◆获奖荣誉
主持(主研)鉴定科技成果10余项,获国家科技进步二等奖1项,四川省科技进步奖5项(一等奖1项、二等奖1项)、中国科普作家协会优秀科普作品奖和神龙中华农业科技奖各1项。
科研成果获奖:
1.《图解畜禽标准化规模养殖系列丛书》,国家科技进步二等奖,2020(排名第4)
2.简州大耳羊新品种培育及配套技术研究与推广应用,四川省人民政府,四川省科技进步奖,一等奖,2013(排名第3)
3.肉用山羊重要经济性状关键功能基因的发掘与应用,四川省人民政府,四川省科技进步奖,二等奖,2018(排名第1)
4.图解畜禽标准化规模养殖系列丛书,神龙中华农业科技奖(科学普及奖),2019(排名第4)
5.南江黄羊快长品系选育及产业化示范研究,四川省人民政府,四川省科技进步奖,三等奖,2012(排名第3)
6.简阳大耳羊品种选育与产业化关键技术研究与示范推广,四川省人民政府,四川省科技进步奖,三等奖,2009(排名第4)
7.波尔山羊引种适应性、纯种繁育和利用研究,四川省人民政府,四川省科技进步奖,三等奖,2001(排名第3)
8.《图解畜禽标准化规模养殖系列丛书》之《绵羊标准化规模养殖图册》,中国科普作家协会优秀科普作品金奖,2014(主编)
9.国家级新品种简州大耳羊培育特别贡献奖,简阳市委、简阳市人民政府,2013
教学成果获奖:
1.“一核心、两资源、三过程、四平台”动物科学专业人才培养模式构建与实践, 四川省人民政府,四川省第八届高等教育教学成果奖一等奖(四川农业大学教学成果特等奖),2018(排名第2)。
2.动物科学专业学术型人才培养模式构建与实践, 四川省人民政府,四川省第七届高等教育教学成果奖二等奖(四川农业大学教学成果特等奖),2014(排名第4)。
3.狠抓教材建设,努力提高《生物统计附试验设计》课程教学质量(教材), 四川省人民政府,四川省高等教育教学成果奖二等奖(四川农业大学教学成果一等奖),2005(排名第3)。
◆科研项目
先后主持(主研)国家科技支撑计划、国家自然科学基金、国家发改委生物育种能力建设、国家星火计划重大项目、科技部科技富民推进行动计划、四川省科技创新产业链示范工程项目、四川省育种攻关等国家及省(部)级科研项目20余项。
1.四川省农业农村厅,2020年畜禽新品种(配套系)培育项目—天府肉羊,2020-2021,首席专家
2.农业农村部农业重大技术协同推广计划试点项目——四川省肉羊高效生产配套技术推广应用,2019-2020,技术首席
3.国家自然科学基金面上项目,环状RNA CDR1as在山羊骨骼肌卫星细胞分化中的作用及分子海绵机制(31772578),2018-2020,主持
4.国家重点研发计划“畜禽重大疫病防控与高效安全养殖综合技术研发”专项“山羊高效安全养殖技术应用与示范”,2018-2020,子课题主持
5.四川省“十三五”育种公关项目,川中黑山羊金堂型高繁品系选育,2016-2020,主持
6.西藏自治区重大项目,西藏特色家畜选育与健康养殖,2017-2018,参加
7.国家自然科学基金面上项目,山羊骨骼肌细胞分化中H19-MyoD轴相关的核心lncRNAs调控网络构建(31672402),2017-2020,主研
◆发表论文
在《BBA- Gene Regulatory Mechanisms》《Current Biology》《Genetics Selection Evolution》《BMC Genomics》《Frontiers in Microbiology》《Frontiers in Genetics》《Scientific Reports》《Functional & Integrative Genomics》《Molecular Reproduction & Development》《Genomics》《BioMed Research International》《Molecular and Cellular Biochemistry》《Gene》《DNA and Cell Biology》《Animals》《Animal》《Animal Science Journal》《Livestock Science》《Biochemical Genetics》《Mitochondrial DNA》《Molecular Biology Reports》《Tropical Animal Health & Production》《Asian-Australasian Journal of Animal Sciences》《Cells》《Cytotechnology》《Gene Reports》和《Small Ruminant Research》等国际学术期刊以及《遗传》《中国农业科学》《畜牧兽医学报》《中国兽医学报》《西北农业学报》《吉林农业大学学报》《云南农业大学学报》《四川农业大学学报》《畜牧与兽医》《中国畜牧杂志》《中国草食动物科学》和《中国畜牧兽医》等国内外重要核心期刊发表科研论文在国内外重要核心期刊发表科研论文200余篇,其中第一作者(通信作者)130余篇,SCI收录60余篇。
[1]Distinct stage changes in early-life colonization and acquisition of the gut microbiota and its correlations with volatile fatty acids in goat kids. Front. Microbiol.,doi:10.3389/fmicb.2020.584742(通信作者)
[2]Identification and population genetic analyses of copy number variations in six domestic goat breeds and bezoar ibexes using next-generation sequencing. BMC Genomics. 2020,11. DOI : 10.1186/s12864-020-07267-6(通信作者)
[3]Comparative genome analyses reveal the unique genetic composition and selection signals underlying phenotypic characterization in three Chinese domestic goat breeds. Genetics Selection Evolution, 2019,51(1):70(通信作者)
[4]Systematic analyses reveal RNA editing events involved in skeletal muscle development of goat (Capra hircus). Functional & Integrative Genomics.2020, DOI: 10.1007/s10142-020-00741-0(通信作者)
