The machinery underlying malaria parasite virulence is conserved between rodent and human malaria parasites

Niz, Mariana De; Ullrich, Ann-Katrin; Heiber, Arlett; Soares, Alexandra Blancke; Pick, Christian; Lyck, Ruth; Keller, Derya; Kaiser, Gesine; Prado, M. J. B. A.; Flemming, Sven; Portillo, Hernando del; Janse, Chris J.; Heussler, Volker; Spielmann, Tobias

doi:10.1038/ncomms11659

Cited by 65 publications

(92 citation statements)

References 65 publications

(109 reference statements)

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“…However, recent studies have shown that P. berghei -infected RBCs can sequester in different organs, including the brain5354, and that accumulation of parasitized RBCs, in addition to the recruitment and sequestration of activated CD8 + T cells55, is necessary for the development of cerebral malaria in mice56. Moreover, there is evidence of an evolutionary conserved machinery underlying sequestration and protein export to the host cell surface between P. berghei and P. falciparum species, although P. berghei lacks PfEMP1 adhesin orthologues57. Taking these findings into consideration, we explain the reduced brain damage in menadione-treated mice in light of our findings that menadione creates an oxidative imbalance in parasitized RBCs that interferes with the export and surface presentation of parasite-encoded virulence factors.…”

Section: Discussionmentioning

confidence: 99%

Oxidative insult can induce malaria-protective trait of sickle and fetal erythrocytes

et al. 2016

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Plasmodium falciparum infections can cause severe malaria, but not every infected person develops life-threatening complications. In particular, carriers of the structural haemoglobinopathies S and C and infants are protected from severe disease. Protection is associated with impaired parasite-induced host actin reorganization, required for vesicular trafficking of parasite-encoded adhesins, and reduced cytoadherence of parasitized erythrocytes in the microvasculature. Here we show that aberrant host actin remodelling and the ensuing reduced cytoadherence result from a redox imbalance inherent to haemoglobinopathic and fetal erythrocytes. We further show that a transient oxidative insult to wild-type erythrocytes before infection with P. falciparum induces the phenotypic features associated with the protective trait of haemoglobinopathic and fetal erythrocytes. Moreover, pretreatment of mice with the pro-oxidative nutritional supplement menadione mitigate the development of experimental cerebral malaria. Our results identify redox imbalance as a causative principle of protection from severe malaria, which might inspire host-directed intervention strategies.

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Section: Discussionmentioning

confidence: 99%

Oxidative insult can induce malaria-protective trait of sickle and fetal erythrocytes

et al. 2016

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“…Intravital microscopy (IVM) is a powerful technique to investigate dynamic cellular processes and host-parasite interactions within functioning organs. Organs studied by IVM in the context of parasitology include the brain [1][2][3][4], the skin [5][6][7], the placenta [8,9], the lungs [10], the liver [11][12][13], and the spleen [14,15] (summarized in table 2, green=IVM exists; yellow=organ relevant but IVM never done; grey = IVM not done). Important advances in parasitology have been achieved using wide-field epifluorescence, confocal, spinning disc, or two-photon IVM.…”

Section: Advanced Fluorescence Methods Applied To Intravital Microscopymentioning

confidence: 99%

Toolbox for In Vivo Imaging of Host–Parasite Interactions at Multiple Scales

Niz

Spadin

Marti

et al. 2019

Trends in Parasitology

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Animal models have for long been pivotal for parasitology research. Over the last few years, techniques such as intravital, optoacoustic and magnetic resonance imaging, optical projection tomography, and selective plane illumination microscopy developed promising potential for gaining insights into host-pathogen interactions by allowing different visualization forms in vivo and ex vivo. Advances including increased resolution, penetration depth, and acquisition speed, together with more complex image analysis methods facilitate tackling biological problems previously impossible to study and/or quantify. Here we discuss advances and challenges in the in vivo imaging toolbox, which hold important potential for the field of parasitology. KeywordsParasitology, imaging, in vivo, animal models Imaging toolbox in parasitologyImaging techniques developed for biomedical applications have had an important impact in parasitology research. Such techniques include platforms developed to image host-pathogen interactions at various scales, ranging from molecules to whole organisms (summarised in table 1). These techniques have complementary advantages with respect to each other. This review focuses on the technological advances used for visualization of host-pathogen interactions either in vivo, or ex vivo in whole organisms in five imaging techniques: intravital microscopy (IVM), optical projection tomography (OPT), bioluminescence imaging, optoacoustic imaging (OAI), and magnetic resonance imaging (MRI). Advanced fluorescence methods applied to intravital microscopyIntravital microscopy (IVM) is a powerful technique to investigate dynamic cellular processes and host-parasite interactions within functioning organs. Organs studied by IVM in the context of parasitology include the brain [1][2][3][4], the skin [5][6][7], the placenta [8,9], the lungs [10], the liver [11][12][13], and the spleen [14,15] (summarized in table 2, green=IVM exists; yellow=organ relevant but IVM never done; grey = IVM not done). Important advances in parasitology have been achieved using wide-field epifluorescence, confocal, spinning disc, or two-photon IVM.Recent developments, which have expanded the applications of IVM include the generation of

