In rotavirus-infected cells, the non-structural proteins NSP5 and NSP2 localize in complexes called viroplasms, where replication and assembly occur. Recently, we have demonstrated direct interaction of NSP5 with NSP2, and as a consequence of that, up-regulation of NSP5 hyperphosphorylation. To investigate a possible structural role for the NSP2-NSP5 interaction, we analysed the cytoplasmic distribution of the two proteins in transfected cells by immunofluorescence using specific antibodies. Here we report that NSP2 and NSP5 can drive the formation of viroplasm-like structures (VLS) in the absence of other rotaviral proteins and rotavirus replication. Several NSP5 deletion mutants were constructed and expressed in combination with NSP2. Both the N-and C-terminal domains of NSP5 were found to be essential for VLS formation. Only one mutant, with an internal deletion of residues 81-130, was able to interact with NSP2 to form VLS. Analysis of the phosphorylation capacity of the different mutants in vivo indicated that hyperphosphorylation of NSP5 is necessary, but not sufficient, for VLS formation. Our results suggest a role for the non-structural protein NSP5 in the structure of viroplasms mediated by its interaction with NSP2.
Astrocytes appear to communicate with each other as well as with neurons via ATP. However, the mechanisms of ATP release are controversial. To explore whether stimuli that increase [Ca 2؉ ] i also trigger vesicular ATP release from astrocytes, we labeled ATP-containing vesicles with the fluorescent dye quinacrine, which exhibited a significant co-localization with atrial natriuretic peptide. The confocal microscopy study revealed that quinacrine-loaded vesicles displayed mainly non-directional spontaneous mobility with relatively short track lengths and small maximal displacements, whereas 4% of vesicles exhibited directional mobility. After ionomycin stimulation only non-directional vesicle mobility could be observed, indicating that an increase in [Ca 2؉ ] i attenuated vesicle mobility. Total internal reflection fluorescence (TIRF) imaging in combination with epifluorescence showed that a high percentage of fluorescently labeled vesicles underwent fusion with the plasma membrane after stimulation with glutamate or ionomycin and that this event was Ca 2؉ -dependent. This was confirmed by patchclamp studies on HEK-293T cells transfected with P2X 3 receptor, used as sniffers for ATP release from astrocytes. Glutamate stimulation of astrocytes was followed by an increase in the incidence of small transient inward currents in sniffers, reminiscent of postsynaptic quantal events observed at synapses. Their incidence was highly dependent on extracellular Ca 2؉ . Collectively, these findings indicate that glutamate-stimulated ATP release from astrocytes was most likely exocytotic and that after stimulation the fraction of quinacrine-loaded vesicles, spontaneously exhibiting directional mobility, disappeared.Many recent studies demonstrate that astrocytes play a significant modulatory role in synaptic physiology (1-4). Astrocytes respond to neurotransmitters, integrate different inputs, and signal back to neurons or forward information to neighboring or more distant astrocytes (2). In response to stimulation they release several chemical substances (5-7), termed gliotransmitters, which can interfere with the neuronal communicating pathways (8 -10).One major extracellular messenger important for coordinating the function of astrocytes, as well as for the cross-talk between them and other cell types, is ATP (11). Whereas several lines of evidence support the idea of ATP release from astrocytes (12-14), the release mechanisms are not completely understood. Some studies have described a connexin hemichannel-mediated release (12, 15, 16) in both resting and activated conditions. Other possible mechanisms, like volume-regulated anion channels (17, 18) and ATP-binding cassette transporters (multidrug resistance P-glycoprotein (19), or cystic fibrosis transmembrane conductance regulator (20) have also been reported. On the contrary, only few studies have focused on the possibility of exocytotic, vesicular ATP release mechanism operating in astrocytes (13, 14), even though it has been shown that astrocytes express the element...
Although the Gas3/PMP22 protein is expressed at highest levels in differentiated Schwann cells, its presence, albeit at lower levels, in non-neuronal tissues and in NIH-3T3 growth-arrested fibroblasts argues for a more general function of this protein that is uncoupled to myelin structure. We show that gas3/PMP22 overexpression in NIH-3T3 growing cells leads to an apoptotic-like phenotype, which is suppressed by antioxidants and characterized by typical membrane blebbing, rounding up, and chromatin condensation, but with no evidence of DNA fragmentation. REF-52 fibroblasts seem to be completely refractive to gas3/PMP22 overexpression. Recently, several point mutations of the human gas3/PMP22 gene have been associated with Charcot-Marie-Tooth type 1A (CMT1A), a common hereditary demyelinating neuropathy. When gas3/PMP22 point mutations (L16P, $79C, TllSM, and G150D) are similarly overexpressed in NIH-3T3 cells, the induced apoptotic-like phenotype as compared to the wild-type is significantly reduced. Both of the dominant mutations (L16P, $79C~ for CMT1A behave as dominant negatives with respect to the wild type, whereas Tl18M, the only recessive mutant described, behaves as recessive under the same coexpression experiments.These data suggest a role for altered Schwann cell apoptosis in the pathogenesis of CMT1A.
