Expression of a dominant negative estrogen receptor alpha variant in transgenic mice accelerates uterine cancer induced by the potent estrogen diethylstilbestrol.

ERΔ3 transgenic mice expressing a dominant negative estrogen receptor α (ERα) variant lacking the second zinc finger in the DNA binding domain were developed to examine its potential to inhibit estrogen action in vivo. To investigate if ERΔ3 expression influences uterine carcinogenesis, ERΔ3 transgenic mice were exposed to diethylstilbestrol (DES) on post-natal days 1-5. Neonatal DES treatment induced uterine adenocarcinomas in 81% of 8-month-old ERΔ3 mice compared to 49% of wild-type females (p<0.016). ERΔ3 did not inhibit the expression of the estrogen-responsive progesterone receptor and lactoferrin genes in the presence of ERα or modify their expression in ERα knockout (αERKO) mice. Higher circulating 17ß-estradiol levels and non-classical signaling by ERΔ3 may be related to the earlier incidence of uterine cancer. These findings indicate that expression of this ERα variant can influence determining events in uterine cancer development and its natural occurrence in the human uterus would unlikely be protective.

Phosphoglycerate kinase 2 (PGK2) is essential for sperm function and male fertility in mice.

Phosphoglycerate kinase 2 (PGK2), an isozyme that catalyzes the first ATP-generating step in the glycolytic pathway, is encoded by an autosomal retrogene that is expressed only during spermatogenesis. It replaces the ubiquitously expressed phosphoglycerate kinase 1 (PGK1) isozyme following repression of Pgk1 transcription by meiotic sex chromosome inactivation during meiotic prophase and by postmeiotic sex chromatin during spermiogenesis. The targeted disruption of Pgk2 by homologous recombination eliminates PGK activity in sperm and severely impairs male fertility, but does not block spermatogenesis. Mating behavior, reproductive organ weights (testis, excurrent ducts, and seminal vesicles), testis histology, sperm counts, and sperm ultrastructure were indistinguishable between Pgk2(-/-) and wild-type mice. However, sperm motility and ATP levels were markedly reduced in males lacking PGK2. These defects in sperm function were slightly less severe than observed in males lacking glyceraldehyde-3-phosphate dehydrogenase, spermatogenic (GAPDHS), the isozyme that catalyzes the step preceding PGK2 in the sperm glycolytic pathway. Unlike Gapdhs(-/-) males, the Pgk2(-/-) males also sired occasional pups. Alternative pathways that bypass the PGK step of glycolysis exist. We determined that one of these bypass enzymes, acylphosphatase, is active in mouse sperm, perhaps contributing to phenotypic differences between mice lacking GAPDHS or PGK2. This study determined that PGK2 is not required for the completion of spermatogenesis, but is essential for sperm motility and male fertility. In addition to confirming the importance of the glycolytic pathway for sperm function, distinctive phenotypic characteristics of Pgk2(-/-) mice may provide further insights into the regulation of sperm metabolism.

Studies using the estrogen receptor alpha knockout uterus demonstrate that implantation but not decidualization-associated signaling is estrogen dependent.

