Your search keyword '"Zehuai Yu"' showing total 9 results

1. Intergeneric chromosome-specific painting reveals differential chromosomal transmission from Tripidium arundinaceum in sugarcane progeny

Author

Fan Yu, Zehuai Yu, Jin Chai, Xikai Yu, Chen Fu, Xinwang Zhao, Hailong Chang, Jiawei Lei, Baoshan Chen, Wei Yao, Muqing Zhang, Jiayun Wu, Qinnan Wang, and Zuhu Deng

Subjects

sugarcane, Tripidium arundinaceum, chromosome painting, Oligo-FISH, chromosomal transmission, Agriculture (General), S1-972

Abstract

Sugarcane has recently attracted increasing attention for its potential as a source of sugar and bioethanol, so increasing its yield is essential to ensure the sugar security and bioenergy production. Intergeneric hybridization is a highly efficient method to produce new genetic variants of crop plants, particularly those species with high ploidy such as sugarcane (Saccharum spp.). Tripidium arundinaceum exhibits many desirable agronomic traits, and has been widely studied to produce hybrids with improved stress tolerance and other characteristics in sugarcane breeding. However, the genetic relationship between T. arundinaceum and Saccharum species, and the individual T. arundinaceum chromosomal compositions in sugarcane hybrids are still elusive. Here we used whole-genome single-nucleotide polymorphisms (SNPs) to ascertain the phylogenetic relationships between these species and found that T. arundinaceum is more closely related to Saccharum than Sorghum, in contrast to the previous narrow genetic analyses using chloroplast DNA. Additionally, oligonucleotide (oligo)-based chromosome-specific painting derived from Saccharum officinarum was able to distinctly identify the chromosomes of T. arundinaceum. We developed the oligo-genomic in situ hybridization (GISH) system for the first time, to unveil the novel chromosome translocations and the transmission of individual T. arundinaceum chromosomes in sugarcane progeny. Notably, we discovered that the chromosomal transmission of T. arundinaceum exhibited several different inheritance modes, including n, 2n, and over 2n in the BC1 progenies. Such inheritance patterns may have resulted from first division restitution (FDR) or FDR+nondisjunction of a chromosome with the sister chromatids in the second meiosis division/second division restitution (FDR+NSC/SDR) model during meiosis. These results will be of substantial benefit for the further selection of T. arundinaceum chromosomes for sugarcane genetic improvement.

Published

2024

2. Identification and characterization of PAL genes involved in the regulation of stem development in Saccharum spontaneum L.

Author

Xiaoqing Wu, Zetian Cui, Xinyi Li, Zehuai Yu, Pingping Lin, Li Xue, Abdullah Khan, Cailan Ou, Zuhu Deng, Muqing Zhang, Wei Yao, and Fan Yu

Subjects

Sugarcane, Saccharum spontaneum, Phenylalanine ammonia-lyase, Stem growth, Genetics, QH426-470

Abstract

Abstract Background Saccharum spontaneum L. is a closely related species of sugarcane and has become an important genetic component of modern sugarcane cultivars. Stem development is one of the important factors for affecting the yield, while the molecular mechanism of stem development remains poorly understanding in S. spontaneum. Phenylalanine ammonia-lyase (PAL) is a vital component of both primary and secondary metabolism, contributing significantly to plant growth, development and stress defense. However, the current knowledge about PAL genes in S. spontaneum is still limited. Thus, identification and characterization of the PAL genes by transcriptome analysis will provide a theoretical basis for further investigation of the function of PAL gene in sugarcane. Results In this study, 42 of PAL genes were identified, including 26 SsPAL genes from S. spontaneum, 8 ShPAL genes from sugarcane cultivar R570, and 8 SbPAL genes from sorghum. Phylogenetic analysis showed that SsPAL genes were divided into three groups, potentially influenced by long-term natural selection. Notably, 20 SsPAL genes were existed on chromosomes 4 and 5, indicating that they are highly conserved in S. spontaneum. This conservation is likely a result of the prevalence of whole-genome replications within this gene family. The upstream sequence of PAL genes were found to contain conserved cis-acting elements such as G-box and SP1, GT1-motif and CAT-box, which collectively regulate the growth and development of S. spontaneum. Furthermore, quantitative reverse transcription polymerase chain reaction (qRT-PCR) analysis showed that SsPAL genes of stem had a significantly upregulated than that of leaves, suggesting that they may promote the stem growth and development, particularly in the + 6 stem (The sixth cane stalk from the top to down) during the growth stage. Conclusions The results of this study revealed the molecular characteristics of SsPAL genes and indicated that they may play a vital role in stem growth and development of S. spontaneum. Altogether, our findings will promote the understanding of the molecular mechanism of S. spontaneum stem development, and also contribute to the sugarcane genetic improving.

