Knockdown of Anopheles dirus far upstream element-binding protein gene lower oocyst numbers of Plasmodium vivax.

The modulation of gene expression levels of Anopheles dirus on Plasmodium vivax infection at the ookinete and oocyst stages was previously reported. In the present study, several upregulated An. dirus genes were selected based on their high expression levels and subcellular locations to examine their roles in P. vivax infection. Five An. dirus genes-carboxylesterase, cuticular protein RR-2 family, far upstream element-binding protein, kraken, and peptidase212-were knocked down by dsRNA feeding using dsRNA-lacZ as a control. The dsRNA-fed mosquitoes were later challenged by P. vivax-infected blood, and the oocyst numbers were determined. The expression of these five genes was examined in many organs of both male and female mosquitoes. The results showed that the decreased expression level of the far upstream element-binding protein gene could lower the oocyst numbers, whereas the others showed no effect on P. vivax infection. The expression levels of these genes in ovaries were found, and in many organs, they were similar between male and female mosquitoes. The reduction of these five gene expressions did not affect the lifespan of the mosquitoes. In addition, the malaria box compound, MMV000634, demonstrated the lowest binding energy to the far upstream element-binding protein using virtual screening. This protein might be a target to block malaria transmission.

Anopheles dirus yellow-g mediates Plasmodium vivax infection.

OBJECTIVE: Our previous transcriptome analysis of Anopheles dirus revealed upregulation of the An. dirus yellow-g gene upon ingestion of Plasmodium vivax-infected blood. This gene belongs to the yellow gene family, but its role regarding P. vivax infection is not known and remains to be validated. The aim of this study was to investigate the role of the An. dirus yellow-g gene in P. vivax infection. METHODS: The qRT-PCR was used to detect the expression of the yellow-g gene in many organs of both male and female mosquitos. The yellow-g gene silencing was performed by dsRNA membrane feeding to An. dirus. These mosquitoes were later challenged by P. vivax-infected blood. The oocyst numbers were determined. RESULTS: The yellow-g transcript was detected in several organs of both male and female An. dirus mosquitoes. Successful knockdown of yellow-g was achieved and resulted in reduced P. vivax infection in the mosquitoes. The decrease in yellow-g expression had no effect on the life span of the mosquitoes. CONCLUSIONS: These results support the yellow-g gene as having an important function in Plasmodium development in Anopheles mosquitoes.

A novel immortalized hepatocyte-like cell line (imHC) supports in vitro liver stage development of the human malarial parasite Plasmodium vivax.

BACKGROUND: Eradication of malaria is difficult because of the ability of hypnozoite, the dormant liver-stage form of Plasmodium vivax, to cause relapse in patients. Research efforts to better understand the biology of P. vivax hypnozoite and design relapse prevention strategies have been hampered by the lack of a robust and reliable model for in vitro culture of liver-stage parasites. Although the HC-04 hepatoma cell line is used for culturing liver-stage forms of Plasmodium, these cells proliferate unrestrictedly and detach from the culture dish after several days, which limits their usefulness in a long-term hypnozoite assay. METHODS: A novel immortalized hepatocyte-like cell line (imHC) was evaluated for the capability to support P. vivax sporozoite infection. First, expression of basic hepatocyte markers and all major malaria sporozoite-associated host receptors in imHC was investigated. Next, in vitro hepatocyte infectivity and intracellular development of sporozoites in imHC were determined using an indirect immunofluorescence assay. Cytochrome P450 isotype activity was also measured to determine the ability of imHC to metabolize drugs. Finally, the anti-liver-stage agent primaquine was used to test this model for a drug sensitivity assay. RESULTS: imHCs maintained major hepatic functions and expressed the essential factors CD81, SR-BI and EphA2, which are required for host entry and development of the parasite in the liver. imHCs could be maintained long-term in a monolayer without overgrowth and thus served as a good, supportive substrate for the invasion and growth of P. vivax liver stages, including hypnozoites. The observed high drug metabolism activity and potent responses in liver-stage parasites to primaquine highlight the potential use of this imHC model for antimalarial drug screening. CONCLUSIONS: imHCs, which maintain a hepatocyte phenotype and drug-metabolizing enzyme expression, constitute an alternative host for in vitro Plasmodium liver-stage studies, particularly those addressing the biology of P. vivax hypnozoite. They potentially offer a novel, robust model for screening drugs against liver-stage parasites.

VIABILITY AND INFECTIVITY OF CRYOPRESERVED PLASMODIUM VIVAX SPOROZOITES.

Plasmodium vivax presents a great challenge to malaria control because of the ability of its dormant form in the liver, the hypnozoite, to cause relapse in otherwise fully recovered patient. Research efforts to better understand P. vivax hypnozoite biology have been hampered by the limited availability of its sporozoite form responsible for liver infection. Thus, the ability to cryopreserve and recover P. vivax sporozoites is an essential procedure. In this study, protective effects of hydroxyethyl starch (HES) alone and in combination with other cryoprotectants on P. vivax sporozoite recovery, viability and in vitro infectivity of a human liver HC-04 cell line were investigated. Sporozoites were harvested from P. vivax-infected female Anopheles mosquitoes and cryopreserved at a freezing rate of -1°C/minute to a final temperature of -80°C before being stored in a vapor phase liquid nitrogen tank. Cryopreserved sporozoites were thawed at 37°C and recovery of intact sporozoites assessed using a hemocytometer. Sporozoite viability and in vitro infectivity was measured using a gliding and an indirect immunofluorescence assay, respectively. A combination of 10% HES + 50% fetal bovine serum was the best cryopreservant compared to HES solution alone or mixed with cryopreservants such as dimethyl sulfoxide (DMSO) and sucrose. A mixture of bovine serum albumin, DMSO and sucrose in RPMI 1640 medium constituted an alternative cryopreservant. Sporozoites recovered from all cryopreservation media exhibited motility and infectivity of < 0.1% and < 0.001%, respectively. Thus, there is an urgent need for a vast improvement in cryopreservation procedures of viable and infective P. vivax sporozoites necessary for advancing research on hypnozoite biology.

LAP-like process as an immune mechanism downstream of IFN-γ in control of the human malaria Plasmodium vivax liver stage.

IFN-γ is a major regulator of immune functions and has been shown to induce liver-stage Plasmodium elimination both in vitro and in vivo. The molecular mechanism responsible for the restriction of liver-stage Plasmodium downstream of IFN-γ remains uncertain, however. Autophagy, a newly described immune defense mechanism, was recently identified as a downstream pathway activated in response to IFN-γ in the control of intracellular infections. We thus hypothesized that the killing of liver-stage malarial parasites by IFN-γ involves autophagy induction. Our results show that whereas IFN-γ treatment of human hepatocytes activates autophagy, the IFN-γ-mediated restriction of liver-stage Plasmodium vivax depends only on the downstream autophagy-related proteins Beclin 1, PI3K, and ATG5, but not on the upstream autophagy-initiating protein ULK1. In addition, IFN-γ enhanced the recruitment of LC3 onto the parasitophorous vacuole membrane (PVM) and increased the colocalization of lysosomal vesicles with P. vivax compartments. Taken together, these data indicate that IFN-γ mediates the control of liver-stage P. vivax by inducing a noncanonical autophagy pathway resembling that of LC3-associated phagocytosis, in which direct decoration of the PVM with LC3 promotes the fusion of P. vivax compartments with lysosomes and subsequent killing of the pathogen. Understanding the hepatocyte response to IFN-γ during Plasmodium infection and the roles of autophagy-related proteins may provide an urgently needed alternative strategy for the elimination of this human malaria.