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Three-dimensional spheroid culture of adipose stromal vascular cells for studying adipogenesis in beef cattle

Published online by Cambridge University Press:  22 February 2018

Y. N. Ma ,
B. Wang ,
Z. X. Wang ,
N. A. Gomez ,
M. J. Zhu  and
M. Du
Y. N. Ma*
Affiliation:
College of Animal Science and Technology, Gansu Agricultural University, Lanzhou, Gansu 730070, P. R. China Department of Animal Sciences, Washington State University, Pullman, WA 99164, USA
B. Wang
Affiliation:
Department of Animal Sciences, Washington State University, Pullman, WA 99164, USA
Z. X. Wang
Affiliation:
Department of Animal Sciences, Washington State University, Pullman, WA 99164, USA
N. A. Gomez
Affiliation:
Department of Animal Sciences, Washington State University, Pullman, WA 99164, USA
M. J. Zhu
Affiliation:
School of Food Science, Washington State University, Pullman, WA 99164, USA
M. Du
Affiliation:
Department of Animal Sciences, Washington State University, Pullman, WA 99164, USA
*
E-mail: [email protected]
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Abstract

Protocols designed for the adipogenic differentiation of human and mouse cells are commonly used for inducing the adipogenesis of bovine stromal vascular cells. However, likely due to metabolic differences between ruminant and non-ruminant animals, these methods result in only few cells undergoing complete adipogenesis with minimal lipid droplet accumulation. Here, we discuss the development of an adipogenic differentiation protocol for bovine primary cells through a three-dimensional spheroid culture. Stromal vascular cells derived from bovine intramuscular fat were isolated and stored in liquid nitrogen before culturing. Cells were cultured in hanging drops for 3 days to allow for the formation of spherical structures. The spheroids were then transferred to cell culture plates with endothelial basal medium-2 for 3 days and in Dulbecco’s Modified Eagle’s Medium (DMEM) supplemented with a standard adipogenic cocktail for 3 additional days, which were then allowed to fully differentiate for 3 days in DMEM supplemented with insulin. Compared with conventional two-dimensional culture, cells in a three-dimensional spheroid culture system had higher adipogenic gene expression and consequently contained more adipocytes with larger lipid droplets. In addition, endothelial induction of spheroids prior to adipogenic differentiation is essential for efficient induction of adipogenesis of bovine stromal vascular cells, mimicking in vivo adipose development. In summary, the newly developed three-dimensional spheroid culture method is an efficient way to induce adipogenic differentiation and study adipose development of cells derived from ruminant animals, which also can be used for studying the role of angiogenesis in adipose development.

Keywords

angiogenesisprimary cultureendotheliumprotocolruminant
Type
Research Article
Information
animal , Volume 12 , Issue 10 , October 2018 , pp. 2123 - 2129
Copyright
© The Animal Consortium 2018 

