Epithelial and cellular innate immune responses of Anopheline mosquitoes to Plasmodium parasites

Pinto, Sofia B.

January 2007

Heidelberg, Univ., Diss., 2007.

Induction of Anopheles stephensi nitric oxide synthase by Plasmodium-derived factor(s)

Lim, Junghwa

17 November 2004

Malaria parasite (Plasmodium spp.) infection in the mosquito Anopheles stephensi induces significant expression of A. stephensi nitric oxide synthase (AsNOS) in the midgut epithelium as early as 6 h post-infection and intermittently thereafter. This induction results in the synthesis of inflammatory levels of nitric oxide (NO) in the blood-filled midgut that limit parasite development. However, the Plasmodium-derived factors that can induce AsNOS expression and the signaling pathways responsible for transduction in A. stephensi have not been identified until completion of the work described herein. In my studies, I have determined that P. falciparum glycosylphosphatidylinositol (PfGPIs) can induce AsNOS expression in A. stephensi cells in vitro and in the midgut epithelium in vivo. Based on related work in mammals, I hypothesized that parasite-derived AsNOS-inducing factors signal through the insulin signaling pathway and the NF-kappaB-dependent Toll and Immune deficiency (Imd) signaling pathways. In support of this hypothesis, I have determined that signaling by P. falciparum merozoites and PfGPIs is mediated through A. stephensi protein kinase B (Akt/PKB) and DSOR1 (mitogen activated protein kinase kinase, MEK)/Extracellular signal-regulated protein kinase (ERK), kinases which are associated with the insulin signaling pathway. However, signaling by P. falciparum and PfGPIs is distinctively different from signaling by insulin and these parasite signals are not insulin-mimetic to A. stephensi cells. In other studies, treatment with pyrrolidine dithiocarbamate (PDTC), an inhibitor of NF-kappaB, reduced AsNOS expression by P. falciparum merozoites in A. stephensi cells. This result suggested the involvement of Toll and Imd pathways in parasite signaling of mosquito cells. Knockout of Pelle, a proximal signaling protein in the Toll pathway, increased AsNOS expression following parasite stimulation, suggesting that the Toll pathway may negatively regulate signaling by Plasmodium-derived AsNOS-inducing factors. In contrast, knockout of TGF-beta-activated kinase 1 (Tak1), a proximal signaling protein in the Imd pathway, reduced AsNOS expression by 20% relative to the control, suggesting that the Imd pathway is required for signaling by Plasmodium-derived AsNOS-inducing factors. Despite the NO-rich environment of the midgut, Plasmodium development is not completely inhibited. This observation suggests that Plasmodium may have efficient detoxification systems during sexual development in A. stephensi. To identify Plasmodium defense genes that may defend parasites against nitrosative stress caused by AsNOS induction, expression of several antioxidant defense genes known to function in nitrosative stress defense in a variety of organisms were examined during sporogonic development. Notably, increased expression levels of P. falciparum peroxiredoxins containing 1 or 2 cysteines (1-cys or 2-cys PfPrx) were associated with periods of parasite development just prior to and during parasite penetration of midgut epithelium, an event associated with significant AsNOS induction in the midgut. The provision of N omega-L-arginine (L-NAME), a known inhibitor of NOS enzyme activity, to A. stephensi with Plasmodium culture by artificial bloodmeal significantly reduced expression of 1-cys and 2-cys PfPrx indicating that these gene products may function to protect parasites against nitrosative stress induced by AsNOS. / Ph. D.

Plasmodium

Nitric oxide synthase

Malaria

Anopheles stephensi

The mosquito midgut-specific stages of the malaria parasite as targets for transmission blocking interventions / Die Moskitomitteldarmstadien des Malariaparasiten als Ziele für übertragungsblockierende Eingriffe

