Notch signaling activation suppresses v-Src-induced transformation of neural cells by restoring TGF-ß-mediated differentiation.

BACKGROUND: We have been investigating how interruption of differentiation contributes to the oncogenic process and the possibility to reverse the transformed phenotype by restoring differentiation. In a previous report, we correlated the capacity of intracellular Notch (ICN) to suppress v-Src-mediated transformation of quail neuroretina (QNR/v-src(ts)) cells with the acquisition by these undifferentiated cells of glial differentiation markers. METHODOLOGY/PRINCIPAL FINDINGS: In this work, we have identified autocrine TGF-ß3 signaling activation as a major effector of Notch-induced phenotypic changes, sufficient to induce transition in differentiation markers expression, suppress morphological transformation and significantly inhibit anchorage-independent growth. We also show that this signaling is constitutive of and contributes to ex-vivo autonomous QNR cell differentiation and that its down-regulation is essential to achieve v-Src-induced transformation. CONCLUSIONS/SIGNIFICANCE: These results support the possibility that Notch signaling induces differentiation and suppresses transformation by a novel mechanism, involving secreted proteins. They also underline the importance of extracellular signals in controlling the balance between normal and transformed phenotypes.

Down regulation of pRb in cultures of avian neuroretina cells promotes proliferation of reactive Müller-like cells and emergence of retinal stem/progenitors.

The aim of this work was to define the role of pRb depletion in the proliferation and differentiation of avian retinoblasts in vitro. For this purpose vectors expressing pRb short hairpin RNA were used to deplete pRb in cultures of avian neuroretinal cells. Down regulation of pRb was observed by Western blot and quantification of nuclear pRb. Cell proliferation and differentiation were studied following BrdU labeling and immunostaining. Transfection significantly down-regulated pRb in neuroretinal cells. Long-term effect of pRb depletion mainly induced proliferation of epithelial-like cells that expressed markers of reactive Müller glial cells. A minority of these cells that survived passaging could be maintained as neurosphere-like aggregates with low pRb, not observed in control cultures. BrdU labeling followed by a two week chase showed the presence of cells still remained labelled, indicating low cell cycling. Under appropriate conditions, these aggregates differentiate in precursors of amacrine interneurons shown by the expression of AP2, in absence of the photoreceptors marker visinin and the late neuronal marker MAP2. Taken together these data show that decrease pRb level in cultures of avian neuroretinal cells promotes the emergence and proliferation of stem cell/progenitors from reactive-like Muller cells.

The noncatalytic TrkCNC2 receptor is cleaved by metalloproteases upon neurotrophin-3 stimulation.

The trkC locus encodes catalytic and noncatalytic receptors, generated by alternative splicing. These primary high-affinity neurotrophin-3 (NT-3) receptors may act in concert to modulate responsiveness to NT-3. Signal modulation can also be achieved by receptors that are post-translationally processed. We report that the noncatalytic TrkC receptor, TrkCNC2, is cleaved at the membrane-proximal region of its extracellular domain. This generates a soluble ectodomain (gp90(TrkCNC2)) recovered in the cell culture medium and a membrane-bound fragment (p20(TrkCNC2)), which contains the transmembrane and intracellular regions including the juxtamembrane and the NC2-specific cytoplasmic domains. We also show that this processing, which does not occur in the TrkC catalytic counterpart, is upregulated by NT-3 and upon treatment with the tumor promoter 12-O-tetradecanoylphorbol-13-acetate. Moreover, cleavage inhibition after EDTA or 1.10 phenanthroline treatment suggests involvement of a metalloprotease(s). Finally, this post-translational processing was observed not only in TrkCNC2-overexpressing NIH3T3 cells but also in primary cultures of cortical neurons and brain extracts. This study shows that, in addition to alternative splicing, ectodomain shedding represents a novel means of regulating TrkC receptor signaling, and consequently NT-3 biological effects on target cells.

D53 is a novel endosomal SNARE-binding protein that enhances interaction of syntaxin 1 with the synaptobrevin 2 complex in vitro.

Synaptobrevin 2 (Sb2), syntaxin1 (Stx1), and synaptosomal-associated protein of 25 kDa (SNAP-25) are the main components of the soluble N -ethylmaleimide-sensitive fusion protein attachment protein receptor (SNARE) complex involved in fusion of synaptic vesicles with the presynaptic plasma membrane. We report the characterization of D53, a novel SNARE-binding protein preferentially expressed in neural and neuro-endocrine cells. Its two-dimensional organization, established by the hydrophobic cluster analysis, is reminiscent of SNARE proteins. D53 contains two putative helical regions, one of which includes a large coiled-coil domain involved in the interaction with Sb2 in vitro. Following subcellular fractionation, endogenous D53 was specifically detected in the membrane-containing fraction of PC12 cells, where it co-immunoprecipitated with Sb2. Analysis by confocal microscopy showed that, in these cells, endogenous D53 co-localized partially with the transferrin receptor in early endosomes. In vitro assays revealed that binding properties of D53 to Stx1 and Sb2 are comparable with those of SNAP-25. Furthermore, D53 forms Sb2/Stx1/D53 complexes in vitro in a manner similar to SNAP-25. We propose that D53 could be involved in the assembly or disassembly of endosomal SNARE complexes by regulating Sb2/Stx interaction.