Pannexin Channels Research Articles

Oscillatory shear stress augments endothelial pannexin1 by inhibiting macro-autophagy

Abstract Funding Acknowledgements Type of funding sources: None. Introduction Atherosclerotic lesions preferentially develop in arterial regions exposed to disturbed blood flow, which are characterized by a dysfunctional proinflammatory endothelial cell (EC) phenotype. ECs release ATP in response to changes in wall shear stress (WSS), which subsequently regulates the inflammatory response. ATP can be released from cells in a controlled manner through Pannexin1 (Panx1) channels. Objective To study the expression of Panx1 in response to WSS and its role in the endothelium. Methods Human ECs (HUVECs or EA.hy926) were exposed to physiological high laminar shear stress (HLSS) and atheroprone oscillatory shear stress (OSS) for 48h using an orbital shaker. Panx1 transcript and protein levels were determined by qPCR and Western blot, respectively. mRNA was extracted for RNAseq. WSS-modifying casts were placed for 1 week around the carotid artery of mice and Panx1 expression was analyzed en face. Carotid WSS-modifying casts were also placed in Tie2CreTgPanx1fl/flApoE-/- and Panx1fl/flApoE-/- mice followed by 9 weeks high fat diet. CD68+ cells were quantified in OSS-induced atherosclerotic lesions. Results We found that Panx1 expression was increased in carotid regions exposed to OSS as compared to HLSS regions. These results were confirmed in vitro in HUVECs. In silico analysis of the promotor of Panx1 revealed binding sites for the WSS-sensitive transcription factors NF-kB and CREB. NF-kB and CREB mRNA levels were similar under OSS and HLSS, however NF-kB activation (phospho-NF-kB) was detected in ECs under OSS. Surprisingly, Panx1 mRNA level was not affected under these conditions, suggesting that the increased Panx1 protein observed under OSS may be due to decreased Panx1 degradation rather than to increased synthesis of the protein. Unbiased analysis of differential gene expression in ECs exposed to HLSS or OSS revealed 320 up-regulated and 353 down-regulated genes under OSS. Down-regulated genes included proteins involved in macro-autophagy. Inhibition of macro-autophagy in ECs by exposure to chloroquine for 6h increased the expression of glycosylated Panx1, suggestive for more Panx1 channels at the plasma membrane under these conditions. Finally, we observed that atherosclerotic lesions in OSS regions of Tie2CreTgPanx1fl/flApoE-/- mice contained more CD68+ cells than Panx1fl/flApoE-/- controls. Conclusion Endothelial Panx1 expression is upregulated in response to OSS. Absence of OSS effects on NF-kB, CREB and Panx1 mRNA revealed that the upregulation of Panx1 protein is not due to transcriptional effects of OSS. Expression of genes involved in the macro-autophagic process were down-regulated under OSS, and chemical inhibition of macro-autophagy augmented the plasma membranous form of Panx1. OSS-induced decrease in autophagic flux may enhance ATP release through Panx1 channels, thereby counterbalancing leukocyte recruitment in atherosclerosis.

Mechanisms of SARS-CoV-2 and Male Infertility: Could Connexin and Pannexin Play a Role?

The impact of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) on male infertility has lately received significant attention. SARS-CoV-2, the virus that causes coronavirus disease (COVID-19) in humans, has been shown to impose adverse effects on both the structural components and function of the testis, which potentially impact spermatogenesis. These adverse effects are partially explained by fever, systemic inflammation, oxidative stress, and an increased immune response leading to impaired blood-testis barrier. It has been well established that efficient cellular communication via gap junctions or functional channels is required for tissue homeostasis. Connexins and pannexins are two protein families that mediate autocrine and paracrine signaling between the cells and the extracellular environment. These channel-forming proteins have been shown to play a role in coordinating cellular communication in the testis and epididymis. Despite their role in maintaining a proper male reproductive milieu, their function is disrupted under pathological conditions. The involvement of these channels has been well documented in several physiological and pathological conditions and their designated function in infectious diseases. However, their role in COVID-19 and their meaningful contribution to male infertility remains to be elucidated. Therefore, this review highlights the multivariate pathophysiological mechanisms of SARS-CoV-2 involvement in male reproduction. It also aims to shed light on the role of connexin and pannexin channels in disease progression, emphasizing their unexplored role and regulation of SARS-CoV-2 pathophysiology. Finally, we hypothesize the possible involvement of connexins and pannexins in SARS-CoV-2 inducing male infertility to assist future research ideas targeting therapeutic approaches.

