Modifications of testosterone-dependent behaviors by estrogen receptor-alpha gene disruption in male mice.

The role of the a form of estrogen receptor (ER alpha) gene expression in the regulation of testosterone-dependent male reproductive behaviors was investigated using ER knockout mice (ERKO), which are specifically deficient in functional ER alpha, but not ER beta, gene expression. Previous studies in gonadally intact ERKO mice revealed that male aggressive behavior was greatly reduced by the lack of a functional ER alpha gene. In the present study the almost complete suppression of male-typical offensive attacks was further confirmed in ERKO mice that had been singly housed since weaning. Regarding aggression, it was also found that ER alpha gene disruption virtually abolished the propensity to initiate offensive attacks, even though ERKO mice could elicit attacks from resident C57BL/6J mice as wild-type (WT) and heterozygous littermates. Daily injection of testosterone propionate (TP) was completely ineffective in inducing aggressive behavior in gonadectomized ERKO mice, whereas it successfully restored aggression in WT mice. In contrast, male sexual behaviors, mounts and intromissions, were induced by daily injection of TP in both gonadectomized ERKO and WT mice. In addition to TP, dihydrotestosterone propionate (DHTP) was also effective in restoring mounts in ERKO mice, although DHTP was much more potent in WT mice than in ERKO mice. Neither TP nor DHTP, however, ever induced ejaculation in ERKO mice. These results together with previous findings in gonadally intact ERKO mice suggest that ER alpha may be responsible for the regulation by testosterone of consummatory, but not motivational, aspects of male sexual behavior. Finally, ERKO male mice retrieved newborn pups placed in their home cage with similar latencies to males of the two other genotypes. During parental behavior tests, however, a higher percentage of ERKO mice (70%) showed infanticide compared with WT mice (35%). The latter result was interpreted as showing that ER alpha activation by testosterone during the perinatal period may exert a suppressive effect on testosterone-inducible infanticide in adulthood. With respect to three major testosterone-dependent behavioral systems reflecting masculinization, these findings demonstrate three different types of effects due to ER alpha gene disruption.

Modulation of estrogen receptor levels in mouse uterus by protein kinase C isoenzymes.

We have recently shown that protein kinase C (PKC) modifies estrogen receptor (ER) binding and modulates the responsiveness to estrogens in a clonal osteoblast-like cell line stably transfected with the ER. The purpose of the present study was to determine whether the interaction observed between the ER and PKC signaling in these cells occurs in additional estrogen target organs, such as the uterus. When uteri were incubated for 2 h with increasing concentrations of a kinase inhibitor (H7), ER binding was enhanced in a dose-dependent manner. Stimulation of PKC with phorbol ester reduced PKC activity levels, but increased ER binding. Interestingly, the changes in binding appeared to be due primarily to alterations in cytosolic ER levels, as binding in the nuclear fraction was minimally enhanced. When levels of ER messenger RNA were evaluated by Northern blot analysis, no differences were observed among the H7- or 12-O-tetradecanoylphorbol-13-acetate (TPA)-treated and untreated groups. Western blot analysis, however, demonstrated that levels of ER cytosolic protein in the H7-, TPA-, and staurosporine-treated groups were increased relative to those in the untreated controls. When uteri were incubated with diethylstilbestrol in the presence of either H7 or TPA, no change in cytosolic ER levels was found, suggesting that only unoccupied ERs are responsive to modulation by PKC. Western blotting of the various PKC isoforms indicated that although PKC alpha, -beta1, -betaII, -delta, and -zeta are expressed in the uterus, only PKC alpha and -beta1 are translocated from the soluble to the particulate fraction and then degraded after phorbol ester stimulation. Hence, one or both of these latter PKC isoforms may regulate cytosolic ER levels. Collectively, these data indicate that PKC may play an important role in the modulation of uterine ER levels and that PKC may exert its effect on the ER at some posttranscriptional or posttranslational step. Finally, our results show that an ER-PKC interaction occurs in a whole organ such as the uterus and that this interaction may be important in the regulation of the ER activity in a variety of estrogen-responsive tissues.

Targeted disruption of the estrogen receptor gene in male mice causes alteration of spermatogenesis and infertility.