Ovarian hormonal signaling is essential for proper functioning of the uterus in the establishment of pregnancy. Previous studies have demonstrated that decidualization, a stromal transformation that occurs in response to embryo implantation, can be elicited in the uterus of estrogen receptor alpha knockout (alphaERKO) mice in the absence of the estrogen dependence normally seen in wild-type (WT) mice for this response. While the alphaERKO stromal compartment demonstrated the necessary decidual response, embryo implantation is a process initiated in the epithelial layer, a uterine component that lacks estrogen responsiveness in the alphaERKO. To determine if the alphaERKO uterus would be competent for implantation, donor embryos were transferred into the uterine lumen of WT and alphaERKO females that had been ovariectomized and treated with exogenous estradiol and progesterone to mimic early pregnancy. No implantation occurred in the alphaERKO, while implantation sites containing live embryos were seen in similarly treated WT uteri, indicating that functional estrogen receptor alpha (ERalpha) is required for implantation. Previous observations of estrogen-independent decidualization in the alphaERKO prompted investigation of the mechanism leading to estrogen independence of this process. The disruption of progesterone receptor (PR), Hoxa10, Cox2, or LIF in transgenic mice results in the loss of decidualization response. Therefore, the expression of these genes was studied in WT and alphaERKO uteri by comparing expression following vehicle, progesterone alone (P), or estradiol priming followed by progesterone with nidatory estradiol (E+Pe) and by comparing expression following the above hormonal manipulations in addition to luminal infusion of oil used previously as decidualization-initiating stimulus. The whole-uterus level of PR and Hoxa10 mRNAs did not vary; however, the PR protein was induced in the stroma 24 h after oil infusion. Interestingly, in the WT, this induction was most apparent in samples receiving E+Pe, while in the alphaERKO samples, the induction occurred independent of any hormone priming. Cox2 protein and mRNA increased in both WT and alphaERKO samples 2 h after oil infusion in all three of the treatment groups. In the WT samples, Cox2 levels remained elevated 24 h after oil infusion only in the E+Pe treatment group; however, the elevated Cox2 was seen in samples taken 24 h after oil infusion in all three alphaERKO treatment groups. The alphaERKO uterine tissue appeared to sustain more extensive damage when examined 24 h after oil infusion. Severe trauma, such as crushing of the uterine tissue, has previously been shown to remove the requirement for nidatory estradiol for deciduomas to develop, indicating that the greater susceptibility of alphaERKO uterine tissue to damage from intraluminal oil infusion is contributing to decidualization in the absence of ERalpha. Leukemia inhibitory factor (LIF) mRNA was also induced following estradiol treatment in the WT, but also following oil infusion in WT samples that were not treated with estradiol. In contrast, estradiol does not induce LIF mRNA in the alphaERKO, but oil infusion leads to a robust increase in LIF in all alphaERKO sample groups. LIF binds and activates its membrane receptor, which initiates responses including the phosphorylation and nuclear translocation of Stat3 transcription factor. Thus, Stat3 phosphorylation was studied in WT and alphaERKO samples and found to be induced following oil infusion in all samples. Together, these and previous observations illustrate that estrogen is essential for epithelial proliferation and embryo implantation and that estrogen is dispensable for stromal decidualization in the alphaERKO, as the essential genes and signals required for the response are still induced.

Early development of the gubernaculum and cremaster sac in estrogen receptor knockout mice.

AIM exogenous estrogen causes gubernacular atrophy and cryptorchidism in fetal rodents. Mice with an estrogen receptor-alpha (ERalpha) disrupted gene mutation (alphaERKO) were studied to determine whether ablation of endogenous estrogen action, through ERalpha, had an effect on gubernacular development. Serial sagittal sections were made of the pelvis in fetal and day 7 postnatal wild-type and alphaERKO mice with the estrogen receptor-alpha "knockout" gene mutation. Wild-type (n = 24), heterozygote (n = 13) and alphaERKO mice (n = 12) were sacrificed at 16, 17 and 18 days fetal life and at 7 days postnatally. The size of the gubernaculum, cremaster muscle, cremaster sac, and the width of the sac at both ends in day 7 mice were quantitated by computer analysis. Visually and statistically the ERKO mice could not be separated from the wild-type mice during fetal life. At day 7 postnatally, a thicker cremaster sac was noted morphologically, and also a statistically significant difference was seen in the width of the cremaster sac at the sac's tip. Sac area, cremaster muscle area and the width of the sac at the sac's end did not differ significantly. Overall there is minimal phenotypic change observed in the alphaERKO mouse compared to wild-type at the early developmental stages investigated. However, at postnatal day 7, there is a difference in the width of the cremasteric sac tip. This suggests that the effect of ERalpha, and thus signaling on the developing gubernaculum, occurs late in development. Alternatively, an action from the recently discovered ERbeta may be involved. Exploration of a betaERKO and the double knock-out alphaERKO/betaERKO mouse should be informative in evaluating the effect of endogenous estrogens in gubernacular development.

Estrogen receptor-alpha is required by the supporting somatic cells for spermatogenesis.

