L. H. K. Defize

PTH/PTHrP receptor in early development and Indian hedgehog-regulated bone growth

The PTH/PTHrP receptor binds to two ligands with distinct functions: the calcium-regulating hormone, parathyroid hormone (PTH), and the paracrine factor, PTH-related protein (PTHrP). Each ligand, in turn, is likely to activate more than one receptor. The functions of the PTH/PTHrP receptor were investigated by deletion of the murine gene by homologous recombination. Most PTH/PTHrP receptor (−/−) mutant mice died in mid-gestation, a phenotype not observed in PTHrP (−/−) mice, perhaps because of the effects of maternal PTHrP. Mice that survived exhibited accelerated differentiation of chondrocytes in bone, and their bones, grown in explant culture, were resistant to the effects of PTHrP and Sonic hedgehog. These results suggest that the PTH/PTHrP receptor mediates the effects of Indian Hedgehog and PTHrP on chondrocyte differentiation.

Twenty one years of P19 cells: what an embryonal carcinoma cell line taught us about cardiomyocyte differentiation

Many different stem cell types have been shown to differentiate into cardiac muscle cells in vitro but P19 embryonal carcinoma (EC) cells were one of the first examples described and have been the most extensively characterized. P19 EC cells, isolated from an experimental embryo-derived teratocarcinoma in mice, are multipotent and can differentiate into cell types of all three germ layers. Because of their capacity to form cardiomyocytes however, they have been used to dissect the role of cardiac-specific transcription factors and upstream signalling pathways in cardiac cell differentiation. Furthermore, they have shed light on unique aspects of cardiac cell physiology during heart cell differentiation, including regulation of the proteins underlying the electrical and contractile systems. Here, we review studies on different subclones of P19 cells, and what they have taught us about cardiac differentiation and physiology.

PARATHYROID HORMONE ACTIVATES MITOGEN-ACTIVATED PROTEIN KINASE VIA A CAMP-MEDIATED PATHWAY INDEPENDENT OF RAS

In a previous study, we demonstrated that parathyroid hormone (PTH) inhibits mitogen-activated protein (MAP) kinase activation in osteosarcoma cells via a protein kinase A-dependent pathway. Here, we show that PTH can induce a transient activation of MAP kinase as well. This was observed in both Chinese hamster ovary R15 cells stably expressing high levels of rat PTH/PTH-related peptide receptor and parietal yolk sac carcinoma cells expressing the receptor endogenously. PTH was a strong activator of adenylate cyclase and phospholipase C in Chinese hamster ovary R15 cells. PTH-induced MAP kinase activation did not depend on activation of Gi, phorbol ester-sensitive protein kinase C, elevated intracellular calcium levels, or release of Gβγ subunits. It could, however, be mimicked by addition of forskolin or 8-bromo-cAMP to these cells. Prolonged treatment with forskolin caused sustained protein kinase A activity, whereas MAP kinase activity returned to basal levels. Subsequent treatment with PTH or 8-bromo-cAMP did not result in MAP kinase activation, whereas phorbol ester- or insulin-induced MAP kinase activation was unaffected. Finally, expression of a dominant negative form of Ras (RasAsn-17), which completely blocked insulin-induced MAP kinase activation, did not affect activation by PTH or cAMP. In conclusion, PTH regulates MAP kinase activity in a cell type-specific fashion. The activation of MAP kinase by PTH is mediated by cAMP and independent of Ras.

Expression pattern of parathyroid hormone/parathyroid hormone related peptide receptor mRNA in mouse postimplantation embryos indicates involvement in multiple developmental processes

In this paper we describe the cloning of the mouse Parathyroid Hormone/Parathyroid Hormone related Peptide Receptor (PTH/PTHrPR) cDNA and expression of its mRNA during mouse postimplantation development from day 5.5 until day 15.5 post coitum (p.c.). In support of a model from previous studies, in which parietal endoderm differentiation is regulated by the interaction of the PTH/PTHrPR and Parathyroid Hormone related Peptide (PTHrP), high levels of PTH/PTHrPR mRNA levels were detected in developing parietal endoderm from day 5.5 p.c. and onwards. In the embryo proper, PTH/PTHrPR mRNA expression was mainly detected at sites of epithelium/mesenchyme interactions, starting at day 9.5 p.c. in the epithelium of the intestine and later in the mesenchyme of the lung, the epithelium of meso- and metanephric tubuli, the dermis and at all sites where bone formation takes place. The complexity of the PTH/PTHrPR expression pattern suggests tight developmental regulation and indicates multiple roles in embryogenesis for the receptor and its ligands, not only in extraembryonic tissue but also in the formation of various organs.

