Spelling suggestions: "subject:"anopheles gambia"" "subject:"anopheles0 gambia""
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Native plants as repellents against malaria mosquitoes : ethnobotanical, behavioural & electrophysiological studies /Waka, Maedot. January 2005 (has links)
Diss. (sammanfattning). Uppsala : Sveriges lantbruksuniv. / Härtill 4 uppsatser.
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Biology of the malaria vector Anopheles gambiae: behavioral and reproductive components of sugar feedingGary, Richard Eugene, Jr. 13 July 2005 (has links)
No description available.
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Plant Semiochemicals as Mosquito AttractantsOtienoburu, Philip E. 20 October 2011 (has links)
No description available.
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Chromosome evolution and mechanisms of speciation in the Anopheles gambiae complexLiang, Jiang-tao 01 June 2020 (has links)
Malaria is a life-threatening disease caused by Plasmodium parasites that are transmitted through the bites of infected females of a few Anopheles mosquito species. Understanding the chromosome evolution and mechanisms of speciation can shed light on developing novel ecological-friendly vector control techniques. Sibling species of the An. gambiae complex provide an excellent model system for these topics.
To understand the mechanisms of speciation, we investigated the cellular basis and phenotypes of hybrid male sterility in species crosses of the An. gambiae complex. By performing inter-species crosses of An. coluzzii/An. gambiae and An. merus lab strains, we found an asymmetric pattern of hybrid male sterility existed in sons from reciprocal interspecies crosses. Compared with pure species, hybrid males from crosses of ♀An. merus ♂An. gambiae/An. coluzzii were normal in the morphology of male reproductive tracts; however, the testes of which that process the reductional meiotic division failed to produce primary spermatocytes and were accompanied with unpaired and insufficiently condensed chromosomes. As a result, primary spermatocytes undergo a mitosis-like anaphase division, producing nonmotile and malfunctional diploid sperm with two tails. However, individuals can mate with females normally and form the mating plug to induce the female monogamy. In contrast, hybrid males from the opposite crosses manifest severely underdeveloped reproductive tracts and a premeiotic arrest of germline stem cells in the testis, accompanied by a strong suppression of premeiotic and meiotic genes. In addition, hybrid males from this cross suffered from a shorter copulation time and failed to form mating plugs to induce female monogamous behaviors, albeit the expression of male accessory gland specific genes were similar between hybrids and pure species.
To figure out chromosome evolution in the An. gambiae complex, we studied the molecular organization of heterochromatin and investigated the spatial organizations of autosomal regions of polytene chromosomes in soma and germline cells. We found that molecular composition of pericentrometric autosome and sex chromosome repetitive DNA differs among sibling species of An. gambiae complex with highly similarity between An. coluzzii and An. arabiensis. In addition, heterochromatin blocks of chromosomes have distinct compositions of satellite DNA sequences. Next, in order to address the relationship between inter-chromosomal (Chr-Chr) contacts and chromosome-nuclear envelope (Chr-NE) attachments during the development of the organism, we conducted microscopic analyses of the 3D organization of polytene chromosome in An. gambiae, An. coluzzii, and An. merus. Our quantitative study on chromosome territories in larval salivary gland cells and adult ovarian nurse cells showed that, compared with autosomal arms, the X chromosome has a significantly smaller volume and occupies more compact territories. The number of Chr-Chr contacts and the percentage of Chr-NE attachment were conserved among the species within the same cell type. Our data also demonstrated that there is a significantly and consistently inverse relationship between the frequencies of Chr–NE and Chr–Chr attachments on autosomes of two cell types in all tested species. / Doctor of Philosophy / Malaria is a life-threatening disease caused by Plasmodium parasites that are transmitted through the bites of infected females of a few Anopheles mosquito species. Despite being treatable and preventable, malaria is estimated to cause large numbers of deaths every year. Since 2015, the malaria elimination program has stalled largely due to increased insecticide resistance. Novel transgenic techniques have a huge potential in reducing malaria transmission more effectively. However, there are large concerns about the potential negative effects of releasing genetically modified mosquitoes, such as a possibility of accidental spread to non-target species with incomplete reproductive barriers and unpredicted ecological damage. Understanding the mechanisms of speciation about how reproductive isolation occurred and developed as well as chromosome evolution can not only empower the development of ecologically friendly vector control techniques but also improve our basic knowledge.