Published

2024

3. A chromosomal-scale genome assembly of modern cultivated hybrid sugarcane provides insights into origination and evolution

Author

Yixue Bao, Qing Zhang, Jiangfeng Huang, Shengcheng Zhang, Wei Yao, Zehuai Yu, Zuhu Deng, Jiaxin Yu, Weilong Kong, Xikai Yu, Shan Lu, Yibin Wang, Ru Li, Yuhan Song, Chengwu Zou, Yuzhi Xu, Zongling Liu, Fan Yu, Jiaming Song, Youzong Huang, Jisen Zhang, Haifeng Wang, Baoshan Chen, Xingtan Zhang, and Muqing Zhang

Subjects

Science

Abstract

Abstract Sugarcane is a vital crop with significant economic and industrial value. However, the cultivated sugarcane’s ultra-complex genome still needs to be resolved due to its high ploidy and extensive recombination between the two subgenomes. Here, we generate a chromosomal-scale, haplotype-resolved genome assembly for a hybrid sugarcane cultivar ZZ1. This assembly contains 10.4 Gb genomic sequences and 68,509 annotated genes with defined alleles in two sub-genomes distributed in 99 original and 15 recombined chromosomes. RNA-seq data analysis shows that sugar accumulation-associated gene families have been primarily expanded from the ZZSO subgenome. However, genes responding to pokkah boeng disease susceptibility have been derived dominantly from the ZZSS subgenome. The region harboring the possible smut resistance genes has expanded significantly. Among them, the expansion of WAK and FLS2 families is proposed to have occurred during the breeding of ZZ1. Our findings provide insights into the complex genome of hybrid sugarcane cultivars and pave the way for future genomics and molecular breeding studies in sugarcane.

Published

2024

4. Repetitive Sequence Barcode Probe for Karyotype Analysis in Tripidium arundinaceum

Author

Jin Chai, Ling Luo, Zehuai Yu, Jiawei Lei, Muqing Zhang, and Zuhu Deng

Subjects

FISH, karyotype, sugarcane, Tripidium arundinaceum, repetitive sequence, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The barcode probe is a convenient and efficient tool for molecular cytogenetics. Tripidium arundinaceum, as a polyploid wild allied genus of Saccharum, is a useful genetic resource that confers biotic and abiotic stress resistance for sugarcane breeding. Unfortunately, the basic cytogenetic information is still unclear due to the complex genome. We constructed the Cot-20 library for screening moderately and highly repetitive sequences from T. arundinaceum, and the chromosomal distribution of these repetitive sequences was explored. We used the barcode of repetitive sequence probes to distinguish the ten chromosome types of T. arundinaceum by fluorescence in situ hybridization (FISH) with Ea-0907, Ea-0098, and 45S rDNA. Furthermore, the distinction among homology chromosomes based on repetitive sequences was constructed in T. arundinaceum by the repeated FISH using the barcode probes including Ea-0663, Ea-0267, EaCent, 5S rDNA, Ea-0265, Ea-0070, and 45S rDNA. We combined these probes to distinguish 37 different chromosome types, suggesting that the repetitive sequences may have different distributions on homologous chromosomes of T. arundinaceum. In summary, this method provide a basis for the development of similar applications for cytogenetic analysis in other species.

