Structural investigation of Trypanosoma cruzi Akt-like kinase as drug target against Chagas disease.

According to the World Health Organization, Chagas disease (CD) is the most prevalent poverty-promoting neglected tropical disease. Alarmingly, climate change is accelerating the geographical spreading of CD causative parasite, Trypanosoma cruzi, which additionally increases infection rates. Still, CD treatment remains challenging due to a lack of safe and efficient drugs. In this work, we analyze the viability of T. cruzi Akt-like kinase (TcAkt) as drug target against CD including primary structural and functional information about a parasitic Akt protein. Nuclear Magnetic Resonance derived information in combination with Molecular Dynamics simulations offer detailed insights into structural properties of the pleckstrin homology (PH) domain of TcAkt and its binding to phosphatidylinositol phosphate ligands (PIP). Experimental data combined with Alpha Fold proposes a model for the mechanism of action of TcAkt involving a PIP-induced disruption of the intramolecular interface between the kinase and the PH domain resulting in an open conformation enabling TcAkt kinase activity. Further docking experiments reveal that TcAkt is recognized by human inhibitors PIT-1 and capivasertib, and TcAkt inhibition by UBMC-4 and UBMC-6 is achieved via binding to TcAkt kinase domain. Our in-depth structural analysis of TcAkt reveals potential sites for drug development against CD, located at activity essential regions.

In Silico, In Vitro, and Pharmacokinetic Studies of UBMC-4, a Potential Novel Compound for Treating against Trypanosoma cruzi.

The lack of therapeutic alternatives for the treatment of Chagas disease, a neglected disease, drives the discovery of new drugs with trypanocidal activity. Consequently, we conducted in vitro studies using UBMC-4, a potential Trypanosoma cruzi AKT-like pleckstrin homology (PH) domain inhibitory compound found using bioinformatics tools. The half effective concentration (EC50) on intracellular amastigotes was determined at 1.85 ± 1 µM showing low cytotoxicity (LC50) > 40 µM on human cell lines tested. In order to study the lethal effect caused by the compound on epimastigotes, morphological changes were assessed by scanning and transmission electron microscopy. Progressive alterations such as flagellum inactivation, cell size reduction, nuclear structure alteration, condensation of chromatin towards the nuclear periphery, vacuole formation, and mitochondrial swelling with kinetoplast integrity loss were evidenced. In addition, apoptosis-like markers in T. cruzi were assessed by flow cytometry, demonstrating that the effect of UBMC-4 on T. cruzi AKT-like kinase reduced the tolerance to nutritional stress-triggered, apoptosis-like events, including DNA fragmentation, mitochondrial damage, and loss of plasma membrane integrity. After this, UBMC-4 was formulated for oral administration and pharmacokinetics were analyzed in a mouse model. Finally, upon oral administration of 200 mg/kg in mice, we found that a UBMC-4 plasma concentration remaining in circulation beyond 24 h after administration is well described by the two-compartment model. We conclude that UBMC-4 has an effective trypanocidal activity in vitro at low concentrations and this effect is evident in T. cruzi cell structures. In mice, UBMC-4 was well absorbed and reached plasma concentrations higher than the EC50, showing features that would aid in developing a new drug to treat Chagas disease.

Novel three-finger toxins from Micrurus dumerilii and Micrurus mipartitus coral snake venoms: Phylogenetic relationships and characterization of Clarkitoxin-I-Mdum.

Micrurus mipartitus and M. dumerilii are the most medically important coral snakes in Colombia. Proteomic characterization of their venoms has previously shown that proteins of the three-finger toxin (3FTx) family are abundant components, especially in M. mipartitus (61%) and to a lesser extent in M. dumerilii (28%). In order to increase knowledge on these toxins, in this work a major 3FTx of M. dumerilii venom (8% of the venom proteins), named Clarkitoxin-I-Mdum, was isolated and characterized. Its amino acid sequence comprises 66 residues, with an isotope-averaged molecular mass of 7537 ±â€¯2 Da and a theoretical pI of 9.36, presenting the conserved pattern of eight cysteines that classifies it as a short-chain (type I) 3FTx. Clarkitoxin-I-Mdum was not lethal to mice by intravenous or intracerebroventricular route and was not cytolytic to myogenic cells in vitro. On the other hand, five coding sequences for 3FTxs were obtained from the venom gland of M. mipartitus. These novel toxin sequences were named Mm3FTx-01 to Mm3FTx-05, all of them also presenting the eight conserved cysteines of short-chain 3FTxs. Phylogenetic analysis revealed high variability of 3FTxs from Micrurus, and ELISA using antibodies raised to the major 3FTxs from M. mipartitus and M. dumerilii confirmed their immunochemical divergence. These results highlight the relevance of performing further studies aiming at a deeper understanding of the functional and antigenic relationships among specific Micrurus toxins, with important implications for the production of antivenoms.

