We have investigated the mechanisms underlying the facilitatory modulation mediated by kainate receptor (KAR) activation in the cortex, using isolated nerve terminals (synaptosomes) and slice preparations. In cortical nerve terminals, kainate (KA, 100 μM) produced an increase in 4‐aminopyridine (4‐AP)‐evoked glutamate release. In thalamocortical slices, KA (1 μM) produced an increase in the amplitude of evoked excitatory post‐synaptic currents (eEPSCs) at synapses established between thalamic axon terminals from the ventrobasal nucleus onto stellate neurons of L4 of the somatosensory cortex. In both, synaptosomes and slices, the effect of KA was antagonized by 6‐cyano‐7‐nitroquinoxaline‐2,3‐dione, and persisted after pre‐treatment with a cocktail of antagonists of other receptors whose activation could potentially have produced facilitation of release indirectly. Mechanistically, the observed effects of KA appear to be congruent in synaptosomal and slice preparations. Thus, the facilitation by KA of synaptosomal glutamate release and thalamocortical synaptic transmission were suppressed by the inhibition of protein kinase A and occluded by the stimulation of adenylyl cyclase. Dissecting this G‐protein‐independent regulation further in thalamocortical slices, the KAR‐mediated facilitation of synaptic transmission was found to be sensitive to the block of Ca2+ permeant KARs by philanthotoxin. Intriguingly, the synaptic facilitation was abrogated by depletion of intracellular Ca2+ stores by thapsigargin, or inhibition of Ca2+‐induced Ca2+‐release by ryanodine. Thus, the KA‐mediated modulation was contingent on both Ca2+ entry through Ca2+‐permeable KARs and liberation of intracellular Ca2+ stores. Finally, sensitivity to W‐7 indicated that the increased cytosolic [Ca2+] underpinning KAR‐mediated regulation of synaptic transmission at thalamocortical synapses, requires downstream activation of calmodulin. We conclude that neocortical pre‐synaptic KARs mediate the facilitation of glutamate release and synaptic transmission by a Ca2+‐calmodulin dependent activation of an adenylyl cyclase/cAMP/protein kinase A signalling cascade, independent of G‐protein involvement.
Kainate receptors (KARs) have been described as modulators of synaptic transmission at different synapses. However, this role of KARs has not been well characterized in the amygdala. We have explored the effect of kainate receptor activation at the synapse established between fibers originating at medial geniculate nucleus and the principal cells in the lateral amygdala. We have observed an inhibition of evoked excitatory postsynaptic currents (eEPSCs) amplitude after a brief application of KARs agonists KA and ATPA. Paired-pulse recordings showed a clear pair pulse facilitation that was enhanced after KA or ATPA application. When postsynaptic cells were loaded with BAPTA, the depression of eEPSC amplitude observed after the perfusion of KAR agonists was not prevented. We have also observed that the inhibition of the eEPSCs by KARs agonists was prevented by protein kinase A but not by protein kinase C inhibitors. Taken together our results indicate that KARs present at this synapse are pre-synaptic and their activation mediate the inhibition of glutamate release through a mechanism that involves the activation of protein kinase A. 相似文献
Apoptosis is characterized by degradation of cell components but plasma membrane remains intact. Apoptotic microtubule network (AMN) is organized during apoptosis forming a cortical structure beneath plasma membrane that maintains plasma membrane integrity. Apoptotic cells are also characterized by high reactive oxygen species (ROS) production that can be potentially harmful for the cell. The aim of this study was to develop a method that allows stabilizing apoptotic cells for diagnostic and therapeutic applications. By using a cocktail composed of taxol (a microtubule stabilizer), Zn2+ (a caspase inhibitor) and coenzyme Q10 (a lipid antioxidant), we were able to stabilize H460 apoptotic cells in cell cultures for at least 72 h, preventing secondary necrosis. Stabilized apoptotic cells maintain many apoptotic cell characteristics such as the presence of apoptotic microtubules, plasma membrane integrity, low intracellular calcium levels and mitochondrial polarization. Apoptotic cell stabilization may open new avenues in apoptosis detection and therapy.Apoptosis, also known as programmed cell death, is central to homoeostasis and normal development and physiology in multicellular organisms, including humans.1 The dysregulation of apoptosis can lead to the destruction of normal tissues in a variety of disorders, including autoimmune and neurodegenerative diseases (increased apoptosis) or cancer (reduced apoptosis). In addition, effective therapy of tumors requires the iatrogenic induction of apoptosis by radiation, chemotherapy or both. In particular, many antineoplasic drugs such as campothecin, a topoisomerase I inhibitor, kill tumor cells by inducing apoptosis.Apoptosis is