Generation and characterization of an estrogen receptor alpha-iCre knock-in mouse.

Two estrogen receptors, ESR1 and ESR2, are responsible for the classical actions of estrogens in mammalian species. They display different spatiotemporal expression patterns and nonoverlapping functions in various tissues and physiological conditions. In this study, a novel knock-in mouse line that expresses codon-improved Cre recombinase (iCre) under regulation of the natural Esr1 promoter (Esr1-iCre) was developed. Functional characterization of iCre expression by crossing them with reporter lines (ROSA26-lacZ or Ai9-RFP) showed that iCre is faithfully expressed in Esr1-lineage cells. This novel transgenic mouse line will be a useful animal model for lineage-tracing Esr1-expressing cells, selective gene ablation in the Esr1-lineage cells and for generating global Esr1 knockout mice.

Generation of an estrogen receptor beta-iCre knock-in mouse.

A novel knock-in mouse that expresses codon-improved Cre recombinase (iCre) under regulation of the estrogen receptor beta (Esr2) promoter was developed for conditional deletion of genes and for the spatial and/or temporal localization of Esr2 expression. ESR2 is one of two classical nuclear estrogen receptors and displays a spatiotemporal expression pattern and functions that are different from the other estrogen receptor, ESR1. A cassette was constructed that contained iCre, a polyadenylation sequence, and a neomycin selection marker. This construct was used to insert iCre in front of the endogenous start codon of the Esr2 gene of a C57BL/6J embryonic stem cell line via homologous recombination. Resulting Esr2-iCre mice were bred with ROSA26-lacZ and Ai9-RFP reporter mice to visualize cells of functional iCre expression. Strong expression was observed in the ovary, the pituitary, the interstitium of the testes, the head and tail but not body of the epididymis, skeletal muscle, the coagulation gland (anterior prostate), the lung, and the preputial gland. Additional diffuse or patchy expression was observed in the cerebrum, the hypothalamus, the heart, the adrenal gland, the colon, the bladder, and the pads of the paws. Overall, Esr2-iCre mice will serve as a novel line for conditionally ablating genes in Esr2-expressing tissues, identifying novel Esr2-expressing cells, and differentiating the functions of ESR2 and ESR1.

Generation and characterization of an endothelin-2 iCre mouse.

A novel transgenic mouse line that expresses codon-improved Cre recombinase (iCre) under regulation of the Endothelin-2 gene (edn2) promoter was developed for the conditional deletion of genes in Endothelin-2 lineage cells and for the spatial and temporal localization of Endothelin-2 expression. Endothelin-2 (EDN2, ET-2, previously VIC) is a transcriptionally regulated 21 amino acid peptide implicated in vascular homeostasis, and more recently in female reproduction, gastrointestinal function, immunology, and cancer pathogenesis that acts through membrane receptors and G-protein signaling. A cassette (edn2-iCre) was constructed that contained iCre, a polyadenylation sequence, and a neomycin selection marker in front of the endogenous start codon of the edn2 gene in a mouse genome BAC clone. The cassette was introduced into the C57BL/6 genome by pronuclear injection, and two lines of edn2-iCre positive mice were produced. The edn2-iCre mice were bred with ROSA26-lacZ and Ai9 reporter mice to visualize areas of functional iCre expression. Strong expression was seen in the periovulatory ovary, stomach and small intestine, and colon. Uniquely, we report punctate expression in the corneal epithelium, the liver, the lung, the pituitary, the uterus, and the heart. In the embryo, expression is localized in developing hair follicles and the dermis. Therefore, edn2-iCre mice will serve as a novel line for conditional gene deletion in these tissues.

Disrupted kisspeptin signaling in GnRH neurons leads to hypogonadotrophic hypogonadism.

