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http://dx.doi.org/10.12717/DR.2015.19.1.043

Exogenous Exposure to Estradiol Benzoate or Flutamide at the Weaning Age Alters Expression of Connexin Isoforms in the Initial Segment of Male Rat  

Lee, Ki-Ho (Dept. of Biochemistry and Molecular Biology, College of Medicine, Eulji University)
Publication Information
Development and Reproduction / v.19, no.1, 2015 , pp. 43-51 More about this Journal
Abstract
Connexin (Cx) is a complex which allows direct communication between neighboring cells via exchange of signaling molecules and eventually leads to functional harmony of cells in a tissue. The initial segment (IS) is an excurrent duct of male reproductive tract and expression of numerous genes in the IS are controlled by androgens and estrogens. The effects of these steroid hormones on gene expression in the IS during postnatal development have not extensively examined. The present research investigated expressional modulation of Cx isoforms in the IS by exogenous exposure to estrogen agonist, estradiol benzoate (EB), or androgen antagonist, flutamide (Flu), at weaning age. Two different doses of EB or Flu were subcutaneously administrated in 21-day old of male rats, and expressional changes of Cx isoforms in the adult IS were analyzed by quantitative real-time PCR. Treatment of a low-dose EB ($0.015{\mu}g/kg$ body weight) resulted in an increased expression of Cx31 gene and a decreased expression of Cx37 gene. A high-dose EB ($1.5{\mu}g/kg$ body weight) treatment caused an increase of Cx31 gene expression. Increased levels of Cx30.3 and Cx40 transcripts were observed with a low-dose Flu ($500{\mu}g/kg$ body weight) treatment. Treatment of high-dose Flu (50 mg/kg body weight) led to expressional increases of Cx30.3, 40, and 43 genes. Our previous and present findings suggest differential responsiveness on gene expression of Cx isoforms in the IS by androgens and estrogens at different postnatal ages.
Keywords
Initial segment; Connexin; Estradiol benzoate; Flutamide; Gene expression; Epididymis;
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Times Cited By KSCI : 4  (Citation Analysis)
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1 Adamali HI, Hermo L (1996) Apical and narrow cells are distinct cell types differing in their structure, distribution, and functions in the adult rat epididymis. J Androl 17:208-222.
2 Akingbemi BT, Hardy MP (2001) Oestrogenic and antiandrogenic chemicals in the environment: Effects on male reproductive health. Ann Med 33:391-403.   DOI
3 Carreau S, de Vienne C, Galeraud-Denis I (2008) Aromatase and estrogens in man reproduction: A review and latest advances. Adv Med Sci 53:139-144.
4 Cooke PS, Young P, Hess RA, Cunha GR (1991) Estrogen receptor expression in developing epididymis, efferent ductules, and other male reproductive organs. Endocrinology 128:2874-2879.   DOI
5 Cosentino MJ, Cokett AT (1986) Structure and function of the epididymis. Urol Res 14:229-240.
6 Cyr DG, Hermo L, Laird DW (1996) Immunocytochemical localization and regulation of connexin 43 in the adult rat epididymis. Endocrinology 137:1474-1484.   DOI
7 Dube E, Dufresne J, Chan PT, Cyr DG (2012) Epidermal growth factor regulates connexin 43 in the human epididymis: role of gap junctions in azoospermia. Hum Reprod 27:2285-2296.   DOI
8 Dufresne J, Finnson KW, Gregory M, Cyr DG (2003) Expression of multiple connexins in the rat epididymis indicates a complex regulation of gap junctional communication. Am J Physiol Cell Physiol 284:33-43.   DOI
9 Goodenough DA, Goliger JA, Paul DL (1996) Connexins, connexons, and intercellular communication. Annu Rev Biochem 65:475-502.   DOI
10 Han SY, Lee K-H (2013) The expression patterns of connexin isoforms in the rat caput epididymis during postnatal development. J Ani Sci Tech 55:245-255.
11 Jones RC (1987) Changes in protein composition of the luminal fluids along the epididymis of the tammar, Macropus eugenii. J Reprod Fertil 80:193-199.   DOI
12 Joseph A, Shur BD, Hess RA (2011) Estrogen, efferent ductules, and the epididymis. Biol Reprod 84:207-217.   DOI
13 Lee K-H (2013) Differential expression of multiple connexins in rat corpus ad cauda epididymis at various postnatal stages. J Ani Sci Tech 55:521-530.   DOI
14 Lee K-H (2014) Expressional modulation of connexin isoforms in the initial segment of male rat treated with estradiol benzoate or flutamide. Dev Rep 18:293-300.   DOI
15 Mese G, Richard G, White TW (2007) Gap junctions: basic structure and function. J Invest Dermatol 127:2516-2524.   DOI
16 Robaire B, Syntin P, Jervis K (2000) The coming of age of the epididymis. In: Jegou B et al. (eds.). Testis, Epididymis and Technologies in the Year 2000. Springer, New York, pp. 229-262.
17 Pointis G, Fiorini C, Defamie N, Segretain D (2005) Gap junctional communication in the male reproductive system. Biochim Biophy Acta 1719:102-116.   DOI
18 Robaire B, Hamzeh M (2011) Androgen action in the epididymis. J Androl 32:592-599.   DOI
19 Robaire B, Hermo L (1988) Efferent ducts, epididymis, and vas deferens: structure, functions, and their regulation. In: Knobil E et al. (eds.). The Physiology of Reproduction. Raven Press, New York, pp 999-1080.
20 Sar M, Welsch F (2000) Oestrogen receptor alpha and beta in rat prostate and epididymis. Andrologia 32:295-301.   DOI
21 Seo H-H, Seon C-W, Choi I, Cheon Y-P, Cheon T-H, Lee K-H (2010) Expressional profiling of connexin isoforms in the initial segment of the male reproductive tract during postnatal development. Reprod Dev Biol 34: 103-109.
22 St-Pierre N, Dufresne J, Rooney AA, Cyr DG (2003) Neonatal hypothyroidism alters the localization of gap junctional protein connexin 43 in the testis and messenger RNA levels in the epididymis of the rat. Biol Reprod 68:1232-1240.   DOI
23 Temple-Smith PD, Zheng SS, Kadioglu T, Southwick GJ (1998) Development and use of surgical procedures to bypass selected regions of the mammalian epididymis: effects on sperm maturation. J Reprod Fertil Suppl 53:183-195.
24 You L, Sar M (1998) Androgen receptor expression in the testes and epididymides of prenatal and postnatal Sprague- Dawley rats. Endocrine 9:253-261.   DOI