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Plasmodium Parasites (plasmodium + parasite)

Distribution by Scientific Domains

Life Sciences	71%

Selected Abstracts

Erythrocyte variants and the nature of their malaria protective effect

CELLULAR MICROBIOLOGY, Issue 6 2005
Gundula Min-Oo
Summary The malaria threat to global health is exacerbated by widespread drug resistance in the Plasmodium parasite and its insect vector, and the lack of an efficacious vaccine. Infection with Plasmodium parasites can cause a wide spectrum of pathologies, from a transient mild form of anaemia to a severe and rapidly fatal cerebral disease. Epidemiological studies in humans and experiments in animal models have shown that genetic factors play a key role in the onset, progression, type of disease developed and ultimate outcome of malaria. The protective effect of polymorphic variants in erythrocyte-specific structural proteins or metabolic enzymes against the blood-stage of the disease is one of the clearest illustrations of this genetic modulation, and has suggested co-evolution of the Plasmodium parasite with its human host in areas of endemic disease. Here, we present a brief overview of erythrocyte polymorphisms with biological relevance to malaria pathogenesis, and current work on the mechanism(s) by which these mediate their protective effect. The recent addition of erythrocyte pyruvate kinase to this group of protective genes will also be discussed. [source]

Structure-Based Design and Synthesis of the First Weak Non-Phosphate Inhibitors for IspF, an Enzyme in the Non-Mevalonate Pathway of Isoprenoid Biosynthesis

HELVETICA CHIMICA ACTA, Issue 6 2007
Corinne Baumgartner
Abstract In this paper, we describe the structure-based design, synthesis, and biological evaluation of cytosine derivatives and analogues that inhibit IspF, an enzyme in the non-mevalonate pathway of isoprenoid biosynthesis. This pathway is responsible for the biosynthesis of the C5 precursors to isoprenoids, isopentenyl diphosphate (IPP, 1) and dimethylallyl diphosphate (DMAPP, 2; Scheme,1). The non-mevalonate pathway is the sole source for 1 and 2 in the protozoan Plasmodium parasites. Since mammals exclusively utilize the alternative mevalonate pathway, the enzymes of the non-mevalonate pathway have been identified as attractive new drug targets in the fight against malaria. Based on computer modeling (cf. Figs.,2 and 3), new cytosine derivatives and analogues (Fig.,1) were selected as potential drug-like inhibitors of IspF protein, and synthesized (Schemes,2,5). Determination of the enzyme activity by 13C-NMR spectroscopy in the presence of the new ligands showed inhibitory activities for some of the prepared cytosine and pyridine-2,5-diamine derivatives in the upper micromolar range (IC50 values; Table). The data suggest that it is possible to inhibit IspF protein without binding to the polar diphosphate binding site and the side chain of Asp56,, which interacts with the ribose moiety of the substrate and substrate analogues. Furthermore, a new spacious sub-pocket was discovered which accommodates aromatic spacers between cytosine derivatives or analogues (binding to ,Pocket III') and rings that occupy the flexible hydrophobic region of ,Pocket II'. The proposed binding mode remains to be further validated by X-ray crystallography. [source]

The liver stage of Plasmodium berghei inhibits host cell apoptosis

MOLECULAR MICROBIOLOGY, Issue 3 2005
Claudia Van De Sand
Summary Plasmodium berghei is the causative agent of rodent malaria and is widely used as a model system to study the liver stage of Plasmodium parasites. The entry of P. berghei sporozoites into hepatocytes has extensively been studied, but little is known about parasite,host interaction during later developmental stages of the intracellular parasite. Growth of the parasite far beyond the normal size of the host cell is an important stress factor for the infected cell. Cell stress is known to trigger programmed cell death (apoptosis) and we examined several apoptotic markers in P. berghei -infected cells and compared their level of expression and their distribution to that of non-infected cells. As none of the apoptotic markers investigated were found altered in infected cells, we hypothesized that parasite infection might confer resistance to apoptosis of the host cell. Treatment with peroxide or serum deprivation induced apoptosis in non-infected HepG2 cells, whereas P. berghei -infected cells appeared protected, indicating that the parasite interferes indeed with the apoptotic machinery of the host cell. To prove the physiological relevance of these results, mice were infected with high numbers of P. berghei sporozoites and treated with tumour necrosis factor (TNF)-,/d -galactosamine to induce massive liver apoptosis. Liver sections of these mice, stained for degraded DNA, confirmed that infected cells containing viable parasites were protected from programmed cell death. However, in non-treated control mice as well as in TNF-,-treated mice a small proportion of dead intracellular parasites with degraded DNA were detected. Most hepatocytes containing dead parasites provoked an infiltration of immunocompetent cells, indicating that these cells are no longer protected from cell death. [source]

