Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species

Malaria is the main cause of approximately one million deaths every year that mostly affect children in south of Sub-Saharan Africa. The Anopheles gambiae complex consists of seven morphologically indistinguishable sibling species. However, their behavior, ecological adaptations, vectorial capacity,...

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Main Author: Kamali, Maryam
Other Authors: Entomology
Format: Others
Published: Virginia Tech 2014
Subjects:
Online Access:http://hdl.handle.net/10919/51040
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spelling ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-510402021-03-24T05:37:42Z Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species Kamali, Maryam Entomology Sharakhov, Igor V. Dickerman, Allan W. Tu, Zhijian Jake Sharakhova, Maria V. Fell, Richard D. Anopheles spp. chromosomal and molecular phylogeny microsatellites Malaria is the main cause of approximately one million deaths every year that mostly affect children in south of Sub-Saharan Africa. The Anopheles gambiae complex consists of seven morphologically indistinguishable sibling species. However, their behavior, ecological adaptations, vectorial capacity, and geographical distribution differ. Studying the phylogenetic relationships among the members of the complex is crucial to understanding the genomic changes that underlie evolving traits. These evolutionary changes can be related to the gain or loss of human blood choice or to other epidemiologically important traits. In order to understand the phylogenetic relationships and evolutionary history of the members of the An. gambiae complex, breakpoints of the 2Ro and 2Rp inversions in An. merus and their homologous sequence in the outgroup species were analyzed using fluorescent in situ hybridization (FISH), library screening, whole-genome mate-paired sequencing and bioinformatics analysis. Molecular phylogenies of breakpoint genes were constructed afterwards. In addition, multigene phylogenetic analyses of African malaria vectors were performed. Our findings revised the chromosomal phylogeny, and demonstrated the ancestry of 2Ro, 2R+p and 2La arrangements.  Our new chromosomal phylogeny strongly suggests that vectorial capacity evolved repeatedly in members of the An. gambiae complex, and the most important vector of malaria in the world, An. gambiae, is more closely related to ancestral species than was previously thought. Our molecular phylogeny data were in agreement with chromosomal phylogeny, indicating that the position of the genetic markers with respect to chromosomal inversion is important for interpretation of the  <br />phylogenetic trees. Multigene phylogenetic analysis revealed that a malaria mosquito from humid savannah and degraded rainforest areas, An. nili, belongs to the basal clade and is more distantly related to other major African malaria vectors than was assumed previously. Finally, for the first time a physical map of 12 microsatellite markers for the Asian malaria vector An. stephensi was developed. Knowledge about the chromosomal position of microsatellites was shown to be important for a proper estimation of population genetic parameters. In conclusion, our study improved understanding of genetics and evolution of some of the major malaria vectors in Africa and Asia.<br /><br /> Ph. D. 2014-12-06T07:00:10Z 2014-12-06T07:00:10Z 2013-06-13 Dissertation vt_gsexam:1198 http://hdl.handle.net/10919/51040 In Copyright http://rightsstatements.org/vocab/InC/1.0/ ETD application/pdf Virginia Tech
collection NDLTD
format Others
sources NDLTD
topic Anopheles spp.
chromosomal and molecular phylogeny
microsatellites
spellingShingle Anopheles spp.
chromosomal and molecular phylogeny
microsatellites
Kamali, Maryam
Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
description Malaria is the main cause of approximately one million deaths every year that mostly affect children in south of Sub-Saharan Africa. The Anopheles gambiae complex consists of seven morphologically indistinguishable sibling species. However, their behavior, ecological adaptations, vectorial capacity, and geographical distribution differ. Studying the phylogenetic relationships among the members of the complex is crucial to understanding the genomic changes that underlie evolving traits. These evolutionary changes can be related to the gain or loss of human blood choice or to other epidemiologically important traits. In order to understand the phylogenetic relationships and evolutionary history of the members of the An. gambiae complex, breakpoints of the 2Ro and 2Rp inversions in An. merus and their homologous sequence in the outgroup species were analyzed using fluorescent in situ hybridization (FISH), library screening, whole-genome mate-paired sequencing and bioinformatics analysis. Molecular phylogenies of breakpoint genes were constructed afterwards. In addition, multigene phylogenetic analyses of African malaria vectors were performed. Our findings revised the chromosomal phylogeny, and demonstrated the ancestry of 2Ro, 2R+p and 2La arrangements.  Our new chromosomal phylogeny strongly suggests that vectorial capacity evolved repeatedly in members of the An. gambiae complex, and the most important vector of malaria in the world, An. gambiae, is more closely related to ancestral species than was previously thought. Our molecular phylogeny data were in agreement with chromosomal phylogeny, indicating that the position of the genetic markers with respect to chromosomal inversion is important for interpretation of the  <br />phylogenetic trees. Multigene phylogenetic analysis revealed that a malaria mosquito from humid savannah and degraded rainforest areas, An. nili, belongs to the basal clade and is more distantly related to other major African malaria vectors than was assumed previously. Finally, for the first time a physical map of 12 microsatellite markers for the Asian malaria vector An. stephensi was developed. Knowledge about the chromosomal position of microsatellites was shown to be important for a proper estimation of population genetic parameters. In conclusion, our study improved understanding of genetics and evolution of some of the major malaria vectors in Africa and Asia.<br /><br /> === Ph. D.
author2 Entomology
author_facet Entomology
Kamali, Maryam
author Kamali, Maryam
author_sort Kamali, Maryam
title Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
title_short Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
title_full Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
title_fullStr Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
title_full_unstemmed Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
title_sort application of chromosome mapping to understanding evolutionary history of anopheles species
publisher Virginia Tech
publishDate 2014
url http://hdl.handle.net/10919/51040
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