4 results on '"Asare, Emmanuel"'
Search Results
2. Evolution of Skipper (SK), a family of DD34E/Tc1 transposons, in animals.
- Author
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Wang, Saisai, Guan, Zhongxia, Diaby, Mohamed, Asare, Emmanuel, Ullah, Numan, Jia, Wenzhu, Gao, Bo, Yu, Duonan, and Song, Chengyi
- Subjects
TRANSPOSONS ,BIOLOGICAL evolution ,ANOPHELES gambiae ,CRUCIAN carp ,SILKWORMS ,STRUCTURAL dynamics - Abstract
High diversity and differential evolution profiles have been observed for DD34E/ Tc1 transposons; several families originating from these groups, such as DD34E/ ZB , DD34E/ SB , DD35E/ TR , DD36E/ IC, and DD38E/ IT , have been well defined. Even though Frisky , Tiang , Tsessebe, and Topi transposons have been identified in Anopheles gambiae , their taxonomic distribution and phylogenetic relationship in nature remain largely unknown. The evolutionary profiles of Frisky , Tiang , Tsessebe , and Topi homology transposons were investigated in the current study. In total, 254 homology transposons of Frisky , Tiang , Hob , Tsessebe, and Topi were obtained in 200 species by data mining. The phylogenetic tree revealed that these transposons were classified into five main clades (Frisky , Tiang , Hob , Tsessebe , and Topi) forming a monophyletic clade with 98% bootstrap support, belonging to the DD34E/ Tc1 group, and named as Skipper (SK). SK transposons show a wide distribution in animals; however, differential taxonomic distribution patterns were observed for the subfamilies of Frisky , Tiang , Hob , Tsessebe, and Topi ; extensive invasion of Frisky in animals was found, whereas Tiang , Hob , Tsessebe, and Topi were mainly detected in Diptera. SK elements share a similar structural organization and display high sequence identities across subfamilies. Evolutionary dynamics and structural analysis revealed that SK s in some species, such as Bombyx mori , Lordiphosa magnipectinata , Carassius gibelio , Triplophysa dalaica , and Silurus glanis , have recently evolved and present as intact copies, indicating that SK s in these genomes may be active. Together, these observations improve our understanding of the diversity of DD34E/ Tc1 transposons and their impacts on genome evolution in animals. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
3. High Diversity of Long Terminal Repeat Retrotransposons in Compact Vertebrate Genomes: Insights from Genomes of Tetraodontiformes.
- Author
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Wang, Bingqing, Saleh, Ahmed A., Yang, Naisu, Asare, Emmanuel, Chen, Hong, Wang, Quan, Chen, Cai, Song, Chengyi, and Gao, Bo
- Subjects
RETROTRANSPOSONS ,PUFFERS (Fish) ,VERTEBRATES ,DATA mining ,REVERSE transcriptase - Abstract
Simple Summary: Long terminal repeat retrotransposons (LTR-RTNs) are vital in genome evolution and diversity. The compact genomes of Tetraodontiformes provide an excellent model for studying LTR-RTN dynamics. An analysis of the genomes of ten tetraodontiform species revealed a total of 819 full-length LTR retrotransposon sequences classified into nine families spanning four distinct superfamilies. Among them, the Gypsy superfamily displayed the highest level of diversity. Takifugu stood out for having the highest abundance of LTR families and sequences. Evidence of recent LTR-RTN activity and multiple invasions was observed in specific tetraodontiform genomes. This investigation provides valuable insights into the evolution of LTR retrotransposons and their impact on the structure and evolution of compact tetraodontiform genomes. This study aimed to investigate the evolutionary profile (including diversity, activity, and abundance) of retrotransposons (RTNs) with long terminal repeats (LTRs) in ten species of Tetraodontiformes. These species, Arothron firmamentum, Lagocephalus sceleratus, Pao palembangensis, Takifugu bimaculatus, Takifugu flavidus, Takifugu ocellatus, Takifugu rubripes, Tetraodon nigroviridis, Mola mola, and Thamnaconus septentrionalis, are known for having the smallest genomes among vertebrates. Data mining revealed a high diversity and wide distribution of LTR retrotransposons (LTR-RTNs) in these compact vertebrate genomes, with varying abundances among species. A total of 819 full-length LTR-RTN sequences were identified across these genomes, categorized into nine families belonging to four different superfamilies: ERV (Orthoretrovirinae and Epsilon retrovirus), Copia, BEL-PAO, and Gypsy (Gmr, Mag, V-clade, CsRN1, and Barthez). The Gypsy superfamily exhibited the highest diversity. LTR family distribution varied among species, with Takifugu bimaculatus, Takifugu flavidus, Takifugu ocellatus, and Takifugu rubripes having the highest richness of LTR families and sequences. Additionally, evidence of recent invasions was observed in specific tetraodontiform genomes, suggesting potential transposition activity. This study provides insights into the evolution of LTR retrotransposons in Tetraodontiformes, enhancing our understanding of their impact on the structure and evolution of host genomes. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
