{"id":32,"date":"2017-03-26T12:23:41","date_gmt":"2017-03-26T19:23:41","guid":{"rendered":"http:\/\/labs.wsu.edu\/du\/?page_id=32"},"modified":"2023-01-16T13:33:24","modified_gmt":"2023-01-16T21:33:24","slug":"papers","status":"publish","type":"page","link":"https:\/\/labs.wsu.edu\/du\/papers\/","title":{"rendered":"Papers"},"content":{"rendered":"
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Selected Recent Publications <\/h2>\n\n<\/div>\r\n\n<\/div>\n\n\n
  1. Chae S. A., J. S. Son, J. M. de Avila, M. Du<\/strong>, and M. J. Zhu. (2022). Maternal exercise improves epithelial development of fetal intestine by enhancing apelin signaling and oxidative metabolism. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology<\/em>, In press. (IF: 3.619) <\/li>
  2. Liu, X., L. Zhao, Y. Chen, J.S. Son, S. A. Chae, Q. Tian, Y. Gao, J. M. de Avila, M. J. Zhu, and M. Du<\/strong>. (2022). AMP-activated protein kinase inhibition in fibro-adipogenic progenitors impairs muscle regeneration and increases fibrosis. Journal of Cachexia, Sarcopenia and Muscle<\/em>. In press (IF: 12.063)<\/li>
  3. Chae, S. A., J. S. Son, L. Zhao, Y. Gao, X. Liu, J. M. de Avila, M. J. Zhu, and M. Du<\/strong>. (2022). Exerkine apelin reverses obesity-induced placental dysfunction by accelerating mitochondrial biogenesis in mice. American Journal of Physiology-Endocrinology and Metabolism<\/em>. 322: E467-479. (IF: 5.382)<\/li>
  4. Liu, X., L. Zhao, Y. Chen, Y. Gao, Q. Tian, J. Sun, S. Chae, J. de avila, M. J. Zhu, and M. Du.<\/strong> (2022). Obesity induces adipose fibrosis and collagen cross-linking through suppressing AMPK and enhancing lysyl oxidase expression. BBA-Molecular Basis of Disease<\/em>. 1868: 166454.<\/li>
  5. Gao, Y., L. Zhao, J.S. Son, X. Liu, Y. Chen, M. J. Deavilla, M. J. Zhu, G. Murdoch, and M. Du.<\/strong> (2022). Maternal exercise before and during pregnancy facilitates embryonic myogenesis by enhancing thyroid hormone signaling. Thyroid<\/em>. 32: 581-593<\/em>.<\/li>
  6. Yu X., Y. Ma, Y. Luo, G. Tang, Z. Jiang, J. Zhang, B. Ye, Z. Huang, Y. Luo, M. Du<\/strong>, and B. Wang. (2022).  Neonatal vitamin A administration increases intramuscular fat by promoting angiogenesis and preadipocyte formation. Meat Science<\/em>. 191: 108847.<\/li>
  7. Zhang Y., Y. Guo, Y. Luo, M. Du<\/strong>, X. Yin, X. Xu, and G. Zhang. (2022). Integrated metabolomics and transcriptome revealed the effect of fermented Lycium barbarum<\/em> reside promoting Ovis aries<\/em> immunity. Frontiers in Immunology.<\/em> 13: 889436.<\/li>
  8. Son J.S., SA Chae, L. Zhao, H. Wang, J. M. de Avila, M. J. Zhu, Z. Jiang, and M. Du<\/strong>. (2022). Maternal exercise intergenerationally derives muscle-based thermogenesis via activation of apelin-AMPK signaling. EBioMedicine<\/em>. 76: 103842.<\/li>
  9. Chae, S. A., J. S. Son, and M. Du<\/strong>. (2022). Prenatal exercise in fetal development: a placental perspective. FEBS Journal<\/em>. 289: 3058\u20133071.<\/li>
  10. Wang, H.N., J. Z. Xiang, Z. Qi, and M. Du<\/strong>. (2022). Plant extracts in prevention of obesity. Critical Reviews in Food Science and Nutrition<\/em>. 62: 2221-2234.<\/li>
  11. Chen, Y.T., Q.Y. Yang, Y. Hu, X.D. Liu, J.M. de Avila, M.J. Zhu, P.W. Nathanielsz, and M. Du<\/strong>. (2021).  Imprinted LncRNA Dio3os preprograms intergenerational brown fat thermogenesis and obese resistance. Nature Communications<\/em>. 12, 6845.<\/li>