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References

Bergen, WG and Mersmann, HJ 2005. Comparative aspects of lipid metabolism: impact on contemporary research and use of animal models. The Journal of Nutrition 135, 24992502.Google Scholar
Bouchard, F and Paquin, J 2013. Differential effects of retinoids and inhibitors of ERK and p38 signaling on adipogenic and myogenic differentiation of P19 stem cells. Stem Cells and Development 22, 20032016.Google Scholar
Cao, Y 2007. Angiogenesis modulates adipogenesis and obesity. The Journal of Clinical Investigation 117, 23622368.Google Scholar
Cao, Y 2013. Angiogenesis and vascular functions in modulation of obesity, adipose metabolism, and insulin sensitivity. Cell Metabolism 18, 478489.Google Scholar
Chawla, A, Schwarz, EJ, Dimaculangan, DD and Lazar, MA 1994. Peroxisome proliferator-activated receptor (PPAR) gamma: adipose-predominant expression and induction early in adipocyte differentiation. Endocrinology 135, 798800.Google Scholar
Dani, C, Smith, AG, Dessolin, S, Leroy, P, Staccini, L, Villageois, P, Darimont, C and Ailhaud, G 1997. Differentiation of embryonic stem cells into adipocytes in vitro. Journal of Cell Science 110, 12791285.Google Scholar
Edvardsson, U, Bergström, M, Alexandersson, M, Bamberg, K, Ljung, B and Dahllöf, B 1999. Rosiglitazone (BRL49653), a PPARγ-selective agonist, causes peroxisome proliferator-like liver effects in obese mice. Journal of Lipid Research 40, 11771184.Google Scholar
Fajas, L, Debril, MB and Auwerx, J 2001. Peroxisome proliferator-activated receptor-gamma: from adipogenesis to carcinogenesis. Journal of Molecular Endocrinology 27, 19.Google Scholar
Grant, AC, Ortiz-Colon, G, Doumit, ME and Buskirk, DD 2008a. Optimization of in vitro conditions for bovine subcutaneous and intramuscular preadipocyte differentiation. Journal of Animal Science 86, 7382.Google Scholar
Grant, A, Ortiz-Colón, G, Doumit, M, Tempelman, R and Buskirk, D 2008b. Differentiation of bovine intramuscular and subcutaneous stromal-vascular cells exposed to dexamethasone and troglitazone. Journal of Animal Science 86, 25312538.Google Scholar
Green, H and Kehinde, O 1974. Sublines of mouse 3T3 cells that accumulate lipid. Cell 1, 113116.Google Scholar
Guan, L, Hu, X, Liu, L, Xing, Y, Zhou, Z, Liang, X, Yang, Q, Jin, S, Bao, J, Gao, H, Du, M, Li, J and Zhang, L 2017. bta-miR-23a involves in adipogenesis of progenitor cells derived from fetal bovine skeletal muscle. Scientific Reports 7, 43716.Google Scholar
Gupta, RK, Arany, Z, Seale, P, Mepani, RJ, Ye, L, Conroe, HM, Roby, YA, Kulaga, H, Reed, RR and Spiegelman, BM 2010. Transcriptional control of preadipocyte determination by Zfp423. Nature 464, 619623.Google Scholar
Hillgartner, FB, Salati, LM and Goodridge, AG 1995. Physiological and molecular mechanisms involved in nutritional regulation of fatty acid synthesis. Physiological Reviews 75, 4776.Google Scholar
Huch, M and Koo, B-K 2015. Modeling mouse and human development using organoid cultures. Development 142, 31133125.Google Scholar
Hudak, CS, Gulyaeva, O, Wang, YH, Park, SM, Lee, L, Kang, C and Sul, HS 2014. Pref-1 marks very early mesenchymal precursors required for adipose tissue development and expansion. Cell Reports 8, 678687.Google Scholar
Iles, LR and Bartholomeusz, GA 2016. Three-dimensional spheroid cell culture model for target identification utilizing high-throughput RNAi screens. Methods in Molecular Biology 1470, 121135.Google Scholar
Laliotis, GP, Bizelis, L and Rogdakis, E 2010. Comparative approach of the de novo fatty acid synthesis (lipogenesis) between ruminant and non ruminant mammalian species: from biochemical level to the main regulatory lipogenic genes. Current Genomics 11, 168183.Google Scholar
Lee, YH, Petkova, AP, Mottillo, EP and Granneman, JG 2012. In vivo identification of bipotential adipocyte progenitors recruited by beta3-adrenoceptor activation and high-fat feeding. Cell Metabolism 15, 480491.Google Scholar