Landmark studies have shown that mutations in kisspeptin and the kisspeptin receptor (Kiss1r) result in reproductive dysfunction in humans and genetically altered mouse models. However, because kisspeptin and its receptor are present in target cells of the central and peripheral reproductive axis, the precise location(s) for the pathogenic signal is unknown. The study described herein shows that the kisspeptin-Kiss1r signaling pathway in the GnRH neuron is singularly critical for both the onset of puberty as well as the attainment of normal reproductive function. In this study, we directly test the hypothesis that kisspeptin neurons regulate GnRH secretion through the activation of Kiss1r on the plasma membrane of GnRH neurons. A GnRH neuron-specific Kiss1r knockout mouse model (GKirKO) was generated, and reproductive development and phenotype were assessed. Both female and male GKirKO mice were infertile, having low serum LH and FSH levels. External abnormalities such as microphallus and decreased anogenital distance associated with failure of preputial gland separation were present in GKirKO males. A delay in pubertal onset and abnormal estrous cyclicity were observed in female GKirKO mice. Taken together, these data provide in vivo evidence that Kiss1r in GnRH neurons is critical for reproductive development and fertility.

A low-copy-number plasmid for retrieval of toxic genes from BACs and generation of conditional targeting constructs.

Bacterial Artificial Chromosome (BAC) clones are widely used for retrieving genomic DNA sequences for gene targeting. In this study, low-copy-number plasmids pBAC-FB, pBAC-FC, and pBAC-DE, which carry the F plasmid replicon, were generated from pBACe3.6. pBAC-FB was successfully used to retrieve a sequence of a BAC that was resistant to retrieval by a high-copy-number plasmid via λ Red-mediated recombineering (gap-repair cloning). This plasmid was also used to retrieve two other genes from BAC, indicating its general usability retrieving genes from BAC. The retrieved genes were manipulated in generating targeting vectors for gene knockouts by recombineering. The functionality of the targeting vector was further validated in a targeting experiment with C57BL/6 embryonic stem cells. The low-copy-number plasmid pBAC-FB is a plasmid of choice to retrieve toxic DNA sequences from BACs and to manipulate them to generate gene-targeting constructs by recombineering.

Complete genome sequence and phylogenetic analysis of a recombinant Korean norovirus, CBNU1, recovered from a 2006 outbreak.

We have determined the complete nucleotide and deduced amino acid sequences of the RNA genome of CBNU1, a human norovirus (NoV) recovered from a 2006 outbreak in South Korea. The genome of 7547 nucleotides, excluding a 3'-poly(A) tail of 11-105 nucleotides, encodes three overlapping open reading frames (ORFs): ORF1 (nucleotides 5-5104), ORF2 (nucleotides 5085-6731), and ORF3 (nucleotides 6731-7495). In a comparison to 108 other currently available completely sequenced NoVs representing all five genogroups (GI-GV) except GIV, the CBNU1 strain was highly similar to GII.3 NoVs. Multiple sequence alignments of the completely sequenced NoV genomes revealed five hypervariable regions throughout their genomes: two in ORF1, one in ORF2, and two in ORF3. At both the nucleotide and amino acid levels, genome-based phylogenetic analyses invariably showed that the CBNU1 strain was most closely related to three GII.3 NoVs: the American Texas/TCH04-577 and the two Japanese Saitama U18 and Saitama U201 strains; furthermore, these genome-based phylogenetic topologies corresponded most closely to those based on the ORF2 genes, as compared to those based on the ORF1 and ORF3 genes. Subsequent ORF2-based phylogenetic analyses of a selection of 126 other NoVs representing all 19 GII genotypes, in combination with genome-based Simplot analyses, showed that the CBNU1 strain was a recombinant GII.3 NoV with a breakpoint at the ORF1/ORF2 junction between two putative parent-like strains, Guangzhou/NVgz01 and Texas/TCH04-577. Overall, the CBNU1 strain represents the first Korean human NoV whose genome has been completely sequenced and for which its relationship with a large panel of genetically diverse NoVs has been extensively characterized.

Japanese encephalitis virus-based replicon RNAs/particles as an expression system for HIV-1 Pr55 Gag that is capable of producing virus-like particles.