The gene for estrogen receptor-alpha (ERalpha) was disrupted in embryonic stem cells by homologous recombination and these cells were used to generate mice with a targeted mutation in the ERalpha gene (alphaERKO mice). It was found that males homozygous for the mutation are infertile, indicating that estrogen signaling through this nuclear hormone receptor is required for male reproductive function. Although spermatogenesis appears normal in juvenile and young adult alphaERKO mice, the sperm produced are unable to fertilize eggs in vitro. To determine whether ERalpha is required by somatic or germ cells in the male reproductive tract, we transplanted germ cells from homozygous mutant (ERalpha(-/-)) males to the testes of wild-type (ERalpha(+/+)) males depleted of germ cells by busulfan treatment. The recipients ('surrogate fathers') sired offspring heterozygous for the mutation (ERalpha(+/-)) and carrying the coat-color marker of the infertile donor males. This indicated that ERalpha(-/-) germ cells are able to produce sperm competent to fertilize when they are supported by ERalpha(+/+) somatic cells. When ERalpha(+/-) offspring produced by germ cell transplantation were mated to produce ERalpha(-/-) males, these mice were found to have the same phenotype as originally reported for alphaERKO males. These studies showed that male germ cells do not require ERalpha for regulation of their own genes for development and function, and strongly imply that somatic cells of the male reproductive tract require ERalpha to support the production of sperm that are capable of fertilization.

Molecular mechanism of estrogen action in the male: insights from the estrogen receptor null mice.

Until recently, 17beta-estradiol was thought to be of little importance in male fertility. However, the descriptions of testicular dysfunction and behavioral deficits leading to complete infertility in male mice lacking estrogen receptor alpha (ERalpha) have indicated the importance of estrogen action in fertility of the male rodent. In contrast, male mice lacking the newly discovered estrogen receptor beta (ERbeta) exhibit no compromised fertility. Recently, elaborate sperm transplantation studies have shown that the altered sperm function characteristic of the ERalpha knockout male are the result of the loss of ERalpha actions in the supporting somatic cells of the testis and epididymis rather than in the germ cell. This brief review will discuss the roles of estrogen action in male reproduction as revealed by mice lacking both known forms of the ER. A brief review of the estrogen signaling system is also included.

Insulin-like growth factor-II/cation-independent mannose 6-phosphate receptor mediates paracrine interactions during spermatogonial development.

The insulin-like growth factor-II/cation-independent mannose 6-phosphate (IGF-II/M6P) receptor transduces signals after binding IGF-II or M6P-bearing growth factors. We hypothesized that this receptor relays paracrine signals between Sertoli cells and spermatogonia in the basal compartment of the seminiferous epithelium. For these studies spermatogonia were isolated from 8-day-old mice with purity >95% and viability >85% after overnight culture. The IGF-II/M6P receptors were present on the surface of spermatogonia, as detected by indirect immunofluorescence. We determined that both IGF-II and M6P-glycoproteins in Sertoli cell conditioned medium (SCM) modulate gene expression in isolated spermatogonia. The IGF-II produced dose-dependent increases in both rRNA and c-fos mRNA. These effects were mediated specifically by IGF-II/M6P receptors, as shown by studies using IGF-II analogues that are specific agonists for either IGF-I or IGF-II receptors. The SCM treatment also induced dose-dependent increases in rRNA levels, and M6P competition showed that this response required interaction with IGF-II/M6P receptors. The M6P-glycoproteins isolated from SCM by IGF-II/M6P receptor affinity chromatography increased spermatogonial rRNA levels at much lower concentrations than required by SCM treatment, providing further evidence for the paracrine activity of Sertoli M6P-glycoproteins. These results demonstrate that Sertoli cells secrete paracrine factors that modulate spermatogonial gene expression after interacting with cell-surface IGF-II/M6P receptors.

BRCA2-null embryonic survival is prolonged on the BALB/c genetic background.

