Browsing by Author "Sharakhov, Igor V."

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    2D and 3D Chromosome Painting in Malaria Mosquitoes
    George, Phillip; Sharma, Atashi; Sharakhov, Igor V. (Journal of Visualized Experiments, 2014-01-01)
    Fluorescent in situ hybridization (FISH) of whole arm chromosome probes is a robust technique for mapping genomic regions of interest, detecting chromosomal rearrangements, and studying three-dimensional (3D) organization of chromosomes in the cell nucleus. The advent of laser capture microdissection (LCM) and whole genome amplification (WGA) allows obtaining large quantities of DNA from single cells. The increased sensitivity of WGA kits prompted us to develop chromosome paints and to use them for exploring chromosome organization and evolution in non-model organisms. Here, we present a simple method for isolating and amplifying the euchromatic segments of single polytene chromosome arms from ovarian nurse cells of the African malaria mosquito Anopheles gambiae. This procedure provides an efficient platform for obtaining chromosome paints, while reducing the overall risk of introducing foreign DNA to the sample. The use of WGA allows for several rounds of re-amplification, resulting in high quantities of DNA that can be utilized for multiple experiments, including 2D and 3D FISH. We demonstrated that the developed chromosome paints can be successfully used to establish the correspondence between euchromatic portions of polytene and mitotic chromosome arms in An. gambiae. Overall, the union of LCM and single-chromosome WGA provides an efficient tool for creating significant amounts of target DNA for future cytogenetic and genomic studies.
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    Aedes aegypti Heat Shock 70 Genes and their Inducible Promoters
    Gross, Tiffany Lauren (Virginia Tech, 2011-07-11)
    Aedes aegypti is an important vector of the viruses that cause dengue fever, dengue hemorrhagic fever, and yellow fever. In depth genetic studies of vector species have been made possible due to the availability of genome sequences and techniques for producing stably transformed mosquitoes. These resources have also contributed to the establishment of new genetics-based approaches to the control of vector borne disease. Genetic studies of Ae. aegypti have benefited from the ability to drive targeted transgene expression, however a ubiquitous inducible promoter has not been identified in this mosquito. The Drosophila melanogaster heat shock 70 promoter has been shown to drive inducible expression in heterologous systems; however, DmHsp70 possesses significant basal activity in Aedes aegypti. This study characterized the sequence and expression of the heat shock 70 genes of Aedes aegypti. AaHsp70 genes were found to be organized in two clusters, each comprised of three divergent pairs. AaHsp70 genes exhibited robust expression upon heat shock in larvae, pupae, and adults as well as in heads, salivary glands, midguts and ovaries. Genomic regions upstream of AaHsp70 genes were found to drive heat-inducible expression of a reporter in both cell and embryo assays. Deletion analysis of AaHsp70-derived promoters yielded two ~1.5 kb genomic fragments that maintained robust heat inducibility in these systems. Aedes aegypti were transformed with AaHsp70-luciferase gene cassettes using the transposable element Mos1. AaHsp70-luciferase transcripts accumulated specifically after heat shock, and displayed a pattern of rapid induction and decay similar to endogenous AaHsp70 genes. Heat-induced expression of luciferase was observed in transgenic larvae, pupae and adults as well as heads, midguts and ovaries but not salivary glands, with levels varying between transgenic strains. The effect of heat shock on the endogenous RNAi pathway as well as the effect of blood feeding on the expression of AaHsp70 genes was investigated, though reproducible results could not be obtained using the assays employed. In conclusion, the heat shock 70 gene family of Aedes aegypti was identified and characterized. The AaHsp70 promoters described could be valuable for gene function studies as well as for the precise timing of the expression of anti-pathogen molecules.
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    Analysis of the Aedes albopictus C6/36 genome provides insight into cell line utility for viral propagation
    Miller, Jason R.; Koren, Sergey; Dilley, Kari A.; Puri, Vinita; Brown, David M.; Harkins, Derel M.; Thibaud-Nissen, Françoise; Rosen, Benjamin D.; Xiao-Guang, Chen; Tu, Zhijian Jake; Sharakhov, Igor V.; Sharakhova, Maria V.; Sebra, R.; Stockwell, T. B.; Bergman, N. H.; Sutton, G. G.; Phillippi, A. M.; Pieemarini, P. M.; Shabman, R. S. (2018-03)
    The 50-year old Aedes albopictus C6/36 cell line is a resource for the detection, amplification, and analysis of mosquito-borne viruses including Zika, dengue, and chikungunya. The cell line is derived from an unknown number of larvae from an unspecified strain of Aedes albopictus mosquitoes. Toward improved utility of the cell line for research in virus transmission, we present an annotated assembly of the C6/36 genome.
