Your search keyword '"ZHOU Jun"' showing total 5 results

1. A novel missense mutation in the gene encoding major intrinsic protein (MIP) in a Giant panda with unilateral cataract formation

Author

Bai, Chao, You, Yuyan, Liu, Xuefeng, Xia, Maohua, Wang, Wei, Jia, Ting, Pu, Tianchun, Lu, Yan, Zhang, Chenglin, Li, Xiaoguang, Yin, Yanqiang, Wang, Liqin, Zhou, Jun, and Niu, Lili

Published

2021

2. Comparative proteomics in captive giant pandas to identify proteins involved in age-related cataract formation.

Author

You, Yuyan, Bai, Chao, Wang, Wei, Zhan, Tongtong, Hu, Xin, Hao, Feier, Xia, Maohua, Liu, Yan, Ma, Tao, Liu, Yanhui, Zheng, Changming, Pu, Tianchun, Zhang, Yizhuo, Lu, Yanping, Ding, Nan, Li, Jing, Yin, Yanqiang, Chen, Yucun, Wang, Liqin, and Zhou, Jun

Subjects

GIANT panda, PANDAS, CATARACT, TRANSCRIPTION factors, PROTEINS, BLOOD testing, PROTEOMICS

Abstract

Approximately 20% of aged captive giant pandas (Ailuropoda melanoleuca) have cataracts that impair their quality of life. To identify potential biomarkers of cataract formation, we carried out a quantitative proteomics analysis of 10 giant pandas to find proteins differing in abundance between healthy and cataract-bearing animals. We identified almost 150 proteins exceeding our threshold for differential abundance, most of which were associated with GO categories related to extracellular localization. The most significant differential abundance was associated with components of the proteasome and other proteins with a role in proteolysis or its regulation, most of which were depleted in pandas with cataracts. Other modulated proteins included components of the extracellular matrix or cytoskeleton, as well as associated signaling proteins and regulators, but we did not find any differentially expressed transcription factors. These results indicate that the formation of cataracts involves a complex post-transcriptional network of signaling inside and outside lens cells to drive stress responses as a means to address the accumulation of protein aggregates triggered by oxidative damage. The modulated proteins also indicate that it should be possible to predict the onset of cataracts in captive pandas by taking blood samples and testing them for the presence or absence of specific protein markers. [ABSTRACT FROM AUTHOR]

Published

2023

3. RNA-Seq analysis in giant pandas reveals the differential expression of multiple genes involved in cataract formation.

Author

You, Yuyan, Bai, Chao, Liu, Xuefeng, Lu, Yan, Jia, Ting, Xia, Maohua, Yin, Yanqiang, Wang, Wei, Chen, Yucun, Zhang, Chenglin, Liu, Yan, Wang, Liqin, Pu, Tianchun, Ma, Tao, Liu, Yanhui, Zhou, Jun, Niu, Lili, Xu, Suhui, Ni, Yanxia, and Hu, Xin

Subjects

GIANT panda, CAPTIVE wild animals, RNA sequencing, REGULATOR genes, CATARACT

Abstract

Background: The giant panda (Ailuropoda melanoleuca) is an endangered mammalian species native to China. Fewer than 2500 giant pandas are known to exist, many of which are bred in captivity as a means to preserve and repopulate the species. Like other captive mammals, giant pandas acquire age-related cataracts, reducing their quality of life. Recent comparative genome-wide methylation analysis revealed 110 differentially methylated genes associated with cataract formation including six also associated with the formation of age-related cataracts in humans. Results: To investigate the pathological pathway in greater detail, here we used RNA-Seq analysis to investigate the differential expression profiles of genes in three giant pandas with cataracts and three healthy controls. We identified more than 700 differentially expressed genes, 29 of which were selected for further analysis based on their low q-value. We found that many of the genes encoded regulatory and signaling proteins associated with the control of cell growth, migration, differentiation and apoptosis, supporting previous research indicating a key role for apoptosis in cataract formation. Conclusion: The identification of genes involved in the formation of age-related cataracts could facilitate the development of predictive markers, preventative measures and even new therapies to improve the life of captive animals. [ABSTRACT FROM AUTHOR]

