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  • The neurotransmitter histamine plays a key role in the sleep

    2022-02-18

    The neurotransmitter histamine plays a key role in the sleep-wake cycle and in learning and memory. Alterations in CU CPT 4a synthesis histamine levels are closely connected with central nervous system dysfunction, and are thought to contribute to neurological disorders, including Alzheimer's disease and depression.15, 16 Histamine binds to four distinct GPCRs (histamine H1H4 receptors); of these, previous studies have reported the expression of H1H3 receptors on astrocytes. In an early study, Inagaki et al. showed comparable H1 receptor binding capacities in primary astrocyte cultures and brain tissue, where besides astrocytes neurons also express H1 receptors. Additionally, histamine stimulation increases [Ca2+]i in astrocytes.19, 20, 21 Taken together, previous findings indicate a significant role for histamine in astrocyte signalling. Yet, only a few studies to date have examined the importance of histamine in astrocyte signalling, and the effect of histamine on gliotransmitter release is unknown. In the present study, we examined the role of histamine in astrocyte intracellular signalling and gliotransmitter release in the human astrocytoma cell line 1321N1.
    Methods
    Results
    Discussion Our study demonstrates that histamine interacts with membranous histamine receptors on astrocytes to activate intracellular signalling cascades and elicit the release of glutamate in a H1 receptor- and concentration-dependent fashion. Histamine has been implicated in astrocyte signalling since the discovery of histamine receptors on astrocytes more than three decades ago. Yet, only a few studies have evaluated the effects of histamine on astrocyte signalling. Here, we demonstrated the expression of HRH1 and HRH2 in the 1321N1 cell line and normal human astrocytes, confirming that the cell line maintained its characteristic gene expression pattern. The H1 receptors were shown to possess a similar binding capacity for histamine in pure astrocyte cultures and the brain, where both astrocytes and neurons express H1 receptors, suggesting astrocytes could be one of the main targets of the histaminergic system in the brain. Indeed, 1321N1 and normal human astrocytes showed an abundant expression of HRH1, further underlining the importance of H1 receptors in astrocytes. Comparable to our own result, previous studies have shown the expression of Hrh1 and Hrh2 in rat primary astrocytes.18, 25 Although a more recent study by Mele and Juric suggested the expression of Hrh3 in rat cortical astrocytes, our data did not confirm their results. However, we observed expression of Hrh3 in rat hippocampal and cerebellar astrocytes, suggesting that the expression of Hrh3 on astrocytes is restricted to certain parts of the rodent brain and is rodent-specific. The H1 and H2 receptors are coupled to the Gq- and Gs-proteins, respectively. We confirmed that astrocytes respond to histamine via Gq-coupled Ca2+ signalling related to H1 receptor activation. The Ca2+ signalling was concentration-dependent and demonstrated a high sensitivity to histamine in 1321N1 cells. The ability of histamine to modulate astrocytic [Ca2+]i is of great importance, as previous studies have outlined the roles of Ca2+ signalling under normal as well as pathological conditions.8, 9, 27 Furthermore, we showed that histamine induced Gs-coupled H2 receptor signalling and increased cAMP levels in a concentration-dependent manner. In astrocytes, the neurotransmitter glutamate is known to promote [Ca2+]i through GPCR activation, thereby eliciting the release of a wide range of gliotransmitters. We provide evidence, for the first time, that histamine can induce gliotransmitter release. Glutamate was released in a concentration-dependent manner, and relied on H1 receptor activation. The H1 receptor antagonists completely attenuated the histamine-induced glutamate release. As no potent H1 receptor agonists are currently available, we treated 1321N1 cells with a partial agonist, 2-PEA, but observed only a slight increase in the glutamate released from 1321N1 cells. This may be because 2-PEA acts as a partial agonist, even at high concentrations, and moreover, it possesses low affinity for the H1 receptor (pKi = 3.7)28, 29. Further, we tested the role of PLC in H1 receptor-mediated glutamate release. Glutamate release was elevated in the presence of the PLC inhibitor U73122, but did not increase further when the cells were co-treated with histamine, indicating the importance of PLC activity for glutamate release. The increased glutamate release in the absence of histamine is most likely attributable to the nature of U73122, which facilitates influx of extracellular Ca2+ at inhibitory concentrations.