毛胜勇

性    别

男

学历学位

研究生学历、农学博士学位

职    称

教授

导师类别

博士生导师

专业领域

动物营养与饲料科学

研究方向

反刍动物营养；饲用微生物资源开发与应用

教育与工作经历

1994年9月-1998年6月，南京农业大学，畜牧专业攻读本科

1998年9月-2001年6月，南京农业大学，动物营养与饲料科学专业攻读硕士

2003年9月-2006年12月，南京农业大学，预防兽医学专业攻读博士

2008年1月-2008年12月，荷兰瓦赫宁根大学，微生物系开展访问学者研究工作

2001年7月至今，南京农业大学动物科技学院任教

联系方式

maoshengyong@njau.edu.cn；025-84395106

奖励及荣誉

教育部自然科学奖二等奖(2019):反刍动物消化道微生物功能及营养调控，排名第一；

教育部自然科学二等奖(2011):家畜胃肠道微生物功能及其调控研究，排名第二；

国家优秀教学成果二等奖一次，排名第8

参加学术团体及任职情况

南京农业大学动物科技学院院长、江苏省高校“青蓝工程”中青年学术带头人、江苏省“六大人才”高峰高层次人才、  中国畜牧兽医学会动物营养学分会常会理事、养牛学分会理事、江苏省饲料工业协会副理事长、南京农业大学反刍动物营养与饲料工程技术研究中心主任。

承担科研项目

1.国家自然科学基金面上项目。31872384，2019/01-2022/12，主持

2.江苏现代农业重大核心技术创新项目。2019/07-2022/06，主持

3.江苏省六大人才高峰项目。2019.1-2021.12，主持。

4.国家重点研发计划项目子课题。2018YFD0501604-02，2018/01－2020 /12，主持

5.国家重点研发计划项目子课题。2016YFD0501206,2016/07-2020/12，主持  

6.江苏省重点研发面上项目。BE2016382，2016/07-2019/06，主持

7.国家自然科学基金面上项目。31572436，2016/01-2019/12，主持

8.江苏省自然科学基金面上项目。BK20151431，2015/07-2018/06，主持

9.国家自然科学基金面上项目。31372339，2014/01-2017/12，主持

10.国家自然科学基金面上项目。31172228，2012/01-2015/12，主持 11.国家奶业“973”项目子课题。2011CB100801，2011/01-2015/11，主持

论文论著(2018-2021)

1.       Guo, C., Xue, Y., Sun, D., Yin, Y., Hu, F.,  & Mao, S. (2021). Transcriptome profiling of hepatic and renal  mRNAs and lncRNAs under a nutritional restriction during pregnancy in a sheep  model. Genomics.

2.       Xue, Y., Yin, Y., Trabi, E. B., Xie, F., Lin,  L., & Mao, S. (2021). Transcriptome analysis reveals the effect of  high-grain pelleted and non-pelleted diets on ruminal epithelium of Hu-lamb.  Animal, 15(7), 100278.

3.       Xie, F., Jin, W., Si, H., Yuan, Y., Tao, Y.,  Liu, J., ... & Mao, S. (2021). An integrated gene catalog and over  10,000 metagenome-assembled genomes from the gastrointestinal microbiome of  ruminants. Microbiome, 9(1), 1-20.

4.       Lin, L., Trabi, E. B., Xie, F., & Mao,  S. (2021). Comparison of the fermentation and bacterial community in the  colon of Hu sheep fed a low-grain, non-pelleted, or pelleted high-grain diet.  Applied Microbiology and Biotechnology, 105(5), 2071-2080.

5.       Sun, D., Yin, Y., Guo, C., Liu, L., Mao, S.,  Zhu, W., & Liu, J. (2021). Transcriptomic analysis reveals the molecular  mechanisms of rumen wall morphological and functional development induced by  different solid diet introduction in a lamb model. Journal of Animal Science  and Biotechnology, 12(1), 1-15.

6.       Yingyun Gong, Yanfeng Xue, Xin Li, Zhao Zhang,  Wenjun Zhou, Paola Marcolongo, Angiolo Benedetti, Shengyong Mao, Leng  Han, Guolian Ding, Zheng Sun. (2021). Inter‐and Transgenerational  Effects of Paternal Exposure to Inorganic Arsenic. Advanced Science, 8(7),  2002715

7.       Zhou, Y., Jin, W., Xie, F., Mao, S.,  Cheng, Y., & Zhu, W. (2021). The role of Methanomassiliicoccales in  trimethylamine metabolism in the rumen of dairy cows. Animal, 15(7), 100259.

