Atrofia tímica induzida por Plamodium berghei : análise da expressão e atividade de metaloproteinases e seus inibidores / Thimic atrophy induced by Plamodium berghei : analisis of expression and activity of metelloproteinases and their inhibitors

Dionete, Alliny Carolina, 1987-

23 August 2018

Orientador: Liana Maria Cardoso Verinaud / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-23T07:43:36Z (GMT). No. of bitstreams: 1 Dionete_AllinyCarolina_M.pdf: 7519445 bytes, checksum: 4e7fd1c1acc58852052f9bc4765da65b (MD5) Previous issue date: 2012 / Resumo: O timo é um órgão linfóide primário localizado no mediastino anterior cuja função principal é o desenvolvimento das células T. Os precursores imaturos dos linfócitos T oriundos da medula óssea chegam ao timo através da junção córtico-medular e são denominados de timócitos. Estes timócitos passam por estágio denominados duplo-negativos (DN), não expressando os co-receptores CD4 e CD8, duplo positivos, expressando estes dois receptores e simples positivo, expressando somente um dos receptores. Desta forma, o completo desenvolvimento de células T torna-se dependente da constante migração dos precursores hematopoiéticos através do microambiente tímico que é composto por componentes linfóides e não linfóides. Já está bem documentada na literatura a importância que a matriz extracelular (MEC) exerce nos processos de migração dos timócitos. Durante todo este processo, os timócitos interagem com os componentes do microambiente tímico composto pela rede tridimensional formada por células epiteliais tímicas (TEC), macrófagos, células dendríticas, fibroblastos e componentes da matriz extracelular. Contudo, esta rede tridimensional pode ser remodelada pela ação de enzimas denominadas metaloproteinases de matriz (MMPs) que são capazes de degradar componentes da MEC revelando sítios de ligação para diversas integrinas e liberando fatores de crescimento e quimiocinas interligadas a esta rede. No timo já foram descritos vários membros da família das MMPs, como a MMP-2, 9, 14, 19 e ADAM 10, 17 e 28. Contudo, pouco se sabe sobre a atuação destas moléculas nos processos intratímicos . Estudos recentes do nosso grupo mostraram que a atrofia tímica induzida por P. berghei, um protozoário transmitido através da picada de um mosquito do gênero anófeles, leva a numerosas alterações no ambiente tímico. Assim, no presente trabalho pretende-se avaliar, quantitativamente e funcionalmente, possíveis alterações nas metaloproteinases MMP-2, 9, bem como nos seus inibidores TIMP-1, TIMP-2 durante a atrofia tímica observada após infecção pelo Plasmodium berghei NK65 / Abstract: The primary function of the thymus is to develop immature T-cells into cells that will be able to carry out immune functions. So, alterations in its microenvironment may disrupt intrathymic processes leading to an altered exportation of T cell to the periphery. We have recently showed that experimentally Plasmodium berghei-infected mice present severe thymic alterations characterized by atrophy with depletion of double-positive thymocytes, histological alterations with loss of delimitation between cortical and medullar regions, and altered expression of cytokines and its respective receptors. Besides, it was also observed that such alterations, conjunctively, are able to promote increase of thymocyte migratory activity. Considering that MMPs also have a crucial role in thymocyte migration, in this study we investigated alterations in the expression pattern and activity of matrix metalloproteinases MMP-2, 9, 14, 19 and ADAM-28, as well as in tissue inhibitors of metalloproteinases TIMP-1, TIMP-2 and RECK, by using the same experimental model. Our results show differential expression pattern of MMPs and TIMPs mRNAs among infected and non-infected mice. Besides, an imbalance between MMPs and their inhibitors those results in altered proteolytic activity were observed in thymus from infected mice. We hypothesize that disturbed MMP and TIMP expression and activity have also a role in the altered thymocyte migration through intrathymic microenvironments observed during plasmodium infection / Mestrado / Imunologia / Mestre em Genética e Biologia Molecular