Ngwa, Che Julius

January 2013

Die Tropenkrankheit Malaria, wird durch eine Infektion mit einzelligen Parasiten der Gattung Plasmodium verursacht und durch den Stich der weiblichen Anopheles-Mücke von Mensch zu Mensch verbreitet. Dabei kann eine erfolgreiche Übertragung des Parasiten auf den Menschen nur dann stattfinden, wenn der Parasit seine sexuelle Entwicklungsphase im Mitteldarm der Mücke erfolgreich durchläuft. Ziel dieser Arbeit war es daher, die Wechselwirkungen des Malariaparasiten im Mitteldarm der Mücke in Hinblick auf die Identifizierung möglicher neuer transmissionsblockierender Strategien zu untersuchen. Der Zweck von transmissionsblockierende Strategien ist es, der Verbreitung der Malaria durch die Mücke entgegenzuwirken, indem die Entwicklung des Parasiten in der Mücke unterbunden und dadurch der Lebenszyklus des Parasiten unterbrochen wird. Der Schwerpunkt der vorliegenden Arbeit lag auf insgesamt drei Aspekten. Der erste Aspekt der Arbeit befasste sich mit der Wechselwirkung zwischen dem Para-siten und der mikrobiellen Darmflora der Mücke. Dabei sollte der mögliche Einfluss des Parasiten auf die Darmflora untersucht werden und weiterführend die potentielle Verwendung von Darmbakterien als Vehikel für die Herstellung paratransgener Mücken erforscht werden. Vergleichende16S-rRNA- und DGGE-Analysen an der Darmflora des asiatischen Malariavektors Anopheles stephensi zeigten eine deutliche Reduktion der mikrobiellen Diversität während der Entwicklung vom Ei zur adulten Mücke. Zudem konnte das gram-negative Bakterium Elizabethkingia meningoseptica, das sich stadien- und generationsübergreifend verbreitet, als dominante Darmspezies bei im Labor aufgezogenen weiblichen und männlichen An. stephensi festgestellt werden. Die Dominanz von E. meningoseptica wurde zudem nicht durch die Aufnahme von infiziertem Blut oder einer veränderten Nahrung beeinflusst. Für die Studien wurde sowohl der humanpathogene Parasit P. falciparum als auch der Nagermalariaerreger P. berghei verwendet. Weiterführende Versuche zeigten, dass Extrakte von E. meningoseptica antibakterielle, antifungale und antiplasmodiale Aktivitäten aufwiesen, die ein möglicher Grund für die Dominanz dieser Spezies im Mitteldarm des Vektors waren. Isolate von E. meningoseptica sind im Labor kultivierbar; dadurch stellt das Bakterium einen potentiellen Kandidaten zur Generierung von paratransgenen Anopheles-Mücken dar. Ein zweites Ziel dieser Arbeit war es, mögliche Unterschiede in der Genexpression von P. falciparum darzustellen, die in den ersten 30 Minuten nach dessen Übertragung auf die Mücke erfolgen. Dies hatte zum einen zum Zweck, die durch den Wirtswechsel hervorgerufenen Genregulationen besser zu verstehen, und bot zum anderen die Möglichkeit, neue Proteine zu identifizieren, die als potentielle transmissionsblockierende Ziele genutzt werden können. Mittels supression substractive hybridization (SSH) konnten insgesamt 126 Gene identifiziert werden, deren Expression sich während der Gametogenese verändert. Die identifizierten Gene konnten einer Vielzahl von putativen Funktionen wie zum Beispiel in der Signaltransduktion (17,5%), im Zellzyklus (14,3%) oder im Zytoskelett (8,7%) zugeordnet werden. Des Weiteren wurden 7,9% der Gene eine Funktion in der Proteastase und 6,4% in metabolischen Prozessen zugeordnet. 12,7% der Gene kodierten für zelloberflächenassoziierte Proteine. 11,9% der Gene hatten anderen Funktionen, während 20% der Gene keine putative Funktion zugeordnet werden konnte. Etwa 40% der identifizierten Genprodukte waren bisher nicht in Proteomstudien nachgewiesen worden. In weiterführenden Analysen wurden 34 Gene aus jeder ontologischen Gruppe ausgewählt und deren Expressionsveränderung per quantitativer real time RT-PCR im Detail untersucht. Für 29 Gene konnte dabei eine Transkriptexpression in Gametozyten nachgewiesen werden. Zudem wiesen 20 Gene eine erhöhte Expression in Gametozyten im Vergleich asexuellen Stadien auf. Insgesamt zeigten 8 Gene besonders hohe Transkriptlevel in aktivierten Gametozyten, was auf eine Funktion dieser Proteine während der Übertragung des Parasiten auf die Mücke hindeutet und diese somit potentielle Angriffspunkte für transmissionsblockierende Strategien darstellen könnten. Im letzten Teil dieser Arbeit stand die Untersuchung verschiedener antimikrobieller Substanzen in Bezug auf ihre transmissionsblockierenden Eigenschaften im Vordergrund. Die Substanzen waren entweder direkt aus der Hämolymphe verschiedener Insekten isoliert oder rekombinant in transgenem Tabak exprimiert worden. Dabei wurden die rekombinanten Peptide so ausgewählt, dass sie entweder gegen die Mitteldarmstadien des Parasiten wirken oder mückenspezifische Rezeptoren blockieren, die der Parasit für seine weitere Entwicklung benötigt. Dabei konnte gezeigt werden, dass das antimikrobielle Molekül Harmonin, ein Abwehrmolekül aus der