The reproductive system of male mice homozygous for a mutation in the estrogen receptor (ER) gene (ER knock-out; ERKO) appears normal at the anatomical level. However, these males are infertile, indicating an essential role for ER-mediated processes in the regulation of male reproduction. Adult ERKO male mice have significantly fewer epididymal sperm than heterozygous or wild-type males. Although spermatogenesis is occurring in some seminiferous tubules of 3- to 5-month-old ERKO males, other tubules either have a dilated lumen and a disorganized seminiferous epithelium with few spermatogenic cells or lack a lumen and contain mainly Sertoli cells. There are no obvious differences in seminiferous tubules at 10 days of age between wild-type and ERKO mice, but the lumen in ERKO males is dilated in all seminiferous tubules by 20 days. However, spermatogenesis progresses and similar numbers of sperm are present in the cauda epididymis of ERKO and wild-type males until 10 weeks of age. Disruption of spermatogenesis and degeneration of the seminiferous tubules become apparent after 10 weeks in the caudal pole of the testis and progresses in a wave to the cranial pole by 6 months. However, the seminal vesicles, coagulating glands, prostate, and epididymis do not appear to be altered morphologically in ERKO mice. Serum testosterone levels are somewhat elevated, but LH and FSH levels are not significantly different from those in wild-type males. Sperm from 8- to 16-week-old mice have reduced motility and are ineffective at fertilizing eggs in vitro. In addition, ERKO males housed overnight with hormone-primed wild-type females produce significantly fewer copulatory plugs than do heterozygous or wild-type males. These results suggest that estrogen action is required for fertility in male mice and that the mutation of the ER in ERKO males leads to reduced mating frequency, low sperm numbers, and defective sperm function.

Estrogen receptor gene disruption: molecular characterization and experimental and clinical phenotypes.

The estrogen receptor (ER) is thought to play a crucial role in the regulation of many life processes, including development, reproduction and normal physiology. Because there have been no known mutations of the estrogen receptor in normal tissue of humans and animals, its presence and tissue distribution is thought to be essential for survival. Using the techniques of homologous recombination, we have disrupted the ER gene and have produced a line of transgenic mice possessing the altered ER gene (ERKO). The mouse ER gene was disrupted by inserting a 1.8 kb PGK-Neomycin sequence into exon 2, approximately 280 bp downstream of the transcription start codon. The correct targeting of the disruption was demonstrated by Southern blot analysis and PCR. Western blot analysis of uterine preparations from ERKO females showed no detectable ER protein. Heterozygotes had one half the level of ER protein compared to wild-type animals. Estrogen insensitivity was confirmed using estrogen agonists, estradiol, hydroxy tamoxifen, diethylstilbestrol treatment for 3 days which resulted in a 3-4-fold increase in uterine wet weight and vaginal cornification in wild-type females, while ERKO mice were totally unresponsive. These data were further supported by the failure of estrogen or EGF treatment to induce DNA synthesis in uterine tissue of similarly treated mice. Lactoferrin, an estrogen-responsive gene in the uterus, was also assayed by Northern blot. Wild-type mice treated with a single estradiol injection showed a 350-fold induction in lactoferrin mRNA. while ERKO females showed no detectable response. Both male and female animals survive to adulthood with normal gross external phenotypes. As expected, females are infertile and demonstrate hypoplastic uteri and hyperemic ovaries with no apparent corpora lutea. Males are also infertile, with atrophy of the testes and seminiferous tubule dysmorphogenesis. Although the reproductive capabilities have been altered with a dramatic effect on the gonads, prenatal development of the reproductive tracts of both sexes appear to be independent of an ER-mediated response. Analysis of the mammary glands of the ERKO females at 4 months of age showed a primitive ductal rudiment rather than the fully developed ductal tree seen in wild-type siblings. Also absent were the terminal end buds seen during normal ductal morphogenesis. Both sexes show a decrease in skeletal bone density, supporting a direct role for ER action in bone. A single patient is described who is homozygous for a point mutation in the human ER gene at codon 157. The mutation produces a truncation of the ER protein and results in estrogen insensitivity syndrome. Most significant of the clinical findings are effects on skeletal bone density and retarded bone age. Findings from the patient and mice suggest that the absence of functional ER is not lethal. Mutation in the ER gene is present in the human population. Further characterization of the mice and identification of additional patients will be required to more fully understand the consequences of ER gene mutations.

Analysis of transcription and estrogen insensitivity in the female mouse after targeted disruption of the estrogen receptor gene.

We employed homologous recombination in mouse embryonic stem cells to disrupt the estrogen receptor (ER) gene. Subsequently generated mice that are homozygous for the gene disruption, termed ERKO, possess no demonstrable wild-type ER by Western blot analysis. However, the presence of residual high affinity binding, as detected by [3H]estradiol binding assays and sucrose gradients in uterine extracts from ERKO females prompted further investigation of transcription and translation products from the disrupted ER gene. Analysis of ERKO uterine messenger RNA (mRNA) by reverse transcriptase-polymerase chain reaction demonstrated that although no full-length wild-type ER mRNA was present, two smaller transcripts, labeled E1 and E2, were identified and partially sequenced. Both ERKO transcripts are splicing variants that result in the disrupting NEO sequence being partially or completely removed from the mRNA. In the ERKO-E2 variant, this results in a frame shift and the creation of at least two stop codons downstream. In the ERKO-E1 variant, the ER reading frame is preserved and encodes for a smaller mutant ER that could be the source of the residual estradiol binding. When this mutant form is overexpressed and characterized in vitro, it results in a smaller protein of the predicted size that possesses significantly reduced estrogen-dependent transcriptional activity compared with that of the wild-type ER. Despite residual amounts of an impaired ER variant, estrogen insensitivity in the female ERKOs was confirmed by the failure of estrogen treatment to induce known uterine markers of estrogen action, such as increased DNA synthesis, and transcription of the progesterone receptor, lactoferrin, and glucose-6-phosphate dehydrogenase genes. Furthermore, serum levels of estradiol in the ERKO female are more than 10-fold higher than those in the wild type, consistent with a syndrome of hormone insensitivity.

