Your search keyword '"Zhu-Kuan Cheng"' showing total 4 results

1. Plant-on-Chip: core morphogenesis processes in the tiny plant Wolffia australiana

Author

Feng Li, Jing-Jing Yang, Zong-Yi Sun, Lei Wang, Le-Yao Qi, Sina A, Yi-Qun Liu, Hong-Mei Zhang, Lei-Fan Dang, Shu-Jing Wang, Chun-Xiong Luo, Wei-Feng Nian, Seth O’Conner, Long-Zhen Ju, Wei-Peng Quan, Xiao-Kang Li, Chao Wang, De-Peng Wang, Han-Li You, Zhu-Kuan Cheng, Jia Yan, Fu-Chou Tang, De-Chang Yang, Chu-Wei Xia, Ge Gao, Yan Wang, Bao-Cai Zhang, Yi-Hua Zhou, Xing Guo, Sun-Huan Xiang, Huan Liu, Tian-Bo Peng, Xiao-Dong Su, Yong Chen, Qi Ouyang, Dong-Hui Wang, Da-Ming Zhang, Zhi-Hong Xu, Hong-Wei Hou, Shu-Nong Bai, and Ling Li

Abstract

A plant can be thought of as a colony comprising numerous growth buds, each developing to its own rhythm. Such lack of synchrony impedes efforts to describe core principles of plant morphogenesis, dissect the underlying mechanisms, and identify regulators. Here, we use the tiniest known angiosperm to overcome this challenge and provide an ideal model system for plant morphogenesis. We present a detailed morphological description of the monocot Wolffia australiana, as well as high-quality genome information. Further, we developed the Plant-on-Chip culture system and demonstrate the application of advanced technologies such as snRNA-seq, protein structure prediction, and gene editing. We provide proof-of-concept examples that illustrate how W. australiana can open a new horizon for deciphering the core regulatory mechanisms of plant morphogenesis.SignificanceWhat is the core morphogenetic process in angiosperms, a plant like a tree indeterminately growing, or a bud sequentially generating limited types of organs? Wolffia australiana, one of the smallest angiosperms in the world may help to make a distinction. Wolffia plantlet constitutes of only three organs that are indispensable to complete life cycle: one leaf, one stamen and one gynoecium. Before the growth tip is induced to flower, it keeps branching from the leaf axil and the branches separate from the main plantlet. Here we present a high-quality genome of W. australiana, detailed morphological description, a Plant-on-Chip cultural system, and some principle-proof experiments, demonstrating that W. australiana is a promising model system for deciphering core developmental program in angiosperms.

Published

2022

2. Rice Cell Division Cycle 20s are required for faithful chromosome segregation and cytokinesis during meiosis

Author

Ya-Nan Lin, Chen-Kun Jiang, Zhu-Kuan Cheng, Dong-Hui Wang, Li-Ping Shen, Cong Xu, Zhi-Hong Xu, and Shu-Nong Bai

Subjects

Crops, Agricultural, Meiosis, Physiology, Gene Expression Regulation, Plant, Regular Issue Content, Chromosome Segregation, Genetics, Oryza, Plant Science, Genes, Plant, Cell Division, Cytokinesis

Abstract

Chromosome segregation must be under strict regulation to maintain chromosome euploidy and stability. Cell Division Cycle 20 (CDC20) is an essential cell cycle regulator that promotes the metaphase-to-anaphase transition and functions in the spindle assembly checkpoint, a surveillance pathway that ensures the fidelity of chromosome segregation. Plant CDC20 genes are present in multiple copies, and whether CDC20s have the same functions in plants as in yeast and animals is unclear, given the potential for divergence or redundancy among the multiple copies. Here, we studied all three CDC20 genes in rice (Oryza sativa) and constructed two triple mutants by clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9-mediated genome editing to explore their roles in development. Knocking out all three CDC20 genes led to total sterility but did not affect vegetative development. Loss of the three CDC20 proteins did not alter mitotic division but severely disrupted meiosis as a result of asynchronous and unequal chromosome segregation, chromosome lagging, and premature separation of chromatids. Immunofluorescence of tubulin revealed malformed meiotic spindles in microsporocytes of the triple mutants. Furthermore, cytokinesis of meiosis I was absent or abnormal, and cytokinesis II was completely prevented in all mutant microsporocytes; thus, no tetrads or pollen formed in either cdc20 triple mutant. Finally, the subcellular structures and functions of the tapetum were disturbed by the lack of CDC20 proteins. These findings demonstrate that the three rice CDC20s play redundant roles but are indispensable for faithful meiotic chromosome segregation and cytokinesis, which are required for the production of fertile microspores.

