Your search keyword '"Liu, Jianquan"' showing total 2 results

1. WGDI: A user-friendly toolkit for evolutionary analyses of whole-genome duplications and ancestral karyotypes.

Author

Sun, Pengchuan, Jiao, Beibei, Yang, Yongzhi, Shan, Lanxing, Li, Ting, Li, Xiaonan, Xi, Zhenxiang, Wang, Xiyin, and Liu, Jianquan

Abstract

Evidence of whole-genome duplications (WGDs) and subsequent karyotype changes has been detected in most major lineages of living organisms on Earth. To clarify the complex resulting multi-layered patterns of gene collinearity in genome analyses, there is a need for convenient and accurate toolkits. To meet this need, we developed WGDI (Whole-Genome Duplication Integrated analysis), a Python-based command-line tool that facilitates comprehensive analysis of recursive polyploidization events and cross-species genome alignments. WGDI supports three main workflows (polyploid inference, hierarchical inference of genomic homology, and ancestral chromosome karyotyping) that can improve the detection of WGD and characterization of WGD-related events based on high-quality chromosome-level genomes. Significantly, it can extract complete synteny blocks and facilitate reconstruction of detailed karyotype evolution. This toolkit is freely available at GitHub (https://github.com/SunPengChuan/wgdi). As an example of its application, WGDI convincingly clarified karyotype evolution in Aquilegia coerulea and Vitis vinifera following WGDs and rejected the hypothesis that Aquilegia contributed as a parental lineage to the allopolyploid origin of core dicots. This work reports an integrated and user-friendly toolkit, WGDI,for polyploid inference, hierarchical inference of genomic homology, and ancestral chromosome karyotyping. WGDI can improve the detection of whole-genome duplication and facilitates dynamic illumination of karyotype evolution. [ABSTRACT FROM AUTHOR]

Published

2022

2. Hybrid speciation via inheritance of alternate alleles of parental isolating genes.

Author

Wang, Zefu, Jiang, Yuanzhong, Bi, Hao, Lu, Zhiqiang, Ma, Yazhen, Yang, Xiaoyue, Chen, Ningning, Tian, Bin, Liu, Bingbing, Mao, Xingxing, Ma, Tao, DiFazio, Stephen P., Hu, Quanjun, Abbott, Richard J., and Liu, Jianquan

Abstract

It is increasingly realized that homoploid hybrid speciation (HHS), which involves no change in chromosome number, is an important mechanism of speciation. HHS will likely increase in frequency as ecological and geographical barriers between species are continuing to be disrupted by human activities. HHS requires the establishment of reproductive isolation between a hybrid and its parents, but the underlying genes and genetic mechanisms remain largely unknown. In this study, we reveal by integrated approaches that reproductive isolation originates in one homoploid hybrid plant species through the inheritance of alternate alleles at genes that determine parental premating isolation. The parent species of this hybrid species are reproductively isolated by differences in flowering time and survivorship on soils containing high concentrations of iron. We found that the hybrid species inherits alleles of parental isolating major genes related to flowering time from one parent and alleles of major genes related to iron tolerance from the other parent. In this way, it became reproductively isolated from one parent by the difference in flowering time and from the other by habitat adaptation (iron tolerance). These findings and further modeling results suggest that HHS may occur relatively easily via the inheritance of alternate parental premating isolating genes and barriers. Using integrated approaches, the authors reveal that reproductive isolation originated in one homoploid hybrid plant species (Ostryopsis intermedia) through the inheritance of alternate alleles at genes that determine parental premating isolation (flowering time and habitat adaptation, i.e., iron tolerance). Their findings and further modeling results suggest that homoploid hybrid speciation can occur easily via the inheritance of alternate, pre-existing, parental reproductive isolations. [ABSTRACT FROM AUTHOR]

Published

2021