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    Anopheles mosquitoes reveal new principles of 3D genome organization in insects
    Lukyanchikova, Varvara; Nuriddinov, Miroslav; Belokopytova, Polina; Taskina, Alena; Liang, Jiangtao; Reijnders, Maarten J. M. F.; Ruzzante, Livio; Feron, Romain; Waterhouse, Robert M.; Wu, Yang; Mao, Chunhong; Tu, Zhijian Jake; Sharakhov, Igor V.; Fishman, Veniamin (Nature Portfolio, 2022-04-12)
    Chromosomes are hierarchically folded within cell nuclei into territories, domains and subdomains, but the functional importance and evolutionary dynamics of these hierarchies are poorly defined. Here, we comprehensively profile genome organizations of five Anopheles mosquito species and show how different levels of chromatin architecture influence each other. Patterns observed on Hi-C maps are associated with known cytological structures, epigenetic profiles, and gene expression levels. Evolutionary analysis reveals conservation of chromatin architecture within synteny blocks for tens of millions of years and enrichment of synteny breakpoints in regions with increased genomic insulation. However, in-depth analysis shows a confounding effect of gene density on both insulation and distribution of synteny breakpoints, suggesting limited causal relationship between breakpoints and regions with increased genomic insulation. At the level of individual loci, we identify specific, extremely long-ranged looping interactions, conserved for similar to 100 million years. We demonstrate that the mechanisms underlying these looping contacts differ from previously described Polycomb-dependent interactions and clustering of active chromatin.
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    Application of Chromosome Mapping to Understanding Evolutionary History of Anopheles Species
    Kamali, Maryam (Virginia Tech, 2013-06-13)
    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  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.
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    Arm-specific dynamics of chromosome evolution in malaria mosquitoes
    Sharakhova, Maria V.; Xia, Ai; Leman, Scotland C.; Sharakhov, Igor V. (Biomed Central, 2011-04-07)
    Background: The malaria mosquito species of subgenus Cellia have rich inversion polymorphisms that correlate with environmental variables. Polymorphic inversions tend to cluster on the chromosomal arms 2R and 2L but not on X, 3R and 3L in Anopheles gambiae and homologous arms in other species. However, it is unknown whether polymorphic inversions on homologous chromosomal arms of distantly related species from subgenus Cellia nonrandomly share similar sets of genes. It is also unclear if the evolutionary breakage of inversion-poor chromosomal arms is under constraints. Results: To gain a better understanding of the arm-specific differences in the rates of genome rearrangements, we compared gene orders and established syntenic relationships among Anopheles gambiae, Anopheles funestus, and Anopheles stephensi. We provided evidence that polymorphic inversions on the 2R arms in these three species nonrandomly captured similar sets of genes. This nonrandom distribution of genes was not only a result of preservation of ancestral gene order but also an outcome of extensive reshuffling of gene orders that created new combinations of homologous genes within independently originated polymorphic inversions. The statistical analysis of distribution of conserved gene orders demonstrated that the autosomal arms differ in their tolerance to generating evolutionary breakpoints. The fastest evolving 2R autosomal arm was enriched with gene blocks conserved between only a pair of species. In contrast, all identified syntenic blocks were preserved on the slowly evolving 3R arm of An. gambiae and on the homologous arms of An. funestus and An. stephensi. Conclusions: Our results suggest that natural selection favors specific gene combinations within polymorphic inversions when distant species are exposed to similar environmental pressures. This knowledge could be useful for the discovery of genes responsible for an association of inversion polymorphisms with phenotypic variations in multiple species. Our data support the chromosomal arm specificity in rates of gene order disruption during mosquito evolution. We conclude that the distribution of breakpoint regions is evolutionary conserved on slowly evolving arms and tends to be lineage-specific on rapidly evolving arms.