Within the trigeminal ganglion, crosstalk between neurons and satellite glial cells (SGCs) contributes to neuronal sensitization and transduction of painful stimuli, including migraine pain, at least partly through activation of purinergic receptor mechanisms. We previously showed that the algogenic mediator bradykinin (BK) potentiates purinergic P2Y receptors on SGCs in primary trigeminal cultures. Our present study investigated the molecular basis of this effect in wild-type (WT) mice and Ca V 2.1 ␣1 R192Q mutant knock-in (KI) mice expressing a human mutation causing familial hemiplegic migraine type 1. Single-cell calcium imaging of WT cultures revealed functional BK receptors in neurons only, suggesting a paracrine action by BK to release a soluble mediator responsible for its effects on SGCs. We identified this mediator as the neuropeptide calcitonin gene-related peptide (CGRP), whose levels were markedly increased by BK, while the CGRP antagonist CGRP 8-37 and the anti-migraine drug sumatriptan inhibited BK actions. Unlike CGRP, BK was ineffective in neuron-free SGC cultures, confirming the CGRP neuronal source. P2Y receptor potentiation induced by CGRP in SGCs was mediated via activation of the extracellular signal-regulated kinase 1/2 pathways, and after exposure to CGRP, a significant release of several cytokines was detected. Interestingly, both basal and BK-stimulated CGRP release was higher in KI mouse cultures, where BK significantly upregulated the number of SGCs showing functional UTP-sensitive P2Y receptors. Our findings suggest that P2Y receptors on glial cells might be considered as novel players in the cellular processes underlying migraine pathophysiology and might represent new targets for the development of innovative therapeutic agents against migraine pain.
Background: Cultured sensory neurons are a common experimental model to elucidate the molecular mechanisms of pain transduction typically involving activation of ATP-sensitive P2X or capsaicin-sensitive TRPV1 receptors. This applies also to trigeminal ganglion neurons that convey pain inputs from head tissues. Little is, however, known about the plasticity of these receptors on trigeminal neurons in culture, grown without adding the neurotrophin NGF which per se is a powerful algogen. The characteristics of such receptors after short-term culture were compared with those of ganglia. Furthermore, their modulation by chronically-applied serotonin or NGF was investigated.
We have previously shown that a number of isoforms of the non-structural rotavirus protein NSP5 are found in virus-infected cells. These isoforms differ in their level of phosphorylation which, at least in part, appears to occur through autophosphorylation. NSP5 co-localizes with another non-structural protein, NSP2, in the viroplasms of infected cells where virus replication takes place. We now show that NSP5 can be chemically cross-linked in living cells with the viral polymerase VP1 and NSP2. Interaction of NSP5 with NSP2 was also demonstrated by coimmunoprecipitation of NSP2 and NSP5 from extracts of UV-treated rotavirus-infected cells. In
Migraine headache originates from the stimulation of nerve terminals of trigeminal ganglion neurons that innervate meninges. Characteristic features of migraine pain are not only its delayed onset but also its persistent duration. Current theories propose that endogenous substances released during a migraine attack (the neuropeptide calcitonin gene-related peptide [CGRP] and the neurotrophin nerve growth factor [NGF]) sensitize trigeminal neurons to transmit nociceptive signals to the brainstem, though the mechanisms remain poorly understood. Recent studies indicate that acute, long-lasting sensitization of trigeminal nociceptive neurons occurs via distinct processes involving enhanced expression and function of adenosine triphosphate (ATP)-gated P2X3 receptors known to play a role in chronic pain. In particular, on cultured trigeminal neurons, CGRP (via protein kinase A-dependent signaling) induces a slowly developing upregulation of the ionic currents mediated by P2X3 receptors by enhancing receptor trafficking to the neuronal membrane and activating their gene transcription. Such upregulated receptors acquire the ability to respond repeatedly to extracellular ATP, thus enabling long-lasting signaling of painful stimuli. In contrast, NGF induces rapid, reversible upregulation of P2X3 receptor function via protein kinase C phosphorylation, an effect counteracted by anti-NGF antibodies. The diverse intracellular signaling pathways used by CGRP and NGF show that the sensitization of P2X3 receptor function persists if the action of only one of these migraine mediators is blocked. These findings imply that inhibiting a migraine attack might be most efficient by a combinatorial approach. The different time domains of P2X3 receptor modulation by NGF and CGRP suggest that the therapeutic efficacy of novel antimigraine drugs depends on the time of administration.
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