Activin and basic fibroblast growth factor regulate neurogenesis of murine embryonal carcinoma cells.

Murine P19 embryonal carcinoma (EC) cells can be differentiated into various germ layer derivatives. The addition of retinoic acid (RA) to P19-EC cell aggregates results in a transient activation of receptor protein tyrosine phosphatase-alpha (RPTP alpha). Subsequent replating of these aggregates leads to neuronal differentiation. P19-EC cells expressing constitutively active RPTP alpha (P19-RPTP alpha) show extensive neuronal differentiation upon RA treatment in monolayer. P19-RPTP alpha cells thus provide a suitable in vitro model for studying neuronal differentiation. We used P19-RPTP alpha cells to study the effects of activin and basic fibroblast growth factor (bFGF) on neurogenesis. We show that P19-RPTP alpha cells express mRNA for types I and II activin receptors. RA addition causes an up-regulation of receptor type IIA expression. Complexes of type I and II receptors were detectable by cross-linking assays both before and after RA treatment. Receptor complexes were functional as determined by transient transfection assays with activin responsive reporter constructs. Undifferentiated as well as differentiated P19-RPTP alpha cells express also the FGF receptors (FGFRs) FGFR-1 and FGFR-2 but not FGFR-3 and FGFR-4. Their functionality was established by bFGF induced mitogen-activated protein kinase phosphorylation. Activin and bFGF appeared to exert differential actions on RA-induced neuronal differentiation. Although activin irreversibly changes the differentiation fate into nonneuronal directions, bFGF does not affect initial neurogenesis but regulates axonal outgrowth in a concentration-dependent way; low concentrations of bFGF enhance axonal outgrowth, whereas high concentrations inhibit this process. These results strengthen the notion that activin and bFGF are important regulators of neurogenesis in the mammalian embryo.

Truncated activin type II receptors inhibit bioactivity by the formation of heteromeric complexes with activin type I. receptors.

Truncated activin type II receptors have been reported to inhibit activin receptor signaling in Xenopus embryos, although the mechanism of action for this effect has not been fully understood. In the present study we demonstrate that in P19 embryonal carcinoma cells both the induction of the activin responsive 3TP-lux reporter construct and the inhibition of retinoic acid-induced neuronal differentiation by activin are blocked by expression of a truncated activin receptor. To reveal the mechanism of action of truncated activin receptors, the interaction between different activin receptors has been investigated upon coexpression in COS cells followed by cross-linking of 125I-activin A and subsequent immunoprecipitation. Complexes between a truncated activin type IIA receptor and activin type IA and type IB receptors can be formed, as demonstrated by coimmunoprecipitation of these type I receptors with the truncated activin type IIA receptor. Other type I receptors known as ALK-1 and ALK-6 also coimmunoprecipitate with the truncated type IIA receptor, whereas ALK-3 and ALK-5 do not. Furthermore, the activin type IIB2 receptor does not coimmunoprecipitate with the truncated type IIA receptor, but decreases activin binding to the truncated type IIA receptor. In double immunoprecipitation experiments with cell lysates from COS cells, in which full-length activin type IIA and type IIB2 receptors were cotransfected, no interaction between these receptors was found. In contrast, homomeric complexes of full-length activin type IIA receptors were detected. These results implicate that truncated activin receptors can interfere with activin signaling by interacting with activin type I receptors. Additionally, truncated activin type IIB2 receptors might also interfere with type IIA receptor signaling by decreasing activin binding to the type IIA receptor and therefore might be more potent in inhibiting activin signal transduction. Furthermore, our data indicate that truncated type IIA receptors can interact with other type I receptors and as such might inhibit signal transduction by type I receptors other than activin type IA and type IB receptors.

Synaptic plasticity in an in vitro slice preparation of the rat nucleus accumbens.

Extra- and intracellular recordings in slices were used to examine what types of synaptic plasticity can be found in the core of the nucleus accumbens, and how these forms of plasticity may be modulated by dopamine. Stimulus electrodes were placed at the rostral border of the nucleus accumbens in order to excite primarily infralimbic and prelimbic afferents, as was confirmed by injections of the retrograde tracer fluoro-gold. In extracellular recordings, tetanization induced long-term potentiation (LTP) of the population spike in 20 out of 53 slices. The presynaptic compound action potential did not change following LTP induction. For the intracellularly recorded excitatory postsynaptic potentiation, three types of synaptic plasticity were noted: long-term potentiation (16 out of 54 cells), decremental potentiation (eight cells) and long-term depression (LTD; six cells). No correlation was found between the occurrence of potentiation or depression and various parameters of the tetanic depolarization (e.g. peak voltage, integral under the curve). The N-methyl-D-aspartate receptor antagonist D(-)-2-amino-5-phosphonopentanoic acid (50 microM; D-AP5) reduced, but did not completely prevent, the induction of LTP. The incidence of LTD was not markedly affected by D-AP5. No difference in LTP was found when comparing slices bathed in dopamine (10 microM) and controls. Likewise, slices treated with a mixture of the D1 receptor antagonist Sch 23390 (1 microM) and the D2 antagonist S(-)-sulpiride (1 microM) generated a similar amount of LTP as controls. In conclusion, both LTP and LTD can be induced in a key structure of the limbic-innervated basal ganglia. LTP in the nucleus accumbens strongly depends on N-methyl-D-aspartate receptor activity, but is not significantly affected by dopamine.