Immune Responses Induced by theLeishmania(Leishmania)donovaniA2 Antigen, but Not by the LACK Antigen, Are Protective against ExperimentalLeishmania(Leishmania)amazonensisInfection

Coelho, Eduardo Antônio Ferraz; Tavares, Carlos Alberto Pereira; Carvalho, Fernando Aécio de Amorim; Chaves, Karina Figueiredo; Teixeira, Kádima Nayara; Rodrigues, Rafaela Chitarra; Charest, Hugues; Matlashewski, Greg; Gazzinelli, Ricardo T.; Fernandes, Ana Paula

doi:10.1128/iai.71.7.3988-3994.2003

Cited by 209 publications

(204 citation statements)

References 41 publications

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“…Several Leishmania proteins have been identified, and the most comprehensively studied antigens include glycoprotein 63 (gp63) (Xu et al 1995;Bhowmick et al 2008), glycoprotein 46 (gp46) or parasite surface antigen 2 (PSA-2) (McMahon-Pratt et al 1992, 1993, Leishmania homologue of receptors for activated C kinase (LACK) (Coelho et al 2003;Pinto et al 2004), and focused mannose ligand (FML) (Palatnik de Sousa et al 1994;). …”

Section: New Perspectives For Applications Of Proteoliposomesmentioning

confidence: 99%

Proteoliposomes in nanobiotechnology

et al. 2012

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Proteoliposomes are systems that mimic lipid membranes (liposomes) to which a protein has been incorporated or inserted. During the last decade, these systems have gained prominence as tools for biophysical studies on lipid-protein interactions as well as for their biotechnological applications. Proteoliposomes have a major advantage when compared with natural membrane systems, since they can be obtained with a smaller number of lipidic (and protein) components, facilitating the design and interpretation of certain experiments. However, they have the disadvantage of requiring methodological standardization for incorporation of each specific protein, and the need to verify that the reconstitution procedure has yielded the correct orientation of the protein in the proteoliposome system with recovery of its functional activity. In this review, we chose two proteins under study in our laboratory to exemplify the steps necessary for the standardization of the reconstitution of membrane proteins in liposome systems: (1) alkaline phosphatase, a protein with a glycosylphosphatidylinositol anchor, and (2) Na,K-ATPase, an integral membrane protein. In these examples, we focus on the production of the specific proteoliposomes, as well as on their biochemical and biophysical characterization, with emphasis on studies of lipid-protein interactions. We conclude the chapter by highlighting current prospects of this technology for biotechnological applications, including the construction of nanosensors and of a multiprotein nanovesicular biomimetic to study the processes of initiation of skeletal mineralization.

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Section: New Perspectives For Applications Of Proteoliposomesmentioning

confidence: 99%

Proteoliposomes in nanobiotechnology

et al. 2012

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“…In this study, a pH of nearly 2.0 was used with a 2% acetic acid solution to dilute the AmpB in aqueous media. 41,42 So as to be successfully incorporated into the system, AmpB should be first solubilized, thus, in this study, a pH of 2.0 in aqueous media was used. This strategy was employed because a net charge on the molecule of AmpB, obtained in acid aqueous media, could increase the solubility in two ways: first, it could decrease the dimerization and association constants by ten-fold or more and, second, it could increase the threshold of degree of aggregation for which oligomers are soluble in water.…”

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confidence: 99%

Novel targeting using nanoparticles: an approach to the development of an effective anti-leishmanial drug-delivery system

