Primordial germ cell-like cells differentiated in vitro from skin-derived stem cells.

BACKGROUND: We have previously demonstrated that stem cells isolated from fetal porcine skin have the potential to form oocyte-like cells (OLCs) in vitro. However, primordial germ cells (PGCs), which must also be specified during the stem cell differentiation to give rise to these putative oocytes at more advanced stages of culture, were not systematically characterized. The current study tested the hypothesis that a morphologically distinct population of cells derived from skin stem cells prior to OLC formation corresponds to putative PGCs, which differentiate further into more mature gametes. METHODOLOGY/PRINCIPAL FINDINGS: When induced to differentiate in an appropriate microenvironment, a subpopulation of morphologically distinct cells, some of which are alkaline phosphatase (AP)-positive, also express Oct4, Fragilis, Stella, Dazl, and Vasa, which are markers indicative of germ cell formation. A known differentially methylated region (DMR) within the H19 gene locus, which is demethylated in oocytes after establishment of the maternal imprint, is hypomethylated in PGC-like cells compared to undifferentiated skin-derived stem cells, suggesting that the putative germ cell population undergoes imprint erasure. Additional evidence supporting the germ cell identity of in vitro-generated PGC-like cells is that, when labeled with a Dazl-GFP reporter, these cells further differentiate into GFP-positive OLCs. SIGNIFICANCE: The ability to generate germ cell precursors from somatic stem cells may provide an in vitro model to study some of the unanswered questions surrounding early germ cell formation.

Porcine DAZL messenger RNA: its expression and regulation during oocyte maturation.

Deleted in Azoospermia-Like (DAZL) is known to play an important role during both spermatogenesis and oogenesis, as mutations in this gene may result in male and female sterility. In order to study the expression of DAZL in the pig, we cloned the full-length coding sequence and determined its mRNA and protein expression profile in the ovary and in oocytes undergoing in vitro maturation (IVM). Immunohistochemisty revealed that DAZL protein localizes to oocytes of both preantral and antral follicles. The expression in the oocytes was also confirmed by Western blot. Immunocytochemistry and real time RT-PCR showed that the DAZL transcript and protein accumulate during oocyte maturation. In addition, glial cell line-derived neurotrophic factor (GDNF), epidermal growth factor (EGF), and follicle-stimulating hormone (FSH) significantly stimulate DAZL expression in oocytes derived from antral follicles during IVM. Our results suggest that the porcine DAZL coding sequence is highly homologous to those reported for the human and mouse cDNAs, and that DAZL expression increases during oocyte maturation.

An epigenetic mechanism regulates germ cell-specific expression of the porcine Deleted in Azoospermia-Like (DAZL) gene.

The Deleted in Azoospermia-Like (DAZL) gene is specifically expressed in fetal and adult gonads. While DAZL is known to play a role during gametogenesis, the mechanisms governing its germ cell-specific expression remain unclear. We identified the 5' untranslated region (UTR) of the porcine DAZL gene and cloned and characterized 2 kilobase pairs of its TATA-less 5' flanking region, identifying CpG-rich regions within the proximal promoter. Nine of 18 CpG sites in proximity to one region were largely unmethylated in germ cells but hypermethylated in somatic cells, suggesting that DNA methylation may regulate DAZL promoter activity. Furthermore, DAZL expression was induced in fibroblasts treated with a demethylating agent. Deletion analyses revealed that the minimal 149 base pair promoter region was sufficient to activate transcription. In vitro methylation of a reporter construct corresponding to these 149 base pairs resulted in complete suppression of DAZL promoter activity in primordial germ cells, further supporting a role for methylation in regulating DAZL expression. Interestingly, the differentially methylated region was shown to harbor several putative Sp1-binding sites. Mutation of only the most highly conserved site significantly reduced promoter activity in a reporter assay. Furthermore, gel shift assays revealed that Sp1 was able to specifically bind to this site, and that complex formation was inhibited when CpG dinucleotides within this region were methylated. Chromatin immunoprecipitation (ChIP) assays revealed that in vivo Sp1 binding to the core DAZL promoter region was enriched in germ cells but not in fibroblasts. Our data suggests that DNA methylation may suppress DAZL expression in somatic cells by interfering with Sp1 binding. This study provides insights into the potential mechanisms underlying the regulation of germ cell-specific gene expression.

Glial cell line-derived neurotrophic factor: an intraovarian factor that enhances oocyte developmental competence in vitro.