Dissociation of cellular responses to epidermal growth factor using anti-receptor monoclonal antibodies.

Three biologically active monoclonal antibodies against the human epidermal growth factor (EGF) receptor (2E9, 2D11 and 2G5) have been used to analyse the interrelationship between various cellular responses to EGF. Antibody 2E9 (IgG1) is directed against the protein core of the receptor, close to or at the EGF binding site, while 2D11 (IgG3) and 2G5 (IgG2a) recognize blood‐group A‐related carbohydrate determinants of the receptor. These antibodies have EGF‐like effects in that they can activate the receptor tyrosine kinase both in vitro and in vivo. Cross‐linking of the receptor‐bound antibodies by a second antibody mimics EGF in inducing a rapid aggregation of receptors on the cell surface. However, all three antibodies fail to mimic EGF in raising cytoplasmic pH and free Ca2+ and do not stimulate DNA synthesis in quiescent fibroblasts, even after external cross‐linking of the occupied receptors. It is concluded that EGF‐R tyrosine kinase activity as well as substrate specificity can be modulated by ligands other than EGF, even if they bind to sites distinct from the EGF binding domain; activation of the receptor tyrosine kinase, receptor clustering and induction of the ionic signals are causally unrelated events; and tyrosine kinase activation and receptor cross‐linking are not sufficient for stimulation of DNA synthesis.

The Ras/Erk Pathway Induces Primitive Endoderm but Prevents Parietal Endoderm Differentiation of F9 Embryonal Carcinoma Cells

The formation of parietal endoderm (PE) is one of the first differentiation processes during mouse development and can be studied in vitro using F9 embryonal carcinoma (EC) cells. Treatment of F9 EC cells with retinoic acid (RA) induces differentiation toward primitive endoderm (PrE), while differentiation toward PE is induced by subsequent addition of parathyroid hormone (PTH) or PTH-related peptide (PTHrP). The signal transduction mechanisms involved in this two-step process are largely unclear. We show that the RA-induced differentiation toward PrE is accompanied by a sustained increase in Ras activity and that ectopic expression of oncogenic Ha-Ras is sufficient to induce PrE differentiation. Ras activity subsequently decreases upon PTH-induced differentiation toward PE. This is a necessary event, since expression of oncogenic Ha-Ras in PrE-like cells prevents PTH-induced PE differentiation. Expression of active PKA in PrE-like F9 cells mimics PTH-induced PE differentiation and is again prevented by oncogenic Ha-Ras. The effect of oncogenic Ras on both differentiation steps is abolished by the MEK inhibitor PD98059 and can be mimicked by constitutively active forms of Raf and MEK. In conclusion, our data suggest that activation of the Ras/Erk is sufficient to induce differentiation to PrE and to prevent subsequent differentiation toward PE. Activation of PKA down-regulates Ras activity, resulting in disappearance of this blockade and transmission of signal(s) triggering PE differentiation.

Transcriptional regulation of retinoic acid receptor β in retinoic acid-sensitive and -resistant P19 embryocarcinoma cells

As in other embryocarcinoma (EC) cell lines retinoic acid (RA) rapidly induces expression of the nuclear retinoic acid receptor (RAR) beta in murine P19 EC cells, while RAR alpha is expressed constitutively. In the RA-resistant P19 EC-derived RAC65 cells, however, there is no such induction and an aberrant (smaller) RAR alpha transcript is expressed. RAR gamma 1 is expressed at low levels in both cell lines. To study the regulation of the RAR beta gene and the possible involvement of RAR alpha protein in transcriptional activation of the RAR beta gene we transfected these cells with a construct containing a 1.6 kb promoter fragment of the human RAR beta gene fused to the CAT gene. Upon transient assays in P19 EC cells CAT activity is enhanced rapidly by RA, to more than 100-fold in a concentration-dependent fashion. On the contrary no activity can be observed in the RA-resistant RAC65 cells; however, co-transfection of hRAR alpha, hRAR beta or hRAR gamma 1 restores the RA-dependent induction of CAT activity. These results clearly show that RAR alpha and RAR gamma 1 can transactivate the RAR beta gene; that RAR beta can stimulate its own expression and that resistance to RA in RAC65 cells is probably due to the altered RAR alpha transcript present in these cells.