Endogenous protein kinase-C activation in osteoblast-like cells modulates responsiveness to estrogen and estrogen receptor levels.

The osteoblast-like osteosarcoma cell line ROS 17/2.8, which expresses very low levels of estrogen receptor (ER), was stably transfected with the mouse ER in order to more easily evaluate the physiological role of estrogens in bone cell homeostasis. These transfected ROS.SMER 14 cells are highly responsive to estrogenic stimulation at subconfluence, but become refractory to estrogenic stimulation when postconfluency is reached. The purpose of these studies was to determine the mechanisms underlying this loss of responsiveness in these ER stably transfected cells at postconfluence. When proliferative capacity was evaluated by bromodeoxyuridine immunocytochemistry, approximately 70% of the subconfluent cells were actively dividing, whereas none of the postconfluent cells underwent division. Subconfluent cells were found to contain 2500-3000 ER-binding sites/cell, whereas the ER in postconfluent cells was low and often undetectable. Steady state ER mRNA levels were not significantly modified by postconfluency. ER protein levels were also unaffected by confluency status. Since protein kinase-C (PKC) has been reported to influence cell proliferation and steroid hormone receptor binding, PKC activity was measured in sub- and postconfluent cells. Calcium-dependent PKC activity was approximately about 2-fold higher in postconfluent compared to subconfluent cells, whereas no differences were discerned in calcium-independent PKC activity. In an effort to examine the role of PKC in greater detail, postconfluent cells were treated with PKC inhibitors (H-7 or staurosporine) or with the tumor promoter TPA (12-O-tetradecanoylphorbol-13-acetate) to down-regulate PKC activity, and changes in ER were evaluated. Inhibition or down-regulation of the PKC activity in postconfluent cells enhanced ER-binding capacity in a dose-dependent manner and estrogen responsiveness of an exogenous reporter gene and of the endogenous alkaline phosphatase, representing an endogenous estrogen-stimulated gene. These data indicate that there is an interaction between the PKC and ER signaling systems in bone cells and that this interaction may be influenced by the proliferative and/or differentiative state of the cells, resulting in modulation of hormone responsiveness.

Coupling of dual signaling pathways: epidermal growth factor action involves the estrogen receptor.

Epidermal growth factor (EGF) reproduces many of the effects of estrogen on the murine female reproductive tract and may partially mediate estrogen-induced growth and differentiation. This study was performed to investigate the mechanism by which EGF elicits estrogen-like actions in the whole animal. EGF was administered to adult ovariectomized mice by slow release pellets implanted under the kidney capsule. The induction of uterine DNA synthesis and phosphatidylinositol lipid turnover by EGF or administration of diethylstilbestrol (5 micrograms/kg), a potent estrogen, was attenuated by the estrogen receptor antagonist ICI 164,384. Furthermore, EGF mimicked the effects of estrogen on enhanced nuclear localization of the estrogen receptor and the formation of a unique form of the estrogen receptor found exclusively in the nucleus. These results suggest that EGF may induce effects similar to those of estrogen in the mouse uterus by an interaction between the EGF signaling pathway and the classical estrogen receptor. The demonstration of cross-talk between polypeptide growth factors and steroid hormone receptors may be of importance to our understanding of the regulation of normal growth and differentiation as well as the mechanisms of transmission of extracellular mitogen signals to the nucleus.

Localization of the estrogen receptor in uterine cells by affinity labeling with [3H]tamoxifen aziridine.

The possibility that estrogen receptors may exist in uterine plasma membranes was investigated by covalent labeling of estrogen receptors in mouse uterine cells with [3H]tamoxifen aziridine (TA). Isolated epithelial and stromal cells of immature mice were incubated with [3H]TA in the presence or absence of unlabeled tamoxifen, homogenized and separated into nuclear, cytosolic and microsomal fractions by differential centrifugation. These fractions were subjected to SDS-polyacrylamide gel electrophoresis and the proteins labeled covalently with TA were visualized by autoradiography. Proteins labeled specifically with [3H]TA were observed almost exclusively in the nuclear fraction of both epithelial and stromal cells. In contrast, very little labeled protein was detected in the cytosolic or microsomal fraction. Although these data do not preclude the possibility that estrogen binding sites are present in plasma membranes of uterine cells, this cellular fraction is definitely not labeled to a significant extent by [3H]TA. Thus, if membrane estrogen binding sites exist, their structural conformations may be different from that of nuclear estrogen receptors.