The success of early embryonic development depends on oocyte nuclear and cytoplasmic maturation. We have investigated whether glial cell line-derived neurotrophic factor (GDNF) affects the in vitro maturation (IVM) of porcine oocytes and their subsequent ability to sustain preimplantation embryo development. GDNF and both its coreceptors, GDNF family receptor alpha-1 (GFR alpha-1) and the rearranged during transformation (RET) receptor, were expressed in oocytes and their surrounding cumulus cells derived from small and large follicles. When included in IVM medium, GDNF significantly enhanced cumulus cell expansion of both small and large cumulus-oocyte complexes and increased the percentage of small follicle-derived oocytes maturing to the metaphase II stage, although nuclear maturation of large oocytes was not significantly affected. Examination of cyclin B1 protein expression as a measure of cytoplasmic maturation revealed that in the presence of GDNF, cyclin B1 levels were significantly increased in large follicle-derived oocytes, as well as in oocytes from small follicles to a level comparable to the untreated large group. After activation, a significantly higher percentage of both small and large oocytes that were matured in the presence of GDNF developed to the blastocyst stage compared with untreated controls. Indeed, GDNF enhanced the blastocyst rate of small oocytes to levels comparable to those obtained for large oocytes matured without GDNF. The effect of GDNF was specific; this was evident because its enhancement of nuclear maturation and embryo developmental potential was blocked by an antibody against GFR alpha-1. Our study provides the first functional evidence that GDNF affects oocyte maturation and preimplantation embryo developmental competence in a follicular stage-dependent manner. This finding may provide insights for improving the formulation of IVM culture systems, especially for oocytes from small follicles.

Relationship between Marek's disease and the time course of viral genome proliferation in feather tips.

A total of 114 male chickens from three sire families of a commercial cross of White Leghorn chickens were infected with RB-1B Marek's disease (MD) virus at 21 days of age by exposing them to chickens previously inoculated with MD virus. The presence of virus in feather tips, feather pulp, and MD viral antibodies indicated all chickens became infected. The first virus-positive chickens were observed at 12 days postexposure (dpe). The frequency reached a maximum at 27 dpe and then decreased. At 80 dpe, when the experiment was terminated, no viral DNA was detected in the feather pulp of the surviving chickens (82%). Death from MD was first observed at 38 dpe and reached 18% by the end of the experiment, with spleen lesions being the major MD lesion. The viral genome titers in spleen extracts of chickens with MD lesions was negatively correlated with the time of death, and, similar to feather pulp, none of the surviving chickens was virus positive at the end of the experiment. Quantization of the viral genome titers in feather tip extracts at 27 and 38 dpe revealed a positive correlation with the presence of MD lesions, but only in the declining phase (38 dpe) and not at the peak (27 dpe) of the viral titer. Sire effects were significant, indicating the presence of genetic factors that affect viral proliferation. Again, significance was only observed at 38 dpe and not at 27 dpe. The results indicate that, in this commercial line, 1) all chickens were susceptible to infection via contact exposure, 2) all surviving chickens recovered from the viral infection, and 3) it is not sufficient to measure viral titers at a single time point when using viral titers as an endpoint for MD susceptibility.

Pharmacological regulation of the insulin receptor signaling pathway mimics insulin action in cells transduced with viral vectors.

Diabetes mellitus derives from either insulin deficiency (type I) or resistance (type II). Homozygous mutations in the insulin receptor (IR) gene cause the rare leprechaunism and Rabson-Mendenhall syndromes, severe forms of hyperinsulinemic insulin resistance for which no therapy is currently available. Systems have been developed that allow protein-protein interactions to be brought under the control of small-molecule dimerizer drugs. As a potential tool to rescue glucose homeostasis at will in both insulin and insulin receptor deficiencies, we developed a recombinant chimeric insulin receptor (LFv2IRE) that can be homodimerized and activated by the small-molecule dimerizer AP20187. In HepG2 cells transduced with adeno-associated viral (AAV) vectors encoding LFv2IRE, AP20187 induces LFv2IRE homodimerization and transphosphorylation minutes after drug administration, resulting in the phosphorylation of a canonical substrate of the insulin receptor tyrosine kinase, IRS-1. AP20187 activation of LFv2IRE is dependent on the dose of drug and the amount of chimeric receptor expressed in AAV-transduced cells. Finally, AP20187-dependent activation of LFv2IRE results in insulin-like effects, such as induction of glycogen synthase activity and cellular proliferation. In vivo LFv2IRE transduction of insulin target tissues followed by AP20187 dosing may represent a therapeutic strategy to be tested in animal models of insulin resistance due to insulin receptor deficiency or of type I diabetes. This system may also represent a useful tool to dissect in vivo the independent contribution of insulin target tissues to hormone action.

