The postnatal ontogeny of rat uterine glands and age-related effects of 17 beta-estradiol.

In the uterus of the newborn rat, only the luminal epithelium is differentiated. Differentiation of musculature and glandular epithelium occurs postnatally, the latter originating as invaginations of the luminal epithelium into the stroma. Using unambiguous criteria for quantification of uterine glands, we find that uterine glands first appear on postnatal day 9 after which the increase in the number of glands is rapid and synchronous, with approximately 4.4 glands per uterine section reached by day 15. Between days 15 and 35, the number of glands per uterine section varied in a cyclic manner with an amplitude of approximately one gland per uterine section and a period of 6-7 days. Although exogenous 17 beta-estradiol (E2) administered on postnatal days 1-5 induced slight premature gland genesis, the number of glands per uterine section was approximately 30% lower between days 15-26 compared to untreated animals. Administration of E2 during the period of normal gland genesis (days 10-14) induced a dose-related delay in the onset of appearance of glands. After this, gland genesis proceeded at a normal rate; however, the maximum levels reached were again generally below those observed in untreated controls. E2 administered after uterine glands were established (days 20-24) induced a small increase in gland number compared to controls. E2 also induced temporary hypertrophy, hyperplasia, and cellular degeneration in the luminal epithelium during each of the dosing periods without corresponding changes in the stroma or myometrium. These data demonstrate that uterine gland genesis occurs between postnatal days 9-15 and that exogenous estrogen can alter, in an age-specific manner, both uterine gland genesis and the number of glands per uterine section.

Inhibition of rat uterine gland genesis by tamoxifen.

We have previously shown that rat uterine gland genesis occurs rapidly and synchronously between postnatal days 9-15. Exogenous estrogens either stimulate or inhibit gland genesis depending on dose and age at administration. We therefore examined the developmental effects of the triphenylethylene antiestrogen tamoxifen, which exhibits both estrogen agonist and antagonist properties, in the postnatal rat uterus. Tamoxifen administered sc in oil on postnatal days 1-5 or days 10-14 caused dose-related inhibition of uterine gland genesis which persisted to day 26 or day 60, respectively. Tamoxifen administered on postnatal days 20-24, which is after the age of normal gland genesis, did not alter the number of preexisting glands. A 24-h exposure to tamoxifen inhibited 17 beta-estradiol (E2)-induced ornithine decarboxylase (ODC) activity measured 6 h after E2 administration in 14-day-old rats. Treatment with tamoxifen before or during the period of gland genesis also reduced uterine responsiveness to a single dose of E2 as measured by both uterine weight gain (after a 24-h exposure on days 14, 19, 22, and 26) and the pattern of E2-induced ODC activity in 26-day-old rats. Control rats respond to E2 with peaks of ODC activity at 6 and 18 h after administration. Treatment with tamoxifen on either postnatal days 1-5 or 10-14 reduced the 18-h peak to approximately half of controls but did not affect the 6-h E2-induced ODC peak. Analysis of both nuclear and translocatable cytosol estrogen receptor in uteri from 26-day-old rats indicate that neither the dissociation constant (KD) nor the number of binding sites was affected by tamoxifen treatment on postnatal days 1-5 or 10-14.