Neuroprotective Effects of the Pannexin-1 Channel Inhibitor: Probenecid on Spinal Cord Injury in Rats.

Proinflammatory immune cell subsets constitute the majority in the local microenvironment after spinal cord injury (SCI), leading to secondary pathological injury. Previous studies have demonstrated that inflammasomes act as an important part of the inflammatory process after SCI. Probenecid, an inhibitor of the Pannexin-1 channel, can inhibit the activation of inflammasomes. This article focuses on the effects of probenecid on the local immune microenvironment, histopathology, and behavior of SCI. Our data show that probenecid inhibited the expression and activation of nucleotide-binding oligomerization domain receptor pyrindomain-containing 1 (NLRP1), apoptosis-associated speck-like protein containing a CARD (ASC) and caspase-1, interleukin-1β (IL-1β), and caspase-3 proteins associated with inflammasomes, thereby suppressing the proportion of M1 cells. And consequently, probenecid reduced the lesion area and demyelination in SCI. Moreover, the drug increased the survival of motor neurons, which resulted in tissue repair and improved locomotor function in the injured SC. Altogether, existing studies indicated that probenecid can alleviate inflammation by blocking Pannexin-1 channels to inhibit the expression of caspase-1 and IL-1β, which in turn restores the balance of immune cell subsets and exerts neuroprotective effects in rats with SCI.

Effects of Drugs Formerly Suggested for COVID-19 Repurposing on Pannexin1 Channels.

Although many efforts have been made to elucidate the pathogenesis of COVID-19, the underlying mechanisms are yet to be fully uncovered. However, it is known that a dysfunctional immune response and the accompanying uncontrollable inflammation lead to troublesome outcomes in COVID-19 patients. Pannexin1 channels are put forward as interesting drug targets for the treatment of COVID-19 due to their key role in inflammation and their link to other viral infections. In the present study, we selected a panel of drugs previously tested in clinical trials as potential candidates for the treatment of COVID-19 early on in the pandemic, including hydroxychloroquine, chloroquine, azithromycin, dexamethasone, ribavirin, remdesivir, favipiravir, lopinavir, and ritonavir. The effect of the drugs on pannexin1 channels was assessed at a functional level by means of measurement of extracellular ATP release. Immunoblot analysis and real-time quantitative reversetranscription polymerase chain reaction analysis were used to study the potential of the drugs to alter pannexin1 protein and mRNA expression levels, respectively. Favipiravir, hydroxychloroquine, lopinavir, and the combination of lopinavir with ritonavir were found to inhibit pannexin1 channel activity without affecting pannexin1 protein or mRNA levels. Thusthree new inhibitors of pannexin1 channels were identified that, though currently not being used anymore for the treatment of COVID-19 patients, could be potential drug candidates for other pannexin1-related diseases.

Pannexin-1 Activation by Phosphorylation Is Crucial for Platelet Aggregation and Thrombus Formation.