To study mechanisms of speciation, we mated males and females from different closely related species in the Anopheles gambiae complex to investigate the fecundity of hybrid generations. Our study identified two different types of reproductive abnormalities leading to hybrid male sterility. Hybrid males from female An. merus and male An. gambiae or An. coluzzii have normal appearing testes and male accessary glands but the testes produce abnormal sperms, which cannot move and have two tails. Hybrid males from female An. gambiae or An. coluzzii and An. merus have severely underdeveloped testes and male accessary glands. The sperm producing process stops unusually very early in their tiny underdeveloped testes.
We also investigated chromosome evolution in species of An. gambiae complex. We found that chromosomal parts containing repetitive DNA, the sequence in the genome not producing proteins, evolve rapidly in An. coluzzii, An. arabiensis, An. quadriannulatus, and An. merus. In contrast, chromosome territories of gene rich regions in giant polytene chromosomes from larval salivary gland cells and adult ovarian nurse cells of An. gambiae, An. coluzzii, and An. merus, were relatively conserved within the same cell type among different species. However, the chromosomal 3D distribution pattern is different among various cell types in these species.
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Revisiting aryl N-methylcarbamate acetylcholinesterase inhibitors as potential insecticides to combat the malaria-transmitting mosquito, Anopheles gambiaeHartsel, Joshua Alan 31 May 2011 (has links)
My graduate work focused on the syntheses and pharmacology of species-selective aryl methylcarbamate acetylcholinesterase inhibitors to combat the malaria-transmitting mosquito, Anopheles gambiae. We identified six novel carbamates that demonstrated levels of target selectivity exceeding our project milestone of 100-fold. Among the C2-substituted phenylcarbamates examined (class II), 2'-(2- ethylbutoxy)phenyl N-methylcarbamate (9bd*) was extraordinarily selective (570-fold ± 72). The high level of selectivity observed for many of the class II carbamates was attributed to a helical displacement within the active site of An. gambiae acetylcholinesterase, able to accommodate carbamates with larger C2-substituted secondary β-branching side chains. Conversely, this type of side chain forms unfavorable interactions within the active site of human acetylcholinesterase. The C3-substituted carbamates (class I), such as terbam (9c), were less selective than many of the class II carbamates; however, class I carbamates related to terbam (9c) were highly toxic to An. gambiae. In particular, the contact toxicity measured for 9c (LC₅₀ = 0.037 mg/mL) was equal to the commonly used agricultural insecticide, propoxur (9a, LC₅₀ = 0.037 mg/mL). In total, seventy aryl carbamates were screened for their inhibition potency and contact toxicity towards An. gambiae.
The common final step in all of these syntheses was the carbamoylation of a phenol, which normally proceeded in a 70 to 90% yield. Thirty seven novel carbamates are reported out of the seventy two prepared. Although sixteen of the phenols were commercially available, the others were prepared with known and adapted synthetic methodologies. The emerging structure-activity relationships led us to focus on the synthesis of 3-tert-alkylphenols (Class I) and 2-alkoxy or 2-alkylthio-substituted phenols (Class II). Three methods particularly stand out: First, we applied the methods of Tanaka to prepare 3-tert-alkylphenols wherein a methyl group was replaced by a trifluoromethyl group. Second, we adapted the methods of Tanaka to prepare 3-tert-alkylphenols that lack fluorine substitution. This method is competitive with the little known method of Reetz to convert aryl ketones to the corresponding 1,1-dimethylalkyl group and allows one to access electron rich tert-alkyl-substituted aromatics that are not accessible by the Friedel-Crafts alkylation (Friedel-Crafts restricted). Third, we found a convenient and high-yielding method for selective S-alkylation of 2-mercaptophenol. In addition to the synthesis of carbamates, the preparation of one hundred three intermediates, phenols, and electron rich tert-alkyl arenes are reported. / Ph. D.