Search of Allosteric Inhibitors and Associated Proteins of an AKT-like Kinase from Trypanosoma cruzi.

Proteins associated to the PI3K/AKT/mTOR signaling pathway are widely used targets for cancer treatment, and in recent years they have also been evaluated as putative targets in trypanosomatids parasites, such as Trypanosoma cruzi. Here, we performed a virtual screening approach to find candidates that can bind regions on or near the Pleckstrin homology domain of an AKT-like protein in T. cruzi. The compounds were also evaluated in vitro. The in silico and experimental results allowed us to identify a set of compounds that can potentially alter the intracellular signaling pathway through the AKT-like kinase of the parasite; among them, a derivative of the pyrazolopyridine nucleus with an IC50 of 14.25 ± 1.00 µM against amastigotes of T. cruzi. In addition, we built a protein⁻protein interaction network of T. cruzi to understand the role of the AKT-like protein in the parasite, and look for additional proteins that can be postulated as possible novel molecular targets for the rational design of compounds against T. cruzi.

The Akt-like kinase of Leishmania panamensis: As a new molecular target for drug discovery.

The Akt-like kinase of Leishmania spp. is a cytoplasmic orthologous protein of the serine/threonine kinase B-PKB/human-Akt group, which is involved in the cellular survival of these parasites. By the application of a computational strategy we obtained two specific inhibitors of the Akt-like protein of L. panamensis (UBMC1 and UBMC4), which are predicted to bind specifically to the pleckstrin domain (PH) of the enzyme. We show that the Akt-like of Leishmania panamensis is phospho-activated in parasites under nutritional and thermic stress, this phosphorylation is blocked by the UBMC1 and UMBC2 and such inhibition leads to cell death. Amongst the effects caused by the inhibitors on the parasites we found high percentage of hypodiploidy and loss of mitochondrial membrane potential. Ultrastructural studies showed highly vacuolated cytoplasm, as well as shortening of the flagellum, loss of nuclear membrane integrity and DNA fragmentation. Altogether the presented results suggest that the cell death caused by UMBC1 and UMBC4 may be associated to an apoptosis-like process. The compounds present an inhibitory concentration (IC50) over intracellular amastigotes of L. panamensis of 9.2±0.8µM for UBMC1 and 4.6±1.9µM for UBMC4. The cytotoxic activity for UBMC1 and UBMC4 in human macrophages derived from monocytes (huMDM) was 29±1.2µM and >40µM respectively. Our findings strongly support that the presented compounds can be plausible candidates as a new therapeutic alternative for the inhibition of specific kinases of the parasite.

The flagellar protein FLAG1/SMP1 is a candidate for Leishmania-sand fly interaction.

Leishmaniasis is a serious problem that affects mostly poor countries. Various species of Leishmania are the agents of the disease, which take different clinical manifestations. The parasite is transmitted by sandflies, predominantly from the Phlebotomus genus in the Old World and Lutzomyia in the New World. During development in the gut, Leishmania must survive various challenges, which include avoiding being expelled with blood remnants after digestion. It is believed that attachment to the gut epithelium is a necessary step for vector infection, and molecules from parasites and sand flies have been implicated in this attachment. In previous work, monoclonal antibodies were produced against Leishmania. Among these an antibody was obtained against Leishmania braziliensis flagella, which blocked the attachment of Leishmania panamensis flagella to Phlebotomus papatasi guts. The protein recognized by this antibody was identified and named FLAG1, and the complete FLAG1 gene sequence was obtained. This protein was later independently identified as a small, myristoylated protein and called SMP1, so from now on it will be denominated FLAG1/SMP1. The FLAG1/SMP1 gene is expressed in all developmental stages of the parasite, but has higher expression in promastigotes. The anti-FLAG1/SMP1 antibody recognized the flagellum of all Leishmania species tested and generated the expected band by western blots. This antibody was used in attachment and infection blocking experiments. Using the New World vector Lutzomyia longipalpis and Leishmania infantum chagasi, no inhibition of attachment ex vivo or infection in vivo was seen. On the other hand, when the Old World vectors P. papatasi and Leishmania major were used, a significant decrease of both attachment and infection were seen in the presence of the antibody. We propose that FLAG1/SMP1 is involved in the attachment/infection of Leishmania in the strict vector P. papatasi and not the permissive vector L. longipalpis.