Women who inherit mutations in the BRCA2 cancer susceptibility gene have an 85% chance of developing breast cancer. The function of the BRCA2 gene remains elusive, but there is evidence to support its role in transcriptional transactivation, tumor suppression, and the maintenance of genomic integrity. Individuals with identical BRCA2 mutations display a different distribution of cancers, suggesting that there are low-penetrance genes that can modify disease outcome. We hypothesized that genetic background could influence embryonic survival of a Brca2 mutation in mice. Brca2-null embryos with a 129/SvEv genetic background (129(B2-/-)) died before embryonic day 8. 5. Transfer of this Brca2 mutation onto the BALB/cJ genetic background (BALB/c(B2-/-)) extended survival to embryonic day 10.5. These results indicate that the BALB/c background harbors genetic modifiers that can prolong Brca2-null embryonic survival. The extended survival of BALB/c(B2-/-) embryos enabled us to ask whether transcriptional regulation of the Brca1 and Brca2 genes is interdependent. The interdependence of Brca1 and Brca2 was evaluated by studying Brca2 gene expression in BALB/c(B1-/-) embryos and Brca1 gene expression in BALB/c(B2-/-) embryos. Nonisotopic in situ hybridization demonstrated that Brca2 transcript levels were comparable in BALB/c(B1-/-) embryos and wild-type littermates. Likewise, reverse transcriptase-polymerase chain reactions confirmed Brca1 mRNA expression in embryonic day 8.5 BALB/c(B2-/-) embryos that was comparable to Brca2-heterozygous littermates. Thus, the Brca1 and Brca2 transcripts are expressed independently of one another in Brca1- and Brca2-null embryos. Mol. Carcinog. 28:174-183, 2000.

Spermatogenic cells do not require estrogen receptor-alpha for development or function.

Estrogen receptors alpha (ERalpha) and beta (ERbeta) are ligand-dependent transcription factors and members of the nuclear hormone receptor superfamily encoded by separate genes. Male mice homozygous for a mutation in the gene encoding ERalpha are infertile. To determine whether germ cells or somatic cells require ERalpha, germ cells were transplanted from donor males homozygous for the mutation (ERalpha-/-) to testes of wild-type (ERalpha+/+) recipient mice depleted of germ cells. The recipients served as "surrogate fathers" for the infertile ERalpha-/- males. When mated to wild-type females, the recipients sired offspring heterozygous for the mutation (ERalpha+/-) and carrying the coat-color marker of the ERalpha-/- donor mice. These studies show that male germ cells do not require ERalpha for development or to function in fertilization, and imply that male ERalpha-/- mice are infertile due to disruption of estrogen action within somatic cells of the male reproductive system.

Human glyceraldehyde 3-phosphate dehydrogenase-2 gene is expressed specifically in spermatogenic cells.

Although the process of glycolysis is highly conserved in eukaryotes, several glycolytic enzymes have unique structural or functional features in spermatogenic cells. We previously identified and characterized the mouse complementary DNA (cDNA) and a gene for 1 of these enzymes, glyceraldehyde 3-phosphate dehydrogenase-s (Gapds). This gene is expressed only in spermatids. The enzyme appears to have an essential role in energy production required for fertilization, and it is reported to be susceptible to inhibition by certain environmental chemicals. We have now cloned and sequenced the cDNA for the human homologue of glyceraldehyde 3-phosphate dehydrogenase (GAPD2) and determined the structure of the gene. The messenger RNA (mRNA) was detected in testis, but not in 15 other human tissues analyzed by Northern blot technique. The deduced GAPD2 protein contains 408 amino acids and is 68% identical with somatic cell GAPD. GAPD2 has a 72-amino acid segment at the amino terminal end that is not present in somatic cell GAPD. This segment is proline-rich but contains smaller stretches of polyproline and is 30 amino acids shorter than the comparable segment of mouse GAPDS. The structure of the human GAPD2 gene was determined by polymerase chain reaction (PCR) to identify exon-intron junctions in a genomic clone and in total genomic DNA. The locations of these junctions in the GAPD2 gene corresponded precisely to those of the 11 exon-intron junctions in the mouse Gapds gene. Immunohistochemical studies found that GAPD2 is located in the principal piece of the flagellum of human spermatozoa, as are GAPDS in mouse and rat spermatozoa. GAPD2 extracted from human spermatozoa and analyzed by Western blot technique migrated with an apparent molecular weight of approximately 56,000, although the calculated molecular weight is 44 501. The conserved nature of the mouse, rat, and human enzymes suggests that they serve similar roles in these and other mammalian species.

