Your search keyword '"Zhicao Yue"' showing total 3 results

1. Evolutionary analysis of a complete chicken genome.

Author

Zhen Huang, Zaoxu Xua, Hao Bai, Yongji Huang, Na Kang, Xiaoting Ding, Jing Liu, Haoran Luo, Chentao Yang, Wanjun Chen, Qixin Guo, Lingzhan Xue, Xueping Zhang, Li Xu, Meiling Chen, Honggao Fu, Youling Chen, Zhicao Yue, Tatsuo Fukagawa, and Shanlin Liun

Subjects

SATELLITE DNA, BIOLOGICAL evolution, TANDEM repeats, CHROMOSOMES, GENOMES

Abstract

Microchromosomes are prevalent in nonmammalian vertebrates [P. D. Waters et al., Proc. Natl. Acad. Sci. U.S.A. 118 (2021)], but a few of them are missing in bird genome assemblies. Here, we present a new chicken reference genome containing all autosomes, a Z and a W chromosome, with all gaps closed except for the W. We identified ten small microchromosomes (termed dot chromosomes) with distinct sequence and epigenetic features, among which six were newly assembled. Those dot chromosomes exhibit extremely high GC content and a high level of DNA methylation and are enriched for housekeeping genes. The pericentromeric heterochromatin of dot chromosomes is disproportionately large and continues to expand with the proliferation of satellite DNA and testis-expressed genes. Our analyses revealed that the 41-bp CNM repeat frequently forms higher-order repeats (HORs) at the centromeres of acrocentric chromosomes. The centromere core regions where the kinetochore attaches often encompass telomeric sequence (TTAGGG)n, and in a one of the dot chromosomes, the centromere core recruits an endogenous retrovirus (ERV). We further demonstrate that the W chromosome shares some common features with dot chromosomes, having large arrays of hypermethylated tandem repeats. Finally, using the complete chicken chromosome models, we reconstructed a fine picture of chordate karyotype evolution, revealing frequent chromosomal fusions before and after vertebrate whole-genome duplications. Our sequence and epigenetic characterization of chicken chromosomes shed insights into the understanding of vertebrate genome evolution and chromosome biology. [ABSTRACT FROM AUTHOR]

Published

2023

2. Wnt3a gradient converts radial to bilateral feather symmetry via topological arrangement of epithelia

Author

Randall B. Widelitz, Cheng-Ming Chuong, Ting-Xin Jiang, and Zhicao Yue

Subjects

Models, Anatomic, animal structures, Body Patterning, Biology, Topology, Models, Biological, Anterior region, Epithelium, Birds, Mesoderm, Wnt3 Protein, Imaging, Three-Dimensional, medicine, Morphogenesis, Animals, Process (anatomy), In Situ Hybridization, Skin, Multidisciplinary, Wing, Reverse Transcriptase Polymerase Chain Reaction, food and beverages, Gene Expression Regulation, Developmental, Feathers, Biological Sciences, Flight feather, Wnt Proteins, Dermal papillae, medicine.anatomical_structure, Retroviridae, Feather, visual_art, visual_art.visual_art_medium, Symmetry (geometry), Chickens

Abstract

The evolution of bilaterally symmetric feathers is a fundamental process leading toward flight. One major unsolved mystery is how the feathers of a single bird can form radially symmetric downy feathers and bilaterally symmetric flight feathers. In developing downy feather follicles, barb ridges are organized parallel to the long axis of the feather follicle. In developing flight-feather follicles, the barb ridges are organized helically toward the anterior region, leading to the fusion and creation of a rachis. Here we discover an anterior–posterior molecular gradient of wingless int (Wnt3)a in flight but not downy feathers. Global inhibition of the Wnt gradient transforms bilaterally symmetric feathers into radially symmetric feathers. Production of an ectopic local Wnt3a gradient reoriented barb ridges toward the source and created an ectopic rachis. We further show that the orientation of the Wnt3a gradient is dictated by the dermal papilla (DP). Swapping DPs between wing covert and breast downy feathers demonstrates that both feather symmetry and molecular gradients are in accord with the origin of the DP. Thus the fates of feather epidermal cells are not predetermined through some molecular codes but can be modulated. Together, our data suggest feathers are shaped by a DP→ Wnt gradient→helical barb ridge organization→creation of rachis→bilateral symmetry sequence. We speculate diverse feather forms can be achieved by adjusting the orientation and slope of molecular gradients, which then shape the topological arrangements of feather epithelia, thus linking molecular activities to organ forms and novel functions.

Published

2006

3. Wnt3a gradient converts radial to bilateral feather symmetry via topological arrangement of epithelia.

Author

Zhicao Yue, Ting-Xin Jiang, Widelitz, Randall Bruce, and Cheng-Ming Chuong

Subjects

*FEATHERS, *ANIMAL flight, *BIRDS, *PHYSICAL & theoretical chemistry, *CELLS, *TISSUES

Abstract

The evolution of bilaterally symmetric feathers is a fundamental process leading toward flight. One major unsolved mystery is how the feathers of a single bird can form radially symmetric downy feathers and bilaterally symmetric flight feathers. In developing downy feather follicles, barb ridges are organized parallel to the long axis of the feather follicle. In developing flight-feather follicles, the barb ridges are organized helically toward the anterior region, leading to the fusion and creation of a rachis. Here we discover an anterior-posterior molecular gradient of wingless int (Wnt3)a in flight but not downy feathers. Global inhibition of the Wnt gradient transforms bilaterally symmetric feathers into radially symmetric feathers. Production of an ectopic local Wnt3a gradient reoriented barb ridges toward the source and created an ectopic rachis. We further show that the orientation of the Wnt3a gradient is dictated by the dermal papilla (DP). Swapping DPs between wing covert and breast downy feathers demonstrates that both feather symmetry and molecular gradients are in accord with the origin of the DP. Thus the fates of feather epidermal cells are not predetermined through some molecular codes but can be modulated. Together, our data suggest feathers are shaped by a DP→Wnt gradient→helical barb ridge organization→creation of rachis→bilateral symmetry sequence. We speculate diverse feather forms can be achieved by adjusting the orientation and slope of molecular gradients, which then shape the topological arrangements of feather epithelia, thus linking molecular activities to organ forms and novel functions. [ABSTRACT FROM AUTHOR]

Published

2006