Your search keyword '"Yue, Yaojing"' showing total 5 results

1. Transcriptomics and metabolomics reveal improved performance of Hu sheep on hybridization with Southdown sheep.

Author

Kong, Lingying, Yue, Yaojing, Li, Jianye, Yang, Bohui, Chen, Bowen, Liu, Jianbin, and Lu, Zengkui

Subjects

*SHEEP, *SHEEP breeds, *AMINO acid metabolism, *SHEEP breeding, *MEAT quality, *METABOLOMICS

Abstract

[Display omitted] • Southdown × Hu F 1 sheep performance improved. • Key genes METTL21C , PPARGC1A and WFIKKN2 were screened. • METTL21C had a significant positive correlation with carnosine. • Amino acid metabolism comprehensively regulates Southdown × Hu F 1 mutton quality. Consumers are increasingly demanding high-quality mutton. Cross breeding can improve meat quality and is widely used in sheep breeding. However, little is known about the molecular mechanism of cross breeding sheep meat quality. In this study, male Southdown and female Hu sheep were hybridized. The slaughter performance and longissimus dorsi quality of the 6-month-old hybrid offspring were measured, and the longissimus dorsi of the hybrid offspring was analyzed by transcriptomics and metabolomics to explore the effect of cross breeding on meat quality. The results showed that the production performance of Southdown × Hu F 1 sheep was significantly improved, the carcass fat content was significantly decreased, and the eating quality of Southdown × Hu F 1 sheep were better. Compared with the HS group (Hu × Hu), the NH group (Southdown × Hu) had 538 differentially expressed genes and 166 differentially expressed metabolites (P < 0.05), which were significantly enriched in amino acid metabolism and other related pathways. Up-regulated genes METTL21C , PPARGC1A and down-regulated gene WFIKKN2 are related to muscle growth and development. Among them, the METTL21C gene, which is related to muscle development, was highly correlated with carnosine, a metabolite related to meat quality (correlation > 0.6 and P < 0.05). Our results provide further understanding of the molecular mechanism of cross breeding for sheep muscle growth and meat quality optimization. [ABSTRACT FROM AUTHOR]

Published

2023

2. Genome‐wide detection of structural variation in some sheep breeds using whole‐genome long‐read sequencing data.

Author

Qiao, Guoyan, Xu, Pan, Guo, Tingting, He, Xue, Yue, Yaojing, and Yang, Bohui

Subjects

*WHOLE genome sequencing, *SHEEP breeding, *MERINO sheep, *SHEEP breeds, *NUCLEOTIDE sequencing, *GENETIC variation, *CATTLE genetics, *SHEEP

Abstract

Genomic structural variants (SVs) constitute a significant proportion of genetic variation in the genome. The rapid development of long‐reads sequencing has facilitated the detection of long‐fragment SVs. There is no published study to detect SVs using long‐read data from sheep. We applied a long‐read mapping approach to detect SVs and characterized a total of 30,771 insertions, deletions, inversions and translocations. We identified 716, 916, 842 and 303 specific SVs in Southdown sheep, Alpine merino sheep, Qilian White Tibetan sheep and Oula sheep, respectively. We annotated these SVs and found that these SV‐related genes were primarily enriched in the well‐established pathways involved in the regulation of the immune system, growth and development and environmental adaptability. We detected and annotated SVs based on NGS resequencing data to validate the accuracy based on third‐generation detection. Moreover, five candidate SVs were verified using the PCR method in 50 sheep. Our study is the first to use a long‐reads sequencing approach to construct a novel structural variation map in sheep. We have completed a preliminary exploration of the potential effects of SVs on sheep. [ABSTRACT FROM AUTHOR]

Published

2024

3. Genome-Wide Association Study of Body Weight Traits in Chinese Fine-Wool Sheep.

Author

Lu, Zengkui, Yue, Yaojing, Yuan, Chao, Liu, Jianbin, Chen, Zhiqiang, Niu, Chune, Sun, Xiaoping, Zhu, Shaohua, Zhao, Hongchang, Guo, Tingting, and Yang, Bohui

Subjects

*SHEEP breeding, *BODY weight, *SHEEP, *SHEEP industry, *MUSCLE growth, *SINGLE nucleotide polymorphisms, *LIPID metabolism

Abstract

Simple Summary: Body weight traits are economically important in the sheep industry, and it is critical to explore their underlying genetic architecture. Hence, four body weight traits, including birth, weaning, yearling, and adult weights were examined. Through a genome-wide association study on Chinese fine-wool sheep, several candidate single-nucleotide polymorphisms (SNPs) and genes were found potentially associated with the traits of interest. The results of this study may facilitate the potential use of the genes involved in growth and production traits for the genetic improvement of productivity in sheep. Body weight is an important economic trait for sheep and it is vital for their successful production and breeding. Therefore, identifying the genomic regions and biological pathways that contribute to understanding variability in body weight traits is significant for selection purposes. In this study, the genome-wide associations of birth, weaning, yearling, and adult weights of 460 fine-wool sheep were determined using resequencing technology. The results showed that 113 single nucleotide polymorphisms (SNPs) reached the genome-wide significance levels for the four body weight traits and 30 genes were annotated effectively, including AADACL3, VGF, NPC1, and SERPINA12. The genes annotated by these SNPs significantly enriched 78 gene ontology terms and 25 signaling pathways, and were found to mainly participate in skeletal muscle development and lipid metabolism. These genes can be used as candidate genes for body weight in sheep, and provide useful information for the production and genomic selection of Chinese fine-wool sheep. [ABSTRACT FROM AUTHOR]