Ectopic expression of the structural protein Pr55(Gag) of HIV-1 has been limited by the presence of inhibitory sequences in the gag coding region that must normally be counteracted by HIV-1 Rev and RRE. Here, we describe a cytoplasmic RNA replicon based on the RNA genome of Japanese encephalitis virus (JEV) that is capable of expressing HIV-1 gag without requiring Rev/RRE. This replicon system was constructed by deleting all three JEV structural protein-coding regions (C, prM, and E) from the 5'-proximal region of the genome and simultaneously inserting an HIV-1 gag expression cassette driven by the internal ribosome entry site of encephalomyocarditis virus into the 3'-proximal noncoding region of the genome. Transfection of this JEV replicon RNA led to expression of Pr55(Gag) in the absence of Rev/RRE in the cytoplasm of hamster BHK-21, human HeLa, and mouse NIH/3T3 cells. Production of the Pr55(Gag) derived from this JEV replicon RNA appeared to be increased by approximately 3-fold when compared to that based on an alphavirus replicon RNA. Biochemical and morphological analyses demonstrated that the Pr55(Gag) proteins were released into the culture medium in the form of virus-like particles. We also observed that the JEV replicon RNAs expressing the Pr55(Gag) could be encapsidated into single-round infectious JEV replicon particles when transfected into a stable packaging cell line that provided the three JEV structural proteins in trans. This ectopic expression of the HIV-1 Pr55(Gag) by JEV-based replicon RNAs/particles in diverse cell types may represent a useful molecular platform for various biological applications in medicine and industry.

Generation of Cyp17iCre transgenic mice and their application to conditionally delete estrogen receptor alpha (Esr1) from the ovary and testis.

A transgenic mouse line that expresses iCre under regulation of the Cytochrome P(450) 17alpha-hydroxylase/17, 20-lyase (Cyp17) promoter was developed as a novel transgenic mouse model for the conditional deletion of genes specifically in the theca/interstitial cells of the ovary and Leydig cells of the testis. In this report, we describe the development of Cyp17iCre mice and the application of these mice for conditional deletion of the estrogen receptor alpha (Esr1) gene in the theca/interstitial and Leydig cells of the female and male gonad, respectively. These mice will prove a powerful tool to inactivate genes in the gonad in a cell-specific manner.

Role of hypoxia in the regulation of periovulatory EDN2 expression in the mouse.

We have previously proposed endothelin-2 (EDN2) as a granulosa cell-derived contractile signal that facilitates ovulation. Spatially, Edn2 mRNA expression is restricted to granulosa cells of periovulatory follicles. Temporally, mRNA for this contractile peptide is expressed immediately before follicle rupture. The primary objective of this study was to test the hypothesis that hypoxia mediates EDN2 expression in granulosa cells at ovulation, and if it does, to determine the region within the promoter responsible for this effect. To determine the effect of hypoxia on mRNA expression, immature mice were treated with 5 IU of PMSG followed 48 h later by 5 IU of human chorionic gonadotropin (hCG). Granulosa cells were isolated at 9 h after hCG, cultured under normal or hypoxic conditions, and the expression level of mRNA was compared. mRNA expression was increased when granulosa cells were cultured in a hypoxic environment (p<0.05). Subsequent promoter analysis found that the 5' upstream region of the EDN2 promoter (between -1894 bp and -1407 bp) was responsible for hypoxia-mediated changes in EDN2 expression. This promoter region contains multiple sites for potential transcriptional regulation, including that by hypoxia-inducible factor 1 (HIF-1, ACGTG) at -1297 bp. The second objective of this study was to determine whether the progesterone receptor (PR) or cyclooxygenase-2 (COX-2), two key regulators of periovulatory events, controlled EDN2 expression. To accomplish this, gonadotropin-primed mice were treated with RU-486 or indomethacin and expression of mRNA for Edn2 was determined in ovaries collected at 12 h after hCG. Treatment with RU-486 or indomethacin did not affect expression of mRNA for Edn2 (p>0.05). Taken together, we believe that hypoxia, but not the PR or COX-2, regulate gonadotropin-induced EDN2 expression in the periovulatory follicle.