Atrofia tímica

Plasmodium berghei

Malaria

Metaloproteases

Thimic atrophy

Plasmodium berghei

Malaria

Metalloproteinases

Tissue inhibitor of Metalloproteinases

Infection des hépatocytes par Plasmodium : rôle des protéines de micronèmes des sporozoïtes / Plasmodium infection of hepatocytes : role of protein micronemes sporozoltes

Topçu, Selma

10 March 2016

L’infection par Plasmodium, parasite responsable du paludisme, débute par l’injection de sporozoïtes par un moustique du genre Anopheles. La première cible des sporozoïtes est le foie, où le parasite se développe avant l’initiation d'une phase d'infection érythrocytaire symptomatique. Dans le foie, les sporozoïtes pénètrent activement les hépatocytes en formant une vacuole parasitophore, dans laquelle le parasite se multiplie. Cette étape, appelée invasion productive, implique des facteurs parasitaires et des protéines de l’hôte, notamment CD81. Toutefois, les mécanismes mis en jeu restent méconnus. À l’aide d’une nouvelle approche génétique développée au laboratoire, nous avons produit de nouvelles souches de parasites transgéniques fluorescents, notamment chez le parasite de rongeurs P. yoelii. L’utilisation des parasites de P. yoelii GFP et d’un système cellulaire de lignées permissives ou non à l’infection, nous a permis de mieux caractériser les mécanismes cellulaires et moléculaires mis en jeu lors de l’invasion. Nous avons confirmé que l’invasion productive est précédée d’une phase de traversée cellulaire. Nous avons découvert et caractérisé la formation de vacuoles transitoires lors de cette phase de traversée cellulaire, distinctes des vacuoles parasitophores productives. Nos résultats montrent que le parasite se sert d’une perforine parasitaire, PLP1 (Perforin-Like Protein 1), pour sortir de cette vacuole transitoire et échapper à la dégradation par les lysosomes cellulaires. Une fois activés, les sporozoïtes passent d’un mode de traversée à un mode d’invasion productive. Nous avons montré que CD81 joue un rôle dans l’invasion productive. CD81 est nécessaire pour induire la sécrétion des rhoptries parasitaires, impliquées dans la formation de la jonction mobile, une structure à travers laquelle le parasite se glisse pour pénétrer dans la cellule. Nous avons pu aussi montrer qu’une autre protéine des hépatocytes, SRBI (scavenger receptor BI), définit une voie d’entrée indépendante de CD81 pour P. berghei et P. vivax. Par une approche génétique originale, nous avons pu montrer que deux protéines des micronèmes des sporozoïtes, P52 et P36, jouent un rôle majeur dans l’entrée via CD81 et SRBI, et mis à jour un lien fonctionnel entre P36 et l’entrée via SRBI. Enfin, nous avons développé plusieurs approches génétiques pour cibler le gène d’ama1 chez P. yoelii, une protéine des micronèmes impliquées dans la formation de la jonction. Nos résultats nous éclairent un peu plus sur les mécanismes d’invasion des sporozoïtes, et ouvrent des perspectives intéressantes vers le développement de nouvelles stratégies vaccinales. / Infection with the Plasmodium parasite begins with the injection of sporozoites by an Anopheles mosquito. The first target is the liver where the parasite replicates as a pre-requisite to the development of pathogenic blood stage infection. In the liver, sporozoites penetrate hepatocytes forming a parasitophorous vacuole in which the parasite multiplies. This step, the productive invasion, involves parasitic factors and host proteins, particularly CD81, but the underlying mechanisms remain largely unknown. To facilitate monitoring of sporozoite invasion, we generated novel transgenic fluorescent parasites, using a new selection strategy named GOMO (gene out marker out) in the rodent parasite P. yoelii. The use of this transgenic parasite and of host cell lines permissive or not to infection, has allowed us to better characterize the cellular and molecular mechanisms involved during invasion. We have confirmed that the productive invasion is preceded by a cell traversal phase. We discovered and characterized the formation of transient vacuoles during this step, before formation of the parasitophorous vacuole. Our results uncovered that the perforin-like protein (PLP1) mediates sporozoite egress from transient vacuoles and escape from degradation by the cell lysosomes. Once activated, the sporozoites switch from the mode of cell traversal to productive invasion. We show that CD81 plays a role in the productive invasion. CD81 is necessary to induce the secretion of rhoptries proteins, involved in the formation of the moving junction, a structure through which the parasite glides to enter the cell. We could also show that another hepatocyte protein, SR-B1 (scavenger receptor B1), defines a CD81-independent pathway for P. berghei and P. vivax infection. Using an original genetic approach, we have shown that two sporozoite micronemal proteins, P52 and P36, play a role in the entry via CD81 and SR-B1, and highlighted a functional link between P36 and entry via SR-B1. Finally, we have developed several genetic approaches to target ama1 gene in P. yoelii, which encodes a protein involved in the formation of the moving junction. Altogether, our results contribute to improve our understanding of the mechanisms of sporozoite invasion, and open interesting perspectives for the development of novel vaccine strategies.