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    Asymmetric Phenotypes of Sterile Hybrid Males From Reciprocal Crosses Between Species of the Anopheles gambiae Complex
    Liang, Jiangtao; Hodge, James M.; Sharakhov, Igor V. (2021-06-10)
    Haldane's rule of speciation states that sterility or inviability affects the heterogametic sex of inter-species hybrids. Darwin's corollary to Haldane's rule implies that there are asymmetric phenotypes in inter-species hybrids from reciprocal crosses. Studying the phenotypes of F1 hybrids among closely related species of malaria mosquitoes can assist researchers in identifying the genetic factors and molecular mechanisms of speciation. To characterize phenotypes of sterile hybrid males in the Anopheles gambiae complex, we performed crosses between laboratory strains of An. merus and either An. gambiae or An. coluzzii. The reproductive tracts had normal external morphology in hybrid males from crosses between female An. merus and male An. gambiae or An. coluzzii. Despite being sterile, these males could copulate with females for a normal period of time and could transfer a mating plug to induce female oviposition and monogamy. In contrast, the entire reproductive tracts in hybrid males from crosses between female An. gambiae or An. coluzzii and male An. merus were severely underdeveloped. These males had atrophic testes and reduced somatic organs of the reproductive system including male accessary glands and ejaculatory duct. In addition, hybrid males with underdeveloped reproductive tracts displayed a shorter copulation time with females and failed to induce female oviposition and monogamy due to their inability to form and transfer a plug to females during mating. The asymmetry of the phenotypes associated with hybrid male sterility suggests that different genetic factors and molecular mechanisms are responsible for reproductive isolation in reciprocal crosses among species of the An. gambiae complex.
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    The Beginning of the End: A Chromosomal Assembly of the New World Malaria Mosquito Ends with a Novel Telomere
    Compton, Austin; Liang, Jiangtao; Chen, Chujia; Lukyanchikova, Varvara; Qi, Yumin; Potters, Mark B.; Settlage, Robert; Miller, Dustin; Deschamps, Stephane; Mao, Chunhong; Llaca, Victor; Sharakhov, Igor V.; Tu, Zhijian Jake (Genetics Society of America, 2020-10-01)
    Chromosome level assemblies are accumulating in various taxonomic groups including mosquitoes. However, even in the few reference-quality mosquito assemblies, a significant portion of the heterochromatic regions including telomeres remain unresolved. Here we produce a de novo assembly of the New World malaria mosquito, Anopheles albimanus by integrating Oxford Nanopore sequencing, Illumina, Hi-C and optical mapping. This 172.6 Mbps female assembly, which we call AalbS3, is obtained by scaffolding polished large contigs (contig N50 = 13.7 Mbps) into three chromosomes. All chromosome arms end with telomeric repeats, which is the first in mosquito assemblies and represents a significant step toward the completion of a genome assembly. These telomeres consist of tandem repeats of a novel 30-32 bp Telomeric Repeat Unit (TRU) and are confirmed by analyzing the termini of long reads and through both chromosomal in situ hybridization and a Bal31 sensitivity assay. The AalbS3 assembly included previously uncharacterized centromeric and rDNA clusters and more than doubled the content of transposable elements and other repetitive sequences. This telomere-to-telomere assembly, although still containing gaps, represents a significant step toward resolving biologically important but previously hidden genomic components. The comparison of different scaffolding methods will also inform future efforts to obtain reference-quality genomes for other mosquito species.
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    Characterization of the expression patterns of the retrogene-parental gene pairs in the African malaria vector Anopheles coluzzii
    Miller, Duncan Joseph (Virginia Tech, 2020-07-09)
    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.
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    Chromosomal Evolution of Malaria Vectors
    Peery, Ashley Nicole (Virginia Tech, 2016-07-01)
    International malaria control initiatives such as the Roll Back Malaria Initiative (RBM) and the Medicines for Malaria Venture (MMV) mobilize resources and spur research aimed at vector control as well as the treatment and eventual eradication of the disease. These efforts have managed to reduce incidence of malaria by an estimated 37% worldwide since 2000. However, despite the promising success of control efforts such as these, the World Health Organization reports a staggering 438,000 deaths from malaria in 2015. The continuing high death toll of malaria as well as emerging insecticide and antimalarial drug resistance suggests that while encouraging, success in reducing malaria incidence may be tenuous. Current vector control strategies are often complicated by ecological and behavioral heterogeneity of vector mosquito populations. As an additional obstruction, mosquito genomes are highly plastic as evidenced by the wealth or chromosomal inversions that have occurred in this genus. Chromosomal inversions have been correlated with differences in adaptation to aridity, insecticide resistance, and differences in resting behavior. However, a good understanding of the molecular mechanisms for inversion generation is still lacking. One possible contributor to inversion formation in Anopheles mosquitoes includes repetitive DNA such as transposable elements (TEs), tandem repeats (TRs) and inverted repeats (IRs). This dissertation provides physical maps for two important malaria vectors, An. stephensi and An. albimanus (Ch.2 and Ch. 3) and then applies those maps to the identification of inversion breakpoints in malaria mosquitoes. Repeat content of each chromosomal arm and the molecular characterization of lineage specific breakpoints is also investigated (Ch. 2 and Ch.4). Our study reveals differences in patterns of chromosomal evolution of Anopheles mosquitoes vs. Drosophila. First, mosquito chromosomes tend to shuffle as intact elements via whole arm translocations and do not under fissions or fusions as seen in fruitflies. Second, the mosquito sex chromosome is changing at a much higher rate relative to the autosomes in malaria mosquitoes than in fruit flies. Third, our molecular characterization of inversion breakpoints indicates that TEs and TRs may participate in inversion genesis in an arm specific manner.