  12. Zhao, L., N. C. Law, N. A. Gomez, J. Son, Y. Gao, J. M. de Avila, M. J. Zhu, and M. Du<\/strong>. (2021). Obesity impairs embryonic myogenesis by enhancing BMP signaling within the dermomyotome. Advanced Science<\/em>. 8: 2102157.<\/li>
  13. Chen, Y., G. Ma, Y. Hu, Q. Yang, J. M. Deavila, M. J. Zhu, and M. Du<\/strong>. (2021). Effects of Maternal Exercise During Pregnancy on Perinatal Growth and Childhood Obesity Outcomes: A Meta-analysis and Meta-regression. Sports Medicine<\/em>. 51: 2329-2347.<\/li>
  14. Gu, H.F., F. Ren, X.Y. Mao, and M. Du<\/strong>. (2021). Mineralized and GSH-responsive hyaluronic acid based nano-carriers for potentiating repressive effects of sulforaphane on breast cancer stem cells-like properties. Carbohydrate Polymers<\/em>. 269: 118294.<\/li>
  15. Yuan, Q., H. Gong, T. Li, M. Du<\/strong>, and X. Mao. (2021). Supplementation of milk polar lipids to obese dams improves neurodevelopment and cognitive function in male offspring. FASEB Journal<\/em>. 35: e21454.<\/li>
  16. Chen, Y. T., Y. Hu, Q. Y. Yang, X. D. Liu, J. S. Son, J. M. de Avila, M. J. Zhu, and M. Du. <\/strong>(2021). Embryonic exposure to hyper glucocorticoids suppresses brown fat development and thermogenesis via REDD1. Science Bulletin<\/em>. 66: 478-489.<\/li>
  17. Son, J. S., S. A. Chae, H. Wang, Y. Chen, A. B. Iniguez, J. M. de Avila, M. J. Zhu, and M. Du<\/strong>. (2020). Maternal inactivity programs skeletal muscle dysfunction in offspring mice via attenuating apelin signaling and mitochondrial biogenesis. Cell Reports<\/em>. 33: 108461.<\/li>
  18. Liu, X., N. Moffitt-Hemmer, J. Deavilla, A. Li, Q. Tian, A. Bravo-Iniguez, Y. Chen, L. Zhao, M. Zhu, S. Meibergs, J. Busboom, M. Nelson, A. Tibary, and M. Du.<\/strong> (2020). Wagyu-Angus cross improves meat tenderness compared to Angus cattle but unaffected by mild protein restriction during late gestation. Animals<\/em>. 15: 100144.<\/li>
  19. Chae, S.A., J.S. Son, M.J. Zhu, J. M. de Avila, and M. Du<\/strong>. (2020). Treadmill running of mouse as a model for studying influence of maternal exercise on offspring. Bio-protocol<\/em>. 10: e3838.<\/li>
  20. Zhao, L., J. S. Son, B. Wang, Q .Tian, Y. Chen, X. Liu, J. M. de Avila, M. J. Zhu, and M. Du.<\/strong> (2020). Retinoic acid signaling in fibro\/adipogenic progenitors robustly enhances muscle regeneration. EBioMedicine<\/em>. 60: 103021.<\/li>
  21. Chen, Y.T., Y. Hu, Q.Y. Wang, J.S. Son, X.D. Liu, J.M. de Avila, M. J. Zhu, and M. Du<\/strong>. (2020). Excessive glucocorticoids during pregnancy impair fetal brown fat development and predisposes offspring to metabolic dysfunctions. Diabetes<\/em>. 69: 1662-1674.<\/li>
  22. Tian Q.Y., X.D. Liu, and M. Du<\/strong>. (2020). Alpha-ketoglutarate for adipose tissue rejuvenation. Aging<\/em>. 12: 13845-13846.<\/li>
  23. Son, J., L. Zhao, Y. Chen, K. Chen, S. A. Chae, J. M. de Avila, H. Wang, M.J. Zhu, Z. Jiang, and M. Du<\/strong>. (2020). Maternal exercise via exerkine apelin enhances brown adipogenesis and prevents metabolic dysfunction in offspring mice. Science Advances<\/em>. 6: eaaz0359.<\/li>