Four naturally occurring mutations in the human GnRH receptor affect ligand binding and receptor function.

In the present study, we performed functional analyses of four mutations in the human GnRH receptor (GnRHR) gene, identified in patients with idiopathic hypogonadotropic hypogonadism. These mutations result in amino acid substitutions in the extracellular N-terminal domain (Thr32Ile), second extracellular loop (Cys200Tyr), third intracellular loop (Leu266Arg) and sixth transmembrane helix (Cys279Tyr). Immunocytochemical analysis of cells transfected with HA-tagged GnRHR constructs revealed that all four mutant receptors were present on the cell surface. However, all four mutant receptors failed to exhibit measurable specific GnRH binding and, except for Thr32Ile, any significant inositol phosphate accumulation after GnRH stimulation. In addition, Leu266Arg and Cys279Tyr receptors were unable to stimulate gonadotropin subunit or GnRHR gene promoter activity in response to GnRH. Interestingly, the Cys200Tyr mutant was able to stimulate gonadotropin subunit and GnRHR promoter activity, albeit with a higher EC(50) and a markedly reduced maximal response compared to wild type receptor. The Thr32Ile mutant was also able to stimulate gonadotropin subunit and GnRHR promoters, but with a further significant increase in EC(50). Similarly, this mutant partially retained the ability to activate extracellular signal-regulated kinase 1 and stimulate CRE-luciferase activity with an identical shift in EC(50). Taken together, the studies suggest that the Thr32Ile mutation reduces hGnRHR function primarily by reducing ligand binding affinity, and the Cys200Tyr mutation reduces cell surface receptor expression. All four amino acid substitutions interfered with ligand binding, and affected signal transduction and stimulation of gonadotropin and GnRHR gene expression in response to GnRH.

Two common naturally occurring mutations in the human gonadotropin-releasing hormone (GnRH) receptor have differential effects on gonadotropin gene expression and on GnRH-mediated signal transduction.

Studies of naturally occurring human GnRH receptor (GnRHR) mutants may provide a useful approach to dissecting the signal transduction pathways involved in mediating the effects of GnRH. We have analyzed two common mutations in the GnRHR, corresponding to amino acid substitutions Gln106Arg and Arg262Gln, for their effects on the stimulation of gonadotropin subunit and GnRHR gene expression by GnRH. Despite similar impairment of GnRH-stimulated inositol phosphate production, dose-response analyses indicated that Gln106Arg and Arg262Gln both reduced the sensitivity of the FSH beta gene promoter to a greater extent than LH beta or alpha GSU, suggesting the involvement of more than one signaling pathway. Furthermore, although the sensitivities of the LH beta and FSH beta gene promoters to GnRH were similarly affected by both mutants, alpha GSU sensitivity was decreased to a greater extent by Arg262Gln than by Gln106Arg. Similarly, GnRHR gene promoter sensitivity was significantly reduced only by Arg262Gln. To further characterize the differential downstream effects of these mutant GnRHRs, we investigated their effects on additional signal transduction pathways. The mutant receptors differentially affected GnRH-mediated activation of the ERK pathway and GnRH stimulation of cAMP response element-mediated transcription. These results indicate that measurement of inositol phosphate production alone may not be adequate for assessing mutant GnRHR function and additional signal transduction pathways may better reflect physiologically relevant effects. The differential stimulation of LH beta, FSH beta, and alpha GSU gene expression may contribute to the varied phenotypes observed among patients harboring these mutations.

Regulation of endogenous gene expression with a small-molecule dimerizer.

Artificial transcription factors containing designer zinc-finger DNA-binding domains (DBDs) have been used to activate or repress expression of a growing number of endogenous genes. We have combined targeted zinc-finger DBD technology with a dimerizer-regulated gene expression system to permit the small-molecule control of endogenous gene transcription. We constructed a dimerizer-responsive transcription factor that incorporates an artificial zinc-finger DBD targeted to the promoter of the human VEGF gene. Introduction of this activator into human cells allowed expression of the chromosomal VEGF gene to be induced by a small-molecule dimerizer compound consisting of a nonimmunosuppressive rapamycin analog. We found that by directly regulating zinc-finger protein (ZFP) activity, we could circumvent difficulties encountered in the generation of cell lines stably expressing conventional unregulated activators. Dimerizer-dependent VEGF induction was rapid, tight, and dose dependent, and resulted in VEGF protein expression levels several-fold greater than those produced by the natural hypoxic response.