Estrogen and antagonist-induced changes in endometrial topography of immature and cycling rats

Fetal Development of the Bovine Uterus: A Light Microscopy and Immunohistochemical Study

Important steps during the prenatal development of the bovine uterus are described using conventional hematoxylin-eosin staining of fetuses from different developmental stages [crown-rump length (CRL) 9.2-94.0 cm]. Additionally, a number of intermediate filaments (keratin 7, 8, 14, 18, 19; and vimentin), the basement membrane protein laminin, smooth-muscle marker (SMA), and S100 were studied to further characterize certain differentiation processes. During early development, the uterine epithelium is simple or (pseudo)stratified with bud-like protrusions. Developing caruncles can be observed in the corpus uteri at a CRL of 15.8 cm onwards, showing a simple, keratin-positive epithelium. In contrast, the intercaruncular areas are characterized by a (pseudo)stratified epithelium, which also shows positive staining in a different manner for the investigated keratins. A differentiation of smooth muscle cell layers can be observed from a CRL of 24.4 cm onwards. Intense SMA-positive cells/fibers, arranged perpendicularly to the developing circular SMA-positive muscle cell layer, can be found preferentially located in the developing caruncles. Lymphocytes occur in the uterine epithelium and stroma in the corpora and cornua of fetuses with a CLR of 15.8 cm and higher.

Treatment with the specific estrogen receptor antagonist ICI 182,780 demasculinizes neuron soma size in the developing zebra finch brain

In zebra finches, many features of the neural song system are more pronounced in males compared to females. The exact mechanism(s) responsible for these differences are unknown, but may involve steroid hormones. More specifically, estrogens are most effective in masculinizing the female brain. Attempts to prevent masculine development through various estrogen receptor antagonists have been relatively ineffective, possibly due to partial agonistic activity of the compounds tested. To further investigate the role of estrogens in dimorphic development we utilized a more potent estrogen receptor blocker, ICI 182,780. Animals were treated during the first 25 days post-hatching. Daily intracranial injections significantly decreased neuron soma size in RA and HVC of both sexes. A similar effect was noted in LMAN. Treatment also appeared to decrease the volume of several song control nuclei. Together, these data support the hypothesis that ICI is an effective estrogen receptor antagonist in the zebra finch brain and that estrogens may influence sexually dimorphic development of the zebra finch song circuit. However, reported inconsistencies about sex differences in estrogen exposure and/or utilization exist, suggesting that complete sexual differentiation and development likely involve additional factors.

Scanning electron microscopic changes of the canine uterine luminal surface during oestrus and late metoestrus

In this study the endometrial morphology of four dogs in oestrus and 10 dogs in late metoestrus was investigated with scanning electron microscopy. In early oestrus the cells were slightly convex with fairly long microvilli and cell boundaries that were apparent but situated on a deeper level than the cell surface. In late oestrus the cells were clearly convex with long and numerous microvilli masking the cell boundaries. At the beginning of late metoestrus the cells became less convex with many but short microvilli and prominent but lower situated cell boundaries. At the end of late metoestrus the cells were flat with very short microvilli and protruding cell borders. These morphological findings were correlated with the cyclic variations of the steroid hormone levels.

Estrous stage determination in rats by means of scanning electron microscopic images of uterine surface epithelium

With the results presented in this paper we devised an alternative method to precisely date the rat endometrium in relation to the estrous cycle. This is done by the exclusive use of scanning electron microscopy. Owing to its short estrous cycle (4 to 6 days, depending on age), the rat is ideally suited for the examination of cyclic changes occurring in the uterine epithelium. The cycle stage of rats predated by vaginal smear cytology was verified through the measurement of hormones relevant to the estrous cycle, i.e. estradiol-17-beta (E2), progesterone (P), luteinizing hormone (LH), and follicle stimulating hormone (FSH). Based on scanning electron images surface changes could thus be correlated to the cyclic variations of blood levels of sex hormones. The appearance of pseudoglands, the most prominent aspect during the cycle, is correlated with decreasing estrogen and rising progesterone levels. Pseudoglands are formed by apoptosis and necrosis of epithelial cells, and are most numerous during estrus. They had in previous studies been classified as genuine uterine glands.

Scanning electron microscopic and morphometric analysis of the guinea pig uterine luminal surface: cyclic and ovarian steroid-induced modifications

A morphometric and scanning electron microscopic analysis of endometrial, luminal topographical changes of cyclic and ovariectomized, ovarian steroid-treated guinea pigs was undertaken to determine the effects of cyclic endocrine influences on the uterine surface features recognized to be involved in the process of interstitial blastocyst implantation. Estrogenic stimulation of the uterine epithelial layer induced microvillus growth and closed the endometrial gland openings on the luminal surface. Progestins antagonized these parameters, as indicated by short, sparse microvillus formation over a flat luminal uterine surface on which gland openings were both numerous and prominent. The combined effects of estrogen and progesterone therapies induced luminal epithelial changes resembling those characterizing the cyclic uterine surface at the time of blastocyst implantation. These data indicate that the cyclic alterations in the uterine luminal surface are directly regulated by ovarian steroid hormones, and that these changes in surface structure are synchronized and directly involved in the preparation for blastocyst-uterine interaction during the nidatory process in this species.