  24. Li, T., H. Gong, Q. Yuan, M. Du<\/strong>, F. Ren, and X. Mao. (2020). Supplementation of polar lipids-enriched milk fat globule membrane in high fat diet fed rats during pregnancy and lactation promotes brown\/beige adipocyte development and prevents obesity in male offspring. FASEB Journal<\/em>. 34: 4619-4634.<\/li>
  25. Tian, Q., J. Zhao, Q. Yang, B. Wang, J. Deavila, M.J. Zhu, and M. Du<\/strong>. (2020). Dietary alpha-ketoglutarate promotes beige adipogenesis and prevents obesity in middle-aged mice. Aging Cell<\/em>. 19: e13059.<\/li>
  26. Zhao, L., B. Wang, N. Gomez, J. Deavila, M. J. Zhu, and M. Du<\/strong>. (2020). Even a Low Dose of Tamoxifen Profoundly Induces Adipose Tissue Browning in Female Mice. International Journal of Obesity<\/em>. 44,226-234.<\/li>
  27. Gu, H., X. Mao, and M. Du<\/strong>. (2020). Prevention of breast cancer by dietary polyphenols: role of cancer stem cells. Critical Reviews in Food Science and Nutrition<\/em>. 60: 810-825.<\/li>
  28. Zou T., Y. Kang, B. Wang, J. M. Deavilla, J. You, M.J. Zhu, and M. Du<\/strong>. (2019). Raspberry supplementation reduces lipid accumulation and improves insulin sensitivity in skeletal muscle of mice fed a high-fat diet. Journal of Functional Foods<\/em>. 63: 103572.<\/li>
  29. Li, X., X. Fu, G. Yang, and M. Du<\/strong>. (2019). Review: Enhancing intramuscular fat development via targeting fibro-adipogenic progenitor cells in meat animals. Animals<\/em>. 14: 312-321.<\/li>
  30. Son, J., X. Liu, Q. Tian, L. Zhao, Y. Chen, Y. Hu, S. A. Chae, J. M. Deavila, M. J. Zhu, and M. Du<\/strong>. (2019). Exercise prevents the adverse effects of maternal obesity on placental vascularization and fetal growth. Journal of Physiology<\/em>. 597: 3333-3347.<\/li>
  31. Zhao, L., Y. Huang, and M. Du<\/strong>. (2019). Farm Animals for Studying Muscle Development and Metabolism: dual purposes for animal production and human health. Animal Frontiers<\/em>. 9:3.<\/li>
  32. Wei, S., A. Li, L. Zhang, and M. Du<\/strong>. (2019). Long noncoding RNAs in adipogenesis and adipose development of meat animals. Journal of Animal Science<\/em>. 97: 2644-2657.<\/li>
  33. Wang, H., Y. Chen, X. Mao, and M. Du<\/strong>. (2019). Maternal obesity impairs fetal mitochondriogenesis and brown adipose tissue development partially via upregulation of miR-204-5p. BBA-Molecular Basis of Disease<\/em>. 1865: 2706-2715.<\/li>
  34. Wang, H., X. Mao, and M. Du<\/strong>. (2019). Phytanic acid activates PPARa to promote beige adipogenic differentiation of preadipocytes. Journal of Nutritional Biochemistry<\/em>. 67: 201-211.<\/li>
  35. Zhao, L., M. Du<\/strong>, J. Gao, B. Zhan, and X. Mao, (2019). Label-free quantitative proteomic analysis of milk fat globule membrane proteins of yak and cow and identification of proteins associated with glucose and lipid metabolism. Food Chemistry<\/em>. 275: 59-68.<\/li>
  36. Chen, Y., Y. Yang, and M. Du<\/strong>. (2018). Beyond brown adipogenesis the inheritance of imprinted H19. Non-coding RNA Investigation<\/em>. 2:64.<\/li>
  37. Wang, B., C. L. Harris, W. Nie, X. Fu, J. M. Deavila, M. J. Zhu, M. Maquivar, S. M. Parish, J. R. Busboom, M. L. Nelson, and M. Du<\/strong>. (2018). Neonatal vitamin A injection promotes cattle muscle development and increase oxidative muscle fibers. Journal of Animal Science and Biotechnology<\/em>. 9: 82.<\/li>