[5]Characterization of the Rumen Microbiota and Volatile Fatty Acid Profile of Weaned Goat Kids under Shrub-grassland Grazing and Indoor Feeding. Animals,2020, 10(2), 176(通信作者)
[6]MyoD-induced circular RNA CDR1as promotes myogenic differentiation of skeletal muscle satellite cells.Biochim Biophys Acta Gene Regul Mech, 2019, 1862(8):807-821(通信作者)
[7]A Novel Long Noncoding RNA, lncR-125b, Promotes the Differentiation of Goat Skeletal Muscle Satellite Cells by Sponging miR-125b, Front. Genet. ,2019,10:01171(通信作者)
[8]Dynamic transcriptomic analysis in hircinelongissimus dorsimuscle from fetal to neonatal development stages, Funct Integr Genomics,2018,18(1):43-54(通信作者)
[9]Genome-wide Identification and Characterization of Long Non-coding RNAs in Developmental Skeletal Muscle of Fetal Goat, BMC Genomics,2016,17:666(通信作者)
[10]Identification and Expression Profiling of miRNAome in Goat longissimus dorsi Muscle from Prenatal Stages to a Neonatal Stage,PLoS ONE,2016, 11(10): e0165764.(通信作者)
[11]Type 3 Iodothyronine Deiodinase in Neonatal Goats:Molecular Cloning, Expression, Localization, and Methylation Signature,Functional & Integrative Genomics,2016,16(4):419-428(通信作者)
[12]Screening of Reproduction-Related Single-Nucleotide Variations From MeDIP-Seq Data in Sheep, Molecular Reproduction & Development, 2016,83:958-967(通信作者)
[13]Fibroblast Growth Factor 21 induces lipolysis more efficiently than it suppresses lipogenesis in goat adipocytes. Cytotechnology. 2018,70(5):1423-1433.(通信作者)
[14]Whole-genome sequencing reveals selection signatures associated with important traits in six goat breeds.Sci Rep. 2018,8(1):10405 .(通信作者)
[15]MiR-183 promotes preadipocyte differentiation by suppressing Smad4 in goats, 2018,Gene ,666: 158-164(通信作者)
[16]DNA Methylation Landscape of Body Size Variation in Sheep. Scientific Reports, 2015(5):13950(通信作者)
[17]Role of microRNA-101a in the Regulation of Goat Skeletal Muscle Satellite Cell Proliferation and Differentiation, Gene, 2015, 572:198-204(通信作者)
[18]Molecular Characterization and Different Expression Patterns of the FABP Gene Family During Goat Skeletal Muscle Development. Molecular Biology Reports, 2015,42(1):201-207(通信作者)
[19]The molecular Characterization and Temporal–spatial Expression of Myocyte Enhancer factor 2 Genes in the Goat and Their Association with Myofiber Traits. Gene, 2015 ,555: 223-230(通信作者)
[20]Comparison of Muscle Characteristics and Underpinning Mechanisms between Texel and Ujumqin Sheep Aged from Day 70 to 135 of Gestation. Livestock Science ,2016,192:8-16(通信作者)
[21]CDR1as/miRNAs-Related regulatory mechanisms in muscle development and diseases. Gene, 2020(730):144315(通信作者)
[22]The differential proliferation and differentiation ability of skeletal muscle satellite cell in Boer and Nanjiang brown goats. Small Ruminant Research, 2018, 169:99-107(通信作者)
[23]Molecular and functional characterization of the adiponectin (AdipoQ) gene in goat skeletal muscle satellite cells. Asian-Australasian Journal of Animal Sciences,2018,31(8): 1088-1097.(通信作者)