Paludisme

Plasmodium

Micronème

Traversée cellulaire

Invasion

Vacuole transitoire

Vacuole parasitophore

Transite vacuole

Plasmodium invasion

Parasitophorous vacuole

616.96

Redox-active 3-benzyl-menadiones as new antimalarial agents : studies on structure-activity relationships, antiparasitic potency and mechanism of action / 3-benzyl-menadiones redox comme nouveaux agents antipaludiques : études sur les relations structure-activité, activité antiparasitaire et mécanisme d'action

Ehrhardt, Katharina

26 September 2014

Le paludisme reste une des maladies infectieuses les plus importantes au monde. Récemment, le laboratoire de Dr E. Davioud-Charvet a conçu des 3-Benzyl-Ménadiones substituées (benzylMD) comme agents antipaludiques prometteurs. Les études sur le mode d'action ont mis en évidenceque ces molecules déstabilisent l'équilibre redox des érythrocytes infectés en agissant comme agent catalytique redox (redox-Cycler), une stratégie prometteur pour le développement de nouveaux agents antipaludiques. Le travail de thèse présenté a caractérisé l'activité in vitro et le mécanisme d'action de tête de série, la 3-[4-(trifluorométhyl)-Benzyl]-Ménadione 1c, ce qui représente une partie principale du développement des benzylMDs. Une deuxième partie explorait les relations structure-Activité de benzylMD dérivés. Dans l'ensemble, les résultats démontrent l'activité in vitro très prometteuse de la benzylMD 1 cet soutiennent l'amélioration de benzylMDs comme nouveaux candidats-Médicaments antipaludiques. / Malaria is still one of the most important infectious diseases worldwide. Previously, the laboratory of Dr. E. Davioud-Charvet presented the chemical design of very promising antimalarial agents, 3-[substituted-Benzyl]-Menadiones (benzylMD). Studies on the mode of action evidenced that these agents disturb the redox balance of the parasitized erythrocyte by acting as redox-Cyclers - a promising strategy for the development of new antimalarial agents. The presented PhD work characterized the in vitro potency and the mechanism of action of the lead agent, the 3-[4-(trifluoromethyl)benzyl]-Menadione 1 c, which represents an essential part of the lead optimization stage of the benzylMD drug development process. A second part of this work focused on the structure-Activity relationships benzylMD derivatives. Overall, the presented findings demonstrate the promising in vitro potency of lead benzylMD 1c and highly support the further development of benzylMDs as antimalarial drug candidates.

3-benzyl-ménadiones substituées

Antipaludique

Redox-cycler

Plasmodium

3-[substituted-benzyl]-menadiones

Antimalarial

Redox-cycler

Plasmodium

615.19

Role of human gamma-delta T lymphocytes in the instruction of the adaptive immune response against Plasmodium falciparum infection. / Rôle des lymphocytes T gamma delta dans l’induction de la réponse immunitaire adaptative dans un contexte d’infection par Plasmodium falciparum.

