The effects of estrogen on the reproductive tract involve cell proliferation, migration, and differentiation, which need to be well coordinated. Polypeptide growth factors are believed to play a vital role in a number of these cellular processes. Among the growth factors now documented to be associated with estrogen action are epidermal growth factor, transforming growth factor-alpha (TGF alpha), transforming growth factor-beta 1 (TGF beta 1), TGF beta 2, TGF beta 3, and insulin-like growth factor-I (IGF-I). Platelet-derived growth factors (PDGFs) are also potent mitogens, which consist of two peptide chains, denoted A and B, that dimerize to isoforms (PDGF-AA, -AB, and -BB) which differ in their functional properties, secretory behavior, receptor binding, and physiological effects. To study the role of the PDGF-A and -B chains and the PDGF receptor subunits, alpha and beta, during estrogen action in the mouse reproductive tract, time-dependent changes in the expression of these genes were examined by Northern and in situ RNA analyses and by immunohistochemistry after a single treatment of immature CD-1 (17- to 19-day-old) mice with the synthetic estrogen, diethylstilbestrol (DES). Our results demonstrate estrogen modulation of the expression of messenger RNA (mRNA) and protein for the PDGF ligands and receptors in both the uterus and vagina of the mouse. Northern and in situ RNA analyses demonstrate time-dependent estrogen induction of the mRNA levels for these genes in both tissues within 3 h after treatment. However, distinctive mRNA expression profiles for the PDGF ligand and receptor genes are exhibited by the uterus and vagina in response to DES, especially in that the induction of transcripts for PDGF-A and both receptor subunits is more transient in the vagina than in the uterus. Steroid specificity studies demonstrate predominant estrogen-specific regulation of mRNA induction for these genes. Analysis of cell-specific RNA expression by in situ hybridization reveals prominent induction of transcripts for the PDGF chains and receptor subunits in the uterine and vaginal epithelium after estrogen treatment, although enhanced expression of mRNA is also noted in the stroma, particularly for the PDGF receptor subunit genes. Cellular localization of the PDGF ligand and receptor protein molecules by immunohistochemistry detected significant immunostaining for all of these proteins in both the uterus and vagina of control animals. After DES treatment, the uterus exhibits a significant decrease in the level of PDGF ligand and receptor proteins immunostained within 6 h, whereas less dramatic effects ar observed in the vagina.(ABSTRACT TRUNCATED AT 400 WORDS)
Neonatal estrogen exposure causes numerous abnormalities in the female reproductive tract, including carcinogenesis. One mechanism by which neonatal estrogen elicits teratogenic and carcinogenic effects is epigenetic and involves the modulation of a number of estrogen-regulated genes including epidermal growth factor (EGF). Because of the evidence that there is an integral relationship between the EGF family, estrogen action, and the regulation of the growth and differentiation of the reproductive tract, we used transforming growth factor-alpha (TGF alpha) transgenic mice to investigate the interaction of constitutive TGF alpha expression with the potent estrogen diethylstilbestrol (DES) in the induction of reproductive-tract alterations. Our study was designed to determine whether TGF alpha expression could modulate DES-induced carcinogenesis of the female mouse reproductive tract. The animals were homozygous TGF alpha transgenic female mice from the MT42 line and the parental CD-1 outbred mice. The presence of the TGF alpha transgene significantly increased the incidence of DES-induced vaginal adenosis, uterine endometrial hyperplasia, uterine polyps, hypospadia, benign ovarian cysts, and pituitary adenomas. However, constitutive TGF alpha expression did not promote reproductive-tract neoplasia. This study demonstrates that TGF alpha participates in the regulation of developmental and morphogenic events in the Müllerian duct and urogenital sinus, suggesting a role for TGF alpha in the pathogenesis of reproductive-tract diseases. Furthermore, we showed that although constitutive expression of the TGF alpha transgene did have an effect on the reproductive tract, TGF alpha overexpression alone could not substitute for DES as a reproductive-tract carcinogen or as a promoter of uterine neoplasia, indicating that DES-induced carcinogenesis requires events in addition to the overexpression of this single peptide growth factor.
Neonatal estrogen exposure causes numerous abnormalities in the female reproductive tract, including carcinogenesis. One mechanism by which neonatal estrogen elicits teratogenic and carcinogenic effects is epigenetic and involves the modulation of a number of estrogen-regulated genes including epidermal growth factor (EGF). Because of the evidence that there is an integral relationship between the EGF family, estrogen action, and the regulation of the growth and differentiation of the reproductive tract, we used transforming growth factor-alpha (TGF alpha) transgenic mice to investigate the interaction of constitutive TGF alpha expression with the potent estrogen diethylstilbestrol (DES) in the induction of reproductive-tract alterations. Our study was designed to determine whether TGF alpha expression could modulate DES-induced carcinogenesis of the female mouse reproductive tract. The animals were homozygous TGF alpha transgenic female mice from the MT42 line and the parental CD-1 outbred mice. The presence of the TGF alpha transgene significantly increased the incidence of DES-induced vaginal adenosis, uterine endometrial hyperplasia, uterine polyps, hypospadia, benign ovarian cysts, and pituitary adenomas. However, constitutive TGF alpha expression did not promote reproductive-tract neoplasia. This study demonstrates that TGF alpha participates in the regulation of developmental and morphogenic events in the Müllerian duct and urogenital sinus, suggesting a role for TGF alpha in the pathogenesis of reproductive-tract diseases. Furthermore, we showed that although constitutive expression of the TGF alpha transgene did have an effect on the reproductive tract, TGF alpha overexpression alone could not substitute for DES as a reproductive-tract carcinogen or as a promoter of uterine neoplasia, indicating that DES-induced carcinogenesis requires events in addition to the overexpression of this single peptide growth factor.
Neonatal exposure of mice to estrogen (diethylstilbestrol) results in a high incidence (90%) of uterine tumor later in life. In an effort to screen for estrogen-regulated genes in the uterus of the neonatal mouse, we have isolated a murine homologue of the human decay-accelerating factor (DAF), a glycosylphosphatidylinositol (GPI)-anchored membrane glycoprotein and a member of the regulators of complement activation family of proteins that function to prevent autologous complement-mediated tissue damage. The induced mouse DAF cDNA has a 64% sequence identity with the human counterpart at the nucleotide level and a 50% identity in the deduced amino acid sequence. It consists of 390 amino acids and contains four short consensus repeats of internal homology characteristic of human DAF. It also contains a hydrophobic C-terminal that most likely serves as a signal for GPI anchor attachment. Sequence comparison with the recently reported mouse DAF cDNAs confirmed that the estrogen-inducible gene corresponds to the mouse GPI DAF gene. The induction of mouse DAF by estrogen is tissue specific and can be mimicked by the antiestrogen tamoxifen. Furthermore, the regulation of uterine DAF expression by estrogen is limited to the GPI DAF gene. The transmembrane DAF gene is not expressed in the mouse uterus, either with or without estrogen stimulation. These results suggest that the two mouse DAF genes are differentially regulated, and that the GPI-anchored DAF may play important roles in estrogen responses and other physiologic or pathophysiologic processes of the female reproductive system.
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