Single amino acids determine specificity of binding of protein kinase A regulatory subunits by protein kinase A anchoring proteins.

Cyclic AMP-dependent protein kinase is tethered to protein kinase A anchoring proteins (AKAPs) through regulatory subunits (R) by RIalpha-specific, RIIalpha-specific, or RIalpha/RIIalpha dual-specific binding. Ala- and Val-scanning mutagenesis determined that hydrophobic amino acids at three homologous positions are required for binding of RIalpha to FSC1/AKAP82 domain B and RIIalpha to AKAP Ht31. A mutation at the middle position reversed the binding specificity of both AKAPs, and mutations at this same position of the dual-specific domain A of FSC1/AKAP82 converted it into either an RIalpha or RIIalpha binding domain. This suggests that hydrophobic amino acids at three conserved positions within the primary sequence and an amphipathic helix of AKAPs are required for cyclic AMP-dependent protein kinase binding, with the size of the aliphatic side chain at the middle position determining RIalpha or RIIalpha binding specificity.

Retrovirus integration site Mintb encoding the mouse homolog of hnRNP U.

Retroviral genes are not usually expressed in mouse embryonal carcinoma (EC) cells, but they are readily expressed upon differentiation of these cells. We previously reported the isolation of EC cell lines that express a neomycin resistance (neo) gene introduced by a recombinant transducing Moloney murine leukemia virus from specific integration sites, Minta, Mintb, Mintc, or Mintd. In some of these clones, the entire 5' long terminal repeat (LTR) was deleted, and the neo gene was expressed by read-through transcription from upstream cellular promoters in a "promoter-trap" fashion. One such promoter ("promoter B" at the Mintb locus) was found in a CpG island, associated with an upstream enhancer ("enhancer B"). Although enhancer B caused expression of the neo gene in the transductant EC cell line, no endogenous transcription from promoter B was detected in the parental EC or NIH3T3 cells. In contrast, we found a strong counter-flow endogenous transcription unit ("R" for reverse), which apparently interfered with transcription from promoter B. Promoter R turned out to have a bidirectional activity in transfection assays. In normal tissues, promoter R activates gene R, which encodes an 800-residue protein that is highly homologous to the rat and human heterogeneous nuclear ribonucleoprotein U (hnRNP U). Northern and in situ hybridization analyses revealed that gene R was abundantly expressed in the testis, especially in the pachytene spermatocytes and round spermatids.

Identification of tethering domains for protein kinase A type Ialpha regulatory subunits on sperm fibrous sheath protein FSC1.

The fibrous sheath is a unique cytoskeletal structure in the sperm flagellum believed to modulate sperm motility. FSC1 is the major structural protein of the fibrous sheath. The yeast two-hybrid system was used to identify other proteins that contribute to the structure of the fibrous sheath or participate in sperm motility. When FSC1 was used as the bait to screen a mouse testis cDNA library, two clones were isolated encoding the type Ialpha regulatory subunit (RIalpha) of cAMP-dependent protein kinase. Deletion analysis using the yeast two-hybrid system and in vitro binding assays with glutathione S-transferase-FSC1 fusion proteins identified two RIalpha tethering domains on FSC1. A domain located at residues 219-232 (termed domain A) corresponds to the reported tethering domain for a type II regulatory subunit (RII) of cAMP-dependent protein kinase, indicating that this binding domain has dual specificity to RI and RII. Another RIalpha tethering site (termed domain B) at residues 335-344 shows specific binding of RIalpha and had no significant sequence homology with known RII tethering domains. However, helical wheel projection analysis indicates that domain B is likely to form an amphipathic helix, the secondary structure of RII tethering domains of protein kinase A anchoring proteins. This was supported by the finding that site-directed mutagenesis to disrupt the amphipathic helix eliminated RIalpha binding. This is apparently the first report of an RIalpha-specific protein kinase A anchoring protein tethering domain.

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.

Morphometric study of the gubernaculum in male estrogen receptor mutant mice.