Published

2021

4. A novel missense mutation in the HSF4 gene of giant pandas with senile congenital cataracts.

Author

You, Yuyan, Bai, Chao, Liu, Xuefeng, Xia, Maohua, Yin, Yanqiang, Chen, Yucun, Wang, Wei, Jia, Ting, Lu, Yan, Pu, Tianchun, Zhang, Chenglin, Li, Xiaoguang, Wang, Liqin, Xiu, Yunfang, Niu, Lili, Zhou, Jun, Du, Yang, Liu, Yanhui, and Xu, Suhui

Subjects

MISSENSE mutation, GIANT panda, CATARACT, BLINDNESS, TRANSCRIPTION factors

Abstract

Cataracts are a common cause of visual impairment and blindness in mammals. They are usually associated with aging, but approximately one third of cases have a significant genetic component. Cataracts are increasingly prevalent among aging populations of captive giant pandas (Ailuropoda melanoleuca) and it is therefore important to identify genetic determinants that influence the likelihood of cataract development in order to distinguish between congenital and age-related disease. Here we screened for cataract-related genetic effects using a functional candidate gene approach combined with bioinformatics to identify the underlying genetic defect in a giant panda with congenital cataracts. We identified a missense mutation in exon 10 of the HSF4 gene encoding heat shock transcription factor 4. The mutation causes the amino acid substitution R377W in a highly conserved segment of the protein between the isoform-specific and downstream hydrophobic regions. Predictive modeling revealed that the substitution is likely to increase the hydrophobicity of the protein and disrupt interactions with spatially adjacent amino acid side chains. The mutation was not found in 13 unaffected unrelated animals but was found in an unrelated animal also diagnosed with senile congenital cataract. The novel missense mutation in the HSF4 gene therefore provides a potential new genetic determinant that could help to predict the risk of cataracts in giant pandas. [ABSTRACT FROM AUTHOR]

Published

2021

5. Genome-wide analysis of methylation in giant pandas with cataract by methylation-dependent restriction-site associated DNA sequencing (MethylRAD).

Author

You, Yuyan, Bai, Chao, Liu, Xuefeng, Xia, Maohua, Jia, Ting, Li, Xiaoguang, Zhang, Chenglin, Chen, Yucun, Zhao, Sufen, Wang, Liqin, Wang, Wei, Yin, Yanqiang, Xiu, Yunfang, Niu, Lili, Zhou, Jun, Ma, Tao, Du, Yang, and Liu, Yanhui

Subjects

GIANT panda, NUCLEOTIDE sequence, NUCLEOTIDE sequencing, CAPTIVE wild animals, CATARACT, EPIGENOMICS, RESTRICTION fragment length polymorphisms

Abstract

The giant panda (Ailuropoda melanoleuca) is a native species to China. They are rare and endangered and are regarded as the ‘national treasure’ and ‘living fossil’ in China. For the time being, there are only about 2500 giant pandas in the world. Therefore, we still have to do much more efforts to protect the giant pandas. In captive wildlife, the cataract incidence of mammalian always increases with age. Currently, in China, the proportion of elderly giant pandas who suffering from cataract has reached 20%. The eye disorder thus has a strong influence on the physical health and life quality of the elderly giant pandas. To discover the genes associated with the pathogenesis of cataract in the elderly giant panda and achieve the goal of early assessment and diagnosis of cataract in giant pandas during aging, we performed whole genome methylation sequencing in 3 giant pandas with cataract and 3 healthy giant pandas using methylation-dependent restriction-site associated DNA sequencing (MethylRAD). In the present study, we obtained 3.62M reads, on average, for each sample, and identified 116 and 242 differentially methylated genes (DMGs) between the two groups under the context of CCGG and CCWGG on genome, respectively. Further KEGG and GO enrichment analyses determined a total of 110 DMGs that are involved in the biological functions associated with pathogenesis of cataract. Among them, 6 DMGs including EEA1, GARS, SLITRK4, GSTM3, CASP3, and EGLN3 have been linked with cataract in old age. [ABSTRACT FROM AUTHOR]

Published

2019