Howard, Jennifer Ruth

16 July 2015

Les phosphoantigènes (P-Ag) de P. falciparum (P.f.) induisent une forte activation et une expansion des lymphocytes T (LT) Vγ9Vδ2 par un mécanisme encore mal décrit. Les LT Vγ9Vδ2 actives inhibent le cycle sanguin de P. f. par des médiateurs cytotoxiques solubles, inhibant ainsi la capacité invasive des mérozoites. Il a été montre in vitro que des LT Vγ9Vδ2 activés par les P-Ag peuvent présenter des antigènes et activer les LT αβ, agissant ainsi comme des cellules présentatrices d’antigènes (APC). Cette fonction n’a cependant pas été démontrée dans un contexte physiopathologique. Le but de ce projet est i) d’étudier les mécanismes d’activation des LT Vγ9Vδ2 par les stades sanguins P. f. et ii) d’evaluer le potentiel APC des LT Vγ9Vδ2 stimules par P. f. Nous montrons que l’activation des LT Vγ9Vδ2 par des globules rouges parasites par P. f. (GRP) intacts ne dépend ni d’un contact cellulaire, ni de l’expression de butyrophiline par le GRP. Les LT Vγ9Vδ2 sont activés par des molécules contenues dans les surnageants de culture de GRP, ayant les caractéristiques de P-Ags et étant libérées lors de la rupture des GRP. In vitro, les LT Vγ9Vδ2 stimules par les GRP expriment des marqueurs de surface associés à un rôle d’APC et cross-présentent un antigène modèle à une lignée T CD8 spécifique. In vivo, nous montrons une expression augmentée des marqueurs APC à la surface de LT Vγ9Vδ2 de patients infectés par P. falciparum. L’ensemble de ces données suggèrent que les P-Ag libérés par les GRP dans le milieu extracellulaire pourraient activer les LT Vγ9Vδ2 à distance, et ouvrent de nouvelles perspectives quant au rôle des LT Vγ9Vδ2 dans la réponse immunitaire adaptative anti-palustre. / P. falciparum derived phosphoantigens (P‐Ag) induce potent activation and expansion of Vγ9Vδ2 T-cells by a poorly described mechanism. Activated Vγ9Vδ2 T cells inhibit the Plasmodium falciparum blood cycle through soluble cytotoxic mediators, abrogating merozoite invasion capacity. In vitro, P-Ag activated Vγ9Vδ2 T lymphocytes have been shown to present antigens and induce αβ T lymphocyte responses, i.e. to act as an antigen presenting cell (APC). Whether this activity can be involved in a pathophysiological context is unknown. The aim of this PhD project is to a) investigate the mechanisms of Vγ9Vδ2 T cell activation by blood stage P. falciparum and b) assess the potential of P. falciparum activated Vγ9Vδ2 T cells to display APC functionality. We show that Vγ9Vδ2 T-cell activation by intact iRBCs is independent of iRBC contact and butyrophilin expression. Blood stage culture supernatants can potently activate Vγ9Vδ2 T-cells and bioactivity is found to be attributable to P-Ags released at the time of parasite egress from the RBC. In vitro iRBC stimulated Vγ9Vδ2 T cells up-regulate surface expression of APC associated markers and can cross-present a model antigen to specific CD8 T cell responders. In vivo we demonstrate an increase in surface expression of APC makers on Vγ9Vδ2 T cells from P. falciparum infected patients.Altogether, these data outline a framework whereby P‐Ag release by iRBC into extracellular milieu can promote activation of distant Vγ9Vδ2 T cells, and opens the door to a new aspect of Vγ9Vδ2 T cell contribution to P. falciparum adaptive immune responses.

