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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Characterization of the expression patterns of the retrogene-parental gene pairs in the African malaria vector Anopheles coluzzii

Miller, Duncan Joseph 09 July 2020 (has links)
Retrogenes are a group of functional genes produced by gene retroduplication events during evolution. It has been observed that many retrogenes have formed since the evolutionary divergence of Anopheles mosquitoes from the Aedes lineage as a result of developing heteromorphic sex chromosomes. It has been further observed that these retroduplications predominately occur from parent genes on the heteromorphic X chromosome to autosomes and have a predisposition to have enriched expression in testis. In order to investigate the nature of this male-biased expression in testis, we utilized bioinformatic techniques to identify retrotransposition events and assign them relative ages based on evolutionary branches of divergence. This list of parent genes and retrogenes were then analyzed and a total of twenty-five gene pairs were selected for further examination. Available gene expression data in the form of RNA-seq and DNA microarray were used in tandem with gene annotation data to computationally investigate gene pairs in An. coluzzii. These pairs were further investigated experimentally by means of RT-PCR conducted on dissected head, thorax, abdomen, and reproductive organs in both male and female Anopheles coluzzii Mopti strain. Testis and male accessory glands (MAGs) were also investigated by this method in An. coluzzii. Available expression data support previously observed testis enriched expression of retrogenes and provides evidence for the predominate expression of retrogenes occurring in postmeiotic cells suggesting retrogene involvement in sperm development. Experimental evidence revealed a small group of five retrogenes which exhibit the expected male-biased expression in male testis with little to no expression in female ovaries, although a shared expression in the heads of both sexes was observed. Of the five retrogenes, four carry out energy related functions involving mitochondria, suggesting contribution to energy requirements of developing sperm. Testis and MAG experiments in An. coluzzii revealed a predisposition for retrogenes to be expressed in testis while parent genes tended to have higher expression in MAGs, and this phenomenon is partially supported by DNA microarray expression data. Overall, these results suggest further investigation of retrogenes in An. coluzzii may reveal unique functions in male mosquito fertility that are exploitable in genetic approaches to mosquito control. / Master of Science in Life Sciences / Malaria is a potentially deadly disease which effects thousands of people every year. Malaria around the world is spread by multiple species of mosquitoes in a genus called Anopheles. Controlling the populations of these disease spreading mosquitoes is essential to preventing the spread of malaria. Current insecticide-based approaches used to stop mosquitoes are becoming less effective overtime as mosquitoes become resistant. A potential way to develop new techniques for mosquito control is through research involving mosquito reproductive genetics. Understanding the genes involved in how mosquitoes reproduce could improve future techniques designed to reduce or prevent mosquitos from reproducing. This research focuses on a group of genes called retrogenes which have formed over the evolution of these mosquitoes via the duplication from a separate parent gene. In mosquitoes these retrogenes are understood to be involved in male reproduction. The retrogenes involved in male mosquito reproduction could have important functions in male sexual reproduction and sterility. These important genes could be manipulated to interrupt whatever important functions these genes have in reproduction. In this research we first computationally identified retrogenes and their parent genes and categorized them by age. We then utilized available annotation and expression data to analyze the potential significance of retrogenes to male fertility and found that multiple retrogenes tended to be expressed during sperm development. Lastly, we conducted gene expression experiments using dissected head, thorax, abdomen, and reproductive organs in both male and female Anopheles mosquitoes. Results revealed unique patterns of expression that suggest male specific roles of five retrogenes in testes and head expression in both males and females suggesting a possible role in mating behavior. These results provide evidence that retrogenes do have functional roles in male fertility specifically related to the maturation and development of sperm.
2

Résistance des moustiques vs virulence du parasite : étude des interactions génétiques entre le parasite humain Plasmodium falciparum et les vecteurs Anopheles gambiae et Anopheles coluzzii en conditions naturelles / Study of genetic interaction between human malaria parasite Plasmodium falciparum and natural vectors Anopheles gambiae et Anopheles coluzzii

Bayibeki Ngano, Albert 28 June 2018 (has links)
Les moustiques An. coluzzii sont des vecteurs du paludisme humain en Afrique sub- saharienne (Fontenille et al., 2003). Ils s’infectent après une prise de repas de sang chez un l’hôte humain porteur de gamétocytes. Les études sur la résistance/sensibilité d’An. coluzzii au parasite P. falciparum définissent sa compétence vectorielle (Ndiath et al., 2011 ; Fryxell et al., 2012 ; Gnémé et al., 2013 ; Boissière et al., 2013). La compétence vectorielle d’An. coluzzii au parasite P. falciparum est déterminée par des gènes pro/antiparasitaires, dont TEP1 qui montre un polymorphisme à l’origine de la résistance/sensibilité des moustiques vis-à-vis de P. berghei, parasite de rongeur (Baxter et al., 2007 ; Blandin et al., 2009). Dans nos travaux nous montrons que TEP1 est un facteur antiparasitaire majeur dans la réponse contre P. falciparum, mais n’explique pas seul la résistance/sensibilité des moustiques vis-à-vis du parasite. D’autres facteurs génétiques pro/antiparasitaires non encore déterminés seraient impliqués dans la compétence vectorielle chez les moustiques An. coluzzii. Pour identifier les gènes pro/antiparasitaires impliqués dans les interactions An. coluzzii – P. falciparum, et étudier l’effet de leur polymorphisme sur la résistance/sensibilité des moustiques vis-à-vis du parasite, nous avons réalisé sur le terrain, à Mfou au Cameroun, des infections expérimentales avec des isolats naturels de P. falciparum chez les moustiques L3-5, S1low et S1high sélectionnés pour leur résistance/sensibilité à P. berghei. Les moustiques Ngousso sont utilisés ici comme contrôle de l’infectivité des parasites. / Anopheles coluzzii mosquitoes are vectors of human malaria in sub-Saharan Africa. Still, even within a vector species, the ability of mosquitoes to carry malaria parasites varies extensively between individuals, with some mosquitoes that eliminate all parasites, and are therefore unable to transmit the disease. Polymorphism in the complement-like protein TEP1 was shown to contribute to determine mosquito susceptibility to the murine malaria parasite P. berghei (Blandin et al., 2009) as well as to the human malaria parasite P. falciparum (White et al., 2010). Still, we demonstrated that TEP1 alone could not fully explain mosquito resistance and we set up to identify additional genetic factors that determine mosquito vector competence in the Ngousso line that was recently colonised in Cameroon and whose phenotype range varies extensively when exposed to P. berghei infection. To be independent from variations in the TEP1 locus, we first selected a parental line homozygous for a single TEP1 allele, TEP1*S1, that was previously linked to mosquito susceptibility. We then created isofemale families and selected them according to their phenotype upon infection with the murine malaria parasite P. berghei over several generations to create two lines carrying either many (S1high) or few (S1low) parasites. To identify the regions of the genomes that are linked to this phenotypic difference, we performed crosses and QTL mapping. To test whether the phenotypic difference selected upon P. berghei infections was conserved for P. falciparum, we subjected our two lines to blood meals infected with natural isolates of the human parasite collected in Cameroon. Results of the selection process and field infections will be presented.

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