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    Chromosome and Genome Divergence between the Cryptic Eurasian Malaria Vector-Species Anopheles messeae and Anopheles daciae
    Naumenko, Anastasia N.; Karagodin, Dmitriy A.; Yurchenko, Andrey A.; Moskaev, Anton V.; Martin, Olga I.; Baricheva, Elina M.; Sharakhov, Igor V.; Gordeev, Mikhail I.; Sharakhova, Maria V. (MDPI, 2020-02-05)
    Chromosomal inversions are important drivers of genome evolution. The Eurasian malaria vector Anopheles messeae has five polymorphic inversions. A cryptic species, An. daciae, has been discriminated from An. messeae based on five fixed nucleotide substitutions in the internal transcribed spacer 2 (ITS2) of ribosomal DNA. However, the inversion polymorphism in An. daciae and the genome divergence between these species remain unexplored. In this study, we sequenced the ITS2 region and analyzed the inversion frequencies of 289 Anopheles larvae specimens collected from three locations in the Moscow region. Five individual genomes for each of the two species were sequenced. We determined that An. messeae and An. daciae differ from each other by the frequency of polymorphic inversions. Inversion X1 was fixed in An. messeae but polymorphic in An. daciae populations. The genome sequence comparison demonstrated genome-wide divergence between the species, especially pronounced on the inversion-rich X chromosome (mean Fst = 0.331). The frequency of polymorphic autosomal inversions was higher in An. messeae than in An. daciae. We conclude that the X chromosome inversions play an important role in the genomic differentiation between the species. Our study determined that An. messeae and An. daciae are closely related species with incomplete reproductive isolation.
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    Chromosome and Genome Evolution in Culicinae Mosquitoes
    Masri, Reem Abed (Virginia Tech, 2021-07-14)
    The Culicinae is the most extensive subfamily among the Culicidae family of mosquitoes. Two genera, Culex and Aedes, from this subfamily have world-wide distribution and are responsible for transmitting of several deadly diseases including Zika, West Nile fevers, chikungunya, dengue, and Rift Valley fevers. Developing high-quality genome assembly for mosquitoes, studying their population structure, and evolution can help to facilitate the development of new strategies for vector control. Studies on Aedes albopitcus as well as on species from the Culex pipiens complex, which are widely spread in the United States, provide excellent models on these topics. Ae. albopictus is one of the most dangerous invasive mosquito species in the world that transmits more than 20 arboviruses. This species has highly repetitive genome that is the largest among mosquito genomes sequenced so far. Thus, sequencing and assembling of such genome is extremally challenging. As a result, the lack of high-quality Ae. albopictus genome assembly has delayed the progress in understanding its biology. To produce a high-quality genome assembly, it was important to anchor genomic scaffolds to the cytogenetic map creating a physical map of the genome assembly. We first developed a new gene-based approach for the physical mapping of repeat-rich mosquito genomes. The approach utilized PCR amplification of the DNA probes based on complementary DNA (cDNA) that does not include repetitive DNA sequences. This method was then used for the development of a physical map for Ae. albopictus based on the in situ hybridization of fifty cDNA fragments or gene exons from twenty-four scaffolds to the mitotic chromosomes from imaginal discs. This study resulted in the construction of a first physical map of the Ae. albopictus genome as well as mapping viral integration and polyphenol oxidase genes. Moreover, comparing our present Ae. albopictus physical map to the current Ae. aegypti assembly indicated the presence of multiple chromosomal inversions between them. To better understand population structure and chromosome evolution in Culicinae mosquitoes, especially in the Culex pipiens complex, we studied genomic and chromosomal differentiation between two subspecies Cx. pipiens pipiens and Cx. pipiens molestus. For the species responsible for