Hämolymphe des asiatischen Marienkäfers Harmonia axyridis, antiplasmodiale als auch transmissions-blockierende Eigenschaften besitzt. Harmonin stellt daher eine potentielle Leitstruktur für die Entwicklung neuer Malariawirkstoffe dar / Malaria is a vector-borne disease caused by the protozoan parasite of the genus Plasmodium and it is transmitted from human to human by female Anopheles mosquitoes during a blood meal. For malaria transmission to occur, the malaria parasite must undergo a crucial developmental sexual phase inside the mosquito midgut. In this study, we sought to investigate the interplay of the malaria parasite in the mosquito midgut with regard to the identification of novel types of transmission blocking intervention strategies. These strategies are aimed at reducing the spread of malaria by blocking the development of the mosquito midgut-specific stages of Plasmodium. We focused on three aspects. The first aspect was to investigate the interplay between mosquito midgut bacteria and malaria parasites in order to determine the potential influence of malaria parasites on the composition of the mosquito gut microbiota and also determine midgut bacteria which could be exploited as vehicles for the generation of paratransgenic Anopheles mosquitoes. We analyzed the microbial diversity of gut bacteria of the Asian malaria vector Anopheles stephensi during development and under different feeding regimes, including feeds on malaria parasite-infected blood, using the human pathogenic P. falciparum as well as the rodent malaria model P. berghei. 16S rRNA and DGGE analyses demonstrated a reduction in the microbial diversity during mosquito development from egg to adult and identified the gram-negative bacterium Elizabethkingia meningoseptica as the dominant species in the midgut of laboratory-reared male and female mosquitoes. E. meningoseptica is transmitted between generations and its predominance in the mosquito midgut was not altered by diet, when the gut microbiota was compared between sugar-fed and blood-fed female mosquitoes. Furthermore, feeds on blood infected with malaria parasites did not impact the presence of E. men-ingoseptica in the gut. Interestingly, extracts from E. meningoseptica exhibited antibacterial, antifungal and antiplasmodial activities, which may account for its dominance in the midgut of the malaria vector. Isolates of E. meningoseptica were cultivable, making the bacterium a potential candidate vehicle for the generation of paratransgenic Anopheles mosquitoes. The second aspect of this thesis was to determine transcriptome changes that occur during the first half hour following transmission of P. falciparum to the mosquito vector in order to better understand gene regulation mechanisms important for the change of hosts and determine novel proteins which could be exploited in malaria transmission blocking interventions. We initially used suppression subtractive hybridization (SSH) to compare mRNA levels of P. falciparum gametocytes before and 30 min fol-lowing activation. We identified a total of 126 genes for which transcript expression changed during gametogenesis. Among these, 17.5% had putative functions in signaling, 14.3% were assigned to cell cycle and gene expression, 8.7% were linked to the cytoskeleton or motor complex, 7.9% were involved in proteostasis and 6.4% in metabolism, 12.7% were genes encoding for cell surface associated proteins, 11.9% were assigned to other functions, and 20.6% represented genes of unknown function. For 40% of the identified genes there has as yet not been any protein evidence. We further selected a subset of 34 genes from all the above ontology groups and analyzed the transcript changes during gametogenesis in detail by quantitative realtime RT-PCR. Of these, 29 genes were expressed in gametocytes, and for 20 genes transcript expres-sion in gametocytes was increased compared to asexual blood stage parasites. Transcript levels of eight genes were particularly high in activated gametocytes, pointing at functions downstream of gametocyte transmission to the mosquito which could be exploited in malaria transmission blocking strategies. The last aspect of this thesis was to determine the transmission blocking effect of a range of antimicrobial molecules as transmission blocking agents. The molecules were either isolated from insect hemolymph or recombinantly expressed in tobacco and designed to act either directly on the mosquito midgut stages or cover receptors on mosquito tissues like the midgut epithelium which the parasite would need for transit. We were able to show an antiplasmodial and transmission blocking effect of the anti-microbial molecule harmonine, a defense compound isolated from the hemolymph of the Asian ladybug Harmonia axyridis. Harmonine thus represents a potential lead structure for the development of novel antimalarials.