8.       Mu, Y. Y., Qi, W. P., Zhang, T., Zhang, J. Y.,  & Mao, S. Y. (2021). Gene function adjustment for carbohydrate  metabolism and enrichment of rumen microbiota with antibiotic resistance  genes during subacute rumen acidosis induced by a high-grain diet in  lactating dairy cows. Journal of Dairy Science, 104(2), 2087-2105.

9.       Y Xue, L Lin, F Hu, W Zhu, S Mao.  Disruption of ruminal homeostasis by malnutrition involved in systemic  ruminal microbiota-host interactions in a pregnant sheep model. Microbiome,  2020,  8 (1), 1-14 

10.    L Lin, Y Wang, L Xu, J Liu, W Zhu, S Mao. Microbiome–host  co-oscillation patterns in remodeling of colonic homeostasis during  adaptation to a high-grain diet in a sheep model. Animal Microbiome, 2020,2  (1), 1-12          

11.    R Zhang, J Liu, L Jiang, S Mao. Effect of high-concentrate  diets on microbial composition, function, and the VFAs formation process in  the rumen of dairy cows. Animal Feed Science and Technology, 2020, 269, 114619            

12.    C Guo, Y Xue, Y Yin, D Sun, H Xuan, J Liu, S Mao. The  effect of glycerol or rumen-protected choline chloride on rumen fermentation  and blood metabolome in pregnant ewes suffering from negative energy balance.  Animal Feed Science and Technology. 2020, 268, 114594         

13.    C Guo, Y Xue, Y Yin, H Xuan, F Hu, S Mao. Urine metabolome  alterations in malnutrition and the impact of glycerol or rumen-protected  choline chloride supplementation in advanced pregnant ewes. British Journal  of Nutrition, 2020, 123 (11), 1258-1268           

14.    Y Xue, F Hu, C Guo, S Mei, F Xie, H Zeng, S Mao.  Undernutrition shifted colonic fermentation and digest-associated bacterial  communities in pregnant ewes. Applied Microbiology and Biotechnology,2020

15.    Y Xue, C Guo, F Hu, W Zhu, S Mao. Undernutrition‐induced lipid metabolism disorder triggers oxidative stress in  maternal and fetal livers using a model of pregnant sheep. The FASEB Journal,  2020, 34 (5), 6508-6520

16.    EB Trabi, H Seddik, F Xie, X Wang, J Liu, S Mao. Effect of  pelleted high-grain total mixed ration on rumen morphology,  epithelium-associated microbiota and gene expression of proinflammatory  cytokines and tight junction. Animal Feed Science and Technology, 2020, 263,  114453         

17.    Y Xue, C Guo, F Hu, W Zhu, S Mao. PPARA/RXRA signalling  regulates the fate of hepatic non-esterified fatty acids in a sheep model of  maternal undernutrition. Biochimica et Biophysica Acta (BBA)-Molecular and  Cell Biology of Lipids , 2020, 1865 (2) .158548

18.    Jin, W., Zhang, Z., Zhu, K., Xue, Y., Xie, F., & Mao, S.  (2019). Comprehensive Understanding of the Bacterial Populations and  Metabolites Profile of Fermented Feed by 16S rRNA Gene Sequencing and Liquid  Chromatography–Mass Spectrometry. Metabolites, 9(10), 239.

19.    Zhang, R. Y., Liu, Y. J., Yin, Y. Y., Jin, W., Mao, S. Y.,  & Liu, J. H. (2019). Response of rumen microbiota, and metabolic profiles  of rumen fluid, liver and serum of goats to high-grain diets. Animal, 1-10.

20.    Liu, L., Sun, D., Mao, S., Zhu, W., & Liu, J. (2019).  Infusion of sodium butyrate promotes rumen papillae growth and enhances  expression of genes related to rumen epithelial VFA uptake and metabolism in  neonatal twin lambs. Journal of Animal Science, 97(2), 909-921.