Lymphocytes T Vγ9Vδ2

Plasmodium falciparum

Butyrophiline

Cellule présentatrice d’antigène

Vγ9Vδ2 T Lymphocytes

Plasmodium falciparum

Butyrophilin

Antigen presenting cells

Plasmodium vivax: Caracterização Molecular de Recaídas Utilizando um Segmento Polimórfico do Gene MSP1 como Marcador Genético. / "Plasmodium vivax: molecular characterization of relapses using a polymorphic segment of MSP1 gene as genetic marker"

Karin Kirchgatter

09 May 1997

Plasmodium vivax é a espécie de malária humana de maior distribuição geográfica, com 35 milhões de casos por ano. No Brasil, é a espécie mais prevalente, sendo responsável por cerca de 70% dos casos de malária. Diferentemente do P. falciparum, o P. vivax apresenta hipnozoítas, formas que se mantêm em estágio dormente no fígado e que, após um período de tempo variável, por mecanismos ainda desconhecidos, causam novo ataque malárico denominado recaída. Para contribuir para um melhor conhecimento acerca das recaídas causadas por P. vivax, neste trabalho foram analisadas amostras pareadas referentes ao ataque primário e à recaída de 10 pacientes que se infectaram na Amazônia Brasileira. Através da amplificação de um segmento polimórfico do gene que codifica a Proteína de Superfície do Merozoíta 1 (PvMSP1), foi encontrado um índice de 40% de infecções mistas, presentes inclusive durante a recaída, indicando que a ativação de hipnozoítas não é clonal. Em análise mais detalhada deste segmento polimórfico, utilizando técnicas de clonagem e sequenciamento, foi possível verificar que a população de parasitas obtida durante o ataque primário é idêntica àquela que surge nas recaídas. O estudo da resposta IgG específica naturalmente adquirida contra a região C-terminal da PvMSP1, a mais imunogênica da molécula, demonstrou, durante a recaída, um aumento nos títulos acompanhado por uma maturação na afinidade destes anticorpos além de um predomínio de IgG1. / Plasmodium vivax is the most widely distributed human malarial parasite causing an estimated 35 million cases annually. In some parts of the world, including Brazil where it reaches almost 70% of malaria cases, this is the most prevalent species. Unlike P. falciparum, P. vivax has hypnozoites, hepatocyte dormant stages that cause clinical and parasitological relapses. Unfortunately, the molecular basis of relapses remain poorly understood. This work compared paired primary attack and relapse samples obtained from 10 infected patients from the brazilian Amazon Region using a polymorphic segment of the gene encoding the Merozoite Surface Protein 1 (PvMSP1) as a genetic marker. PCR, Southern blot and DNA sequence analysis demonstrated that the parasite population from the primary attack is identical to the one arising during relapses and that the activation of hypnozoites is not clonal; moreover, a large percentage (40%) of mixed infections, were detected. Studies on the naturally acquired human specific IgG response of these patients against the C-terminal region of the PvMSP1 molecule, the most immunogenic region, demonstrated an increase in the titers, affinity maturation and a predominance of the IgG1 subclass during the relapse.

afinidade de anticorpos

MSP1

Plasmodium vivax

polimorfismo aléico

recaídas

subclasses de IgG

allelic polymorphism

antibody affinity

IgG subclasses

MSP1

Plasmodium vivax

relapses

Análise de seqüências var de populações naturais de Plasmodium falciparum da Amazônia Brasileira / Analysis of var sequences from natural parasite populations of Plasmodium falciparum in the Brazilian Amazon