Infection of epithelial cells with dengue virus promotes the expression of proteins favoring the replication of certain viral strains.

Dengue virus (DENV) is the causative agent of dengue and severe dengue. To understand better the dengue virus-host interaction, it is important to determine how the expression of cellular proteins is modified due to infection. Therefore, a comparison of protein expression was conducted in Vero cells infected with two different DENV strains, both serotype 2: DENV-2/NG (associated with dengue) and DENV-2/16681 (associated with severe dengue). The viability of the infected cells was determined, and neither strain induced cell death at 48 hr. In addition, the viral genomes and infectious viral particles were quantified, and the genome of the DENV-2/16681 strain was determined to have a higher replication rate compared with the DENV-2/NG strain. Finally, the proteins from infected and uninfected cultures were separated using two-dimensional gel electrophoresis, and the differentially expressed proteins were identified by mass spectrometry. Compared with the uninfected controls, the DENV-2/NG- and DENV-2/16681-infected cultures had five and six differentially expressed proteins, respectively. The most important results were observed when the infected cultures were compared to each other (DENV-2/NG vs. DENV-2/16681), and 18 differentially expressed proteins were identified. Based on their cellular functions, many of these proteins were linked to the increase in the replication efficiency of DENV. Among the proteins were calreticulin, acetyl coenzyme A, acetyl transferase, and fatty acid-binding protein. It was concluded that the infection of Vero cells with DENV-2/NG or DENV-2/16681 differentially modifies the expression of certain proteins, which can, in turn, facilitate infection.

Expresión diferencial de proteínas en Leishmania (Viannia) panamensis asociadas con mecanismos de resistencia a antimoniato de meglumina / Differential expression of proteins in Leishmania (Viannia) panamensis associated with mechanisms of resistance to meglumine antimoniate.

Introducción. Los mecanismos de resistencia al antimonio pentavalente conocidos hasta el momento, se han descrito ampliamente en cepas del subgénero Leishmania, pero poco se sabe sobre las proteínas involucradas en los mecanismos de resistencia presentes en cepas del subgénero Viannia, como Leishmania panamensis. Objetivo. Identificar proteínas diferencialmente expresadas entre las cepas de L. panamensis (UA140), sensible y resistente al antimonio pentavalente, y analizar el posible papel de estas proteínas en mecanismos de resistencia. Materiales y métodos. Las proteínas de las cepas, sensible y resistente al antimonio pentavalente, se compararon usando electroforesis bidimensional. Las proteínas con aumento de la expresión fueron aisladas e identificadas por espectrometría de masas mediante MALDI-TOF/TOF (Matrix Assisted Laser Desorption Ionization/Time of Flight). La expresión del ARNm de cinco de estas proteínas se cuantificó mediante PCR en tiempo real. Resultados. Los geles bidimensionales de las cepas sensible y resistente detectaron 532±39 y 541±43 manchas proteicas. Se encontraron 10 manchas con aumento de la expresión en la cepa resistente, identificadas como proteínas de choque térmico (Hsp60 mitocondrial, Hsp70 mitocondrial y citosólica), isomerasa de disulfuro, proteasa de cisteína, enolasa, factor de elongación 5-α, la subunidad 5-α del proteasoma y dos proteínas hipotéticas nombradas como Sp(2) y Sp(25). Conclusión. Este es el primer estudio llevado a cabo con una cepa resistente al antimonio pentavalente en L. panamensis, en el cual se han identificado proteínas que están relacionadas con el mecanismo de resistencia del parásito frente al medicamento, abriendo el camino para futuros estudios de estas proteínas como blancos terapéuticos.

