Growth hormone acts on the synthesis and secretion of α-casein in bovine mammary epithelial cells

Kazuhito Sakamoto; Tokushi Komatsu; Takuya Kobayashi; Michael T Rose; Hisashi Aso; Akihiko Hagino; Yoshiaki Obara

doi:10.1017/S0022029905000889

Abstract

To study the effect of growth hormone (GH) on the functions of mammary epithelia, we examined the effect of GH on the synthesis and secretion of α-casein in a bovine mammary epithelial cell (BMEC) clonal line, which was established from a 26-d-pregnant Holstein heifer. GH receptors (GHR) were observed in the BMEC on the membrane as well as in the cytoplasm. After BMEC were plated onto cell culture inserts, GH stimulated α-casein release in both the presence and absence of the lactogenic hormone complex, which included dexamethasone, insulin and prolactin (DIP). DIP enhanced the effect of GH on α-casein release. Although αs1-casein mRNA expression was not detected in untreated control cells, its expression was observed in BMEC in response to the GH, DIP and GH+DIP treatments. Expression was greater for GH and GH+DIP than for just DIP. Expression of GHR mRNA was increased by DIP treatment, while the mRNA expression was little changed by GH treatment. We conclude that GH acts on BMEC and induces the expression of both the α-casein gene and protein. GHR gene expression was shown to be regulated by DIP and GHR. GHR may be involved in a synergic effect between GH and DIP on casein secretion. These results suggest that GH, in addition to its widely accepted homeorhetic role in vivo, also can act on the mammary parenchyma, and that the effects of GH on mammary epithelial cells could partly account for the clear galactopoietic effect of recombinant bovine GH seen in lactating dairy cows.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Yonekura, Shinichi Sakamoto, Kazuhito Komatsu, Tokushi Hagino, Akihiko Katoh, Kazuo and Obara, Yoshiaki 2006. Growth hormone and lactogenic hormones can reduce the leptin mRNA expression in bovine mammary epithelial cells. Domestic Animal Endocrinology, Vol. 31, Issue. 1, p. 88.

Mellado, M. Nazarre, E. Olivares, L. Pastor, F. and Estrada, A. 2006. Milk production and reproductive performance of cows induced into lactation and treated with bovine somatotropin. Animal Science, Vol. 82, Issue. 4, p. 555.

Sakamoto, Kazuhito Yano, Tomoki Kobayashi, Takuya Hagino, Akihiko Aso, Hisashi and Obara, Yoshiaki 2007. Growth hormone suppresses the expression of IGFBP-5, and promotes the IGF-I-induced phosphorylation of Akt in bovine mammary epithelial cells. Domestic Animal Endocrinology, Vol. 32, Issue. 4, p. 260.

CHAIYABUTR, Narongsak THAMMACHAROEN, Sumpun KOMOLVANICH, Siripen and CHANPONGSANG, Somchai 2007. Effects of long‐term administration of recombinant bovine somatotropin on the plasminogen–plasmin system and milk composition of crossbred Holstein cattle. Animal Science Journal, Vol. 78, Issue. 3, p. 251.

Zhou, Y. Akers, R.M. and Jiang, H. 2008. Growth Hormone Can Induce Expression of Four Major Milk Protein Genes in Transfected MAC-T Cells. Journal of Dairy Science, Vol. 91, Issue. 1, p. 100.

Johnson, Tasha L Fujimoto, Brent AS Jiménez-Flores, Rafaél and Peterson, Daniel G 2010. Growth hormone alters lipid composition and increases the abundance of casein and lactalbumin mRNA in the MAC-T cell line. Journal of Dairy Research, Vol. 77, Issue. 2, p. 199.

Macrina, A.L. Kauf, A.C.W. and Kensinger, R.S. 2011. Effect of bovine somatotropin administration during induction of lactation in 15-month-old heifers on production and health. Journal of Dairy Science, Vol. 94, Issue. 9, p. 4566.

Li, Hui-Ming Wang, Chun-Mei Li, Qing-Zhang and Gao, Xue-Jun 2012. MiR-15a Decreases Bovine Mammary Epithelial Cell Viability and Lactation and Regulates Growth Hormone Receptor Expression. Molecules, Vol. 17, Issue. 10, p. 12037.