Interdependent action of RalGEF and Erk in Ras-induced primitive endoderm differentiation of F9 embryonal carcinoma cells.

Previous work by us and others has implicated a role for Ral guanine exchange factors (RalGEFs) in Ras-induced cell growth and oncogenic transformation. Here we show for the first time that RalGEFs are involved in Ras-induced differentiation as well. Expression of oncogenic Ras in F9 embryonal carcinoma (EC) cells is known to induce differentiation to a primitive endoderm (PrE)-like phenotype, but the downstream signal transduction mechanisms involved are unclear. We found that PrE differentiation is induced by the Ras effector domain mutants, RasV12G37 and RasV12E38, but not by RasV12C40. Accordingly, expression of constitutively active forms of RalGEF (Rlf-CAAX) or Raf1 (Raf-CAAX) is sufficient to induce differentiation. Inhibition of RalGEF activity by expression of dominant negative Ral completely abolishes Rlf-CAAX- and RasV12G37-induced differentiation, while it reduces differentiation by RasV12 and Raf-CAAX. Finally, while Rlf-CAAX does not increase Erk activity, inhibition of MEK blocks both Ras- as well as Rlf-CAAX-induced differentiation, suggesting that RalGEFs induce PrE differentiation in a manner depending on basal MEK or Erk activity. Based on these results we conclude that Ras induces PrE differentiation of F9 EC cells via an interplay of Erk- and RalGEF-mediated pathways.

PARATHYROID HORMONE-RELATED PEPTIDE (PTHRP) INDUCES PARIETAL ENDODERM FORMATION EXCLUSIVELY VIA THE TYPE I PTH/PTHRP RECEPTOR

A number of studies suggest a role for PTHrP and the classical PTH/PTHrP receptor (type I) in one of the first differentiation processes in mouse embryogenesis, i.e. the formation of parietal endoderm (PE). We previously reported that although in type I receptor (-/-) embryos PE formation seemed normal, the embryos were smaller from at least day 9.5 p.c. and 60% had died before day 12.5 p.c. Here we show that the observed growth defect commences even earlier, at day 8.5 p.c. Using two novel antibodies, we show that the expression of the type I receptor protein at this stage is confined to extraembryonic endoderm only. In addition, we show that large amounts of PTHrP protein are present in the adjacent trophoblast giant cells, suggesting a paracrine interaction of PTHrP and the type I PTH/PTHrP receptor in PE formation. The involvement in PE differentiation of other recently described receptors for PTHrP would explain a possible redundancy for the type I receptor in PE formation. However, deletion of the type I PTH/PTHrP receptor in ES cells by homologous recombination completely prevents PTHrP-induced PE differentiation. Based upon these observations, we propose that PTHrP and the type I PTH/PTHrP receptor, although not required for the initial formation of PE, are required for its proper differentiation and/or functioning.

Dynamic connexin43 expression and gap junctional communication during endoderm differentiation of F9 embryonal carcinoma cells

Gap junctional communication permits the direct intercellular exchange of small molecules and ions. In vertebrates, gap junctions are formed by the conjunction of two connexons, each consisting of a hexamer of connexin proteins, and are either established or degraded depending on the nature of the tissue formed. Gap junction function has been implicated in both directing developmental cell fate decisions and in tissue homeostasis/metabolite exchange. In mouse development, formation of the extra embryonal parietal endoderm from visceral endoderm is the first epithelial-mesenchyme transition to occur. This transition can be mimicked in vitro, by F9 embryonal carcinoma (EC) cells treated with retinoic acid, to form (epithelial) primitive or visceral endoderm, and then with parathyroid hormone-related peptide (PTHrP) to induce the transition to (mesenchymal) parietal endoderm. Here, we demonstrate that connexin43 mRNA and protein expression levels, protein phosphorylation and subcellular localization are dynamically regulated during F9 EC cell differentiation. Dye injection showed that this complex regulation of connexin43 is correlated with functional gap junctional communication. Similar patterns of connexin43 expression, localization and communication were found in visceral and parietal endoderm isolated ex vivo from mouse embryos at day 8.5 of gestation. However, in F9 cells this tightly regulated gap junctional communication does not appear to be required for the differentiation process as such.