the spread of human diseases, understanding the population dynamics and processes of taxa diversification is important for an effective mosquito control . Two vectors of West Nile virus, Cx. p. pipiens and Cx. p. molestus, exhibit epidemiologically important behavioral and physiological differences, but the whole-genome divergence between them was unexplored. The first goal of this study was to better understand the level of genomic differentiation and population structures of Cx. p. pipiens and Cx. p. molestus from different continents. We sequenced and compared whole genomes of 40 individual mosquitoes from two locations in Eurasia and two in North America. Principal Component, ADMIXTURE, and neighbor joining analyses of the nuclear genomes identified two major intercontinental, monophyletic clusters of Cx. p. pipiens and Cx. p. molestus. The level of genomic differentiation between the subspecies was uniform along chromosomes. The ADMIXTURE analysis determined signatures of admixture in Cx. p. pipens populations, but not in Cx. p. molestus populations. Thus, our study identified that Cx. p. molestus and Cx. p. pipiens represent different evolutionary units with monophyletic origin that have undergone incipient ecological speciation. The second goal was to study differences at the chromosome level between these two organisms. We first measured whole chromosome and chromosome arm length differences between Cx. p. molestus and Cx. p. pipiens as a basic cytogenetic approach. In addition, we used the novel Hi-C approach to detect chromosomal rearrangements between them since Hi-C was successful in detecting a known inversion in Cx. quinquefasciatus. Cx. p. molestus and Cx. p. pipiens embryos were used to perform the Hi-C technique. Analysis of the Hi-C data showed the presence of two different inversions in Cx. p. pipiens and Cx. p. molestus heatmap, which could explain their different physiology and adaptation in nature. Developing modern genomic and cytogenetic tools is important to enhance the quality of genome assemblies, improve gene annotation, and provide a better framework for comparative and population genomics of mosquitoes; also it is the foundation for the development of novel genome-based approaches for vector control.
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    Chromosome evolution and mechanisms of speciation in the Anopheles gambiae complex
    Liang, Jiang-tao (Virginia Tech, 2020-06-01)
    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.
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    Chromosome-level genome assemblies of the malaria vectors Anopheles coluzzii and Anopheles arabiensis
    Zamyatin, Anton; Avdeyev, Pavel; Liang, Jiangtao; Sharma, Atashi; Chen, Chujia; Lukyanchikova, Varvara; Alexeev, Nikita; Tu, Zhijian Jake; Alekseyev, Max A.; Sharakhov, Igor V. (Oxford University Press, 2021-03-01)
    Background: Anopheles coluzzii and Anopheles arabiensis belong to the Anopheles gambiae complex and are among the major malaria vectors in sub-Saharan Africa. However, chromosome-level reference genome assemblies are still lacking for these medically important mosquito species. Findings: In this study, we produced de novo chromosome-level genome assemblies for A. coluzzii and A. arabiensis using the long-read Oxford Nanopore sequencing technology and the Hi-C scaffolding approach. We obtained 273.4 and 256.8 Mb of the total assemblies for A. coluzzii and A. arabiensis, respectively. Each assembly consists of 3 chromosome-scale scaffolds (X, 2, 3), complete mitochondrion, and unordered contigs identified as autosomal pericentromeric DNA, X pericentromeric DNA, and Y sequences. Comparison of these assemblies with the existing assemblies for these species demonstrated that we obtained improved reference-quality genomes. The new assemblies allowed us to identify genomic coordinates for the breakpoint regions of fixed and polymorphic chromosomal inversions in A. coluzzii and A. arabiensis. Conclusion: The new chromosome-level assemblies will facilitate functional and population genomic studies in A. coluzzii and A. arabiensis. The presented assembly pipeline will accelerate progress toward creating high-quality genome references for other disease vectors.