To determine role of estrogen receptors in testicular descent, a morphometric study of the testis and structures derived from the gubernaculum was made in sexually mature male mice having an estrogen receptor disrupted gene mutation (ERKO). Macroscopic dissections and sagittal serial sections were made of the pelvis of four wild-type mice, four mice heterozygous for the ERKO mutation, and four homozygous ERKO males. By external morphological examination the testes appeared to be descended in all three genotypes. All mice had development of a cremaster sac, which is derived from the gubernaculum, but this was twice as large in wild-type mice than in both the heterozygote or homozygote ERKO groups. The cause for the smaller cremaster sac appeared to be excessive development of the cremaster muscle in ERKO mice. The thickened muscle was associated with postmortem retraction of the testes into the inguinal canal or abdomen. Spermatogenesis and testicular volume were deficient in homozygous ERKO mice at this age. This study demonstrates that estrogen has a previously unknown role in masculine sexual development of the gubernaculum and the structures derived from it, such as the cremaster muscle.

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.

Characterization of Fsc1 cDNA for a mouse sperm fibrous sheath component.

The fibrous sheath is a major cytoskeletal structure in the principal piece of the mammalian sperm flagellum. We have cloned a cDNA and used it to characterize the expression of mRNA for a mouse sperm fibrous sheath protein. Peptides from a tryptic digest of fibrous sheath proteins were separated by HPLC and a 31 amino acid sequence was obtained from one of the peptides. Through the use of degenerate oligonucleotide polymerase chain reaction (PCR) primers predicted from this sequence, an 80-bp product was amplified from mouse testis first-strand cDNA. This was utilized as a probe to isolate a 2.9-kb cDNA clone from a mouse round spermatid cDNA library. Sequence analysis of the cDNA clone showed that it encodes a protein with an open reading frame of 849 amino acids and includes the original peptide sequence. The predicted protein has a molecular weight of 93,795 and contains 32 cysteine residues and 32 potential phosphorylation sites. It has no significant homology with other known cytoskeletal proteins. Northern blot analysis detected an mRNA of approximately 3 kb that was abundant in round spermatids of the mouse and in testes from six other mammalian species, but not in twelve somatic tissues from the mouse. In situ hybridization analysis indicated that the mRNA is first detected in step 1-6 spermatids, is most abundant in step 8-12 spermatids, and decreases in amount in step 13-15 spermatids, suggesting that expression of the mRNA occurs in the postmeiotic phase of spermatogenesis.(ABSTRACT TRUNCATED AT 250 WORDS)

Aberrant reproductive phenotypes evident in transgenic mice expressing the wild-type mouse estrogen receptor.

The estrogen receptor (ER) acts as a transcription factor to regulate multiple cellular functions involved in normal physiology, differentiation, and reproduction. To date, there is no known animal model for studying aberrant ER expression. Therefore, we created transgenic mice expressing the wild-type mouse ER under the control of the mouse metallothionein-I (MT) promoter to determine whether overexpression of the ER would disrupt normal reproductive processes. Five male and one female founder mice were produced, and all were fertile. The progeny from these mice were screened for MT-mER expression by the ribonuclease protection assay. Mice in all six lines were found to express the transgene in a variety of tissues, although generally at low levels. The highest level of expression was observed in the female reproductive tract of line E. Females in all six lines demonstrated aberrant reproductive phenotypes involving processes at parturition and, with some of the lines, a tendency toward reduced fertility. Gestational length was prolonged up to 4 days beyond the normal gestation of 19 days, providing evidence of delayed parturition. In addition, prolonged labor (up to 3 days in length to deliver all pups) and labors requiring cesarean sections for maternal survival demonstrated the occurrence of dystocia in the MT-mER females. As maternal age increased, the incidence of stillborn litters, delayed parturition, and dystocia approached 100% in the transgenic dams. Difficulties at parturition were not observed in nontransgenic control females. These phenotypes suggest that the mechanisms regulating parturition may be perturbed by improper expression of the ER. The MT-mER transgenic mice may provide a novel approach for studying the estrogen-regulated signals involved in parturition and fertility as well as a unique animal model for the human reproductive phenotypes of delayed parturition and dystocia.