Cell biology. Fusion without SNAREs?

Highly orchestrated molecular rearrangements are required for two membranes to fuse, as happens, for example, during neurotransmitter release into the synapse. In an elegant Perspective, Scales et al. discuss two studies (Schoch et al., Wang et al.) that shed new light on the protein interactions involved in membrane fusion.

BMP-4 inhibits neural differentiation of murine embryonic stem cells.

Members of the transforming growth factor-beta superfamily, including bone morphogenetic protein 4 (BMP-4), have been implicated as regulators of neuronal and glial differentiation. To test for a possible role of BMP-4 in early mammalian neural specification, we examined its effect on neurogenesis in aggregate cultures of mouse embryonic stem (ES) cells. Compared to control aggregates, in which up to 20% of the cells acquired immunoreactivity for the neuron-specific antibody TuJ1, aggregates maintained for 8 days in serum-free medium containing BMP-4 generated 5- to 10-fold fewer neurons. The action of BMP-4 was dose dependent and restricted to the fifth through eighth day in suspension. In addition to the reduction in neurons, we observed that ES cell cultures exposed to BMP-4 contained fewer cells that were immunoreactive for glial fibrillary acidic protein or the HNK-1 neural antigen. Furthermore, under phase contrast, cultures prepared from BMP-4-treated aggregates contained a significant proportion of nonneuronal cells with a characteristic flat, elongated morphology. These cells were immunoreactive for antibodies to the intermediate filament protein vimentin; they were rare or absent in control cultures. Treatment with BMP-4 enhanced the expression of the early mesodermal genes brachyury and tbx6 but had relatively little effect on total cell number or cell death. Coapplication of the BMP-4 antagonist noggin counteracted the effect of exogenous BMP-4, but noggin alone had no effect on neuralization in either the absence or presence of retinoids. Collectively, our results suggest that BMP-4 can overcome the neuralizing action of retinoic acid to enhance mesodermal differentiation of murine ES cells.

Glutamate receptor-mediated calcium entry in neurons derived from P19 embryonal carcinoma cells.

We have examined the control of calcium elevation by glutamate in neurons derived from the mouse P19 embryonal carcinoma cell line. Following transient exposure to retinoic acid, P19 cells differentiate into neurons that express both NMDA and non-NMDA glutamate receptor subtypes. Fluorescence videomicroscopy using the indicator fura-2 revealed concentration-dependent elevation in cytosolic calcium levels with exposure to NMDA or kainate. Replacement of extracellular sodium with N-methylglucamine significantly reduced the action of kainate. Exposure to high K+ medium also elicited an elevation of cytosolic calcium in P19 cells, which was partially inhibited by the calcium channel antagonist nimodipine. These experiments suggest that the elevation in calcium produced by kainate involves the activation of voltage-gated calcium channels as a consequence of membrane depolarization, in contrast to direct calcium entry through NMDA receptor channels. Whole-cell recordings revealed that P19 NMDA receptors were highly permeable to calcium (PCa/PNa = 5.6 +/- 0.2). In most cells, channels gated by kainate displayed low permeability to calcium; the median permeability ratio, PCa/PNa, was 0.053 (range 0.045 to 0.132). Activation of peak currents by NMDA, glycine, and kainate was half-maximal at 24 microM, 240 nM, and 81 microM, respectively. In addition, cadmium-sensitive currents through voltage-gated calcium channels were recorded in P19 cells bathed in barium/TEA chloride. Staining with antibodies directed against AMPA receptor subunits revealed wide-spread immunoreactivity for anti-GluR-B/C and anti-GluR-B/D. About half of the P19 cells were stained with antibodies selective for GluR-D but there was little or no immunoreactivity for the GluR-A subunit.

Synapse formation and establishment of neuronal polarity by P19 embryonic carcinoma cells and embryonic stem cells.

A number of different cell lines that exhibit a partial neuronal phenotype have been identified, but in many cases the full extent of their neuronal differentiation has not been directly addressed by functional studies. We have used electrophysiology and immunofluorescence to examine the formation of synapses and the development of neuronal polarity by murine embryonic stem (ES) cells and the mouse P19 embryonic carcinoma cell line. Within 2-3 weeks after induction by retinoic acid, subsets of P19 and ES cells formed excitatory synapses, mediated by glutamate receptors, or inhibitory synapses, mediated by receptors for GABA or glycine. In ES-cell cultures, both NMDA and non-NMDA receptors contributed to the excitatory postsynaptic response. Staining with antibodies to growth-associated protein-43 and microtubule-associated protein-2 revealed segregation of immunoreactivity into separate axonal and somato-dendritic compartments, respectively. Consistent with our physiological evidence for synapse formation, intense punctate staining was observed with antibodies to the synaptic vesicle proteins synapsin, SV2, and synaptophysin. These results demonstrate the in vitro acquisition by pluri-potent cell lines of neuronal polarity and functional synaptic transmission that is characteristic of CNS neurons.