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    The chromosome-scale genome assembly for the West Nile vector Culex quinquefasciatus uncovers patterns of genome evolution in mosquitoes
    Ryazansky, Sergei S.; Chen, Chujia; Potters, Mark; Naumenko, Anastasia N.; Lukyanchikova, Varvara; Masri, Reem A.; Brusentsov, Ilya I.; Karagodin, Dmitriy A.; Yurchenko, Andrey A.; dos Anjos, Vitor L.; Haba, Yuki; Rose, Noah H.; Hoffman, Jinna; Guo, Rong; Menna, Theresa; Kelley, Melissa; Ferrill, Emily; Schultz, Karen E.; Qi, Yumin; Sharma, Atashi; Deschamps, Stéphane; Llaca, Victor; Mao, Chunhong; Murphy, Terence D.; Baricheva, Elina M.; Emrich, Scott; Fritz, Megan L.; Benoit, Joshua B.; Sharakhov, Igor V.; McBride, Carolyn S.; Tu, Zhijian; Sharakhova, Maria V. (2024-01-25)
    Background: Understanding genome organization and evolution is important for species involved in transmission of human diseases, such as mosquitoes. Anophelinae and Culicinae subfamilies of mosquitoes show striking differences in genome sizes, sex chromosome arrangements, behavior, and ability to transmit pathogens. However, the genomic basis of these differences is not fully understood. Methods: In this study, we used a combination of advanced genome technologies such as Oxford Nanopore Technology sequencing, Hi-C scaffolding, Bionano, and cytogenetic mapping to develop an improved chromosome-scale genome assembly for the West Nile vector Culex quinquefasciatus. Results: We then used this assembly to annotate odorant receptors, odorant binding proteins, and transposable elements. A genomic region containing male-specific sequences on chromosome 1 and a polymorphic inversion on chromosome 3 were identified in the Cx. quinquefasciatus genome. In addition, the genome of Cx. quinquefasciatus was compared with the genomes of other mosquitoes such as malaria vectors An. coluzzi and An. albimanus, and the vector of arboviruses Ae. aegypti. Our work confirms significant expansion of the two chemosensory gene families in Cx. quinquefasciatus, as well as a significant increase and relocation of the transposable elements in both Cx. quinquefasciatus and Ae. aegypti relative to the Anophelines. Phylogenetic analysis clarifies the divergence time between the mosquito species. Our study provides new insights into chromosomal evolution in mosquitoes and finds that the X chromosome of Anophelinae and the sex-determining chromosome 1 of Culicinae have a significantly higher rate of evolution than autosomes. Conclusion: The improved Cx. quinquefasciatus genome assembly uncovered new details of mosquito genome evolution and has the potential to speed up the development of novel vector control strategies.
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    Chromosome–nuclear envelope attachments affect interphase chromosome territories and entanglement
    Kinney, Nicholas A.; Sharakhov, Igor V.; Onufriev, Alexey V. (2018-01-22)
    Background It is well recognized that the interphase chromatin of higher eukaryotes folds into non-random configurations forming territories within the nucleus. Chromosome territories have biologically significant properties, and understanding how these properties change with time during lifetime of the cell is important. Chromosome–nuclear envelope (Chr–NE) interactions play a role in epigenetic regulation of DNA replication, repair, and transcription. However, their role in maintaining chromosome territories remains unclear. Results We use coarse-grained molecular dynamics simulations to study the effects of Chr–NE interactions on the dynamics of chromosomes within a model of the Drosophila melanogaster regular (non-polytene) interphase nucleus, on timescales comparable to the duration of interphase. The model simulates the dynamics of chromosomes bounded by the NE. Initially, the chromosomes in the model are prearranged in fractal-like configurations with physical parameters such as nucleus size and chromosome persistence length taken directly from experiment. Time evolution of several key observables that characterize the chromosomes is quantified during each simulation: chromosome territories, chromosome entanglement, compactness, and presence of the Rabl (polarized) chromosome arrangement. We find that Chr–NE interactions help maintain chromosome territories by slowing down and limiting, but not eliminating, chromosome entanglement on biologically relevant timescales. At the same time, Chr–NE interactions have little effect on the Rabl chromosome arrangement as well as on how chromosome compactness changes with time. These results are rationalized by simple dimensionality arguments, robust to model details. All results are robust to the simulated activity of topoisomerase, which may be present in the interphase cell nucleus. Conclusions Our study demonstrates that Chr–NE attachments may help maintain chromosome territories, while slowing down and limiting chromosome entanglement on biologically relevant timescales. However, Chr–NE attachments have little effect on chromosome compactness or the Rabl chromosome arrangement.