thought to be physiologically advantageous because apoptotic cells are removed by phagocytosis before they lose their permeability barrier, thus preventing induction of an inflammatory response to the dying cells and potential harmful secondary effects. However, when massive cell death overwhelms macrophage clearance, as for example in early postchemotherapy or viral infection,2 apoptotic cells may progress to secondary necrosis characterized by cell membrane degradation with spillage of intracellular contents to the extracellular milieu.3 Similarly, cells undergoing apoptosis in vitro cannot usually be cleared by phagocytes and undergo a late process of secondary necrosis.4In the execution phase of apoptosis, effector caspases cleave vital cellular proteins, leading to the morphological changes that characterize apoptosis. These changes include destruction of the nucleus and other organelles, DNA fragmentation, chromatin condensation, cell shrinkage, cell detachment and membrane blebbing.5 In apoptosis, all the degradative processes are isolated from the extracellular space by the plasma membrane that remains impermeable. However, the mechanisms involved in plasma membrane and associated protein protection from the action of caspases are not completely understood. In contrast, necrosis is accompanied by disruption of plasma membrane integrity with the subsequent release of all intracellular compounds to the intercellular space, thus inducing inflammation and more toxic effects to adjacent cells.6, 7To allow the dramatic morphological changes that accompany the execution phase, an apoptotic cell undergoes a series of profound cytoskeletal breakdowns/rearrangements. Previous evidence suggests that the actomyosin cytoskeleton plays an essential role in apoptotic cell remodeling during the early events of the execution phase, whereas all other cytoskeleton elements (microtubules and intermediate filaments) are dismantled.8 However, during the course of the execution phase and after actininomyosin ring contraction, the actomyosin filaments are also depolymerized by a caspase-dependent mechanism. In this situation, the apoptotic cell forms a network of apoptotic microtubules that becomes the main cytoskeleton element of the apoptotic cell. The presence of microtubules in apoptotic cells has previously been reported.9, 10 Moreover, more recent results indicate that microtubules during apoptosis assist in the dispersal of nuclear and cellular fragments,11, 12 and may help to preserve the integrity of plasma membrane of the dying cell.13Reactive oxygen species (ROS) are also important mediators of apoptosis. ROS have been shown to play a major role in apoptosis signaling.14, 15, 16 Electron leak in the presence of oxygen during the process of oxidative phosphorylation make mitochondria the major endogenous source of ROS in the cell. Although mitochondria have been identified as a key player, the mechanism connecting ROS and apoptosis remains unclear.17 It has been debated whether increased ROS during apoptosis is a cause or a consequence of impaired mitochondrial function, and whether ROS are a death signal to the mitochondria or are produced as effector molecules by the mitochondria in response to apoptosis signal.18, 19 Hyperproduction of ROS in execution stages of apoptosis is thought to be caused by the disruption of the mitochondrial respiratory chain after release of cytochrome c into the cytosol.20The main objective of this work was to develop a method for the stabilization of apoptotic cells for proper apoptosis detection or safer potential therapeutic applications. Our results show that apoptotic cells can be stabilized by a cocktail of a microtubule stabilizer (taxol), a caspase inhibitor such (Zn2+) and an antioxidant (coenzyme Q10 (CoQ)). 相似文献
J. Neurochem. (2012) 122, 891-899. ABSTRACT: Presynaptic kainate receptors (KARs) modulate the release of glutamate at synapses established between mossy fibers (MF) and CA3 pyramidal cells in the hippocampus. The activation of KAR by low, nanomolar, kainate concentrations facilitates glutamate release. KAR-mediated facilitation of glutamate release involves the activation of an adenylate cyclase/cyclic adenosine monophosphate/protein kinase A cascade at MF-CA3 synapses. Here, we studied the mechanisms by which KAR activation produces this facilitation of glutamate release in slices and synaptosomes. We find that the facilitation of glutamate release mediated by KAR activation requires an increase in Ca(2+) levels in the cytosol and the formation of a Ca(2+) -calmodulin complex to activate adenylate cyclase. The increase in cytosolic Ca(2+) underpinning this modulation is achieved, both, by Ca(2+) entering via Ca(2+) -permeable KARs and, by the mobilization of intraterminal Ca(2+) stores. Finally, we find that, congruent with the Ca(2+) -calmodulin support of KAR-mediated facilitation of glutamate release, induction of long-term potentiation at MF-CA3 synapses has an obligate requirement for Ca(2+) -calmodulin activity. 相似文献
