Your search keyword '"Wanfei Liu"' showing total 3 results

1. Improved 93-11 Genome and Time-Course Transcriptome Expand Resources for Rice Genomics

Author

Sen Wang, Shenghan Gao, Jingyi Nie, Xinyu Tan, Junhua Xie, Xiaochun Bi, Yan Sun, Sainan Luo, Qianhui Zhu, Jianing Geng, Wanfei Liu, Qiang Lin, Peng Cui, Songnian Hu, and Shuangyang Wu

Subjects

time course transcriptome, alternative splicing, waxy, 93-11, chromosome level, Plant culture, SB1-1110

Abstract

In 2002, the first crop genome was published using the rice cultivar 93-11, which is the progenitor of the first super-hybrid rice. The genome sequence has served as a reference genome for the indica cultivars, but the assembly has not been updated. In this study, we update the 93-11 genome assembly to a gap-less sequence using ultra-depth single molecule real-time (SMRT) reads, Hi-C sequencing, reference-guided, and gap-closing approach. The differences in the genome collinearity and gene content between the 93-11 and the Nipponbare reference genomes confirmed to map the indica cultivar sequencing data to the 93-11 genome, instead of the reference. Furthermore, time-course transcriptome data showed that the expression pattern was consistently correlated with the stages of seed development. Alternative splicing of starch synthesis-related genes and genomic variations of waxy make it a novel resource for targeted breeding. Collectively, the updated high quality 93-11 genome assembly can improve the understanding of the genome structures and functions of Oryza groups in molecular breeding programs.

Published

2022

2. DRDB: An Online Date Palm Genomic Resource Database

Author

Zilong He, Chengwei Zhang, Wanfei Liu, Qiang Lin, Ting Wei, Hasan A. Aljohi, Wei-Hua Chen, and Songnian Hu

Subjects

date palm, short sequence repeat, single nucleotide polymorphism, genome variation, cultivar classification, Plant culture, SB1-1110

Abstract

Background: Date palm (Phoenix dactylifera L.) is a cultivated woody plant with agricultural and economic importance in many countries around the world. With the advantages of next generation sequencing technologies, genome sequences for many date palm cultivars have been released recently. Short sequence repeat (SSR) and single nucleotide polymorphism (SNP) can be identified from these genomic data, and have been proven to be very useful biomarkers in plant genome analysis and breeding.Results: Here, we first improved the date palm genome assembly using 130X of HiSeq data generated in our lab. Then 246,445 SSRs (214,901 SSRs and 31,544 compound SSRs) were annotated in this genome assembly; among the SSRs, mononucleotide SSRs (58.92%) were the most abundant, followed by di- (29.92%), tri- (8.14%), tetra- (2.47%), penta- (0.36%), and hexa-nucleotide SSRs (0.19%). The high-quality PCR primer pairs were designed for most (174,497; 70.81% out of total) SSRs. We also annotated 6,375,806 SNPs with raw read depth≥3 in 90% cultivars. To further reduce false positive SNPs, we only kept 5,572,650 (87.40% out of total) SNPs with at least 20% cultivars support for downstream analyses. The high-quality PCR primer pairs were also obtained for 4,177,778 (65.53%) SNPs. We reconstructed the phylogenetic relationships among the 62 cultivars using these variants and found that they can be divided into three clusters, namely North Africa, Egypt – Sudan, and Middle East – South Asian, with Egypt – Sudan being the admixture of North Africa and Middle East – South Asian cultivars; we further confirmed these clusters using principal component analysis. Moreover, 34,346 SSRs and 4,177,778 SNPs with PCR primers were assigned to shared cultivars for cultivar classification and diversity analysis. All these SSRs, SNPs and their classification are available in our database, and can be used for cultivar identification, comparison, and molecular breeding.Conclusion:DRDB is a comprehensive genomic resource database of date palm. It can serve as a bioinformatics platform for date palm genomics, genetics, and molecular breeding. DRDB is freely available at http://drdb.big.ac.cn/home.

Published

2017

3. Improved 93-11 Genome and Time-Course Transcriptome Expand Resources for Rice Genomics

Author

Sen Wang, Shenghan Gao, Jingyi Nie, Xinyu Tan, Junhua Xie, Xiaochun Bi, Yan Sun, Sainan Luo, Qianhui Zhu, Jianing Geng, Wanfei Liu, Qiang Lin, Peng Cui, Songnian Hu, and Shuangyang Wu

Subjects

time course transcriptome, alternative splicing, 93-11, Plant culture, food and beverages, Plant Science, chromosome level, waxy, SB1-1110, Original Research

Abstract

In 2002, the first crop genome was published using the rice cultivar 93-11, which is the progenitor of the first super-hybrid rice. The genome sequence has served as a reference genome for the indica cultivars, but the assembly has not been updated. In this study, we update the 93-11 genome assembly to a gap-less sequence using ultra-depth single molecule real-time (SMRT) reads, Hi-C sequencing, reference-guided, and gap-closing approach. The differences in the genome collinearity and gene content between the 93-11 and the Nipponbare reference genomes confirmed to map the indica cultivar sequencing data to the 93-11 genome, instead of the reference. Furthermore, time-course transcriptome data showed that the expression pattern was consistently correlated with the stages of seed development. Alternative splicing of starch synthesis-related genes and genomic variations of waxy make it a novel resource for targeted breeding. Collectively, the updated high quality 93-11 genome assembly can improve the understanding of the genome structures and functions of Oryza groups in molecular breeding programs.

Published

2021