Pituitary gonadotroph estrogen receptor-alpha is necessary for fertility in females.

Estrogens play a central role in regulating female reproduction throughout the reproductive axis, and the pituitary is one of the major targets of estrogen action. We hypothesized that estrogen receptor alpha (ERalpha) mediates estrogen action in the pituitary gonadotroph. To test this hypothesis, we generated a mouse line with a selective ERalpha deletion in the gonadotropin alpha-subunit (alphaGSU)-expressing pituitary cells (pituitary-specific ERalpha knockout; ERalpha(flox/flox) alphaGSU(cre)). Although the ERalpha(flox/flox) alphaGSU(cre) female mice maintain a basal level of serum LH and FSH and their ovulatory capacity is comparable to that in controls, they do not display regular estrous cycles and are infertile, indicating a potential disorder in regulating LH and/or FSH secretion. The ERalpha(flox/flox) alphaGSU(cre) female mice express equivalent levels of LHbeta and alphaGSU mRNA compared with wild-type mice as determined by microarray analysis. Taken together, these findings indicate that pituitary gonadotroph ERalpha carries out the effects of estrogens with regard to estrous cyclicity and ultimately fertility.

Glucocorticoids modulate NF-kappaB-dependent gene expression by up-regulating FKBP51 expression in Newcastle disease virus-infected chickens.

FK506-binding protein 51(FKBP51, coded by FKBP5) is a co-chaperone molecule that interacts with the chaperone HSP90 and the glucocorticoid receptor (GR) in an inactive GR complex. It is a negative regulator of glucocorticoid action and is replaced by the positive regulator, FK506-binding protein 52 (FKBP52, coded by FKBP4) when hormone binds to GR, which renders the GR complex active. In this study, we found that the expression of FKBP51 mRNA in 12 organs of Newcastle disease virus (NDV)-infected chickens was robustly induced. The level of corticosterone in NDV-infected chickens was also elevated, approximately 2- to 6.5-fold in the organs compared to non-infected control chickens. The induction of FKBP51 mRNA expression was reproduced by dexamethasone treatment, indicating a role for glucocorticoids in the systemic induction of FKBP51 mRNA expression. In chicken UMNSAH/DF-1 cells, nuclear factor kappaB (NF-kappaB) was activated in an FKBP51-dependent manner. Regulation of the three NF-kappaB-dependent, anti-apoptotic genes, bcl-2, bcl-x and bfl-1/A1 was investigated in UMNSAH/DF-1 cells. Dexamethasone treatment of UMNSAH/DF-1 cells resulted in up-regulation of bcl-2, and down-regulation of bcl-x and bfl-1/A1. Expression of FKBP51 also resulted in down-regulation of bfl-1/A1, but had no effect on bcl-2 and bcl-x, suggesting the involvement of glucocorticoid-FKBP51-NF-kappaB signaling in the regulation of expression of bfl-1/A1 in UMNSAH/DF-1 cells. We observed organ-specific up- or down-regulation of expression of, bcl-2, bcl-x and bfl-1/A1 in NDV-infected and dexamethasone-treated chickens. Differential regulation of bfl-1/A1, bcl-2 and bcl-x upon NDV-infection and dexamethasone treatment suggests that additional factors are involved in the regulation of these genes. These results suggest that systemic elevation of FKBP51 in NDV-infected chickens activates NF-kappaB, which cooperates with other factors to regulate the expression of NF-kappaB-dependent genes.

Kalirin is under-expressed in Alzheimer's disease hippocampus.