Pannexin-1 (PANX1) is a transmembrane protein that forms ion channels as hexamers on the plasma membrane. Electrophysiological studies prove that PANX1 has a high conductance for adenosine triphosphate (ATP), which plays an important role as a signal molecule in platelet activation. Recently, it was shown that PANX1 channels modulate platelet functions. To date, it remains unclear how PANX1 channels are activated and which signaling mechanisms are responsible for impaired hemostasis and thrombosis. Analysis of PANX1 phosphorylation at Tyr198 and Tyr308, and the impact on platelet activation and thrombus formation using genetically modified platelets or pharmacological inhibitors. Platelet activation via immunoreceptor tyrosine-based activation motif (ITAM) coupled, G Protein-Coupled Receptors (GPCR) and thromboxane receptor (TP)-mediated signaling pathways led to increased PANX1 phosphorylation at Tyr198 and Tyr308. We identified the Src-GPVI signaling axes as the main pathway inducing PANX1 activation, while PKC and Akt play a minor role. PANX1 channels function as ATP release channels in platelets to support arterial thrombus formation. PANX1 activation is regulated by phosphorylation at Tyr198 and Tyr308 following platelet activation. These results suggest an important role of PANX1 in hemostasis and thrombosis by releasing extracellular ATP to support thrombus formation.

Autocrine P2X4 receptor activation in RBCs drives oxygen‐dependent hyperemic responses in mouse skeletal muscle capillaries

Microvascular blood flow is tightly coupled to tissue function and when disturbed, organ insult ensues. Changes in red blood cell (RBC) oxygenation are thought to be key to the initiation of robust microvascular responses, a process mechanistically linked to ATP release from RBCs and conducted signalling. The RBC signaling cascade governing ATP release was the focus of this study, and of note is the role of ATP‐activated P2X4 receptors. Using an in‐vivo mouse muscle preparation (extensor digitorum longus, EDL) and a focally delivered oxygen stimulus via a rapid gas exchange chamber, we probed capillary hemodynamics, prior to and following purinergic receptor antagonism. Dropping oxygen tension from 7% to 2% reduced RBC oxygen saturation in surface capillaries while increasing RBC supply rate. Incubating the EDL with PPADS (non‐selective purinergic receptor antagonist, 30 µM) or 5‐BDBD (selective P2X4 antagonist, 20 µM) reduced baseline RBC supply rate by ≍ 40% and 47%, respectively, and attenuated the capillary responses to the oxygen stimulus by ≍ 5 and 3 RBC/s, respectively. This blunting predictably enhanced the drop in capillary RBC oxygen saturation, as more oxygen was drawn per RBC to meet tissue demand. Immunofluorescence labeling revealed robust expression of P2X4 receptors in RBCs but not endothelial cells. Together, this data begins to elucidate a role for RBC P2X4 receptors, potentially in a positive feedback loop with pannexin channels, to dynamically regulate demand‐supply coupling in skeletal muscle.

Abstract 194: Pharmacologic Inhibition By Spironolactone Attenuates Experimental Abdominal Aortic Aneurysms

Introduction: Abdominal aortic aneurysms (AAA) are characterized by vascular inflammation and remodeling that can lead to aortic rupture resulting in significant risk of mortality. Spironolactone has been recently described as a pannexin-1 (Panx1) channel modulator. Our hypothesis focuses on the role of spironolactone on Panx1 channels to attenuate AAA formation. Methods: A topical elastase (0.4 U/mL type 1 porcine pancreatic elastase) or heat inactivated elastase (control) AAA model was used in C57BL/6 (wild-type; WT) male mice. Mice were administered either a vehicle control (saline) or spironolactone (1.25 mg/kg) i.p. daily for 14 days. On day 14, the abdominal aortic diameter was measured by video micrometry and expressed as percentage increase over baseline. In a second model, mice were subjected to β-aminopropionitrile (BAPN) two days prior to elastase treatment and everyday thereafter. A vehicle control (saline) or spironolactone was given i.p. daily starting from day 14. Immunohistochemistry was used to analyze immune cell infiltration and elastic fiber disruption (Verhoeff Van Gieson staining). Groups were compared using ANOVA and data is displayed as mean ± SEM with p<0.05 as statistically significant. Results: Aortic diameter was significantly increased in elastase-treated WT mice compared to controls (202.5 ± 4.2% vs 0.5 ± 1.9%; n=9/group, p<0.001). Elastase-treated WT mice administered spironolactone had a significant, dose-independent decrease in AAA formation compared to elastase-treated WT controls (139.8 ± 9.9% vs 202.5 ± 4.2%; n=10/group, p<0.001). Elastase-treated mice given BAPN and administered spironolactone had significant attenuation of AAA formation compared to controls on day 28 (420.2 ± 30.5% vs 643.8 ± 41.3%; n=8/group, p<0.001). A significant decrease in immune cell infiltration and elastic fiber disruption occurred in all mice treated with spironolactone compared to respective controls. Conclusion: These results suggest spironolactone mitigates aortic remodeling to attenuate AAA formation as well as decrease growth of preformed aneurysms. Further studies aim to characterize the molecular mechanisms of specific intercellular interactions involving Panx1-mediated AAA formation by spironolactone.