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Oviposition cues as a tool for developing a new malaria control strategyEneh, Lynda January 2016 (has links)
Anopheles gambiae sensu lato mosquitoes are among the dominant malaria vectors in sub-Saharan Africa. However, not much is known about the oviposition behaviour of these species necessary for the development of malaria vector control strategies. With the aim of investigating cues associated with selected oviposition sites, artificial oviposition sites- ponds (soil mixed with water) were set-up in an open field at Mbita, Western Kenya in 2012 and 2013. Ponds were allowed to be colonized by wild An. gambiae s.l.. The numbers of Anopheles early instar larvae were counted and used as a proxy for oviposition preference. Water samples were then analysed for physicochemical, bacterial and chemical profiles. The bacterial profiles were analysed using denaturing gradient gel electrophoresis (DGGE) and the chemical profiles with gas chromatography-mass spectrometry (GC-MS). The detection of possible oviposition cues from oviposition substrates requires sensitive analytical methods. Volatiles detection was improved seven times. The detection of bacteria deoxyribonucleic acid (DNA) bands with DGGE was also improved to a minimum DNA concentration of 50 ng/µl. Results showed that ponds were colonized differently. Fresh ponds were preferred over slightly older ponds. Bacterial analysis revealed a low number of bacteria colony forming units (CFU) in preferred ponds. Some volatiles, including: 6,10-dimethyl-5,9-undecadien-2-one (geranylacetone) and 4-ethylbenzaldehyde, were associated with the oviposition preferred pond. In addition, low pH and high turbidity were associated with the ponds selected for oviposition. Finally, fungi isolated from the rhizomes of nut grass yielded a promising array of volatiles of which one is known to attract oviposition site seeking malaria mosquitoes. This finding opens the door for a cost effective and environmental friendly method of using fungi in an “attract and kill” strategy targeting malaria vectors. / Myggor i Anopheles gambiae sensu lato komplexet tillhör de myggor som är bäst på att sprida malaria parasiter i afrika söder om Sahara. Kunskapen om de här myggornas äggläggningsbeteende är begränsad. Den här kunskapen behövs för att kunna utveckla nya och förbättra tillgängliga malaria vektor kontroll metoder. Nya metoder som kan komplettera de som används idag (insecticides treated nets (ITNs) och indoor residual spraying (IRS)) behövs eftersom de metoderna har problem med resistensutveckling. Två studier utfördes på icipe fältstation i Mbita västra Kenya under 2012 och 2013 med målet att identifiera faktorer som påverkar myggornas äggläggningsbeteende. Baljor fyllda med en blandning av jord och vatten (äggläggningssubstrat) användes för att tillverka artificiella äggläggningsplatser som liknar de vattenpölar som de här myggarterna gärna lägger ägg i. Baljorna koloniserades av vilda myggor och antalet mygglarver som detekterades i baljorna jämfördes och användes som en proxy för äggläggningspreferens. Fysikaliska och kemiska parametrar mättes på jordvattenblandningarna i baljorna och prover togs för att analysera bakteriepopulationer med hjälp av denaturing gradient gel electrophoresis (DGGE) och flyktiga ämnen med hjälp av gas-kromatografi kopplat till mass-spektrometri (GC-MS). För att kunna detektera de låga halter av flyktiga ämnen och bakterier som fanns i de här proverna krävdes det känsliga metoder. Antalet flyktiga ämnen som kunde detekteras ökades sju gånger genom att tillsätta NaCl till vattenproverna innan doften insamlades och termisk desorption användes istället för lösningsmedels desorption. För att förbättra detektionsgränsen för bakterier amplifierades bakterie-DNA i två PCR reaktioner som sedan mixades och koncentrerades. Resultaten från fältstudierna med baljorna visade att de koloniserades olika av Anopheles myggorna. Baljor med nyblandat substrat innehöll dubbelt så många mygglarver som baljor med jord-vattensubstrat som åldrats under en längre tid. Lägre mängd bakterier, lägre pH och högre grumlighet var gemensamt för de baljor som myggorna föredrog. De flyktiga ämnen som detekterades i de olika baljor varierade mellan olika försök och inget ämne fanns med i alla upprepningar av ett försök. Trots det detekterades några ämnen oftare i de baljor som myggorna föredrog att lägga ägg jämfört med de med en mindre mängd mygglarver. De inkluderar geranylacetone och 4-ethylbenzaldehyde. Svampar isolerades från rotstockar av gräs som fanns i den jord som användes för att göra äggläggningssubstraten i fältstudierna. De flyktiga ämnen som avgavs från svampkulturerna analyserades. Bland annat så identifierades ett ämne som fungerar som en äggläggningsattrahent för An. gambiae s.l. myggor.Resultaten från den här avhandlingen kommer att kunna användas för att utveckla miljövänliga ”attract and kill” metoder för att kontrollera malaria myggor. / <p>QC 20160211</p>