  38. Zhu, M.J., X. Sun, and M. Du<\/strong>. (2018). AMPK in regulation of apical junctions and barrier junction of intestinal epithelium. Tissue Barriers<\/em>. 6: 1-13.<\/li>
  39. Harris, C. L., B. Wang, J. M. Deavila, J. R. Busboom, M. Maquivar, S. M. Parish, B. McCann, M. L. Nelson, and M. Du<\/strong>. (2018). Vitamin A administration at birth promotes calf growth and marbling fat development in Angus beef cattle. Journal of Animal Science and Biotechnology<\/em>. 9: 55.<\/li>
  40. Ma, Y.N., B. Wang, Z.X. Wang, N. A. Gomez, M. J. Zhu, and M. Du<\/strong>. (2018). Three dimensional spheroid culture of adipose stromal vascular cells for studying adipogenesis in beef cattle. Animals<\/em>. 12: 2123-2129.<\/li>
  41. Zhao, L., T. Zou, N. A. Gomez, B. Wang, M. J. Zhu, and M. Du<\/strong>. (2018). Raspberry alleviates obesity-induced inflammation and insulin resistance in skeletal muscle through activation of AMP-activated protein kinase (AMPK) \u03b11. Nutrition & Diabetes<\/em>. 8: 39.<\/li>
  42. Zou, T., B. Wang, Q. Yang, J. M. de Avila, M. J. Zhu, J. You, D. Chen, and M. Du<\/strong>. (2018). Raspberry promotes brown and beige adipocyte development in mice fed high-fat diet through activation of AMP-activated protein kinase (AMPK) a1. Journal of Nutritional Biochemistry<\/em>. 55: 157.<\/li>
  43. Bibi, S., M. Du<\/strong>, and M. J. Zhu. (2018). Dietary red raspberries reduces colorectal inflammation and carcinogenic risk in DSS-induced colitis in mice. Journal of Nutrition<\/em>. 51: 40-46.<\/li>
  44. Zhu, M. J., Kang, Y., Y. Xue, X. Liang, M. P. Gonzalez Carcia, D. Rodgers, D. K. Kagel, and  M. Du<\/strong>. (2018). Red raspberries suppress NLRP3 inflammasome and attenuate metabolic abnormalities in diet-induced obese mice. Journal of Nutritional Biochemistry<\/em>. 53:96-103.<\/li>
  45. Xing, T., Y. Kang, X. Xu, B. Wang, M. Du<\/strong>, and M. J. Zhu. (2018). Raspberry supplementation improves insulin signaling and promotes brown-like adipocyte development in white adipose tissue of obese mice. Molecular Nutrition & Food Research<\/em>. 2018, 62:1701035.<\/li>
  46. Wang, B., X. Fu, X. Liang, J. M. Deavila, Z. Wang, L. Zhao, Q. Tian, J. Zhao, N. A. Gomez, S. C. Trombetta, M. J. Zhu, and M. Du<\/strong>.(2017). Retinoic acid induces white adipose tissue browning by increasing adipose vascularity and inducing beige adipogenesis of PDGFRa+ adipose progenitors. Cell Discovery<\/em>. 3:17036.<\/li>
  47. Sun, X. X. Fu, Q. Y. Yang, M. Du<\/strong>, and M. J. Zhu. (2017). AMPK regulate intestinal differentiation via histone modification of CDX2. Cell Death and Differentiation<\/em>. 24: 819-831.<\/li>
  48. Yang, Q., X. Liang, X. Sun, L. Zhang, X. Fu, C. J. Rogers, A. Berim, S. Zhang, S. Wang, B. Wang, M. Foretz, B. Viollet, D. R. Gang, B. D. Rodgers, M. Zhu, and M. Du<\/strong>. (2016). AMPK\/\u03b1-ketoglutarate axis dynamically mediates DNA demethylation in the Prdm16 promoter and brown adipogenesis. Cell Metabolism<\/em>. 24: 542-554.<\/li><\/ol>\n\n\n\n

    For all publications, please visit: <\/p>\n\n\n\n

    https:\/\/www.webofscience.com\/wos\/author\/rid\/H-4311-2011<\/a><\/p>\n\n\n\n

    https:\/\/scholar.google.com\/citations?user=gzjcTFUAAAAJ&hl=en<\/a><\/p>\n","protected":false},"excerpt":{"rendered":"

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