4. PiggyBac Transposon Mining in the Small Genomes of Animals.
- Author
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Guo, Mengke, Addy, George A., Yang, Naisu, Asare, Emmanuel, Wu, Han, Saleh, Ahmed A., Shi, Shasha, Gao, Bo, and Song, Chengyi
- Subjects
TRANSPOSONS ,GENOMES ,MOBILE genetic elements ,BIOLOGICAL evolution ,PROKARYOTIC genomes ,EUKARYOTIC genomes ,AMERICAN oyster - Abstract
Simple Summary: Transposable elements (TEs) are mobile genetic elements that play vital role in defining and contributing to the size, shape and structure of both prokaryotic and eukaryotic genomes in nature. The piggyBac (PB), a superfamily of DNA transposons, has been isolated over the years from various organisms including insects, fungi and plants. These piggyBac transposon systems have high efficiency with a wide usage in the study of gene therapies, mutagenesis and transgenesis. Currently, there is limited information available on DNA transposons in small (compact) genomes of animals. Therefore, this study aims to annotate the PB transposons in small genomes of animals, revealing their evolution profiles in both vertebrate and invertebrate genomes. TEs, including DNA transposons, are major contributors of genome expansions, and have played a very significant role in shaping the evolution of animal genomes, due to their capacity to jump from one genomic position to the other. In this study, we investigated the evolution landscapes of PB transposons, including their distribution, diversity, activity and structure organization in 79 species of small (compact) genomes of animals comprising both vertebrate and invertebrates. Overall, 212 PB transposon types were detected from almost half (37) of the total number of the small genome species (79) investigated. The detected PB transposon types, which were unevenly distributed in various genera and phyla, have been classified into seven distinct clades or families with good bootstrap support (>80%). The PB transposon types that were identified have a length ranging from 1.23 kb to 9.51 kb. They encode transposases of approximately ≥500 amino acids in length, and possess terminal inverted repeats (TIRs) ranging from 4 bp to 24 bp. Though some of the transposon types have long TIRs (528 bp), they still maintain the consistent and reliable 4 bp target site duplication (TSD) of TTAA. However, PiggyBac-2_Cvir transposon originating from the Crassostrea virginica species exhibits a unique TSD of TATG. The TIRs of the transposons in all the seven families display high divergence, with a highly conserved 5′ end motif. The core transposase domains (DDD) were better conserved among the seven different families compared to the other protein domains, which were less prevalent in the vertebrate genome. The divergent evolution dynamics analysis also indicated that the majority of the PB transposon types identified in this study are either relatively young or old, with some being active. Additionally, numerous invasions of PB transposons were found in the genomes of both vertebrate and invertebrate animals. The data reveals that the PB superfamily is widely distributed in these species. PB transposons exhibit high diversity and activity in the small genomes of animals, and might play a crucial role in shaping the evolution of these small genomes of animals. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
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