Published

2020

4. Genetic signatures of high-altitude adaptation and geographic distribution in Tibetan sheep.

Author

Liu, Jianbin, Yuan, Chao, Guo, Tingting, Wang, Fan, Zeng, Yufeng, Ding, Xuezhi, Lu, Zengkui, Renqing, Dingkao, Zhang, Hao, Xu, Xilan, Yue, Yaojing, Sun, Xiaoping, Niu, Chune, Zhuoga, Deqing, and Yang, Bohui

Subjects

*SHEEP breeding, *CHROMOSOMES, *GENOMES, *POLYMERASE chain reaction, *CATTLE

Abstract

Most sheep breeding programs designed for the tropics and sub-tropics have to take into account the impacts of environmental adaptive traits. However, the genetic mechanism regulating the multiple biological processes driving adaptive responses remains unclear. In this study, we applied a selective sweep analysis by combing 1% top values of Fst and ZHp on both altitude and geographic subpopulations (APS) in 636 indigenous Tibetan sheep breeds. Results show that 37 genes were identified within overlapped genomic regions regarding Fst significantly associated with APS. Out of the 37 genes, we found that 8, 3 and 6 genes at chromosomes (chr.) 13, 23 and 27, respectively, were identified in the genomic regions with 1% top values of ZHp. We further analyzed the INDEL variation of 6 genes at chr.27 (X chromosome) in APS together with corresponding orthologs of 6 genes in Capra, Pantholops, and Bos Taurus. We found that an INDEL was located within 5′UTR region of HAG1 gene. This INDEL of HAG1 was strongly associated with the variation of APS, which was further confirmed by qPCR. Sheep breeds carrying "C-INDEL" of HAG1 have significantly greater body weight, shear amount, corpuscular hemoglobin and globulin levels, but lower body height, than those carrying "CA-INDEL" of HAG1. We concluded that "C-INDEL" variation of HAG1 gene confers better hypoxia tolerance in the highlands of Tibetan and explains well geographic distributions in this population. These results contribute to our understanding of adaptive responses to altitude and geographic adaptation in Tibetan sheep populations and will help to guide future conservation programs for Tibetan sheep native to Qinghai-Tibetan Plateau. [ABSTRACT FROM AUTHOR]

Published

2020

5. Comparative proteomics reveals genetic mechanisms underlying secondary hair follicle development in fine wool sheep during the fetal stage.

Author

Guo, Tingting, Han, Jilong, Yuan, Chao, Liu, Jianbin, Niu, Chune, Lu, Zengkui, Yue, Yaojing, and Yang, Bohui

Subjects

*HAIR follicles, *SHEEP breeding, *WOOL, *SHEEP, *PROTEOMICS, *FETAL development

Abstract

The aim of this study was to investigate the genetic mechanisms underlying wool production by characterizing the skin protein profile and determining the proteomic changes that occur as a consequence of development in wool-producing sheep using a label-free proteomics approach. Samples were collected at four stages during gestation (87, 96, 102, and 138 days), and every two consecutive stages were statistically compared (87 versus 96, 96 versus 102, and 102 versus 138 days). We identified 227 specific proteins in the sheep proteome that were present in all four stages, and 123 differentially abundant proteins (DAPs). We also observed that the microstructure of the secondary follicles changed significantly during the development of the fetal skin hair follicle. The screened DAPs were strictly related to metabolic and skin development pathways, and were associated with pathways such as the glycolysis/gluconeogenesis. These analyses indicated that the wool production of fine wool sheep is regulated via a variety of pathways. These findings provide an important resource that can be used in future studies of the genetic mechanisms underlying wool traits in fine wool sheep, and the identified DAPs should be further investigated as candidate markers for predicting wool traits in sheep. Wool quality (fiber diameter, length, etc.) is an important economic trait of fine wool sheep that is determined by secondary follicle differentiation and re-differentiation. Secondary follicles of fine wool sheep developed from a bud (87 days), and underwent differentiation (96 days) and rapid growth (102 days) until maturity (138 days) during gestation. Comparative analysis based on differential proteomics of these four periods could provide a better understanding of the wool growth mechanism of fine wool sheep and offer novel strategies for improving fine wool quality by breeding. Unlabelled Image • Proteomic changes occur as a consequence of development in wool-producing sheep. • Secondary follicle microstructure changed during fetal skin hair follicle development. • The KRT family plays a key role in hair follicle development. • Alpha-fetoprotein may prevent fine wool sheep from freezing. [ABSTRACT FROM AUTHOR]

Published

2020