To identify genes aberrantly expressed in the brain of individuals with Alzheimer's Disease (AD), we analyzed RNA extracts from the hippocampus and cerebellum from 19 AD patients and 15 age- and sex-matched control subjects. Our analysis identified a number of genes that were over-expressed or under-expressed specifically in AD hippocampus. Among these genes, kalirin was the most consistently under-expressed in AD hippocampus, which was verified by semi-quantitative RT-PCR and real time PCR. Kalirin is predominantly expressed in the brain, particularly in the hippocampus, and plays crucial roles in neuronal stability and growth. Our observation is the first to relate kalirin to AD and a human disease. In addition to kalirin, the genes for voltage-gated Ca++ channel gamma subunit 3 and visinin-like protein 1 (a Ca++ sensor protein) were under-expressed, whereas inositol 1,4,5-triphosphate 3-kinase B was over-expressed in AD hippocampus. Collectively, these differential expressions could severely impair calcium homeostasis. Remarkably, these aberrant gene expressions in AD hippocampus were not observed in AD cerebellum. Furthermore, housekeeping genes such as ribosomal protein genes are not affected by AD. These results provide new insights into the biochemistry of AD.

Endothelin-2 in ovarian follicle rupture.

The ovulatory process is activated by a surge of LH, a pituitary gonadotropin, which initiates a cohort of dramatic changes in biochemical, physical, and gene expression in the ovary, leading to follicle rupture and oocyte release. Here we report the identification of endothelin-2 (EDN2) as a last moment-trigger of follicle rupture. In the ovary, EDN2 is exclusively and transiently expressed in the granulosa cells immediately before ovulation. Administration of EDN2 to the ovarian tissue induced rapid contraction, whereas addition of tezosentan, an endothelin receptor antagonist, diminishes the EDN2 effect. In vivo, treatment of tezosentan before ovulation substantially decreases gonadotropin-induced superovulation. As a target tissue of EDN2 action, we identified a layer of smooth muscle cells in the follicular wall of each follicle. Taken together, our data indicate that EDN2 induces follicular rupture by constricting periovulatory follicles.

Decay-accelerating factor in the periovulatory rat ovary.

One of the most prominent inflammatory reactions is the activation of the complement system. The activated complement system does not distinguish between pathogens and the host cell. In order to prevent autologous complement-mediated attack, host cells express a variety of both membrane-bound and fluid-phase complement regulatory proteins which control activity of the complement cascade by acting on convertase enzymes or the membrane-attack complex. Although the process of ovulation is facilitated by the inflammatory reaction, this reaction has the potential to cause serious damage to growing follicles, ovulated follicles, and other important ovarian tissues. This study was undertaken to characterize the expression and regulation of decay-accelerating factor (DAF), a complement regulator, as a potential mediator of ovarian tissue protection from ovulatory inflammation. DNA microarray and Northern blot analyses showed that an ovulatory gonadotropin stimulus dramatically yet transiently induced DAF mRNA expression in the immature rat ovary. Northern blot and PCR analyses revealed that of the three known DAF isoforms, glycosylphosphatidylinositol (GPI)-, soluble-, and transmembrane-(TM) DAF, GPI-DAF was the predominant form. In situ hybridization localized GPI-DAF mRNA expression in the theca-interstitial cells of the periovulatory ovary. Neither the anti-progestin RU486 nor the cyclooxygenase inhibitor indomethacin significantly inhibited human chorionic gonadotropin (hCG)-induced GPI-DAF mRNA expression in vivo. In vitro theca cell culture studies indicated that hCG induces GPI-DAF mRNA expression through the protein kinase A pathway. This study suggests that gonadotropin-induced GPI-DAF may be involved in the protection of ovarian tissues from the potential attack by the complement system activated by the inflammatory response associated with ovulation.

An upstream initiator-like element suppresses transcription of the rat luteinizing hormone receptor gene.

