BACKGROUND: The proximal region of the prostatic ducts harbor the prostatic epithelial stem cells. As stem cell niches in other organs are highly vascularized, we determined if the proximal region is more highly vascularized than the remaining regions of the prostate. The effect of androgen on vascular density in the different prostatic regions was also examined. METHODS: Sections from prostates were immunostained with antibodies to CD31, and the vascular density in proximal, intermediate, and distal regions was calculated by image analysis software. Vascular density was compared in prostates from castrated mice that received daily inoculations of testosterone or vehicle alone for 3 days. To examine the role of angiogenic factors in the response to androgen, some animals were also treated with soluble VEGF receptor-2-Fc or Tie-2--Fc fusion proteins, which inhibit the activities of VEGF and angiopoietins, respectively. The endothelial proliferative response to androgen was determined by double staining sections with antibodies to CD31 and Ki-67. RESULTS: In prostates from intact mice, vascular density was highest in the proximal region and lowest in the distal region. Administration of testosterone to castrated mice increased vascular density to the greatest extent in the distal and intermediate regions. The increase in vascular density required VEGF and the angiopoietins. Endothelial cell proliferation was less sensitive to androgen in the proximal region than the remainder of the prostate. CONCLUSIONS: Vascular density is highest in the proximal region of the prostate, but the proximal vessels are less responsive to testosterone.
BACKGROUND: The proximal region of the prostatic ducts harbor the prostatic epithelial stem cells. As stem cell niches in other organs are highly vascularized, we determined if the proximal region is more highly vascularized than the remaining regions of the prostate. The effect of androgen on vascular density in the different prostatic regions was also examined. METHODS: Sections from prostates were immunostained with antibodies to CD31, and the vascular density in proximal, intermediate, and distal regions was calculated by image analysis software. Vascular density was compared in prostates from castrated mice that received daily inoculations of testosterone or vehicle alone for 3 days. To examine the role of angiogenic factors in the response to androgen, some animals were also treated with soluble VEGF receptor-2-Fc or Tie-2--Fc fusion proteins, which inhibit the activities of VEGF and angiopoietins, respectively. The endothelial proliferative response to androgen was determined by double staining sections with antibodies to CD31 and Ki-67. RESULTS: In prostates from intact mice, vascular density was highest in the proximal region and lowest in the distal region. Administration of testosterone to castrated mice increased vascular density to the greatest extent in the distal and intermediate regions. The increase in vascular density required VEGF and the angiopoietins. Endothelial cell proliferation was less sensitive to androgen in the proximal region than the remainder of the prostate. CONCLUSIONS: Vascular density is highest in the proximal region of the prostate, but the proximal vessels are less responsive to testosterone.
Authors: David A Ingram; Laura E Mead; Daniel B Moore; Wayne Woodard; Amy Fenoglio; Mervin C Yoder Journal: Blood Date: 2004-12-07 Impact factor: 22.113
Authors: Ken Goto; Sarah N Salm; Sandra Coetzee; Xiaozhong Xiong; Patricia E Burger; Ellen Shapiro; Herbert Lepor; David Moscatelli; E Lynette Wilson Journal: Stem Cells Date: 2006-04-27 Impact factor: 6.277
Authors: M Burchardt; T Burchardt; M W Chen; O R Hayek; C Knight; A Shabsigh; A de La Taille; R Buttyan Journal: Prostate Date: 2000-05-15 Impact factor: 4.104
Authors: Sarah N Salm; Patricia E Burger; Sandra Coetzee; Ken Goto; David Moscatelli; E Lynette Wilson Journal: J Cell Biol Date: 2005-06-27 Impact factor: 10.539
Authors: Mugdha D Samant; Courtney M Jackson; Carina L Felix; Anthony J Jones; David W Goodrich; Barbara A Foster; Wendy J Huss Journal: Stem Cells Dev Date: 2015-02-25 Impact factor: 3.272
Authors: Dah-Jiun Fu; Andrew D Miller; Teresa L Southard; Andrea Flesken-Nikitin; Lora H Ellenson; Alexander Yu Nikitin Journal: Annu Rev Pathol Date: 2017-10-20 Impact factor: 23.472