Abstract
The prostate is a male sex accessory organ whose development is regulated by androgens and mesenchymal/epithelial interactions. The organ comprises branched epithelial ducts within a stroma consisting of fibroblasts and smooth muscle as well as other compo-nents such as vasculature and nerves. The function of the prostate is to produce secretions that make up part of the seminal fluid, though it is not certain if these are essential for fertility or sperm fixnction. There has been considerable interest in the identification of molecules and pathways that regulate prostatic growth, due to their relevance in prostatic disease. Few studies have focussed direcdy on prostatic branching though some have identified factors or pathways that play a role in prostatic growth and branching morphogenesis. Several pathways have been identified that appear to influence growth of the prostate and the process of branching mor-phogenesis simultaneously. However, genetic evidence suggests that prostatic growth and pro-static branching morphogenesis are processes that are independently regulated. The prostate is not one of the organs widely used for studies of branching morphogenesis, though this seems unfortunate as there are many factors which suggest that this organ would be an excellent model for the study of branching. These are: the ease with which these organs can be grown in vitro, the fact that the prostate is not required for viability, and the late genesis and growth of this organ relative to others during organogenesis.
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References
Takeda H, Mizuno T, Lasnitzki I. Autoradiographic studies of androgen-binding sites in the rat urogenital sinus and postnatal prostate. J Endocrinol 1985; 104:87–92.
Cunha GR, Chung LW. Stromal-epithelial interactions—I. Induction of prostatic phenotype in urothelium of testicular feminized (Tfm/y) mice. J Steroid Biochem 1981; 14:1317–1324.
Gao J, Arnold JT, Isaacs JT. Conversion from a paracrine to an autocrine mechanism of androgen-stimulated growth during malignant transformation of prostatic epithelial cells. Cancer Research 2001; 61:5038–5044.
Timms BG, Mohs TJ, Didio LJ. Ductal budding and branching patterns in the developing prostate. J Urol 1994; 151:1427–1432.
McNeal JE. Normal histology of the prostate. Am J Surg Pathol 1988; 12:619–633.
Sugimura Y, Cunha GR, Donjacour AA. Morphogenesis of ductal networks in the mouse prostate. Biol Reprod 1986; 34:961–971.
Hayashi N, Cunha GR, Parker M. Permissive and instructive induction of adult rodent prostatic epithelium by heterotypic urogenital sinus mesenchyme. Epithelial Cell Biol, 1993 2:66–78.
Timms BG et al. Instructive induction of prostate growth and differentiation by a defined urogenital sinus mesenchyme. Microsc Res Tech 1995; 30:319–332.
Donjacour AA, Thomson AA, Cunha GR. FGF-10 plays an essential role in the growth of the fetal prostate. Dev Biol 2003; 261:39–54.
Podlasek CA et al. Prostate development requires Sonic hedgehog expressed by the urogenital sinus epithelium. Dev Biol 1999; 209:28–39.
Freestone SH et al. Sonic hedgehog regulates prostatic growth and epithelial differentiation. Dev Biol 2003. In press.
Thomson AA et al. The role of smooth muscle in regulating prostatic induction. Development 2002; 129:1905–1912.
Hayward SW et al. Stromal development in the ventral prostate, anterior prostate and seminal vesicle of the rat. Acta Anat 1996; 155:94–103.
Tollet J, Everett AW, Sparrow MP. Spatial and temporal distribution of nerves, ganglia, and smooth muscle during the early pseudoglandular stage of fetal mouse lung development. Dev Dyn 2001; 221:48–60.
Toilet J, Everett AW, Sparrow MP. Development of neural tissue and airway smooth muscle in fetal mouse lung explants: a role for glial-derived neurotrophic factor in lung innervation. Am J Respir Cell Mol Biol 2002; 26:420–429.
Sugimura Y et al. Keratinocyte growth factor (KGF) can replace testosterone in the ductal branching morphogenesis of the rat ventral prostate. International Journal of Developmental Biology 1996; 40:941–951.
Thomson AA, Cunha GR. Prostatic growth and development are regulated by FGF10. Development 1999; 126:3693–3701.
