Extracellular events regulate functions in the cell nucleus by means of calcium ions acting through effector enzymes. Recently, the traditional view of the nuclear pore as freely permeable to small ions has been questioned as a result of reports that nuclear calcium can be regulated independently of cytosolic calcium. We have used confocal microscopy of fluorescent Ca2+ indicators to investigate the Ca2+ dynamics between cytosol and nucleus in neurons. We find that a previously reported amplification of Ca2+ changes in the nucleus is a measurement artefact. Small changes of cytosolic Ca2+ cause equally rapid changes in nuclear Ca2+, consistent with the free diffusion of Ca2+ through nuclear pores. In contrast, large cytosolic Ca2+ increases (above 300 nM) are attenuated in the nucleus. Our results show the nuclear envelope shapes but does not block the passage of Ca2+ signals from cytosol to nucleus.
Spinal cord injury often leads to permanent incapacity because long axons cannot regenerate in the CNS. Eph receptors inhibit axon extension through an effect on the actin cytoskeleton. We have previously reported that after injury EphA4 appears at high levels in stumps of corticospinal axons, while a cognate ligand, ephrinB2, is upregulated at the lesion site so as to confine the injured axons. In this study we have infused lesioned spinal cords with a peptide antagonist of EphA4. In treated animals the retrograde degeneration that normally follows corticospinal tract injury is absent. Rather, corticospinal tract axons sprout up to and into the lesion centre. In a behavioural test of corticospinal tract function, peptide treatment substantially improved recovery relative to controls. These results suggest that blocking EphA4 is likely to contribute to a future successful clinical treatment for spinal cord injury.
SUMMARY1. Photoreceptor cells of Limulus ventral eyes were bathed in artificial sea water (ASW) that contained 10 mM-EGTA and no added Ca2+ (EGTA-ASW). Test flashes elicited responses that increased to a maximum size within 10 min in EGTA-ASW but did not change further when dark-adapted cells were bathed for an additional 35 min in this solution.2. Light responses progressively declined from this maximum size if the cells were repetitively illuminated in EGTA-ASW. In this state of reduced responsiveness, response amplitudes were further reduced by intracellular ionophoretic injection of EGTA; response amplitudes were increased by intracellular ionophoretic injection of Ca2+. Both of these findings are opposite to what is normally observed for cells bathed in ASW. Also, after repetitive illumination in EGTA-ASW, both the slope of the response versus intensity relationship became steeper and light responses often had a delayed increase in amplitude.3. The light responses and the response versus intensity relation returned to normal when the bathing medium was changed back to ASW containing 10 mM-Ca2+.4. The light-induced rise in luminescence recorded from photoreceptors injected with the photoprotein aequorin (the 'aequorin response') declined by at most 50 % after dark-adapted photoreceptors were bathed in EGTA-ASW for 45 min. However, the aequorin response progressively declined by 98 % if cells were repetitively illuminated while bathed in EGTA-ASW. 5. The total intracellular Ca content of whole end-organs was measured by atomic absorption spectroscopy. Total intracellular Ca content did not change significantly while photoreceptors were bathed in EGTA-ASW even after repetitive illumination.6. We suggest that cytosolic Ca2+ is required by one or more steps in the mechanisms that link rhodopsin isomerization to both (i) an increase in the conductance of the cell membrane to Na+ and (ii) a release of Ca2+ from a light-labile store.
Mast cells are key regulators in allergy and inflammation, and release histamine, cytokines, and other proinflammatory mediators. In the classical view, IgE acts merely to prime mast cells, attaching to FcεRs but not evoking any cell signaling response until cross-linked by the presence of a multivalent allergen. However, several recent studies have reported that IgE alone can promote cell survival and cytokine production in the absence of cross-linking by allergen. In this study we demonstrate that acute addition of monomeric IgE elicits a wide spectrum of responses in the rat basophilic leukemia-2H3 mast cell line, including activation of phospholipases Cγ and D, a rise in cytosol Ca2+, NFAT translocation, degranulation, and membrane ruffling within minutes. Calcium transients persist for hours as long as IgE is present resulting in the maintained translocation of the transcription factor NFAT to the nucleus. Removal of IgE reverses the signaling processes. Our results indicate that, far from simply preparing the cells for a response to allergen, monomeric IgE can stimulate signaling pathways that lead to degranulation, membrane ruffling, and NFAT translocation. The mechanism of activation is likely to be via aggregation of the FcεR1 because activation by IgE can be inhibited with monovalent hapten.
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