Karin Kirchgatter

06 March 2002

Os genes var de Plasmodium falciparum codificam a proteína PfEMP1 expressa na superfície de eritrócitos infectados e que medeia os fenômenos de citoaderência e \"rosetting\". Ambos os fenômenos estão diretamente associados à malária grave, e seu domínio mais N-terminal, DBL1alfa, media especificamente \"rosetting\". Análise de seqüências DBL1alfa de isolados brasileiros e de outros países revelou que a similaridade entre elas não pode predizer origem geográfica. Com o objetivo de determinar se existem seqüências DBL1alfa associadas à malária grave, analisamos as seqüências DBL1alfa expressas em parasitas obtidos de pacientes brasileiros com esta manifestação clínica e encontramos que as seqüências predominantemente expressas apresentavam uma ou duas deleções de cisteínas. Significativamente, apesar de freqüentes no genoma de parasitas de pacientes com malária não grave, essas seqüências foram raramente expressas. Esses dados demonstram a primeira associação de seqüências PfEMP1 expressas e malária grave em pacientes da Amazônia Brasileira. / Plasmodium falciparum var genes code for PfEMP1, a protein expressed on the surface of infected erythrocytes, and which mediates cytoadherence and rosetting. Both phenomena are directly associated with severe malaria and the most N-terminal domain, DBL1alfa, specifically mediates rosetting. DBL1alfa sequence analysis from Brazilian and worldwide isolates revealed that sequence similarities cannot predict geographical origin. To determine whether there are DBL1alfa sequences associated with severe malaria, we examined expressed var DBL1alfa sequences in patients with severe malaria from the Brazilian Amazon and found that the predominantly expressed DBL1alfa sequences from these parasites lacked 1-2 cysteine residues. Significantly, these sequences were amply found on the genomic repertoire of parasites from patients with mild malaria and yet they were rarely expressed. These data demonstrate the first association of particular PfEMP1 expressed sequences and severe malaria in patients from the Brazilian Amazon.

DBL1alfa

Genes var

Malária

Malária grave

Plasmodium falciparum

Proteína PfEMP1

DBL1alfa

Malaria

PfEMP1

Plasmodium falciparum

severe malaria

var genes

Dimorfismo alélico na proteína de superfície MSP-6 de merozoítos de Plasmodium falciparum. / Allelic dimorphism in Plasmodium falciparum merozoite surface protein-6 (MSP-6).

Rogério Lauria da Silva

29 August 2008

O desenvolvimento de uma vacina contra malária causada por P. falciparum é prejudicado pelo alto nível de polimorfismo apresentado pelos antígenos desse parasito. O dimorfismo alélico é um padrão no qual os alelos observados de um gene se encontram divididos em duas famílias. A proteína dimórfica MSP-6 se associa à proteína MSP-1 (também dimórfica) na superfície do merozoíto. Genes de msp-6 de 21 isolados obtidos de pacientes do Brasil, mais 2 isolados da Tanzânia, África, foram seqüenciados para estudo da diversidade nucleotídica e distribuição geográfica dos alelos. As duas famílias possuem distribuição global. Não foi verificada associação entre o dimorfismo de MSP-1 e MSP-6. O gene ortólogo de msp-6 em P. reichenowi, grupo irmão de P. falciparum, foi seqüenciado para estudos evolutivos. Os alelos dimórficos de MSP-6 aparentam ter surgido de uma população ancestral polimórfica, tendo sido mantidos no presente por seleção balanceada. O alto grau de conservação encontrado dentro de cada família alélica torna MSP-6 um potencial alvo de uma vacina contra a malária. / The development of a vaccine against malaria caused by Plasmodium falciparum has been hampered by the high level of antigen polymorphism exhibited by this parasite. Allelic dimorphism is a pattern in which every observed allele of a gene is clearly grouped into one of two families. The dimorphic protein MSP-6 forms a complex with MSP-1 (also dimorphic) on merozoite surface. The msp-6 genes were sequenced in isolates obtained from 21 patients from Brazil, plus 2 isolates from Tanzania, Africa, to study nucleotide diversity and geographic distribution of alleles. Both families are globally distributed. Moreover, no association was observed between the MSP-1 and MSP-6 allelic types. Orthologous gene of msp-6 in P. reichenowi, chimpanzee parasite and sister group of P. falciparum, was sequenced for evolutionary studies. Dimorphic alleles of MSP-6 seem to have originated from an ancestral polymorphic population and are maintained by balancing selection. The high degree of conservation observed within each allelic family makes MSP-6 an promising target for vaccine development.