21.    Liu, J., Xue, C., Sun, D., Zhu, W., & Mao, S. (2019).  Impact of high‐grain diet feeding on mucosa‐associated bacterial community and gene expression of tight  junction proteins in the small intestine of goats. MicrobiologyOpen, 8(6),  e00745.

22.    Xue, Y., Guo, C., Hu, F., Zhu, W., & Mao, S. (2019).  Maternal undernutrition induces fetal hepatic lipid metabolism disorder and  affects the development of fetal liver in a sheep model. The FASEB Journal,  fj-201900406R.

23.    Guo, C., Sun, D., Wang, X., & Mao, S. (2019). A  Combined Metabolomic and Proteomic Study Revealed the Difference in  Metabolite and Protein Expression Profiles in Ruminal Tissue From Goats Fed  Hay or High-Grain Diets. Frontiers in Physiology, 10.

24.    Liu, J., Li, H., Zhu, W., & Mao, S. (2019). Dynamic  changes in rumen fermentation and bacterial community following rumen fluid  transplantation in a sheep model of rumen acidosis: implications for rumen  health in ruminants. The FASEB Journal, fj-201802456R.

25.    Lin, L., Xie, F., Sun, D., Liu, J., Zhu, W., & Mao, S.  (2019). Ruminal microbiome-host crosstalk stimulates the development of the  ruminal epithelium in a lamb model. Microbiome, 7(1), 83.

26.    Trabi, E. B., Seddik, H. E., Xie, F., Lin, L., & Mao, S.  (2019). Comparison of the rumen bacterial community, rumen fermentation and  growth performance of fattening lambs fed low-grain, pelleted or non-pelleted  high grain total mixed ration. Animal Feed Science and Technology, 253, 1-12.  

27.    Xue, Y. F., Guo, C. Z., Hu, F., Sun, D. M., Liu, J. H., & Mao,  S. Y. (2019). Molecular mechanisms of lipid metabolism disorder in livers  of ewes with pregnancy toxemia. Animal, 13(5), 992-999.

28.    Seddik, H., Xu, L., Wang, Y., & Mao, S. Y. (2019). A  rapid shift to high-grain diet results in dynamic changes in rumen epimural  microbiome in sheep. Animal, 13(8), 1614-1622.

29.    Xu, L., Y. Wang, J. Liu, W. Zhu, and S. Mao. 2018.  Morphological adaptation of sheep's rumen epithelium to high-grain diet  entails alteration in the expression of genes involved in cell cycle  regulation, cell proliferation and apoptosis. Journal of Animal Science and  Biotechnology 9.

30.    Zhang, R. Y., W. Jin, P. F. Feng, J. H. Liu, and S. Y. Mao.  2018. High-grain diet feeding altered the composition and functions of the  rumen bacterial community and caused the damage to the laminar tissues of  goats. Animal : an international journal of animal bioscience:1-10.

31.    Guo, C., H. Li, D. Sun, J. Liu, and S. Mao. 2018. Effects  of abomasal supplementation of quercetin on performance, inflammatory  cytokines, and matrix metalloproteinase genes expression in goats fed a  high-grain diet. Livestock Science 209:20-24.

32.     Hu, F., Y. Xue, C. Guo, J. Liu, and S. Mao.  2018. The response of ruminal fermentation, epithelium-associated microbiota,  and epithelial barrier function to severe feed restriction in pregnant ewes.  Journal of Animal Science 96(10):4293-4305.

33.    Sun, D. M., S. Y. Mao, W. Y. Zhu, and J. H. Liu. 2018.  Effect of starter diet supplementation on rumen epithelial morphology and  expression of genes involved in cell proliferation and metabolism in  pre-weaned lambs. Animal : an international journal of animal bioscience  12(11):2274-2283.

34.   Sun, D., H. Li, S. Mao, W. Zhu, and J.  Liu. 2018a. Effects of different starch source of starter on small intestinal  growth and endogenous GLP-2 secretion in preweaned lambs. Journal of Animal  Science 96(1):306-317.

35.   Jin, W., Y. Li, Y. Cheng, S. Mao, and  W. Zhu. 2018. The bacterial and archaeal community structures and  methanogenic potential of the cecal microbiota of goats fed with hay and high-grain  diets. Antonie Van Leeuwenhoek International Journal of General and Molecular  Microbiology 111(11):2037-2049.