Ultrastructure as a basis for dating of rat endometrium

Studies on the endometrial cycle depend upon the precise dating of the cycle stage. In the present paper the generally applied method of vaginal smear was carefully verified through the measurement of the hormones relevant to the endometrial cycle. From rats predated through vaginal smear cytology, the hormone levels of estradiol-17-beta (E2) and progesterone (P), luteinizing hormone (LH), and follicle stimulating hormone (FSH) were measured. The values obtained were then compared to the standardized values of our reference curve. Animals with values that did not fit within the standard deviation of our reference curve were excluded from this investigation. Thus, for the first time exactly dated rat endometrial morphology was studied with electron microscopy. The morphology of the surface epithelium of rat endometrium from all four stages of the cycle is described in detail. In addition a semiquantitative morphometric analysis of the following parameters was performed: cell volume, nuclear volume, the volume density of secretory granules, digestive vacuoles, mitochondria, Golgi apparatus, rough endoplasmic reticulum, and lipid vacuoles as well as the size of lipid vacuoles. With the cellular content of lipid vacuoles and their diameter, it is possible to differentiate between proestrus/estrus and diestrus I/diestrus II, the latter possessing definitely more and larger lipid vacuoles. During estrus the greatest cytoplasmic volume develops. In addition to this, secretory granules are only present during estrus. Finally, diestrus I can be well differentiated from diestrus II, because diestrus I exhibits more digestive vacuoles and during diestrus II a high percentage of free ribosomes is present. On the basis of distinct morphological features, described in this paper, it is now clearly possible to distinguish between the four different cycle stages.

Electron microscopical tracers in the uterine epithelium of the pregnant guinea-pig

Horseradish peroxidase and lanthanum nitrate were used in pregnant guinea-pigs as electron dense tracers to determine whether the 'permeability' characteristics of the uterine epithelium support the hypothesis that immunoglobulin G gains access to the uterine lumen by transepithelial diffusion. Horseradish peroxidase was injected intravenously in eight animals in experiments ranging from 1-43 min and directly into the uterine lumen in five animals in experiments of 1-8 min duration. Lanthanum nitrate was injected only into the uterine lumen of eight animals for exposures of 1-8 min. Horseradish peroxidase did not traverse the junctional complexes regardless of injection site; lanthanum nitrate did not penetrate the complexes either except in one animal. We conclude that the uterine epithelium is a barrier that prevents the diffusional transfer of IgG from mother to fetus. Further studies are required to locate the site where maternal IgG is transferred to the uterine lumen.

Cytoskeletal alterations in the microvilli of uterine epithelial cells during early pregnancy

We have studied the arrangement of microfilaments in uterine microvilli during early pregnancy, using transmission electron microscopy and immunofluorescence microscopy. Observations indicate that changes in actin microfilament organization occur in association with the alterations to the uterine cell surface which precede blastocyst implantation. We consider these findings with reference to the possible mechanisms involved.

Upper genital tract abnormalities in the Syrian hamster as a result of in utero exposure to diethylstilbestrol. II. Scanning electron microscope analysis of endometrium cell surfaces

Using scanning electron microscopy (SEM), we show that an in utero exposure to diethylstilbestrol (DES) will induce endometrial abnormalities postnatally. These changes are magnified when a subsequent postnatal DES treatment is given. More specifically, changes in cell surface morphology are associated with alterations in cell size and shape (from columnar to cuboid/squamous), and in microvilli and mucus secretion. Uteri from hamsters treated postnatally with DES and derived from normal (CD) or DES-treated mothers (DD) show that accumulated mucoid secretion products are not expelled in the uterine lumen but are "stored" in cystic dilated glandular spaces of the fibrocellular stroma of polyps and papillae filling the uterine lumen. Uteri from female hamsters that have been prenatally treated with DES (DC) show endometrial mucosal crypts containing mucus and other cell debris including migrating granulocytes. In all cases, DES-treated uteri show mucosal cell surface pleomorphism in the sequence DD greater than CD greater than DC Merocrine and/or cystic secretions were observed. Microvilli cover cell surfaces and include some rare and peculiar long microvillous growth. In contrast, DC hypoplastic uteri present no secretory activity. Structures similar to those described for CD uteri can be observed only after 250 days of age in DC uteri. This report confirms and complements previous observations, favoring the choice of the hamster as an animal mode for the study of endometrial carcinogenesis.