Endothelial Pannexin 3 – B Cell Lymphoma‐6 Interactions Protect Against Oxidative Stress

Pannexin channel isoforms (Panx1‐3) are thought to release nucleotides into the extracellular milieu and have been shown to effect vascular hemodynamics. For this reason, we examined their mRNA and protein expression in hypertensive humans and genetically‐inbred hypertensive mice. In both mouse and humans, we found a significant reduction in Panx3 expression in resistance artery endothelium. Thus, we hypothesized Panx3 may be a regulator of vascular function. In en face endothelial preparations from 3rd order mesenteric arteries, we localized Panx3 to the Golgi Apparatus as opposed to Panx1 which localized to the plasma membrane. Next, we generated an inducible, endothelial cell Panx3 knockout mouse (Panx3ECKO). Radiotelemetry revealed a renin‐independent spontaneous hypertension, with unremarkable immune infiltration in the kidney. There was no change in cytoplasmic or released ATP. To understand how Panx3 may regulate blood pressure, we examined whether Panx3 interacted with B Cell Lymphoma 6 (BCL6), a potential binding partner. En face proximity ligation assays demonstrated an interaction between Panx3 and BCL6 in the Golgi. Panx3ECKO mice exhibited significantly decreased BCL6 protein, hinting that Panx3 may stabilize BCL6 by binding at the BCL6 ubiquitin sites. In silico “threading” of the Panx3 sequence onto the cryo‐EM structure of Panx1 confirmed this site of interaction. BCL6 is a NFκB repressor, thus its degradation in Panx3ECKO mice caused an increase in NFκB activity with IκBα and p100 significantly upregulated. A novel mimetic peptide designed to block Panx3‐BCL6 interactions was administered into C57Bl/6J mice, which recapitulated these results. In addition, Panx3ECKO mice had increased endothelial NOX4 (but not NOX1 or NOX2), likely due to increased NFκB activity—this correlated with a significant increase in plasma H2O2, nitrotyrosine (NT3), and 4‐hydroxynonenal (4‐HNE). In line with this observation, 3rd order mesenteric arteries from Panx3ECKO mice constricted (not dilated) to acetylcholine, which was rescued with the H2O2‐scavenger catalase (1000U/mL), suggesting that vascular oxidative stress drives hypertension in Panx3ECKO mice. Interestingly, Panx3ECKO mice also exhibit a significant increase in IL‐4 receptors on endothelium, and increased IL‐4 cytokines in bone marrow lysates. Because IL‐4 can drive BCL6 expression in other cell types, we suggest a possible homeostatic immune‐endothelial signaling axis. These data elucidate a novel Golgi‐localized oxidative signaling pathway in endothelium with a potential immune‐derived negative feedback loop.

Effects of flow and polycystin‐1 dysfunction on ATP release in the inner medullary collecting duct of the kidney

