近年来在Nature Genetics、Nature Communications、Genome Research等学术杂志发表研究型SCI论文60篇(其中影响因子10分以上3篇),累计影响因子约188.74,累计引用次数853次。以第一或共同第一作者在Nature Genetics等杂志发表SCI论文20篇,累计影响因子73.12,通讯作者发表中文核心期刊2篇: 1.Genomic analyses identify distinct patterns of selection in domesticated pigs and Tibetan wild boars. Nature Genetics, 2013, 45: 1431-1438. (SCI, IF=29.648),共同第一作者 2.Mitochondrial DNA evidence indicates the local origin of domestic pigs in the upstream region of the Yangtze River. PLoS One, 2012, 7: e51649. (SCI, IF=3.730)第一作者 3.Genome-wide Profiling of Gene Expression and DNA Methylation Provides Insight into Low-altitude Acclimation in Tibetan Pigs. Gene, 2018, 642: 522-532. (SCI, IF=2.638)第一作者 4.Global Long Noncoding RNA and mRNA Expression Changes between Prenatal and Neonatal Lung Tissue in Pigs. Genes, 2018, 9, 443. (SCI, IF=3.331)第一作者 5.Transcriptional Differences of Coding and Non-Coding Genes Related to the Absence of Melanocyte in Skins of Bama Pig. Genes, 2020, 11, 47. (SCI, IF=3.331)第一作者 6.Genomic analyses identify distinct patterns of selection in domesticated pigs and Tibetan wild boars. Nature Genetics, 2013, 45: 1431-1438. (SCI, IF=29.648)共同第一作者 7.Snapshot of structural variations in the Tibetan wild boar genome at single-nucleotide resolution. Journal of Genetics & Genomics, 2014, 41: 653-657. (SCI, IF=3.585)共同第一作者 8.Transcriptomic analysis between Normal and high-intake feeding geese provides insight into adipose deposition and susceptibility to fatty liver in migratory birds. BMC Genomics, 2019; 20:372. (SCI, IF=3.501)共同第一作者 9.Long Noncoding RNA GAS5 Suppresses 3T3-L1 Cells Adipogenesis Through miR-21a-5p/PTEN Signal Pathway. DNA and Cell Biology, 2018. (SCI, IF=2.918)共同第一作者 10.Identification of a novel antisense long non-coding RNA PLA2G16-AS that regulates the expression of PLA2G16 in pigs. Gene, 2018. (SCI, IF=2.638)共同第一作者 11.Detection of genetic diversity and selection at the coding region of the melanocortin receptor 1 (MC1R) gene in Tibetan pigs and Landrace pigs. Gene, 2016, 575: 537 ~ 542. (SCI, IF=2.415)共同第一作者 12.Deciphering the microRNA transcriptome of skeletal muscle during porcine development, Peer J, 2016, 4: e1504 ~ e1504. (SCI, IF=2.177)共同第一作者 13.Dynamic microRNAome profiles in the developing porcine liver. Bioscience, Biotechnology, & Biochemistry, 2017, 81 (1): 127 ~ 134. (SCI, IF=1.255)共同第一作者 14.Dynamic changes in genes related to glucose uptake and utilization during pig skeletal and cardiac muscle development, Bioscience, Biotechnology, and Biochemistry. 2014, 78(7). (SCI, IF=1.063)共同第一作者 15.Hemicastration induced spermatogenesis-related DNA methylation and gene expression changes in mice testis. Asian-Australasian Journal of Animal Sciences, 2018, 31(2): 189. (SCI, IF=1.243)共同第一作者 16.Analysis of mitochondrial DNA sequence and copy number variation across five high-altitude species and their low-altitude relatives. Mitochondrial DNA, 2018. (SCI, IF=0.561)共同第一作者 17.Detecting mitochondrial signatures of selection in wild Tibetan pigs and domesticated pigs. Mitochondrial DNA, 2014, 27: 747-752. (SCI, IF=1.209)共同第一作者 18.Quantitative changes in mitochondrial DNA copy number in various tissues of pigs during growth. Genetics & Molecular Research, 2015, 14: 1662-1670. (SCI, IF=1.013),共同第一作者 19.Development-related expression patterns of protein-coding and miRNA genes involved in porcine muscle growth. Genetics & Molecular Research, 2014, 13: 9921-9930. (SCI, IF=0.775),共同第一作者 20.Genome-wide analysis reveals selection for Chinese Rongchang pigs. Frontiers of Agricultural Science and Engineering, 2017, 4(3): 319-326.共同第一作者 21.哺乳动物染色质三维结构单元的特征及其相互关系,农业生物技术学报, 2019, 27(8).通讯作者 22.LncRNA调控骨骼肌发育的分子机制及其在家养动物中的研究进展,遗传, 2018, 40(4): 292-304.通讯作者 |