Malariamücke

Anopheles stephensi

Mitteldarm

Malaria

Krankheitsübertragung

ddc:390

Native plants as repellents against malaria mosquitoes : ethnobotanical, behavioural & electrophysiological studies /

Waka, Maedot.

January 2005

Diss. (sammanfattning). Uppsala : Sveriges lantbruksuniv. / Härtill 4 uppsatser.

The early zygotic genes and microRNAs in the yellow fever mosquito Aedes aegypti  and the Asian malaria mosquito Anopheles stephensi

Hu, Wanqi

03 November 2014

Mosquitoes are notorious vectors for multiple diseases like malaria, yellow fever and dengue fever. To manipulate gene expression in mosquito and spread desired genes among natural population for vector control, a thorough understanding of mosquito development and gene regulation is critical. Early embryogenesis is a rapid, complex yet crucial process in the very beginning of development. Previous research in other species indicated genes transcribed that early evolved fast and played essential roles. The study of mosquito early zygotic genes (EZGs) would offer unique insights into mosquito gene evolution as well as potential targets for mosquito control. In this study, I identified 61 pure EZGs (pEZGs) in mosquito Aedes aegypti. These pEZGs were enriched in architectures adapting to the rapid embryonic cell cycles and were over represented by domains or functions related to maternal zygotic transition. Phylogenetic analysis showed that pEZGs originated mainly from duplication, retrotransposition and de novo emergence. The comparison of pEZGs in Ae. aegypti with those in Drosophila revealed an interesting evolutionary paradox where the early zygotic genes turned over fast but the regulatory motif was conserved in two species. Curiously, the motif binding protein in Drosophila (zelda) seemed unable to initiate the earliest zygotic transcription in Ae. aegypti due to late temporal expression. The regulatory motif (VBRGGTA) found in Ae. aegypti pEZGs was shown necessary and sufficient for driving early zygotic gene expression by transient reporter assays and one motif-bearing promoter was tested with success in driving gene expression as early as 2-4h after egg laying in transgenic Ae. aegypti. This was the first characterized promoter with early zygotic but no maternal expression in Ae. aegypti that can be used for future genetic studies and mosquito control strategies. As important gene regulators, miRNAs also play essential roles in early embryogenesis. The genome-wide predictions and systematic analysis of miRNAs in Ae. aegypti and Anopheles stephensi were conducted in this study. The first miRNA profiling in mosquito across all developmental stages was also performed to provide basis for future functional study. Several lineage-specific miRNAs were found highly expressed in embryos, indicating their special roles in the embryogenesis of mosquitoes. / Ph. D.

Aedes aegypti

Anopheles stephensi

early zygotic gene

cis-regulatory motif

early zygotic promoter

transgenic mosquito

microRNA

Stress thermique et thermorégulation chez lez insectes hématophages / Thermal stress and thermoregulation in haematophagous insects

Lahondère, Chloé

23 November 2012

Les insectes sont soumis aux fluctuations thermiques de leur environnement mais disposent d’un panel varié de réponses comportementales, physiologiques et biochimiques pour en minimiser les effets délétères et maintenir leur intégrité physiologique. Ainsi certaines espèces régulent activement leur température interne indépendamment de la température de l’environnement. Si ces insectes peuvent s’affranchir des contraintes thermiques imposées par leur environnement, ceux qui se nourrissent du sang chaud d’hôtes vertébrés endothermes n’ont pas d’autres choix que de se confronter à une situation de stress thermique à chaque prise alimentaire. Le principal objectif de ce travail de thèse est de comprendre comment des insectes hématophages, employant des stratégies alimentaires différentes, gèrent le stress thermique associé au flux massif de chaleur engendré par l’ingestion du repas de sang. Nos résultats montrent que ces insectes ont su s’adapter en développant différentes stratégies de thermorégulation. / Insects are submitted to thermal fluctuations of their environment and have developed a wide ranged panel of behavioral, physiological and biochemical responses, to minimize the subsequent deleterious effects and maintain their physiological integrity. Some species actively regulate their internal temperature independently of the temperature of the environment. If these insects can overcome the constraints imposed by their thermal environment, those that feed on warm-blooded vertebrate hosts have no choice but to confront a situation of thermal stress at each feeding event. The main objective of this work is to understand how bloodsucking insects manage heat stress associated with the massive flow of heat generated by the ingestion of the blood meal. Our results show these insects have developed different strategies of thermoregulation to protect themselves from overheating.

Thermorégulation

Stress thermique

Effets de la température

Insectes hématophages

Vecteurs de maladie

Rhodnius prolixus

Aedes aegypti

Anopheles stephensi

Glossina morsitans morsitans

Physiologie

Thermographie

Hétérothermie

Evaporative cooling

Alimentation artificielle

Thermoregulation processes

Thermal stress

Temperature effect

Haematophagous insects

Disease vectors

Rhodnius prolixus

Anopheles stephensi

Aedes aegypti

Glossina morsitans morsitans

Physiology

Thermography

Heterothermy

Evaporative cooling

Artificial feeding