Introduction. The well-known drug resistance mechanisms to pentavalent antimony have been widely described in strains of the Leishmania subgenus, but little is known about the mechanisms of resistance and the proteins associated with it in strains of the Viannia subgenus such as Leishmania panamensis. Objective. Differentially expressed proteins were identified between pentavalent antimonial sensitive and resistant L. panamensis (UA140) strains, and the role of these proteins was analyzed as possible resistance mechanisms. Materials and methods. The protein lysates of pentavalent antimony sensitive and resistant strains were separated by two-dimensional gel electrophoresis,and the protein patterns compared. The proteins identified as overexpressed were separated and analyzed using MALDI-TOF/TOF (Matrix Assisted Laser Desorption Ionization/Time of Flight). The level of mRNA expression of five of these proteins was quantified using real-time PCR. Results. On the 2-dimensional gels, 532 ± 39 protein spots were identified for the sensitive strains, and 541 ± 43 spots for the resistant strains. Ten spots were overexpressed in the resistant strain and identified as heat shock protein (Hsp60 mitochondrial, Hsp70 cytosolic and mitochondrial), disulfide isomerase, cysteine protease, enolase, elongation factor 5-alpha, the proteasome alpha-5 subunit and two hypothetical proteins named as Sp(2) and Sp(25). Conclusion. This is the first proteomic study conducted with a L. panamensis resistant strain where several proteins were identified and related with the parasite resistance mechanism to pentavalent antimony. This opens the way for future studies aimed at modulating the drug resistance or at evaluating these proteins as therapeutic targets.

[Differential expression of proteins in Leishmania (Viannia) panamensis associated with mechanisms of resistance to meglumine antimoniate]. / Expresión diferencial de proteínas en Leishmania (Viannia) panamensis asociadas con mecanismos de resistencia a antimoniato de meglumina.

INTRODUCTION: The well-known drug resistance mechanisms to pentavalent antimony have been widely described in strains of the Leishmania subgenus, but little is known about the mechanisms of resistance and the proteins associated with it in strains of the Viannia subgenus such as Leishmania panamensis. OBJECTIVE: Differentially expressed proteins were identified between pentavalent antimonial sensitive and resistant L. panamensis (UA140) strains, and the role of these proteins was analyzed as possible resistance mechanisms. MATERIALS AND METHODS: The protein lysates of pentavalent antimony sensitive and resistant strains were separated by two-dimensional gel electrophoresis,and the protein patterns compared. The proteins identified as overexpressed were separated and analyzed using MALDI-TOF/TOF (Matrix Assisted Laser Desorption Ionization/Time of Flight). The level of mRNA expression of five of these proteins was quantified using real-time PCR. RESULTS: On the 2-dimensional gels, 532 ± 39 protein spots were identified for the sensitive strains, and 541 ± 43 spots for the resistant strains. Ten spots were overexpressed in the resistant strain and identified as heat shock protein (Hsp60 mitochondrial, Hsp70 cytosolic and mitochondrial), disulfide isomerase, cysteine protease, enolase, elongation factor 5-alpha, the proteasome alpha-5 subunit and two hypothetical proteins named as Sp(2) and Sp(25). CONCLUSION: This is the first proteomic study conducted with a L. panamensis resistant strain where several proteins were identified and related with the parasite resistance mechanism to pentavalent antimony. This opens the way for future studies aimed at modulating the drug resistance or at evaluating these proteins as therapeutic targets.

In silico predicted epitopes from the COOH-terminal extension of cysteine proteinase B inducing distinct immune responses during Leishmania (Leishmania) amazonensis experimental murine infection.