The response of the uterine surface to ovarian hormones in the aged rat

By scanning electron microscopy uterine luminal epithelium of the rat was studied to determine whether aging alters ovarian hormone stimulated ultrastructural changes in that portion of the endometrial surface into which implantation takes place in the younger animal. Results show that in the aged rat this surface differentiates in response to ovarian hormones in a manner qualitatively similar to that which occurs in the young animal. Epithelial cells of ovariectomized rats, both young and aged, were polygonal in outline, flattened, or even somewhat concave, and had short microvilli. Following estrogen treatment cells of both groups were round or oval and bulged into the lumen. Cells of young rats were covered with long microvilli. Most cells of aged rats had microvilli of equal or greater length; a small number of epithelial cells had fewer and shorter microvilli. Cells of progesterone-treated young and aged animals both were covered with short microvilli and bore membrane protrusions. The protrusions varied in size, shape and numbers both within and between age groups. These findings suggest that differences in the surface ultrastructure of the aged uterus reflect age-related changes in hormone levels.

Estrogen action at endometrial membranes: alterations in luminal surface detectable within seconds

The morphological effects of estrogen on the luminal surfaces of rat endometrial cells were investigated by scanning electron microscopy. Ovariectomized rats were injected intravenously with estradiol-17 beta (E2 beta), 0.5 micrograms/0.25 ml per 100 g body wt. At various intervals thereafter, the lumen of a uterine horn was flushed with buffered 2% glutaraldehyde and then prepared for scanning electron microscopy by conventional methods. In control rats that had received an equivalent volume of placebo vehicle, the luminal cell surface was characterized by short, sparse microvilli (MV) and, in most cells, a single, central cilium. At 30 s after E2 beta injection, the number of MV was significantly increased. By 1 min, MV density was further increased and MV were frequently clustered; also, the central cilium of many cells was no longer evident. Similar results were obtained after exposure to diethylstilbestrol for 30 s to 1 min, whereas neither a subthreshold dose of E2 beta nor a dose of the relatively inactive congener E2 alpha equivalent to a saturating concentration of E2 beta gave statistically significant responses in surface changes by the present criteria. After 3-7 min of E2 beta exposure, MV had increased greatly in length and density. These effects underwent dramatic regression by 15-30 min after E2 beta treatment, with distinct diminution of microvillar lengths and numbers, reduction of clustering, and reappearance of the central cilium in many cells. This was succeeded at 1 h by a renewed surge of surface activity. These results are consistent with cumulative evidence for rapid alterations of the surface membrane of estrogen-sensitive cells in response to physiological levels of active hormone. Whether these responses in the luminal surfaces are primary, or are secondary reflections of receptor-mediated membrane alterations at the basolateral blood-front, remains to be determined.

Endometrial hyperplasia and carcinoma. Are ultrastructural, biochemical and immunocytochemical studies useful in distinguishing between them?

Endometrial hyperplasia and carcinoma represent different points in a disease continuum which may be difficult to distinguish using standard histologic criteria. The role of ancillary biochemical, ultrastructural and immunocytochemical techniques in understanding the normal physiologic responses to hormonal stimuli is briefly considered in order to serve as a basis for an analysis of abnormal proliferative states. Not surprisingly, the ultrastructural and biochemical features of hyperplastic and carcinomatous endometria demonstrate a progressive continuum of abnormalities. The role of the immunohistologic detection of CEA, HCG, Casein, and other markers in distinguishing between the various endometrial diseases is discussed. The endometrium represents one of the more spectacular of endocrine target organs in which marked morphologic and ultrastructural changes occur throughout a women's lifetime. Such changes include those accompanying the menarche and the menopause as well as the extensive remodelling which occurs during the reproductive years. During the latter period, the endometrium cyclically proliferates, undergoes secretory differentiation, regresses, degenerates and regenerates. These regularly occurring changes are distinctive and have been described in histological detail, (Noyes et al., 1950, Noyes, 1973, Dallenbach-Hellweg, 1974), as well as ultrastructurally (Cavazos and Lucas, 1973, Ferenczy and Richart, 1974, Ferenczy, 1977). Morphological studies, coupled with advances in knowledge of steroid biochemistry, have confirmed that the cyclic morphological alterations are under the regulatory role of estrogens and progesterone.

Age-dependent morphological changes in the seminal colliculus in male mice. Light and scanning electron microscopic study

The developmental changes in the seminal colliculus of male mice were studied by light and scanning electron microscopy. The epithelium of the mouse seminal colliculus is transformed to the mature epithelium between 20 and 25 days of age, while the transformation of the remaining urethral wall occurred from 5 to 10 days of age. During the process of this epithelial transformation at the seminal colliculus unusual structures, including prominent epithelial proliferations and protrusions, were observed in the area adjacent to the ejaculatory duct openings and the ventral area of the upper medial region of the seminal colliculus in 15-day-old mice. In these unusual structures, three types of cells were recognized by their surface characteristics: cells which had distinct borders and ruffled cell surfaces with microridges; cells which had distinct borders and flat or slightly ruffled cell surfaces with many short microvilli, and small cells which had rounded cell surfaces with many long microvilli. In the remaining area of the seminal colliculus, two types of cells were distinguished: those which had flat or slightly rounded cell surfaces with many short microvilli and those cells with many long microvilli similar to the ones in the previously described area. In 25-day-old mice, the unusual protruding structures were not observed, but some cells with ruffled surfaces were still seen.