Pu, Y and Veiga-Lopez, A 2017. PPAR gamma agonist through the terminal differentiation phase is essential for adipogenic differentiation of fetal ovine preadipocytes. Cellular & Molecular Biology Letters 22, 6.Google Scholar
Qu, H, Donkin, S and Ajuwon, K 2015. Heat stress enhances adipogenic differentiation of subcutaneous fat depot-derived porcine stromovascular cells. Journal of Animal Science 93, 38323842.Google Scholar
Raoufi, MF, Tajik, P, Dehghan, MM, Eini, F and Barin, A 2011. Isolation and differentiation of mesenchymal stem cells from bovine umbilical cord blood. Reproduction in Domestic Animals 46, 9599.Google Scholar
Roh, SG, Hishikawa, D, Hong, YH and Sasaki, S 2006. Control of adipogenesis in ruminants. Animal Science Journal 77, 472477.Google Scholar
Rosen, ED, Hsu, C-H, Wang, X, Sakai, S, Freeman, MW, Gonzalez, FJ and Spiegelman, BM 2002. C/EBPα induces adipogenesis through PPARγ: a unified pathway. Genes & Development 16, 2226.Google Scholar
Rosen, ED and MacDougald, OA 2006. Adipocyte differentiation from the inside out. Nature Reviews. Molecular Cell Biology 7, 885896.Google Scholar
Smith, GC, Savell, JW, Cross, HR, Carpenter, ZL, Murphey, CE, Davis, GW, Abraham, HC, Parrish, FC and Berry, BW 1987. Relationship of USDA quality grades to palatability of cooked beef. Journal of Food Quality 10, 269286.Google Scholar
Smith, SB, Prior, RL and Mersmann, HJ 1983. Interrelationships between insulin and lipid metabolism in normal and alloxan-diabetic cattle. The Journal of Nutrition 113, 10021015.Google Scholar
Sun, T, Yu, C, Gao, Y, Zhao, C, Hua, J, Cai, L, Guan, W and Ma, Y 2014. Establishment and biological characterization of a dermal mesenchymal stem cells line from bovine. Bioscience Reports 34, e00101.Google Scholar
Tang, QQ, Otto, TC and Lane, MD 2004. Commitment of C3H10T1/2 pluripotent stem cells to the adipocyte lineage. Proceedings of the National Academy of Sciences of the United States of America 101, 96079611.Google Scholar
Taniguchi, M, Guan, LL, Zhang, B, Dodson, MV, Okine, E and Moore, SS 2008. Adipogenesis of bovine perimuscular preadipocytes. Biochemical and Biophysical Research Communications 366, 5459.Google Scholar
Taylor, SM and Jones, PA 1979. Multiple new phenotypes induced in 10T1/2 and 3T3 cells treated with 5-azacytidine. Cell 17, 771779.Google Scholar
Tran, KV, Gealekman, O, Frontini, A, Zingaretti, MC, Morroni, M, Giordano, A, Smorlesi, A, Perugini, J, De Matteis, R, Sbarbati, A, Corvera, S and Cinti, S 2012. The vascular endothelium of the adipose tissue gives rise to both white and brown fat cells. Cell Metabolism 15, 222229.Google Scholar
Vernon, RG 1980. Lipid metabolism in the adipose tissue of ruminant animals. Progress in Lipid Research 19, 23106.Google Scholar
Villena, JA, Kim, KH and Sul, HS 2002. Pref-1 and ADSF/resistin: two secreted factors inhibiting adipose tissue development. Hormone and Metabolic Research 34, 664670.Google Scholar
Vishvanath, L, MacPherson, KA, Hepler, C, Wang, QA, Shao, M, Spurgin, SB, Wang, MY, Kusminski, CM, Morley, TS and Gupta, RK 2015. Pdgfrβ+ mural preadipocytes contribute to adipocyte hyperplasia induced by high-fat-diet feeding and prolonged cold exposure in adult mice. Cell Metabolism 23, 350359.Google Scholar
Wang, B, Fu, X, Liang, X, Deavila, JM, Wang, Z, Zhao, L, Tian, Q, Zhao, J, Gomez, NA, Trombetta, SC, Zhu, MJ and Du, M 2017a. Retinoic acid induces white adipose tissue browning by increasing adipose vascularity and inducing beige adipogenesis of PDGFRalpha+ adipose progenitors. Cell Discovery 3, 17036.Google Scholar
Wang, B, Fu, X, Liang, X, Wang, Z, Yang, Q, Zou, T, Nie, W, Zhao, J, Gao, P, Zhu, MJ, De avila, JM, Maricelli, J, Rodgers, BD and Du, M 2017b. Maternal retinoids increase PDGFRalpha+ progenitor population and beige adipogenesis in progeny by stimulating vascular development. EBioMedicine 18, 288299.Google Scholar