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Variation in the Anopheles gambiae TEP1 Gene Shapes Local Population Structures of Malaria MosquitoesRono, Evans Kiplangat 24 November 2017 (has links)
Die Allele (*R1, *R2, *S1 und *S2) des A. gambiae complement-like thioester-containing Protein 1 (TEP1) bestimmen die Fitness der Mücken, welches die männlichen Fertilität und den Resistenzgrad der Mücke gegen Pathogene wie Bakterien und Malaria-Parasiten. Dieser Kompromiss zwischen Reproduktion und Immunnität hat Auswirkungen auf die Größe der Mückenpopulationen und die Rate der Malariaübertragung. Wie die genetische Diversität von TEP1 die genetische Struktur natürlicher Vektorpopulationen beeinflusst, ist noch unklar. Die Zielsetzung dieser Doktorarbeit waren: i) die biogeographische Kartographierung der TEP1 Allele und Genotypen in lokalen Malariavektorpopulationen in Mali, Burkina Faso, Kamerun, und Kenia, und ii) die Bemessung des Einflusses von TEP1 Polymorphismen auf die Entwicklung humaner P. falciparum Parasiten in der Mücke. Die Analysen der TEP1 Polymorphismen zeigten, dass die natürliche Selektion auf Exone, sowie Introne wirkt, was auf eine starke funktionale Beschränkung an diesem Lokus hindeutet. Außerdem zeigen unsere Daten die strukturierte Erhaltung natürlicher genetischer Variation im TEP1 Lokus, in welchem die Allele und Genotypen spezifische evolutionäre Wege verfolgen. Diese Ergebnisse weisen auf die Existenz von arten- und habitatspezifischen Selektionsdrücken hin, die auf den TEP1 Lokus wirken. Resultate haben gezeigt, dass TEP1*S1 und *S2 Mücken gleichermassen empfänglich für Plasmodium-Infektionen sind. Insgesamt tragen die Resultate der biogeographischen Kartographierung des TEP1 Lokus und der Züchtungs- und Infektionsexperimente zu einem besseren Verständnis über den Einfluss der verschiedenen Vektorarten und lokale Umwelteinflüsse auf die Vektorpopulationen und Malariaübertragung bei. Des weiteren kann die hier beschriebene hochdurchsatz-genotypisierungs Methode, zur Studie lokaler A. gambiae Mückenpopulationen, in der Feldforschungsarbeit eingesetzt werden. Dieser neue Ansatz wird die epidemiologisch relevante Überwachung und Vorhersage dynamischer Prozesse in lokalen Malariavektorpopulationen unterstützen, welche die Entwicklung neuer Strategien der Vektorkontrolle ermöglichen könnten. / The alleles (*R1, *R2, *S1 and *S2) and genotypes of A. gambiae complement-like thioester-containing protein 1 (TEP1) determine the fitness in male fertility and the degree of mosquito resistance to pathogens such as bacteria and malaria parasites. This trade-off between the reproduction and the immunity impacts directly on mosquito population abundance and malaria transmission respectively. How TEP1 genetic diversity influences the genetic structure of natural vector populations and development of human malaria parasites is unclear. The aims of this thesis were to: i) map distribution of TEP1 alleles and genotypes in local malaria vector populations in Mali, Burkina Faso, Cameroon and Kenya, and ii) assess the impact of TEP1 polymorphism on development of human P. falciparum parasites in mosquitoes. Analyses of TEP1 polymorphism revealed that natural selection acts in concert on both exons and introns, suggesting strong functional constrains acting at this locus. Moreover, our data demonstrate a structured maintenance of natural TEP1 genetic variation, where the alleles and the genotypes follow distinct evolutionary paths. These findings suggest the existence of species- and habitat-specific selection patterns that act on TEP1 locus. Results revealed that the TEP1*S1 and *S2 mosquitoes are equally susceptible to Plasmodium infections. Collectively, results of my thesis on the biogeographic TEP1 mapping, and on the breeding and infection experiments contribute to a better understanding of how the vector species and local environmental factors, shape vector population structures and malaria transmission. Furthermore, the high throughput TEP1 genotyping approach reported here could be used for field studies of local A. gambiae mosquito populations. This new approach will benefit surveilance and prediction of dynamics in local malaria vector populations that may have epidemiological significance, and therefore inform the development of novel vector control measures.