After filtration of blood by the kidney, the remaining pro‐urine flows through the renal tubular system with a flow rate that can vary considerably. These variations in pro‐urinary flow can be sensed by mechanosensing proteins on the epithelial cells lining the renal tubules. An important mechanosensing protein is polycystin‐1 (PC1), which is thought to be a key sensor of fluid flow. Mutations in PC1 give rise to autosomal dominant polycystic kidney disease (ADPKD), which is characterized by the formation of fluid‐filled cysts in the kidney. Previous research has highlighted a role for the ATP release channel pannexin‐1 (PANX1) in the increased flow‐induced ATP release in a Pkd1‐/‐ cell model of the distal convoluted tubule. However, it remains unclear if other purinergic signaling components are also involved, especially in the collecting duct.Using the mouse inner medullary collecting duct 3 (mIMCD3) cell line in combination with microfluidic experiments, we show here that a similar flow‐induced ATP release is present in Pkd1‐/‐ mIMCD3 cells under low (0.32 mL/min) or high (1.27 mL/min) flow application for 1 minute compared to wildtype (WT) mIMCD3 cells. This is despite a six‐fold increase in the expression of Panx1 observed in Pkd1‐/‐ mIMCD3 cells. Moreover, application of the specific PANX1‐inhibitor BB‐FCF revealed that PANX1 did not drive the high flow‐induced increased ATP release. Accordingly, intermediate flow application (0.47 mL/min) for 3 hours did not increase Panx1 expression in WT mIMCD3 cells compared to the static condition. Flow did not increase the expression of any of the known purinergic receptors in the collecting duct cells compared to the static condition. We did observe a two‐fold increase in gene expression of the putative ATP release channel connexin‐30.3 (CX30.3) compared to static conditions. Moreover, we also report a three‐fold increase in CX30.3 gene expression in Pkd1‐/‐ mIMCD3 cells compared to WT cells.In conclusion, we show here that flow‐induced purinergic signaling in the collecting duct greatly differs from previously published work on the distal convoluted tubule. Specifically, in the inner medulla of the collecting duct, PANX1 may not be the key flow‐regulated ATP release channel. Instead, CX30.3 may facilitate flow‐induced ATP release in this segment in health and in ADPKD.

Endogenous pannexin1 channels form functional intercellular cell–cell channels with characteristic voltage-dependent properties

The occurrence of intercellular channels formed by pannexin1 has been challenged for more than a decade. Here, we provide an electrophysiological characterization of exogenous human pannexin1 (hPanx1) cell–cell channels expressed in HeLa cells knocked out for connexin45. The observed hPanx1 cell–cell channels show two phenotypes: O-state and S-state. The former displayed low transjunctional voltage (Vj) sensitivity and single-channel conductance of ∼175 pS, with a substate of ∼35 pS; the latter showed a peculiar dynamic asymmetry in Vj dependence and single-channel conductance identical to the substate conductance of the O-state. S-state hPanx1 cell–cell channels were also identified between TC620 cells, a human oligodendroglioma cell line that endogenously expresses hPanx1. In these cells, dye and electrical coupling increased with temperature and were strongly reduced after hPanx1 expression was knocked down by small interfering RNA or inhibited with Panx1 mimetic inhibitory peptide. Moreover, cell–cell coupling was augmented when hPanx1 levels were increased with a doxycycline-inducible expression system. Application of octanol, a connexin gap junction (GJ) channel inhibitor, was not sufficient to block electrical coupling between HeLa KO Cx45-hPanx1 or TC620 cell pairs. In silico studies suggest that several arginine residues inside the channel pore may be neutralized by hydrophobic interactions, allowing the passage of DAPI, consistent with dye coupling observed between TC620 cells. These findings demonstrate that endogenously expressed hPanx1 forms intercellular cell–cell channels and their unique properties resemble those described in innexin-based GJ channels. Since Panx1 is ubiquitously expressed, finding conditions to recognize Panx1 cell–cell channels in different cell types might require special attention.

TLR2/caspase-5/Panx1 pathway mediates necrosis-induced NLRP3 inflammasome activation in macrophages during acute kidney injury

Acute kidney injury (AKI) is characterized by necroinflammation formed by necrotic tubular epithelial cells (TECs) and interstitial inflammation. In necroinflammation, macrophages are key inflammatory cells and can be activated and polarized into proinflammatory macrophages. Membranous Toll-like receptors (TLRs) can cooperate with intracellular NOD-like receptor protein 3 (NLRP3) to recognize danger signals from necrotic TECs and activate proinflammatory macrophages by assembling NLRP3 inflammasome. However, the cooperation between TLRs and NLRP3 is still unclear. Using conditioned medium from necrotic TECs, we confirmed that necrotic TECs could release danger signals to activate NLRP3 inflammasome in macrophages. We further identified that necrotic TECs-induced NLRP3 inflammasome activation was dependent on ATP secretion via Pannexin-1 (Panx1) channel in macrophages. Next, we verified that TLR2 was required for the activation of Panx1 and NLRP3 in macrophages. Mechanistically, we indicated that caspase-5 mediated TLR2-induced Panx1 activation. In addition, we showed that necrotic TECs-induced activation of TLR2/caspase-5/Panx1 axis could be decreased in macrophages when TECs was protected by N-acetylcysteine (NAC). Overall, we demonstrate that danger signals from necrotic TECs could activate NLRP3 inflammasome in macrophages via TLR2/caspase-5/Panx1 axis during AKI.

Pannexin1 channels regulate mechanically stimulated but not spontaneous adenosine release.

Fast-scan cyclic voltammetry (FSCV)is a rapid technique to measure neuromodulators, and using FSCV, two modes of rapid adenosine have been discovered. Spontaneous transients occur randomly in the brain, while mechanical stimulation also causes a rapid adenosine event. Pannexin1 channels are membrane channels that transport ions, including ATP, out of the cell where it is rapidly broken down into adenosine. Pannexin 1 channels (Panx1) have a flickering mode of rapid opening and are also mechanically stimulated. Here, we test the extent to which pannexin channels, specifically pannexin1 (Panx1) channels, are responsible for rapid adenosine events. Spontaneous adenosine release or mechanosensitive adenosine release were measured using fast-scan cyclic voltammetry in hippocampal (CA1) brain slices. In global Panx1KO mice, there is no significant difference in the frequency or concentration of spontaneous adenosine release, indicating Panx1 is not a release mechanism for spontaneous adenosine. Spontaneous adenosine frequency decreased slightly after administration of a large (100µM) dose of carbenoxolone, a nonspecific inhibitor of many pannexin and connexin channels, suggesting other hemichannels only play a small role at most. For mechanically stimulated adenosine release, the concentration of each adenosine event significantly decreased 30% in Panx1KO mice and the frequency of stimulations that evoked adenosine also decreased. The response was similar in WT mice with carbenoxolone. Thus, Panx1 is a release mechanism for mechanically stimulated adenosine release, but not the only mechanism. These results demonstrate that pannexin channels differentially regulate rapid adenosine release and could be targeted to differentially affect mechanically stimulated adenosine due to brain damage.

Probenecid-Blocked Pannexin-1 Channel Protects Against Early Brain Injury via Inhibiting Neuronal AIM2 Inflammasome Activation After Subarachnoid Hemorrhage.

AimPrevious studies have proved that inhibiting inflammasome activation provides neuroprotection against early brain injury (EBI) after subarachnoid hemorrhage (SAH), which is mainly focused on the microglial inflammatory response, but the potential role of neuronal inflammasome activation in EBI has not been clearly identified. This study examined whether the pannexin-1 channel inhibitor probenecid could reduce EBI after SAH by inhibiting neuronal AIM2 inflammasome activation.MethodsThere are in vivo and in vitro parts in this study. First, adult male SD rats were subjected to the endovascular perforation mode of SAH. The time course of pannexin-1 and AIM2 expressions were determined after SAH in 72 h. Brain water content, neurological function, AIM2 inflammasome activation, and inflammatory response were evaluated at 24 h after SAH in sham, SAH, and SAH + probenecid groups. In the in vitro part, HT22 cell treated with hemin was applied to mimic SAH. The expression of AIM2 inflammasome was detected by immunofluorescence staining. Neuronal death and mitochondrial dysfunction were determined by the LDH assay kit and JC-1 staining.ResultsThe pannexin-1 and AIM2 protein levels were upregulated after SAH. Pannexin-1 channel inhibitor probenecid attenuated brain edema and improved neurological dysfunction by reducing AIM2 inflammasome activation and reactive oxygen species (ROS) generation after SAH in rats. Treating HT22 cells with hemin for 12 h resulted in AIM2 and caspase-1 upregulation and increased mitochondrial dysfunction and neuronal cell death. Probenecid significantly attenuated the hemin-induced AIM2 inflammasome activation and neuronal death.ConclusionsAIM2 inflammasome is activated in neurons after SAH. Pharmacological inhibition of the pannexin-1 channel by probenecid attenuated SAH-induced AIM2 inflammasome activation and EBI in vivo and hemin-induced AIM2 inflammasome activation and neuronal death in vitro.