Expression of the rat LH receptor (rLHR) is characterized by a dynamic response to a variety of hormonal stimuli. In addition to activation, the pattern of rLHR expression is also modulated by repression. In this report, an upstream initiator-like element (UInr-lE), CTCACTCTAA, of which the CTC direct repeat motif (CTCACTC) is conserved in the rat, mouse, and human, was identified as a suppressor element. Disruption of the element resulted in a 2-fold enhancement of promoter activity in the LHR-expressing murine Leydig tumor cells. The sequences of the two major initiators (Inr), Inr3 and Inr4, of the rLHR core promoter are similar to UInr-lE and competed efficiently with UInr-lE in the formation of specific protein complexes, suggesting that the same proteins interact with both UInr-lE and the Inrs in vivo. The Inrs are necessary for full promoter activity because a mutant promoter lacking Inrs showed a 70% reduction in activity. UInr-lE also further suppressed the activity of a mutant promoter lacking Inrs. UInr-lE interacted with transcription factor II-I (TFII-I) and an unidentified nuclear protein. However, dominant-negative inhibition experiments using p70 indicated that TFII-I positively regulates LHR promoter activity through UInr-lE and Inrs, suggesting that TFII-I can compromise the suppression of promoter activity mediated by UInr-lE. UInr-lE also showed binding properties distinct from that of the upstream initiator-like suppressor element (upstream regulatory element: CACTCTCC) of rat and human dynorphin promoters. Transfection assays using mutated promoters indicate that the suppression of rLHR promoter activity could be regulated via specific interactions between UInr-lE and trans-acting factors.

Trans-activation of mutant follicle-stimulating hormone receptors selectively generates only one of two hormone signals.

Previously, we reported that a liganded LH receptor (LHR) is capable of activating itself (cis-activation) and other nonliganded LHRs to induce cAMP (trans-activation). Trans-activation of the LHR raises two crucial questions. Is trans-activation unique to LHR or common to other G protein-coupled receptors? Does trans-activation stimulate phospholipase Cbeta as it does adenylyl cyclase? To address these questions, two types of novel FSH receptors (FSHRs) were constructed, one defective in hormone binding and the other defective in signal generation. The FSHR, a G protein-coupled receptor, comprises two major domains, the N-terminal extracellular exodomain that binds the hormone and the membrane-associated endodomain that generates the hormone signals. For signal defective receptors, the exodomain was attached to glycosyl phosphatidylinositol (ExoGPI) or the transmembrane domain of CD8 immune receptor (ExoCD). ExoGPI and ExoCD can trans-activate another nonliganded FSH. Surprisingly, the trans-activation generates a signal to activate either adenylyl cyclase or phospholipase Cbeta, but not both. These results indicate that trans-activation in these mutant receptors is selective and limited in signal generation, thus providing new approaches to investigating the generation of different hormone signals and a novel means to selectively generate a particular hormone signal. Our data also suggest that the FSHR's exodomain could not trans-activate LHR.

Orientation of follicle-stimulating hormone (FSH) subunits complexed with the FSH receptor. Beta subunit toward the N terminus of exodomain and alpha subunit to exoloop 3.

Follicle-stimulating hormone (FSH) comprises an alpha subunit and a beta subunit, whereas the FSH receptor consists of two halves with distinct functions: the N-terminal extracellular exodomain and C-terminal membrane-associated endodomain. FSH initially binds to exodomain, and the resulting FSH/exodomain complex modulates the endodomain and generates signal. However, it has been difficult to determine which subunit of FSH contacts the exodomain or endodomain and in what orientation FSH interacts with them. To address these crucial issues, the receptor was Ala-scanned and the hormone subunits were probed with photoaffinity labeling with receptor peptides corresponding to the N-terminal region of the exodomain and exoloop 3 of the endodomain. Our results show that both regions of the receptors are important for hormone binding and signal generation. In addition, the FSH beta subunit is specifically labeled with the N-terminal peptide, whereas the alpha subunit is labeled with the exoloop 3 peptide. These contrasting results show that the FSH beta subunit is close to the N-terminal region and that the alpha subunit is projected toward exoloop 3 in the endodomain. The results raise the fundamental question whether the alpha subunit, common among the glycoprotein hormones, plays a major role in generating the hormone signal common to all glycoprotein hormones.