Distinct host-related dendritic cell responses during the early stage of Plasmodium yoelii infection in susceptible and resistant mice

PARASITE IMMUNOLOGY, Issue 5 2010
W. ZHENG
Summary The diverse outcomes of experimental murine infection with Plasmodium parasites, ranging from spontaneous cure to death, depend largely on the establishment of an effective Th1 immune response during the early stages of infection. However, the molecular and cellular factors responsible for the induction and regulation of this response are poorly understood. As immunity is initiated by dendritic cells (DCs), we compared their phenotype and function during the early stages of infection with Plasmodium yoelii 17XL (P.y 17XL) strain in susceptible (BALB/c) and resistant (DBA/2) mice. Resistant DBA/2 mice developed a greater number of myeloid (CD11c+CD11b+) and mature DCs, which were fully functional and capable of secreting IL-12p40. In contrast, susceptible BALB/c mice produced more plasmacytoid (CD11c+CD45R/B220+) and less mature DCs, resulting in high levels of IL-10 and TGF-,1. In addition, an in vitro experiment confirmed that splenic DCs from the two strains of mice differ in their ability to prime CD4+T cells in response to P.y 17XL stimulation. These findings indicate that the subset, the phenotype and the type of inflammatory and anti-inflammatory signals of splenic DCs are critical factors responsible for the discrepancy in the ability to induce or regulate Th1 immune responses in different hosts. [source]

Nomadic or sessile: can Kupffer cells function as portals for malaria sporozoites to the liver?

CELLULAR MICROBIOLOGY, Issue 10 2006
Ute Frevert
Summary The initial site of replication for Plasmodium parasites in mammalian hosts are hepatocytes, cells that offer unique advantages for the extensive parasite replication occurring prior to the erythrocytic phase of the life cycle. The liver is the metabolic centre of the body and has an unusual relationship to the immune system. However, to reach hepatocytes, sporozoites must cross the sinusoidal barrier, composed of specialized endothelia and Kupffer cells, the resident macrophages of the liver. Mounting evidence suggests that, instead of taking what would seem a safer route through endothelia, the parasites traverse Kupffer cells yet suffer no harm. Kupffer cells have a broad range of responses towards incoming microorganisms, toxins and antigens which depend on the nature of the intruder, the experimental conditions and the environmental circumstances. Kupffer cells may become activated or remain anergic, produce pro- or anti-inflammatory mediators. Consequently, outcomes are diverse and include development of immunity or tolerance, parenchymal necrosis or regeneration, chronic cirrhotic transformation or acute liver failure. Here we review data concerning the unique structural and functional characteristics of Kupffer cells and their interactions with Plasmodium sporozoites in the context of a model in which these hepatic macrophages function as the sporozoite gate to the liver. [source]

Plasmodium,mosquito interactions: a tale of dangerous liaisons

CELLULAR MICROBIOLOGY, Issue 11 2005
Carolina Barillas-Mury
Summary To complete their life cycle, Plasmodium parasites must survive the environment in the insect host, cross multiple barriers including epithelial layers, and avoid destruction by the mosquito immune system. Completion of the Anopheles gambiae and Plasmodium falciparum genomes has opened the opportunity to apply high throughput methods to the analysis of gene function. The burst of information generated by these approaches and the use of molecular markers to investigate the cell biology of these interactions is broadening our understanding of this complex system. This review discusses our current understanding of the critical interactions that take place during the journey of Plasmodium through the mosquito host, with special emphasis on the responses of midgut epithelial cells to parasite invasion. [source]