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    Comparative Analysis of Heterochromatin in the Anopheles gambiae Complex
    Sharma, Atashi (Virginia Tech, 2016-05-10)
    Mosquito borne diseases continue to be a big threat to human health worldwide. Despite using various vector control methods, we lose a great number of lives to this malicious disease in tropical and subtropical countries each year. Not surprisingly, mosquito is considered as the deadliest animal on the earth, because mortality rates from mosquito-vectored infections only lag behind other major diseases such as HIV and tuberculosis. Current approaches of vector control are mostly limited to using insecticidal bed nets, thus novel techniques are required to prevent a staggering loss to human health and quality of life. Advances in the genome sequencing in the past decade have helped to uncover numerous secrets of diverse genomes. The genome of malaria mosquito Anopheles gambiae was first sequenced in 2002 and since then has been updated to include additional scaffolds, their orientations and correction of mis-assemblies. Yet, the greatest challenge remains in assembling the heterochromatin regions, that are repeat rich part and contain relatively low-gene density. Although previously neglected by scientific studies due to its characteristic paucity of genes, heterochromatin is now recognized to be crucial for several processes such as cell viability, chromosome pairing, meiosis, longevity etc. It is therefore not surprising that heterochromatin comprises of a significant portion of the genome in many species. The efforts to analyze the genome of malaria mosquito in order to identify potential new leads for vector control warrant a better understanding of the heterochromatin. Mosquitoes diploid chromosome number equal 6. While autosomes 2 and 3 are submetacentric and present in both sexes, females are homogametic with XX and males are heterogametic with XY sex chromosomes. To achieve a better understanding of the Anopheles heterochromatin, we investigated heterochromatic region of the X chromosome. Despite one arm of the X chromosome being completely heterochromatic, few studies have investigated the molecular content of this region. Protocols were developed for performing fluorescent in situ hybridization (FISH) on mitotic X chromosomes in An. gambiae. Using cytogenetics and molecular biology techniques, we characterized the X chromosome heterochromatin in members of the An. gambiae complex. Specific satellite DNA and 18S ribosomal DNA probes (major components of heterochromatin) were mapped to X chromosomes enabling their differentiation and characterization in the An. gambiae complex. Microarray studies have highlighted the importance of X chromosome during investigation of nascent species An. gambiae and An. coluzzii. Here for the first time qualitative differences in heterochromatin in between nascent species are described. Cytogenetic idiograms are developed as to include the molecular and qualitative differences between the species of the An. gambiae complex. These idiograms are expected to provide a better resolution of the X chromosome heterochromatin for comparison in major malaria vectors, closing some of the gaps present due to poor sequencing of unassembled repeat rich regions in An. gambiae complex. The current understanding of Y chromosome for transgenic manipulation is poor and limited to very few genes. Due to its near total heterochromatic composition, it is the hardest part of the genome to assemble. In collaboration with other researchers, the Y chromosome content was characterized among sibling species of the An. gambiae complex. Our data revealed the swift changes the Y chromosome has undergone in a relatively short evolutionary time period. These include a rapid rate of turnover not only in heterochromatin but also in euchromatin. In addition to previously described repeats, a novel highly repetitive element called Zanzibar was discovered and mapped to the males of various Anopheles sibling species. Our data can form the basis for evolutionary studies in heterochromatin for male mosquitoes within the An. gambiae complex while also help identify novel targets to create successful transgenic male populations. Along with the X chromosome heterochromatin, to our knowledge this is the most extensive contribution to improve the understanding of mitotic chromosome heterochromatin in malaria mosquitoes. This study also investigated if epigenetics play role in mosquito development, fecundity and heterochromatin formation. DNA methylation, histone modifications and small noncoding RNAs are among the epigenetic mechanisms scrutinized in mammals. However, knowledge about epigenetic mechanisms and their effects is sparse in mosquitoes. A protocol for testing the various effects of epigenetics on different stages of malaria mosquito was developed. An epigenetic drug was utilized to probe the effects on immature and adult malaria mosquitoes. Different concentrations of DZNep, a histone methyltransferase inhibitor, were administered to An. coluzzii larvae. Total survivorship and pupation were compared for treated and untreated groups. The drug was also administered to adult blood feeding females to determine any effects on fecundity and egg morphology, revealing a negative association with an increase in drug concentration. A dose dependent decrease in SAH hydrolase concentration in An. coluzzii was also noticed. These results suggest epigenetics plays a critical role in mosquito pupation and ovarian development. Our work lays the groundwork for future investigations into the field of epigenetics in mosquitoes by revealing its effect on several important developmental stages in malaria mosquitoes. Although genomics and next-gen sequencing technology have come a long way in the last decade since the first Anopheles genome was sequenced, considerable gaps still exist in case characterization of heterochromatin function in an organism. Through our work, we have endeavored to elucidate a few of the major roles that heterochromatin may play in organization, evolution and adaptation of the malaria mosquitoes.