Published

2022

5. Diversity Chromosome Evolution of Ty1-copia Retrotransposons in Pennisetum purpureum Revealed by FISH

Author

Zehuai Yu, Yongji Huang, Jiayun Wu, Muqing Zhang, and Zuhu Deng

Subjects

Pennisetum purpureum, reverse transcriptase, chromosomal pattern, chromosome evolution, fluorescence in situ hybridization (FISH), Agriculture

Abstract

Pennisetum purpureum is a potential species for biofuel production. Characterization and chromosomal distribution of retrotransposons could enhance the comprehension of the role and dynamics of the repetitive elements in plants. In this study, a phylogenetic tree was constructed according to the conserved reverse transcriptase sequences and revealed that these Ty1-copia retrotransposons had a typical structure. Analysis showed that the total Ty1-copia retrotransposons had a significant component, as high as 5.12 × 103 copy numbers in P. purpureum. Then, the chromosomal pattern of four known lineages were also analyzed with the Pennisetum glaucum genome, which suggested that the Sire/Maximus lineage had the highest copy number and followed by Tork/Angela, Tork/TAR, Retrofit/Ale. Additionally, the chromosomal distribution of total Ty1-copia retrotransposons was detected by fluorescence in situ hybridization (FISH) to be a dispersed pattern with weak clustering, mostly near the centromeric regions of P. purpureum chromosomes; interestingly, there were four obvious signals in the subterminal chromosomes. These results suggested that there occurred differential dynamic evolution directions of Ty1-copia retrotransposons within P. purpureum. Furthermore, co-localization of Ty1-copia, 5S rDNA, and 35S rDNA indicated that two chromosome 2 and four chromosome 4 were identified. Concurrently, subterminal signals of Ty1-copia-type retrotransposons were located on four other homologous chromosomes. Altogether, these results shed light on the diversification of Ty1-copia retrotransposons and have the significance for generation of valid chromosomal markers in retrotransposon families.

Published

2022

6. Chromosomal Characterization of Tripidium arundinaceum Revealed by Oligo-FISH

Author

Fan Yu, Jin Chai, Xueting Li, Zehuai Yu, Ruiting Yang, Xueer Ding, Qiusong Wang, Jiayun Wu, Xiping Yang, and Zuhu Deng

Subjects

T. arundinaceum, sugarcane, sorghum, maize chromosome painting probes, oligo-FISH, ribosomal DNA, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Sugarcane is of important economic value for producing sugar and bioethanol. Tripidium arundinaceum (old name: Erianthus arundinaceum) is an intergeneric wild species of sugarcane that has desirable resistance traits for improving sugarcane varieties. However, the scarcity of chromosome markers has hindered the cytogenetic study of T. arundinaceum. Here we applied maize chromosome painting probes (MCPs) to identify chromosomes in sorghum and T. arundinaceum using a repeated fluorescence in situ hybridization (FISH) system. Sequential FISH revealed that these MCPs can be used as reliable chromosome markers for T. arundinaceum, even though T. arundinaceum has diverged from maize over 18 MYs (million years). Using these MCPs, we identified T. arundinaceum chromosomes based on their sequence similarity compared to sorghum and labeled them 1 through 10. Then, the karyotype of T. arundinaceum was established by multiple oligo-FISH. Furthermore, FISH results revealed that 5S rDNA and 35S rDNA are localized on chromosomes 5 and 6, respectively, in T. arundinaceum. Altogether, these results represent an essential step for further cytogenetic research of T. arundinaceum in sugarcane breeding.

Published

2021

7. A complete gap-free diploid genome in Saccharum complex and the genomic footprints of evolution in the highly polyploid Saccharum genus

Author

Tianyou Wang, Baiyu Wang, Xiuting Hua, Haibao Tang, Zeyu Zhang, Ruiting Gao, Yiying Qi, Qing Zhang, Gang Wang, Zehuai Yu, Yongji Huang, Zhe Zhang, Jing Mei, Yuhao Wang, Yixing Zhang, Yihan Li, Xue Meng, Yongjun Wang, Haoran Pan, Shuqi Chen, Zhen Li, Huihong Shi, Xinlong Liu, Zuhu Deng, Baoshan Chen, Muqing Zhang, Lianfeng Gu, Jianping Wang, Ray Ming, Wei Yao, and Jisen Zhang