Itoh N et al. Developmental and hormonal regulation of transforming growth factor-beta1 (TGFbeta1),-2, and-3 gene expression in isolated prostatic epithelial and stromal cells: Epidermal growth factor and TGF-beta interactions. Endocrinology 1998; 139:1378–1388.
Cancilla B et al. Regulation of prostate branching morphogenesis by activin A and follistatin. Dev Biol 2001; 237:145–158.
Marker PC et al. Hormonal, cellular, and molecular control of prostatic development. Dev Biol 2003; 253:165–174.
Brown TR et al. Deletion of the steroid-binding domain of the human androgen receptor gene in one family with complete androgen insensitivity syndrome: evidence for further genetic heterogeneity in this syndrome. Proc Natl Acad Sci USA 1988; 85:8151–8155.
He WW, Kumar MV, Tindall DJ. A frameshift mutation in the androgen receptor gene causes complete androgen insensitivity in the testicular-feminized mouse. Nucleic Acids Res 1991; 19:2373–2378.
Andersson S et al. Deletion of steroid 5 alpha-reductase 2 gene in male pseudohermaphroditism. Nature 1991; 354:159–161.
Mahendroo M.S et al. Unexpected virilization in male mice lacking steroid 5 alpha-reductase enzymes. Endocrinology 2001; 142:4652–4662.
Russell DW, Wilson JD. Steroid 5 alpha-reductase: two genes/two enzymes. Annu Rev Biochem 1994; 63:25–61.
Foster BA, Cunha GR. Efficacy of various natural and synthetic androgens to induce ductal branching morphogenesis in the developing anterior rat prostate. Endocrinology 1999; 140:318–328.
Ruan W et al. Evidence that insulin-like growth factor I and growth hormone are required for prostate gland development. Endocrinology 1999; 140:1984–1989.
Steger RW et al. Neuroendocrine and reproductive functions in male mice with targeted disruption of the prolactin gene. Endocrinology 1998; 139:3691–3695.
Podlasek CA et al. Hoxa-10 deficient male mice exhibit abnormal development of the accessory sex organs. Dev Dyn 1999; 214:1–12.
Podlasek CA, Clemens JQ, Bushman W. Hoxa-13 gene mutation results in abnormal seminal vesicle and prostate development. J Urol 1999; 161:1655–1661.
Podlasek CA, Duboule D, Bushman W. Male accessory sex organ morphogenesis is altered by loss of function of Hoxd-13. Dev Dyn 1997; 208:454–465.
Warot X et al. Gene dosage-dependent effects of the Hoxa-13 and Hoxd-13 mutations on morphogenesis of the terminal parts of the digestive and urogenital tracts. Development 1997; 124:4781–4791.
Bhatia-Gaur R et al. Roles for Nkx3.1 in prostate development and cancer. Genes Dev 1999; 13:966–977.
Schneider A et al. Targeted disruption of the Nkx3.1 gene in mice results in morphogenetic defects of minor salivary glands: Parallels to glandular duct morphogenesis in prostate. Mech Dev 2000; 95:163–174.
Tanaka M et al. Nkx3.1, a murine homolog of Ddrosophila bagpipe, regulates epithelial ductal branching and proliferation of the prostate and palatine glands. Dev Dyn 2000; 219:248–260.
Lamm ML et al. Mesenchymal factor bone morphogenetic protein 4 restricts ductal budding and branching morphogenesis in the developing prostate. Dev Biol 2001; 232:301–314.
Baker J et al. Effects of an Igf1 gene null mutation on mouse reproduction. Mol Endocrinol 1996; 10:903–918.
Signoretti S et al. p63 is a prostate basal cell marker and is required for prostate development. Am J Pathol 2000; 157:1769–1775.
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Thomson, A.A., Marker, P.C. (2005). Branching Morphogenesis of the Prostate. In: Branching Morphogenesis. Molecular Biology Intelligence Unit. Springer, Boston, MA. https://doi.org/10.1007/0-387-30873-3_10
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DOI: https://doi.org/10.1007/0-387-30873-3_10
Publisher Name: Springer, Boston, MA
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