Pan, Shenggang Rasul, Fahd Li, Wu Tian, Hua Mo, Zhaowen Duan, Meiyang and Tang, Xiangru 2013. Roles of plant growth regulators on yield, grain qualities and antioxidant enzyme activities in super hybrid rice (Oryza sativa L.). Rice, Vol. 6, Issue. 1,

Gigli, Isabel and Maizon, Daniel Omar 2013. microRNAs and the mammary gland: a new understanding of gene expression. Genetics and Molecular Biology, Vol. 36, Issue. 4, p. 465.

Johnson, T.L. Tomanek, L. and Peterson, D.G. 2013. A proteomic analysis of the effect of growth hormone on mammary alveolar cell-T (MAC-T) cells in the presence of lactogenic hormones. Domestic Animal Endocrinology, Vol. 44, Issue. 1, p. 26.

Suzuki, Yutaka Haga, Satoshi Katoh, Daiki So, Kyoung-ha Choi, Ki-choon Jung, U-suk Lee, Hong-gu Katoh, Kazuo and Roh, Sang-gun 2015. Chemerin is a novel regulator of lactogenesis in bovine mammary epithelial cells. Biochemical and Biophysical Research Communications, Vol. 466, Issue. 3, p. 283.

Lin, Xueyan Wu, Miaomiao Liu, Guimei Wang, Yun Hou, Qiuling Shi, Kerong and Wang, Zhonghua 2015. The Effects of Amino Acid Nutritional Deficiency on the Expression of Protein Metabolism-Related Genes in the Mammary Gland and Muscle Tissues of Lactating Mice. Advances in Bioscience and Biotechnology, Vol. 06, Issue. 09, p. 601.

Muroya, Susumu Hagi, Tatsuro Kimura, Ataru Aso, Hisashi Matsuzaki, Masatoshi and Nomura, Masaru 2016. Lactogenic hormones alter cellular and extracellular microRNA expression in bovine mammary epithelial cell culture. Journal of Animal Science and Biotechnology, Vol. 7, Issue. 1,

Wang, M. Z. Ji, Y. Wang, C. Chen, L. M. Wang, H. R. and Loor, J. J. 2016. The preliminary study on the effects of growth hormone and insulin‐like growth factor‐I on κ‐casein synthesis in bovine mammary epithelial cells in vitro. Journal of Animal Physiology and Animal Nutrition, Vol. 100, Issue. 2, p. 251.

Cui, Yingjun Sun, Xia Jin, Lianfeng Yu, Guangpu Li, Qingzhang Gao, Xuejun Ao, Jinxia and Wang, Chunmei 2017. MiR-139 suppresses β-casein synthesis and proliferation in bovine mammary epithelial cells by targeting the GHR and IGF1R signaling pathways. BMC Veterinary Research, Vol. 13, Issue. 1,

Lopdell, Thomas J. Tiplady, Kathryn Struchalin, Maksim Johnson, Thomas J. J. Keehan, Michael Sherlock, Ric Couldrey, Christine Davis, Stephen R. Snell, Russell G. Spelman, Richard J. and Littlejohn, Mathew D. 2017. DNA and RNA-sequence based GWAS highlights membrane-transport genes as key modulators of milk lactose content. BMC Genomics, Vol. 18, Issue. 1,

Tsugami, Yusaku Suzuki, Norihiro Kawahara, Manabu Suzuki, Takahiro Nishimura, Takanori and Kobayashi, Ken 2020. Establishment of an in vitro culture model to study milk production and the blood–milk barrier with bovine mammary epithelial cells. Animal Science Journal, Vol. 91, Issue. 1,

Wang, Baosheng Shi, Linlin Men, Jingjing Li, Qingzhang Hou, Xiaoming Wang, Chunmei and Zhao, Feng 2020. Controlled synchronization of prolactin/STAT5 and AKT1/mTOR in bovine mammary epithelial cells. In Vitro Cellular & Developmental Biology - Animal, Vol. 56, Issue. 3, p. 243.

Xing, Y. Y. Li, D. B. Sun, M. Zhang, H. Hou, X. Z. and Gao, M. 2020. Effect of hormones on genes related to hormone receptors and milk component synthesis in bovine mammary epithelial cells grown in two and three dimensional culture system. Italian Journal of Animal Science, Vol. 19, Issue. 1, p. 147.

Download full list

Article contents

Growth hormone acts on the synthesis and secretion of α-casein in bovine mammary epithelial cells

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Growth hormone acts on the synthesis and secretion of α-casein in bovine mammary epithelial cells

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests