IL-1β is a potent proinflammatory cytokine of the innate immune system that is involved in host defense against infection. However, increased production of IL-1β plays a pathogenic role in various inflammatory diseases, such as rheumatoid arthritis, gout, sepsis, stroke, and transplant rejection. To prevent detrimental collateral damage, IL-1β release is tightly controlled and typically requires two consecutive danger signals. LPS from Gram-negative bacteria is a prototypical first signal inducing pro–IL-1β synthesis, whereas extracellular ATP is a typical second signal sensed by the ATP receptor P2X7 that triggers activation of the NLRP3-containing inflammasome, proteolytic cleavage of pro–IL-1β by caspase-1, and release of mature IL-1β. Mechanisms controlling IL-1β release, even in the presence of both danger signals, are needed to protect from collateral damage and are of therapeutic interest. In this article, we show that acetylcholine, choline, phosphocholine, phosphocholine-modified LPS from Haemophilus influenzae, and phosphocholine-modified protein efficiently inhibit ATP-mediated IL-1β release in human and rat monocytes via nicotinic acetylcholine receptors containing subunits α7, α9, and/or α10. Of note, we identify receptors for phosphocholine-modified macromolecules that are synthesized by microbes and eukaryotic parasites and are well-known modulators of the immune system. Our data suggest that an endogenous anti-inflammatory cholinergic control mechanism effectively controls ATP-mediated release of IL-1β and that the same mechanism is used by symbionts and misused by parasites to evade innate immune responses of the host.
Significance We report the presence of a previously unidentified cholinergic, polymodal chemosensory cell in the mammalian urethra, the potential portal of entry for bacteria and harmful substances into the urogenital system. These cells exhibit structural markers of respiratory chemosensory cells (“brush cells”). They use the classical taste transduction cascade to detect potential hazardous compounds (bitter, umami, uropathogenic bacteria) and release acetylcholine in response. They lie next to sensory nerve fibers that carry acetylcholine receptors, and placing a bitter compound in the urethra enhances activity of the bladder detrusor muscle. Thus, monitoring of urethral content is linked to bladder control via a previously unrecognized cell type.
Breakdown of cellular membranes is a characteristic feature of neuronal degeneration in acute (stroke) and chronic (senile dementia) neurological disorders. The present review summarizes recent experimental and clinical work which concentrated on changes of choline-containing phospholipids as indicators of neuronal membrane breakdown. Experimental studies identified glutamate release, calcium influx, and activation of cellular phospholipase A2 (PLA2) as important steps initiating membrane breakdown in cultured neurons or brain slices under hypoxic or ischemic conditions. Proton NMR studies have shown an elevation of choline-containing compounds in the brain of Alzheimer patients while neurochemical studies in post mortem-brain demonstrated increases of the catabolic metabolite, glycerophosphocholine, an indicator of PLA2 activation. In contrast, studies of cerebrospinal fluid, phosphorus NMR studies, and measurements of phospholipases in post mortem Alzheimer brain gave ambiguous results which may be explained by methodical limitations. The finding that, in experimental studies, choline was a rate-limiting factor for phospholipid biosynthesis has stimulated clinical studies aimed at counteracting phospholipid breakdown, e.g. by combinations of choline and cytidine. Future experimental approaches should clarify whether loss of membrane phospholipids is cause or consequence of the neurodegenerative disease process.
Agonist exposure of many G protein-coupled receptors induces a rapid receptor phosphorylation and uncoupling from G proteins. Resensitization of these desensitized receptors requires endocytosis and subsequent dephosphorylation. Using a yeast two-hybrid screen, the rat -opioid receptor (MOR1, also termed MOP) was found to be associated with phospholipase D2 (PLD2), a phospholipid-specific phosphodiesterase located in the plasma membrane, which has been implicated in the formation of endocytotic vesicles. Coimmunoprecipitation experiments in HEK293 cells coexpressing MOR1 and PLD2 confirmed that MOR1 constitutively interacts with PLD2. ]enkephalin) led to an increase in PLD2 activity, whereas morphine, which does not induce MOR1 receptor internalization, failed to induce PLD2 activation. The DAMGO-mediated PLD2 activation was inhibited by brefeldin A, an inhibitor of ADP-ribosylation factor (ARF) but not by the protein kinase C (PKC) inhibitor calphostin C indicating that opioid receptor-mediated activation of PLD2 is ARF-but not PKC-dependent. Furthermore, heterologous stimulation of PLD2 by phorbol ester led to an accelerated internalization of the -opioid receptor after both DAMGO and morphine exposure. Conversely the inhibition of PLD2-mediated phosphatidic acid formation by 1-butanol or overexpression of a negative mutant of PLD2 prevented agonist-mediated endocytosis of MOR1. Together, these data suggest that PLD2 play a key role in the regulation of agonist-induced endocytosis of the -opioid receptor. Phospholipase D (PLD)1 is a widely distributed phospholipid-specific diesterase that hydrolyzes phosphatidylcholine (PC) to phosphatidic acid (PA) and choline and is assumed to play an important function in cell regulation (1, 2). Signal-dependent activation of PLD was demonstrated in numerous cell types stimulated by various hormones, growth factors, cytokines, neurotransmitters, adhesion molecules, drugs, and physical stimuli (reviewed in Ref. 3). Pathways leading to PLD activation include protein serine/threonine kinases, e.g. protein kinase C, small GTPases, e.g. ADP-ribosylation factor (ARF), RhoA and Ral, phosphatidylinositol 4,5-bisphosphate (PIP2), and tyrosine kinases (4 -6). Recently two mammalian PLDs (PLD1 and PLD2) have been identified (7-10). Subcellular fractionation studies have demonstrated the presence of PLD1 in intracellular membranes, e.g. ER, Golgi, and vesicular compartment (9, 11), whereas PLD2 was largely associated with the plasma membrane (9). After stimulation with serum, redistribution of PLD2 from the plasma membrane into submembraneous endocytotic vesicles (early endosomes) was observed (9). Another study revealed that PLD2 is associated with the EGF receptor (12). Interestingly, EGF receptor endocytosis is impaired when PLD activity is inhibited (13) suggesting a role for PLD2 in receptor trafficking.Using the yeast two-hybrid system to identify proteins that interact with the -opioid receptor, we isolated a rat cDNA encoding for the NH 2 terminus of PLD2. We therefore investig...
Highlights d Tracheal chemosensory cells recognize virulence-associated formyl peptides d This activates a TRPM5-dependent pathway, triggering acetylcholine release d Acetylcholine released from chemosensory cells activates mucociliary clearance d Mice with genetic impairment of this pathway are more susceptible to infection
Central cholinergic systems are involved in a plethora of brain functions and are severely and selectively damaged in neurodegenerative diseases such as Alzheimer's disease and dementia with Lewy bodies. Cholinergic dysfunction is treated with inhibitors of acetylcholinesterase (AChE) while the role of butyrylcholinesterase (BChE) for brain cholinergic function is unclear. We have used in vivo microdialysis to investigate the regulation of hippocampal acetylcholine (ACh) levels in mice that are devoid of AChE (AChE-/-mice). Extracellular ACh levels in the hippocampus were 60-fold elevated in AChE-/-mice compared with wild-type (AChE+/+) animals. In AChE-/-mice, calcium-free conditions reduced hippocampal ACh levels by 50%, and infusion of tetrodotoxin by more than 90%, indicating continuous ACh release. Infusion of a selective AChE inhibitor (BW284c51) caused a dosedependent, up to 16-fold increase of extracellular ACh levels in AChE+/+ mice but did not change ACh levels in AChE-/-mice. In contrast, infusion of a selective inhibitor of BChE (bambuterol) caused up to fivefold elevation of ACh levels in AChE-/-mice, but was without effect in AChE+/+ animals. These results were corroborated with two other specific inhibitors of AChE and BChE, tolserine and bis-norcymserine, respectively. We conclude that lack of AChE causes dramatically increased levels of extracellular ACh in the brain. Importantly, in the absence of AChE, the levels of extracellular ACh in the brain are controlled by the activity of BChE. These results point to a potential usefulness of BChE inhibitors in the treatment of central cholinergic dysfunction in which brain AChE activity is typically reduced.
In rat hippocampal slices superfused with magnesium-free buffer, glutamate (1 mM) caused the release of large amounts of choline due to phospholipid breakdown. This phenomenon was mimicked by N-methyl-D-aspartate (NMDA) in a calcium-sensitive manner and was blocked by NMDA receptor antagonists such as MK-801 and 7-chlorokynurenate. The NMDA-induced release of choline was not caused by activation of phospholipase D but was mediated by phospholipase A2 (PLA2) activation as the release of choline was accompanied by the formation of lyso-phosphatidylcholine (lyso-PC) and glycerophospho-choline (GPCh) and was blocked by 5-[2-(2-carboxyethyl)-4-dodecanoyl-3,5-dimethylpyrrol-1-yl]pentano ic acid, a PLA2 inhibitor. Bilobalide, a constituent of Ginkgo biloba, inhibited the NMDA-induced efflux of choline with an IC50 value of 2.3 microM and also prevented the formation of lyso-PC and GPCh. NMDA also caused a release of choline in vivo when infused into the hippocampus of freely moving rats by retrograde dialysis. Again, the effect was completely inhibited by bilobalide which was administered systemically (20 mg/kg i.p.). Interestingly, convulsions which were observed in the NMDA-treated rats were almost totally suppressed by bilobalide. We conclude that release of choline is a sensitive marker for NMDA-induced phospholipase A2 activation and phospholipid breakdown. Bilobalide inhibited the glutamatergic excitotoxic membrane breakdown both in vitro and in vivo, an effect which may be beneficial in the treatment of brain hypoxia and/or neuronal hyperactivity.
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