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    Comparative analysis of the global transcriptome of Anopheles funestus from Mali, West Africa
    Serazin, Aandrew C.; Dana, Ali N.; Hillenmeyer, Maureen E.; Lobo, Neil F.; Coulibaly, Mamadou B.; Willard, Michael B.; Harker, Brent W.; Sharakhov, Igor V.; Collins, Frank H.; Ribeiro, Jose M. C.; Besansky, Nora J. (2009-11-19)
    BACKGROUND: Anopheles funestus is a principal vector of malaria across much of tropical Africa and is considered one of the most efficient of its kind, yet studies of this species have lagged behind those of its broadly sympatric congener, An. gambiae. In aid of future genomic sequencing of An. funestus, we explored the whole body transcriptome, derived from mixed stage progeny of wild-caught females from Mali, West Africa. PRINCIPAL FINDINGS: Here we report the functional annotation and comparative genomics of 2,005 expressed sequence tags (ESTs) from An. funestus, which were assembled with a previous EST set from adult female salivary glands from the same mosquito. The assembled ESTs provided for a nonredundant catalog of 1,035 transcripts excluding mitochondrial sequences. CONCLUSIONS/SIGNIFICANCE: Comparison of the An. funestus and An. gambiae transcriptomes using computational and macroarray approaches revealed a high degree of sequence identity despite an estimated 20-80 MY divergence time between lineages. A phylogenetically broader comparative genomic analysis indicated that the most rapidly evolving proteins--those involved in immunity, hematophagy, formation of extracellular structures, and hypothetical conserved proteins--are those that probably play important roles in how mosquitoes adapt to their nutritional and external environments, and therefore could be of greatest interest in disease control.
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    Comparative Genomics Insights into Speciation and Evolution of Hawaiian Drosophila
    Kang, Lin (Virginia Tech, 2017-05-01)
    Speciation and adaptation have always been of great interest to biologists. The Hawaiian archipelago provides a natural arena for understanding adaptive radiation and speciation, and genomics and bioinformatics offer new approaches for studying these fundamental processes. The mode of speciation should have profound impacts on the genomic architecture and patterns of reproductive isolation of new species. The Hawaiian Drosophila are a spectacular example of sequential colonization, adaptive radiation, and speciation in the islands with nearly 1,000 estimated species, of which more than 500 have been described to date. This dissertation gives an overview of the Hawaiian Drosophila system (Chapter 1), new insights into genomes of three recently diverged species of Hawaiian picture-winged Drosophila (Chapter 2), as well as estimated gene flow patterns (Chapter 3). Additionally, I present a new approach of mapping genomic scaffolds onto chromosomes, based on NextGen sequencing from chromosomal microdissections (Chapter 4), and gene expression profiles of backcross hybrids and their parental forms (Chapter 5). Overall, obtained results were used to address such fundamental questions as the role of adaptive changes, founder effects (small effective population size in isolation), and genetic admixture during speciation.
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    Comparative genomics of chromosomal rearrangements in malaria mosquitoes
    Xia, Ai (Virginia Tech, 2010-01-25)
    To better understand the evolutionary dynamics of chromosomal inversions, a physical map for an Asian malaria vector, Anopheles stephensi, was created and compared with the maps of the major African malaria vectors A. gambiae and A. funestus No interchromosomal transposition was observed between A. gambiae and A. stephensi. Several cases of euchromatin and heterochromatin transitions weridentified between A. gambiae and A. stephensi. The study of paracentric inversions between lineages in Anopheles mosquitoes demonstrated that X chromosome has the fastest rate of inversion fixations and highest density of repetitive elements. Among the autosomes, 2R evolved faster than other autosomes. The slowly evolved autosomes have more M/SARs than rapidly evolving arms. Breakpoint regions are enriched with repetitive elements. The study revealed that fixed inversions are distributed nonrandomly and breakpoint clustering is common in lineages of A. gambiae and A. stephensi. The parallel association between the density of inversion fixations and polymorphisms suggests that polymorphic inversions can be fixed during evolution. To understand the direction of evolution in A. gambiae complex, the ancestral status of fixed inversions for this complex was identified. The presence of the 2La inversion in outgroups, A. stephensi and A. nili, confirmed the ancestral status of the 2La inversion. The presences of breakpoint structure of the 2Ro inversion in outgroup species, A. stephensi, indicated that the 2Ro is ancestral arrangement. The presence of SINE elements at the breakpoints of the 2R+p in A. gambiae PEST strain suggested that the 2R+p is a derived arrangement. Therefore, the carrier of 2Rop inversions, A. merus, was considered closest to the ancestral species. We have developed a new protocol for laser microdissection and whole genome amplification of polytene chromosomal fragments to obtain DNA for sequencing and assembly. The chromosomal regions spanning both breakpoints of the 2La in A. arabiensis and A. merus were laser microdissected from the polytene chromosomes. Subsequently, DNA samples were amplified using Illustra GenomePhi V2 DNA and Whole-pool amplification methods for obtaining amplicons. Successful amplification of our target DNA was confirmed by PCR with specific primers followed by Sanger sequencing.