BACKGROUND: Leishmania parasites have been reported to interfere and even subvert their host immune responses to enhance their chances of survival and proliferation. Experimental Leishmania infection in mice has been widely used in the identification of specific parasite virulence factors involved in the interaction with the host immune system. Cysteine-proteinase B (CPB) is an important virulence factor in parasites from the Leishmania (Leishmania) mexicana complex: it inhibits lymphocytes Th1 and/or promotes Th2 responses either through proteolytic activity or through epitopes derived from its COOH-terminal extension. In the present study we analyzed the effects of Leishmania (Leishmania) amazonensis CPB COOH-terminal extension-derived peptides on cell cultures from murine strains with distinct levels of susceptibility to infection: BALB/c, highly susceptible, and CBA, mildly resistant. RESULTS: Predicted epitopes, obtained by in silico mapping, displayed the ability to induce cell proliferation and expression of cytokines related to Th1 and Th2 responses. Furthermore, we applied in silico simulations to investigate how the MHC/epitopes interactions could be related to the immunomodulatory effects on cytokines, finding evidence that specific interaction patterns can be related to in vitro activities. CONCLUSIONS: Based on our results, we consider that some peptides from the CPB COOH-terminal extension may influence host immune responses in the murine infection, thus helping Leishmania survival.

The C-terminal extension of Leishmania pifanoi amastigote-specific cysteine proteinase Lpcys2: a putative function in macrophage infection.

Cysteine proteinases have been implicated in many aspects of protozoan parasite pathogenesis. These hydrolases are normally found as zymogens, and some classes in trypanosomatids possess a long C-terminal extension (CTE), for which no function has been assigned. In this paper we hypothesize that the CTE domain of Lpcys2, the abundant lysosomal cysteine proteinase of Leishmania pifanoi amastigotes, is involved in host cell infection. Confirming previous reports that this peptide is highly immunogenic in Trypanosoma cruzi, we detected antibodies against CTE in sera of leishmaniasis patients. We produced a polyclonal antibody specific to Lpcys2 CTE and determined that this antibody was capable of recognizing both L. pifanoi and Leishmania amazonensis cysteine proteinases. Using this antibody, we detected a predominant localization of Lpcys2 CTE in the lysosome and flagellar pocket of cultured axenic amastigotes of both parasite species; however, its location was shifted towards the surface of the parasites during macrophage infection. We examined the role of Lpcys2 CTE in macrophage infection and found a significant reduction in the percentage of infected cells when macrophages were infected with L. pifanoi and L. amazonensis in the presence of anti-CTE antibody. This study suggests a role for leishmanial cysteine proteinases CTE at early stages of infection.

Leishmania lysosomal targeting signal is recognized by yeast and not by mammalian cells.

Leishmaniasis, caused by Leishmania parasites, is an important public health problem worldwide. Leishmania, like other trypanosomatids, present unique biological features as compared to higher eukaryotes that can be exploited with the intent of finding new chemotherapeutical/vaccine candidates. Mechanisms of cellular sorting in Leishmania can be viewed as such potential targets. We have previously demonstrated a role for the pro-domain of a Leishmania cysteine proteinase in lysosomal targeting. In this paper, we show that this signal is not recognized by mammalian cells and is recognized by yeast; we also discuss here the implications of these findings related to evolution and further characterization of the Leishmania trafficking machinery.

[Metacyclogenesis: a basic process in the biology of Leishmania]. / Metaciclogénesis: un proceso fundamental en la biología de Leishmania.

Metacyclogenesis is a process whereby Leishmania transforms from poorly infective procyclic promastigotes into highly infective metacyclic promastigotes. In nature, metacyclogenesis occurs in the insect vector. This transformation is accompanied by an increased ability to infect and survive in the vertebrate host, where the parasite is attacked by the host's immune system. Metacyclogenesis has also been shown to occur in axenic cultures of promastigotes. Morphological changes in size and shape, and length of flagellum were first associated with differentiation in the insect gut and in different phases of growth in culture. Later, the expression of molecules such as LPG and the surface protease gp63 were associated with this process. These two molecules were observed to undergo qualitative and quantitative modifications as the promastigotes differentiated from procyclic to metacyclic forms. Using cDNA subtractive hybridization-based methods or differential amplification, previously unknown genes tightly linked to metacyclogenesis have been identified. Gene products exclusively expressed in metacyclic promastigotes included a gene B product and Mat-1--a gene associated with metacyclogenesis. Other proteins, Meta-1, SHERP and HASP, were up-regulated during the metacyclic stage. The function and stage-regulated expression of these molecules and their relationship with infectivity are now under investigation.