Dimorfismo alélico

Malária

MSP-6

Plasmodium falciparum

Proteínas da membrana

Plasmodium falciparum

Allelic dimorphism

Malaria

Membrane protein

MSP-6

Caracterização do acúmulo de expressão dos transcritos de gambicina em Aedes aegypti infectado por Plasmodium gallinaceum e vírus dengue. / Characterization of the accumulation of the expression of gambicina transcripts in Aedes aegypti infected with Plasmodium gallinaceum and dengue virus.

Maria Karina Costa

02 July 2015

A imunidade inata que o mosquito apresenta tenta combater os patógenos dentro do organismo do mosquito impedindo que este seja transmitido para outros hospedeiros. A resposta celular apresenta três diferentes processos: fagocitose, encapsulamento e formação nodular, todos estes processos buscam eliminar os patógenos. Peptídeos antimicrobianos fazem parte da resposta humoral do mosquito, sendo codificados por genes e secretados por diversos tipos celulares. Um peptídeo novo pouco conhecido descoberto em Anopheles gambiae, a gambicina, demonstrou bons resultados no combate de parasitas. Na infecção por Plasmodium galleceum, não há diferença significativa na expressão deste peptídeo entre o grupo controle e infectado nos intervalos analisados. Na infecção por vírus dengue, sorotipo 2, a gambicina não apresenta diferença significativa no intervalo de 24 horas após a infecção, quando comparamos grupo controle e infectado, nos intervalos de 7 dias e 14 dias após a infecção, a expressão da gambicina é maior no grupo controle quando comparemos com o grupo infectado. / Innate immunity presents a mosquito tries to combat the pathogens inside the body of the mosquito preventing it from being transmitted to other hosts. The cellular response has three different processes: phagocytosis, encapsulation and nodule formation, all these processes seek to eliminate pathogens. Antimicrobial peptides are part of the humoral response mosquito being encoded by genes and secreted by several cell types. A little known new peptide discovered in Anopheles gambiae, the gambicina showed good results in controlling pests. In Plasmodium infection galleceum, there is no significant difference in the expression of this peptide between the control group and infected in the analyzed intervals. In infection with dengue virus serotype 2, the gambicina no significant difference within 24 hours after infection when comparing the control group and infected at intervals of 7 days and 14 days after infection, the expression is higher in gambicina control group when compare to the infected group.

Aedes aegypti

Plasmodium

Gambicina

Peptídeos antimicrobianos

Sistema imune

Vírus dengue

Aedes aegypti

Plasmodium

Antimicrobial peptides

Dengue virus

Gambicin

Immune system

Papel das quinases PfPK7, PfNEK2, PfNEK3, PfMAP1 e PfelK1 na transdução de sinal de melatonina no desenvolvimento do ciclo celular intraeritrocítico de Plasmodium falciparum. / The role of the kinases PfPK7, PfNEK2, PfNEK3, PfMAP1 e PfeIK1 in signal transduction of melatonin in development of intraerytrocyte cell cycle of Plasmodium falciparum.

Ramira Yuri Ribeiro

29 September 2010

Estudamos o papel de quinases de Plasmodium na modulação, via derivados de triptofano, no ciclo celular do parasita. Foram realizadas análises com melatonina, N-acetilserotonina, triptamina e serotonina, avaliadas através de microscopia e citometria de fluxo. Parasitas deficientes para as proteínas PfNEK2, PfNEK3 e PfMAP1 apresentaram respostas similares ao parasita selvagem enquanto pfpk7- e pfeik1- não apresentaram resposta aos compostos indólicos. Estes dados sugerem envolvimento das quinases PfPK7 e PfeIK1 na transdução de sinal via compostos derivados de triptofano na modulação do ciclo intraeritrocítico em P. falciparum. Ensaios de medidas de cálcio intracelular mostraram que a ausência de pfpk7- leva a uma atenuação na liberação de cálcio promovida por melatonina, sugerindo que a ativação desta quinase é importante no aumento de cálcio citosólico. Estes resultados ampliaram a compreensão dos mecanismos moleculares que regulam resposta a melatonina. / We evaluated the role of Plasmodium kinases in the modulation, via tryptophan derivatives, of the parasite cell cycle. We performed analysis with melatonin, N-acetylserotonin, tryptamine and serotonin through blood smears and flow cytometry analyzes. Parasites deficient in the proteins PfNEK2, PfNEK3 and PfMAP1 showed similar responses to the wild type while pfpk7- e pfeik1- did not respond to the indolic compounds. This data suggest the involvement of the kinases PfPK7 and PfeIK1 in melatonin signal transduction for cell cycle modulation in P.falciparum. Intracellular calcium measurement assays showed that pfpk7- diminished the ability of melatonin to rise cytosolic calcium concentration, suggesting that this kinase is involved with cytosolic calcium increase. These results expand the understanding of the molecular mechanisms that regulate melatonin-dependent cell cycle modulation.