Ribeiro

Chávez-Fumagalli

Valadares

et al. 2014

IJN

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The study reported here aimed to develop an optimized nanoparticle delivery system for amphotericin B (AmpB) using a polyelectrolyte complexation technique. For this, two oppositely charged polymers presenting anti-leishmanial activity – chitosan (Cs) and chondroitin sulfate (ChS) – were used: Cs as a positively charged polymer and ChS as a negatively charged polymer. The chitosan (NQ) nanoparticles, chitosan-chondroitin sulfate (NQC) nanoparticles, and chitosan-chondroitin sulfate-amphotericin B (NQC-AmpB) nanoparticles presented a mean particle size of 79, 104, and 136 nm, respectively; and a polydispersity index of 0.2. The measured zeta potential of the nanoparticles indicated a positive charge in their surface, while scanning and transmission electron microscopy revealed spherical nanoparticles with a smooth surface. Attenuated total reflectance-Fourier transform infrared spectroscopy analysis showed an electrostatic interaction between the polymers, whereas the release profile of AmpB from the NQC-AmpB nanoparticles showed a controlled release. In addition, the Cs; ChS; and NQ, NQC, and NQC-AmpB nanoparticles proved to be effective against promastigotes of Leishmania amazonensis and Leishmania chagasi , with a synergistic effect observed between Cs and ChS. Moreover, the applied NQ, NQC, and NQC-AmpB compounds demonstrated low toxicity in murine macrophages, as well as null hemolytic activity in type O + human red blood cells. Pure AmpB demonstrated high toxicity in the macrophages. The results show that cells infected with L. amazonensis and later treated with Cs, ChS, NQ, NQC, NQC-AmpB nanoparticles, or pure AmpB presented with a significant reduction in parasite number in the order of 24%, 31%, 55%, 66%, 90%, and 89%, respectively. The data presented indicate that the engineered NQC-AmpB nanoparticles could potentially be used as an alternative therapy to treat leishmaniasis, mainly due its low toxicity to mammals’ cells.

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“…It is encoded by a multigene family that is abundantly expressed in the amastigote forms of some Leishmania species able to cause VL (40) . Studies of the administration of recombinant A2 protein associated with immune adjuvants (41) (42) or as a DNA vaccine (43) , as well as in attenuated non-replicative viruses (44) , non-pathogenic bacteria (45) , or non-virulent Leishmania tarentolae (46) , have provided evidence of its protective effi cacy in mammalian models. In general, anti-A2 protective immunity is associated with the generation of parasite-specifi c IgG2a antibodies, as well as with the production of high levels of antileishmanial IFN-γ and low levels of IL-10 by T cells in recall response to the A2 protein or parasite extracts (40) .…”

Section: Second-generation Vaccines Against Visceral Leishmaniasismentioning

confidence: 99%

“…It has been postulated that a formulation containing different Leishmania proteins expressed in both parasite stages should provide better results, in terms of a more effective and protective vaccine against VL (42) (55) . The use of vaccines combining different proteins could provide the benefi ts of increased simplicity and reduced production costs, since it would only be necessary to produce a single vaccine to protect against different Leishmania species (56) .…”

Section: Second-generation Vaccines Against Visceral Leishmaniasismentioning

confidence: 99%

Recent updates and perspectives on approaches for the development of vaccines against visceral leishmaniasis

Duarte

Lage

Martins

et al. 2016

Rev. Soc. Bras. Med. Trop.

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Visceral leishmaniasis (VL) is one of the most important tropical diseases worldwide. Although chemotherapy has been widely used to treat this disease, problems related to the development of parasite resistance and side effects associated with the compounds used have been noted. Hence, alternative approaches for VL control are desirable. Some methods, such as vector control and culling of infected dogs, are insuffi ciently effective, with the latter not ethically recommended. The development of vaccines to prevent VL is a feasible and desirable measure for disease control; for example, some vaccines designed to protect dogs against VL have recently been brought to market. These vaccines are based on the combination of parasite fractions or recombinant proteins with adjuvants that are able to induce cellular immune responses; however, their partial effi cacy and the absence of a vaccine to protect against human leishmaniasis underline the need for characterization of new vaccine candidates. This review presents recent advances in control measures for VL based on vaccine development, describing extensively studied antigens, as well as new antigenic proteins recently identifi ed using immuno-proteomic techniques.

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Immune Responses Induced by theLeishmania(Leishmania)donovaniA2 Antigen, but Not by the LACK Antigen, Are Protective against ExperimentalLeishmania(Leishmania)amazonensisInfection

Cited by 209 publications

References 41 publications

Proteoliposomes in nanobiotechnology

Proteoliposomes in nanobiotechnology

Novel targeting using nanoparticles: an approach to the development of an effective anti-leishmanial drug-delivery system

Recent updates and perspectives on approaches for the development of vaccines against visceral leishmaniasis

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