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“…(Image reproduced from Frevert, Nacer, Cabrera, Movila, & Leberl, ) (Scale bar, 50 μm). (ii) IVM still images showing the lungs of a UBC‐GFP mouse infected with WT PbANKA mCherry parasites displaying sequestration, and the lungs of a UBC‐GFP mouse infected with PbSBP1KO mCherry parasites (absent from the vasculature) (Image reproduced from De Niz et al, ) (Scale bar, 10 μm). (iii) An important biological finding in the field of Plasmodium was the egress of merozoites from liver‐derived merosomes in the pulmonary capillaries.…”

Section: Organs In the Thoracic Cavitymentioning

confidence: 99%

“…(Figure d(i)). A study using lung IVM in the context of Plasmodium aimed to study the dynamics of P. berghei relative to the vasculature when the machinery for protein export was intact, as opposed to when proteins PbMAHRP1a and PbSBP1 were absent (De Niz et al, ). P. falciparum MAHRP1 and SBP1 are known to be essential for virulence factor export and sequestration.…”

Section: Organs In the Thoracic Cavitymentioning

confidence: 99%

Intravital imaging of host‐parasite interactions in organs of the thoracic and abdominopelvic cavities

Niz

Carvalho

Penha‐Gonçalves

et al. 2020

Cellular Microbiology

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Infections with protozoan and helminthic parasites affect multiple organs in the mammalian host. Imaging pathogens in their natural environment takes a more holistic view on biomedical aspects of parasitic infections. Here, we focus on selected organs of the thoracic and abdominopelvic cavities most commonly affected by parasites. Parasitic infections of these organs are often associated with severe medical complications or have health implications beyond the infected individual. Intravital imaging has provided a more dynamic picture of the host-parasite interplay and contributed not only to our understanding of the various disease pathologies, but has also provided fundamental insight into the biology of the parasites. K E Y W O R D S diseases, imaging, infection, intravital, microscopy, parasitology 1 | INTRODUCTION Most parasitic infections in mammals involve organs of the thoracic, abdominal and pelvic cavities, and may cause severe complications as a result of damage to these organs. Organs in the thoracic cavity include the heart, the lungs, the thymus, the thyroid and parathyroid.The heart is an important target of Trypanosoma cruzi; and the lungs, are key targets of multiple parasites causing a broad spectrum of pathology ranging from focal lesions to diffuse lung damage. In the abdominal cavity, organs include the stomach, the intestine, the liver, the gallbladder, the pancreas, the spleen, the kidneys, the adrenal glands and regional lymph nodes. In the pelvic cavity, the reproductive organs and the urinary bladder are harboured. All the above organs can be compromised by vector-borne and soil/water/food-borne parasites alike. Intravital microscopy (IVM) allows studying cellular and sub-cellular events within living animals, including host-pathogen interactions. In this review, we focus on key IVM-based findings on parasite biology in different organs of the thoracic and abdominopelvic cavities. Importantly, some of these organs pose specific challenges for visualisation. Here, we discuss the advances on surgical procedures, imaging platforms and image processing tools that have made visualisation of parasites within these organs possible. | ORGANS IN THE THORACIC CAVITYThe organs in the thoracic cavity most frequently affected by parasites are the lungs and heart (Figure 1a). The heart as the central organ of the circulatory system carries out vital functions by distributing blood, oxygen and nutrients to tissues and removing metabolic waste

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The machinery underlying malaria parasite virulence is conserved between rodent and human malaria parasites

Cited by 65 publications

References 65 publications

Oxidative insult can induce malaria-protective trait of sickle and fetal erythrocytes

Oxidative insult can induce malaria-protective trait of sickle and fetal erythrocytes

Toolbox for In Vivo Imaging of Host–Parasite Interactions at Multiple Scales

Intravital imaging of host‐parasite interactions in organs of the thoracic and abdominopelvic cavities

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