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Elementos de transposición en el genoma de Anopheles gambiae / Transposable elements in the genome of Anopheles gambiaeFernández Medina, Rita Daniela January 2009 (has links)
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Previous issue date: 2009 / Até hoje não existem mecanismos eficientes de controle da malaria, uma das doenças infecciosas mais importantes do mundo. Nas últimas décadas, a
transformação genética dos mosquitos transmissores tem sido proposta como uma alternativa para o controle de esta doença. Para isso, além do desenvolvimento de técnicas para a introdução de DNA em células germinais dos mosquitos e da identificação de genes capazes de bloquear ou reduzir a transmissão de parasitas aos humanos, é necessário o desenvolvimento de
métodos eficientes para a introdução e fixação de genes refratários à malaria nas populações naturais de mosquitos. O uso de elementos de transposição tem sido sugerido para tais fins pelas características biológicas de invasão e
propagação em genomas eucariotas que presentão estes elementos. Na presente tese, analisaram-se os elementos de transposição presentes no
genoma do mosquito Anopheles gambiae, um dos principais vetores da malaria no mundo. Os resultados apresentados se encontram divididos em três partes, primeiramente a descrição de AnoTExcel, uma base de dados com informação
detalhada dos elementos de transposição presentes neste genoma. Por outra, a partir desta base, foram identificados e caracterizados elementos novos, não detectados previamente em nenhum genoma. Por último, foram analisados elementos representativos pertencentes às diferentes classes de elementos de transposição desde uma perspectiva evolutiva e foi proposta uma análise de redes (Network analysis) para inferir as inter-relações entre elementos de transposição pertencentes à mesma família. / Up today, there are no efficient mechanisms for the control of Malaria, one of the most important diseases in the world. In the last decades, the genetic transformation of the malaria vectors have been proposed as an alternative. For achieving so, besides the development of techniques for the introduction of foreign DNA into the mosquitoes germinal cells and the identification of genes able to block or reduced the parasites transmission to human, the development of efficient methods for the introduction and fixation of the refractory genes into the mosquitoes natural populations is needed. In this regard, the use of transposable elements has been suggested as a driver system due to their biological characteristics of eukaryotic genomes invasion and propagations.
In this thesis the analysis of the transposable elements in the genome of Anopheles gambiae, one of the most important vectors of malaria, has been
proposed. The results are divided in three parts, first of all a description of AnoTExcel, a
database with detailed information of the transposable elements present in the mosquito genome. The characterization of Novel elements that have not been described before is also described. Last, an evolutionary analysis of
representative elements from different classes and families of elements has been performed. Finally, we have also proposed a network analysis for inferring the relationships between elements within the same family.