Subjects

Plant Science

Published

2023

8. Genomic insights into the recent chromosome reduction of autopolyploid sugarcane Saccharum spontaneum

Author

Qing Zhang, Yiying Qi, Haoran Pan, Haibao Tang, Gang Wang, Xiuting Hua, Yongjun Wang, Lianyu Lin, Zhen Li, Yihan Li, Fan Yu, Zehuai Yu, Yongji Huang, Tianyou Wang, Panpan Ma, Meijie Dou, Zongyi Sun, Yibin Wang, Hengbo Wang, Xingtan Zhang, Wei Yao, Yuntong Wang, Xinlong Liu, Maojun Wang, Jianping Wang, Zuhu Deng, Jingsheng Xu, Qinghui Yang, ZhongJian Liu, Baoshan Chen, Muqing Zhang, Ray Ming, and Jisen Zhang

Subjects

Ploidies, Genetics, Genomics, Chromosomes, Genome, Plant, Saccharum

Abstract

Saccharum spontaneum is a founding Saccharum species and exhibits wide variation in ploidy levels. We have assembled a high-quality autopolyploid genome of S. spontaneum Np-X (2n = 4x = 40) into 40 pseudochromosomes across 10 homologous groups, that better elucidates recent chromosome reduction and polyploidization that occurred circa 1.5 million years ago (Mya). One paleo-duplicated chromosomal pair in Saccharum, NpChr5 and NpChr8, underwent fission followed by fusion accompanied by centromeric split around 0.80 Mya. We inferred that Np-X, with x = 10, most likely represents the ancestral karyotype, from which x = 9 and x = 8 evolved. Resequencing of 102 S. spontaneum accessions revealed that S. spontaneum originated in northern India from an x = 10 ancestor, which then radiated into four major groups across the Indian subcontinent, China, and Southeast Asia. Our study suggests new directions for accelerating sugarcane improvement and expands our knowledge of the evolution of autopolyploids.

Published

2022

9. Chromosomal Characterization of Tripidium arundinaceum Revealed by Oligo-FISH

Author

Jin Chai, Zehuai Yu, Fan Yu, Xueting Li, Xiping Yang, Jiayun Wu, Xueer Ding, Zuhu Deng, Ruiting Yang, and Qiusong Wang

Subjects

QH301-705.5, Article, Chromosomes, Plant, Catalysis, oligo-FISH, Chromosome Painting, Inorganic Chemistry, sugarcane, Botany, medicine, Biology (General), Physical and Theoretical Chemistry, T. arundinaceum, Sugar, QD1-999, Molecular Biology, Ribosomal DNA, Spectroscopy, ribosomal DNA, biology, medicine.diagnostic_test, Organic Chemistry, maize chromosome painting probes, Chromosome, Karyotype, General Medicine, chromosome identification, Sorghum, biology.organism_classification, Saccharum, Computer Science Applications, karyotype, Plant Breeding, Chemistry, %22">Fish , sorghum, Chromosome painting, DNA Probes, Fluorescence in situ hybridization

Abstract

Sugarcane is of important economic value for producing sugar and bioethanol. Tripidium&nbsp, arundinaceum (old name: Erianthus&nbsp, arundinaceum) is an intergeneric wild species of sugarcane that has desirable resistance traits for improving sugarcane varieties. However, the scarcity of chromosome markers has hindered the cytogenetic study of T. arundinaceum. Here we applied maize chromosome painting probes (MCPs) to identify chromosomes in sorghum and T. arundinaceum using a repeated fluorescence in situ hybridization (FISH) system. Sequential FISH revealed that these MCPs can be used as reliable chromosome markers for T. arundinaceum, even though T. arundinaceum has diverged from maize over 18 MYs (million years). Using these MCPs, we identified T. arundinaceum chromosomes based on their sequence similarity compared to sorghum and labeled them 1 through 10. Then, the karyotype of T. arundinaceum was established by multiple oligo-FISH. Furthermore, FISH results revealed that 5S rDNA and 35S rDNA are localized on chromosomes 5 and 6, respectively, in T. arundinaceum. Altogether, these results represent an essential step for further cytogenetic research of T. arundinaceum in sugarcane breeding.

Published

2021