Published

2021

3. Cytological identification of an isotetrasomic in rice and its application to centromere mapping

Author

Heng Xiu Yu, Changjie Yan, Zhu Kuan Cheng, Li Huang Zhu, and Ming Hong Gu

Subjects

Genetics, Isochromosome, Centromere, Aneuploidy, Chromosome, Chromosome Mapping, Oryza, Cell Biology, Biology, medicine.disease, Blotting, Southern, Genetic linkage, medicine, Identification (biology), Restriction fragment length polymorphism, Ploidy, Molecular Biology

Abstract

The aneuploid with isochromosome or telochromosome is ideal material for exploring the position of centromere in lingkage map. For obtaining these aneuploids in rice, the primary trisomics from triplo-1 to triplo-12 and the aneuploids derived from a triploid of indica rice variety Zhongxian 3037 were carefully investigated. From the offsprings of triplo-10, a primary trisomic of chromosome 10 of the variety, an isotetrasomic "triplo-10-1" was obtained. Cytological investigation revealed that a pair of extra isochromosomes of triplo-10-1 were come from the short arm of chromosome 10. In the offsprings of the isotetrasomic, a secondary trisomic "triplo-10-2", in which the extra- chromosome was an isochromosome derived from the short arm of chromosome 10, was identified. With the isotetrasomic, secondary trisomic, primary trisomic and diploid of variety Zhongxian 3037, different molecular markers were used for exploring the position of the centromere of chromosome 10. Based on the DNA dosage effect, it was verified that the molecular markers G1125, G333 and L169 were located on the short arm, G1084 and other 16 available molecular markers were on the long arm of chromosome 10. So the centromere of chromosome 10 was located somewhere between G1125 and G1084 according to the RFLP linkage map given by Kurata et al[1]. The distance from G1125 to G1084 was about 3.2 cM.

Published

1997

4. Integration of Cytological Features with Molecular and Epigenetic Properties of Rice Chromosome 4.

Author

Ben-Liang Yin, Lan Guo, Dong-Fen Zhang, Terzaghi, William, Xiang-Feng Wang, Ting-Ting Liu, Hang He, Zhu-Kuan Cheng, and Xing Wang Deng

Subjects

HETEROCHROMATIC genes, GENETIC transcription, GENES, METHYLATION, LYMPHOPROLIFERATIVE disorders

Abstract

It has been reported that rice chromosome 4 has eight major heterochromatic knobs within the heterochromatic half and that this organization correlates with chromosomal-level transcriptional activity. To better understand this chromosomal organization, we created a model based on the statistical distribution of various types of gene models to divide chromosome 4 into 17 euchromatic and heterochromatic regions that correspond with the cytological staining. Fluorescence in-situ hybridization (FISH) experiments using a set of bacterial artificial chromosome (BAC) clones from chromosome 4 placed all 18 clones in the region predicted by the model. Elevated levels of H3K4 di- and tri-methylation detected by chromatin-immunoprecipitation (ChIP) on chip were correlated with euchromatic regions whereas lower levels of these two modifications were detected in heterochromatic regions. Small RNAs were more abundant in the heterochromatic regions. To validate these findings, H3K4 trimethylation, H3K9 acetylation, H4K12 acetylation, and H3K9 di- and tri-methylation of 19 individual genes were measured by ChIP–PCR. Genes in heterochromatic regions had elevated H3K9 di- and tri-methylation while genes in euchromatic regions had elevated levels of the other three modifications. We also assayed cytosine methylation of these genes using the restriction enzymes McrBC, HapII, and Msp I. This analysis indicated that cytosines of transposable elements and some genes located in heterochromatic regions were methylated while cytosines of the other genes were unmethylated. These results suggest that local transcriptional activity may reflect the organization of the corresponding part of the chromosome. They also indicate that epigenetic regulation plays an important role in correlating chromosomal organization with transcriptional activity. [ABSTRACT FROM PUBLISHER]

Published

2008