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Distribution nationale de moustiquaires imprégnées d'insecticide au Niger : effets sur les anophèles vecteursCzeher, Cyrille 02 July 2010 (has links) (PDF)
Une distribution nationale de moustiquaires imprégnées d'insecticide à longue durée d'action à destination des populations vulnérables du Niger a été effectuée fin 2005. Déjà montrée lors d'études pilotes à l'échelle du village, l'efficacité de cet outil dans le contrôle du paludisme restait à évaluer à l'occasion de vastes programmes opérationnels qui se multiplient en Afrique. Peu d'études des populations de vecteurs ont été publiées dans ce cadre. Nous avons mis en place un suivi entomologique au niveau de sites sentinelles répartis dans la zone Sahélienne du Niger, ayant couvert trois saisons de transmission, dont une avant intervention considérée comme période contrôle. Les paramètres entomologiques de la transmission ont été déterminés pour An. gambiae s.l., et la distribution spatiale des deux principaux vecteurs, An. gambiae et An. arabiensis, a été précisée. Le suivi temporel a mis en évidence une baisse globale du niveau de transmission de P. falciparum, probablement entrainée par la forte hausse d'utilisation de moustiquaires imprégnées. Cependant la hausse de la résistance des populations aux pyréthrinoïdes semble avoir été rapidement amorcée faisant craindre à moyen terme une perte d'efficacité de cet outil central des stratégies de lutte contre le paludisme. L'étude de la structure génétique des populations d'An. gambiae et d'An. arabiensis à l'aide de marqueurs microsatellites a montré une homogénéité génétique dans l'espace, entre les villages, même séparés par plusieurs centaines de kilomètres, ainsi que dans le temps, entre la saison de transmission 2005 contrôle et la saison 2006 après distribution. Ces résultats ont suggéré qu'au cours de la première année d'intervention, la couverture en moustiquaires imprégnées atteinte n'a pas eu d'effet de masse suffisant pour entrainer une baisse de la diversité génétique ou une modification des fréquences alléliques des populations. La faible différenciation spatiale observée pourrait être expliquée par des échanges de gènes importants à l'intérieur de la zone d'étude, hypothèse appuyée par l'expansion rapide de la mutation kdr dans l'ensemble des sites où An. gambiae est présent. L'évaluation rigoureuse de tels programmes de contrôle permettra d'améliorer les outils de contrôle et par exemple de préserver l'efficacité des pyréthrinoïdes, seule classe d'insecticides actuellement disponible pour l'imprégnation des moustiquaires.
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Identification and characterization of microRNAs and their putative target genes in Anopheles funestus s.sAli, Mushal Allam Mohamed Alhaj January 2013 (has links)
Philosophiae Doctor - PhD / The discovery of microRNAs (miRNAs) is one of the most exciting scientific
breakthroughs in the last decade. miRNAs are short RNA molecules that do not encode proteins but instead, regulate gene expression. Over the past several years, thousands of miRNAs have been identified in various insect genomes through cloning and sequencing, and even by computational prediction. However, information concerning possible roles of miRNAs in mosquitoes is limited. Within this context, we report here the first systematic analysis of these tiny RNAs and their target mRNAs in one of the principal African malaria vectors, Anopheles funestus s.s. Firstly, to extend the known repertoire of miRNAs expressed in this insect, the small RNAs from the four developmental stages (egg, larvae, pupae
and the adult females), were sequenced using next generation sequencing
technology. A total of 98 miRNAs were identified, which included 65 known Anopheles miRNAs, 25 miRNAs conserved in other insects and 8 novel miRNAs that had not been reported in any species. We further characterized new variants for miR-2 and miR-927 and stem-loop precursors for miR-286 and miR-2944. The analysis showed that many miRNAs have stage-specific expression, and co-transcribed and co-regulated during development. Secondly, for a better understanding of the molecular details of the miRNAs function, we identified the target genes for the Anopheles miRNAs using a novel approach that identifies overlap genes among three target prediction tools followed by filtering genes based on functional enrichment of GO terms and KEGG pathways. We found that most of the miRNAs are metabolic regulators. Moreover, the results suggest implication
of some miRNAs not only in the development but also in insect-parasite interaction.
Finally, we developed the InsecTar database (http://insectar.sanbi.ac.za) for miRNA targets in the three mosquito species; Anopheles gambiae, Aedes aegypti, and Culex quinquefasciatus, which incorporates prediction and the functional analysis of these target genes. The proposed database will undoubtedly assist to explore the roles of these regulatory molecules in insects. This type of analysis is a key step towards improving our understanding of the complexity and regulationmode of miRNAs in mosquitoes. Moreover, this study opens the door for exploration of miRNA in regulation of critical physiological functions specific to vector arthropods which may lead to novel approaches to combat mosquito-borne infectious diseases.
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