Plasmodium falciparum

Ciclo celular

Malária

Melatonina

PfeIK1

PfPK7

Quinases

Plasmodium falciparum

Cell cycle

Kinases

Malaria

Melatonin

PfeIK1

PfPK7

Fatores de Plasmodium falciparum envolvidos na fosforilação de eIF2α em resposta a melatonina. / Plasmodium falciparum factors involved in eIF2α phosphorylation in response to melatonin.

Fahyme Costa da Silva Almeida

17 February 2016

A malária é causada por parasitas Plasmodium falciparum, e embora vários aspectos ainda sejam desconhecidos, é sabido que a regulação do ciclo intraeritrocítico é crítica para a compreensão do ciclo celular e patogênese. A melatonina modula o ciclo de P. falciparum promovendo a sincronização, mas, o mecanismo de transdução de sinal é parcialmente caracterizado, envolvendo variações citosólicas de cálcio, AMPc e ativação da PKA. Modificações pós-traducionais participam na via de sinalização, e diversas proteínas quinase podem estar envolvidas na sinalização por melatonina. eIF2α fosforilado é capaz de ativar a tradução de mRNAs em resposta a situações desfavoráveis. O genoma de P. falciparum codifica três quinases cujo substrato é eIF2α: PfeIK1, PfeIK2 e PfPK4. Investigamos o papel da PfeIK1 na via de transdução de sinal de melatonina usando cepas nocaute para PfeIK1. Além disso, os efeitos de metabólitos da degradação do heme sobre a fosforilação de eIF2α. Sugerimos que o mecanismo de fosforilação e defosforilação de eIF2α possam ser relevantes para a resposta do parasita a hemina ou biliverdina. Nossos dados indicam a PfeIK1, juntamente com a PfK7 e PKA, como quinases-chaves no controle do desenvolvimento durante o ciclo intraeritrocítico. / Malaria is caused by Plasmodium falciparum parasites, and although some aspects are still unknown, its established that the intraerythrocytic cycle regulation is critic for understanding the cell cycle and pathogenesis of the parasite. Melatonin modulates the cycle of P. falciparum promoting synchronization; however, the signal transduction mechanism is partially characterized, and it contains cytosolic variations of calcium, AMPc and PKA activation. Post-translational modifications participate in this signal pathway, and several kinase proteins may be involved in melatonin signaling pathway. Phosphorylated eIF2α is able to activate mRNAs translation in stress conditions. The genome of P. falciparum encodes three kinases whose substrate is eIF2α: PfeIK1, PfeIK2 e PfPK4. We investigate the role of PfeIK1 in melatonin signaling pathway by using knockout strains for PfeIK1. Furthermore, we investigate the effects of heme degradation metabolities in eIF2α phosphorylation. We suggest that the phosphorylation and dephosphorylation mechanisms of eIF2α may be relevant for parasite response to heme and billiverdin. Our data indicates PfeIK1, PfK7 and PKA as key kinases for the development control during intraerythrocytic cycle.

Plasmodium falciparum

Biliverdina

eIF2α

Melatonina

PfeIK1

Quinase

Plasmodium falciparum

Biliverdin

eIF2α

Kinase

Melatonin

PfeIK1