to α-Gal glycotopes. Animals vaccinated with Galα3LN-HSA were fully protected against lethal T . cruzi challenge by inducing a strong anti-α-Gal antibody-mediated humoral response. Furthermore, Galα3LN-HSA-vaccinated α1,3GalT-KO mice exhibited significant reduction (91.7–99.9%) in parasite load in all tissues analyzed, cardiac inflammation, myocyte necrosis, and T cell infiltration. This is a proof-of-concept study to demonstrate the efficacy of a prophylactic α-Gal-based glycovaccine for experimental acute Chagas disease. Chagas disease: Unexplored glycans make for an effective anti-parasitic therapy A vaccine candidate derived from an immunodominant parasitic glycan could offer a much-needed preventive therapy for Chagas disease. The disease, caused by the parasite Trypanosoma cruzi , is endemic to Latin America and an emergent threat to North America and Europe. Current therapies are few, poorly efficacious, and toxic. Igor Almeida, from the University of Texas at El Paso, United States, and his team created a candidate which presents a host with T . cruzi surface-derived α-galactose-containing (α-Gal) glycan covalently linked to a carrier protein. Parasite-derived α-Gal-containing proteins are known to be highly immune-stimulating to humans but were previously unexplored as prophylactics. In a mouse model designed to mimic the human response to Chagas disease, vaccinated animals had a strong antibody response and were fully protected against lethal exposure to T . cruzi . The results offer a promising candidate for future research and validate the method used in this proof-of-concept study.

Chagas disease, caused byTrypanosoma cruzi, is responsible for producing significant morbidity and mortality throughout Latin America. The disease has recently become a public health concern to nonendemic regions like the U.S. and Europe. Currently there are no fully effective drugs or vaccine available to treat the disease. The mucin-associated surface proteins (MASPs) are glycosylphosphatidylinositol (GPI)-anchored glycoproteins encoded by a multigene family with hundreds of members. MASPs are among the most abundant antigens found on the surface of the infective trypomastigote stage ofT. cruzi, thus representing an attractive target for vaccine development. Here we used immunoinformatics to select a 20-mer peptide with several predicted overlapping B-cell, MHC-I, and MHC-II epitopes, from a MASP family member expressed on mammal-dwelling stages ofT. cruzi. The synthetic MASP peptide conjugated to keyhole limpet hemocyanin (MASPpep-KLH) was tested in presence or not of an adjuvant (alum, Al) as a vaccine candidate in the C3H/HeNsd murine model ofT. cruziinfection. In considerable contrast to the control groups receiving placebo, Al, or KLH alone or the group immunized with MASPpep-KLH/Al, the group immunized with MASPpep-KLH showed 86% survival rate after challenge with a highly lethal dose of trypomastigotes. As evaluated by quantitative real-time polymerase chain reaction, MASPpep-KLH-immunized animals had much lower parasite load in the heart, liver, and spleen than control animals. Moreover, protected animals produced trypanolytic, protective antibodies, and a cytokine profile conducive to resistance against parasite infection. Finally, in vivo depletion of either CD4+or CD8+T cells indicated that the latter are critical for protection in mice immunized with MASPpep-KLH. In summary, this new peptide-based vaccine with overlapping B- and T-cell epitopes is able to controlT. cruziinfection in mice by priming both humoral and cellular immunity.