Your search keyword '"Jiangtao Liang"' showing total 3 results

1. MALARIA JOURNAL

Author

Igor V. Sharakhov, Cong Wang, Danyu Shen, Jing Wang, Biao Cheng, Jiangtao Liang, Yun Wei, Guoding Zhu, Jun Cao, Jianxia Tang, Ai Xia, Entomology, and Fralin Life Sciences Institute

Subjects

0301 basic medicine, Anopheles gambiae, Genome, Insect, ved/biology.organism_classification_rank.species, Sequence assembly, Genome, OrthoDB, 0302 clinical medicine, Synteny blocks, In Situ Hybridization, Fluorescence, Polytene Chromosomes, Genetics, Sex Chromosomes, biology, GENUS ANOPHELES, Fluorescence in situ hybridization, REARRANGEMENTS, Chromosome Mapping, PLASMODIUM-VIVAX, MOSQUITO, Infectious Diseases, lcsh:Arctic medicine. Tropical medicine, lcsh:RC955-962, 030231 tropical medicine, GRIMM, Mosquito Vectors, Inversion fixation, SEQUENCE, DNA sequencing, lcsh:Infectious and parasitic diseases, Anopheles sinensis, 03 medical and health sciences, DIPTERA-CULICIDAE, Gene mapping, CENTRAL CHINA, CHROMOSOMES, Tropical Medicine, Anopheles, Animals, lcsh:RC109-216, ved/biology, Research, Chromosomal evolution, Chromosome, biology.organism_classification, EVOLUTION, Malaria, 030104 developmental biology, Chromosome Inversion, Parasitology, STEPHENSI

Abstract

Background Anopheles sinensis is a dominant natural vector of Plasmodium vivax in China, Taiwan, Japan, and Korea. Recent genome sequencing of An. sinensis provides important insights into the genomic basis of vectorial capacity. However, the lack of a physical genome map with chromosome assignment and orientation of sequencing scaffolds hinders comparative analyses with other genomes to infer evolutionary changes relevant to the vector capacity. Results Here, a physical genome map for An. sinensis was constructed by assigning 52 scaffolds onto the chromosomes using fluorescence in situ hybridization (FISH). This chromosome-based genome assembly composes approximately 36% of the total An. sinensis genome. Comparisons of 3955 orthologous genes between An. sinensis and Anopheles gambiae identified 361 conserved synteny blocks and 267 inversions fixed between these two lineages. The rate of gene order reshuffling on the X chromosome is approximately 3.2 times higher than that on the autosomes. Conclusions The physical map will facilitate detailed genomic analysis of An. sinensis and contribute to understanding of the patterns and mechanisms of large-scale genome rearrangements in anopheline mosquitoes. Electronic supplementary material The online version of this article (doi:10.1186/s12936-017-1888-7) contains supplementary material, which is available to authorized users.

Published

2017

2. Comparative physical genome mapping of malaria vectors Anopheles sinensis and Anopheles gambiae.

Author

Yun Wei, Biao Cheng, Guoding Zhu, Danyu Shen, Jiangtao Liang, Cong Wang, Jing Wang, Jianxia Tang, Jun Cao, Sharakhov, Igor V., and Ai Xia

Subjects

CHROMOSOME abnormalities, CHROMOSOME inversions, FLUORESCENCE in situ hybridization, ANOPHELES, PLASMODIUM vivax

Abstract

Background: Anopheles sinensis is a dominant natural vector of Plasmodium vivax in China, Taiwan, Japan, and Korea. Recent genome sequencing of An. sinensis provides important insights into the genomic basis of vectorial capacity. However, the lack of a physical genome map with chromosome assignment and orientation of sequencing scaffolds hinders comparative analyses with other genomes to infer evolutionary changes relevant to the vector capacity. Results: Here, a physical genome map for An. sinensis was constructed by assigning 52 scaffolds onto the chromosomes using fluorescence in situ hybridization (FISH). This chromosome-based genome assembly composes approximately 36% of the total An. sinensis genome. Comparisons of 3955 orthologous genes between An. sinensis and Anopheles gambiae identified 361 conserved synteny blocks and 267 inversions fixed between these two lineages. The rate of gene order reshuffling on the X chromosome is approximately 3.2 times higher than that on the autosomes. Conclusions: The physical map will facilitate detailed genomic analysis of An. sinensis and contribute to understanding of the patterns and mechanisms of large-scale genome rearrangements in anopheline mosquitoes. [ABSTRACT FROM AUTHOR]

Published

2017

3. Structural divergence of chromosomes between malaria vectors Anopheles lesteri and Anopheles sinensis.

Author

Jiangtao Liang, Biao Cheng, Guoding Zhu, Yun Wei, Jianxia Tang, Jun Cao, Yajun Ma, Sharakhova, Maria V., Ai Xia, and Sharakhov, Igor V.

Subjects

*ANOPHELES, *CHROMOSOME structure, *MALARIA, *MOSQUITO vectors, *PUBLIC health

Abstract

Background: Anopheles lesteri and Anopheles sinensis are two major malaria vectors in China and Southeast Asia. They are dramatically different in terms of geographical distribution, host preference, resting habitats, and other traits associated with ecological adaptation and malaria transmission. Both species belong to the Anopheles hyrcanus group, but the extent of genetic differences between them is not well understood. To provide an effective way to differentiate between species and to find useful markers for population genetics studies, we performed a comparative cytogenetic analysis of these two malaria vectors. Results: Presented here is a standard cytogenetic map for An. lesteri, and a comparative analysis of chromosome structure and gene order between An. lesteri and An. sinensis. Our results demonstrate that much of the gene order on chromosomes X and 2 was reshuffled between the two species. However, the banding pattern and the gene order on chromosome 3 appeared to be conserved. We also found two new polymorphic inversions, 2Lc and 3Rb, in An. lesteri, and we mapped the breakpoints of these two inversions on polytene chromosomes. Conclusions: Our results demonstrate the extent of structural divergence of chromosomes between An. lesteri and An. sinensis, and provide a new taxonomic cytogenetic tool to distinguish between these two species. Polymorphic inversions of An. lesteri could serve as markers for studies of the population structure and ecological adaptations of this major malaria vector. [ABSTRACT FROM AUTHOR]

Published

2016