Endothelial pannexin-1 channels modulate macrophage and smooth muscle cell activation in abdominal aortic aneurysm formation

Pannexin-1 (Panx1) channels have been shown to regulate leukocyte trafficking and tissue inflammation but the mechanism of Panx1 in chronic vascular diseases like abdominal aortic aneurysms (AAA) is unknown. Here we demonstrate that Panx1 on endothelial cells, but not smooth muscle cells, orchestrate a cascade of signaling events to mediate vascular inflammation and remodeling. Mechanistically, Panx1 on endothelial cells acts as a conduit for ATP release that stimulates macrophage activation via P2X7 receptors and mitochondrial DNA release to increase IL-1β and HMGB1 secretion. Secondly, Panx1 signaling regulates smooth muscle cell-dependent intracellular Ca2+ release and vascular remodeling via P2Y2 receptors. Panx1 blockade using probenecid markedly inhibits leukocyte transmigration, aortic inflammation and remodeling to mitigate AAA formation. Panx1 expression is upregulated in human AAAs and retrospective clinical data demonstrated reduced mortality in aortic aneurysm patients treated with Panx1 inhibitors. Collectively, these data identify Panx1 signaling as a contributory mechanism of AAA formation.

Is the Pannexin-1 Channel a Mechanism Underlying Hypertension in Humans? a Translational Study of Human Hypertension

In preclinical models, the pannexin-1 channel has been shown to be involved in blood pressure regulation through an effect on peripheral vascular resistance. Pannexin-1 releases ATP, which can activate constrictive purinergic receptors on the smooth muscle cells. Pannexin-1 opening is proposed to be mediated by α-adrenergic receptors to potentiate sympathetic constriction. This positions pannexin-1 as a putative pharmacological target in blood pressure regulation in humans. The aim was to provide the first translational evidence for a role of pannexin-1 in essential hypertension in humans by use of an advanced invasive mechanistic approach. Middle-aged stage-1 hypertensive (n=13; 135.7±6.4 over 83.7±3.7 mm Hg) and normotensive men (n=12; 117.3±5.7 over 72.2±3.5 mm Hg) were included. Blood pressure and leg vascular resistance were determined during femoral arterial infusion of tyramine (α-adrenergic receptor stimulation), sodium nitroprusside, and acetylcholine. Measurements were made during control conditions and with pannexin-1 blockade (3000 mg probenecid). Expression of Pannexin-1, purinergic- and α-adrenergic receptors in skeletal muscle biopsies was determined by Western blot. The changes in leg vascular resistance in response to tyramine (+289% versus +222%), sodium nitroprusside (-82% versus -78%) and acetylcholine (-40% versus -44%) infusion were not different between the 2 groups (P>0.05) and pannexin-1 blockade did not alter these variables (P>0.05). Expression of pannexin-1 and of purinergic- and α-adrenergic receptors was not different between the 2 groups (P>0.05). Contrary to our hypothesis, the data demonstrate that pannexin-1 does not contribute to the elevated blood pressure in essential hypertension, a finding, which also opposes that reported in preclinical models.

P2X7 Receptor Triggers Lysosomal Leakage Through Calcium Mobilization in a Mechanism Dependent on Pannexin-1 Hemichannels.

The P2X7 receptor is a critical purinergic receptor in immune cells. Its activation was associated with cathepsin release into macrophage cytosol, suggesting its involvement in lysosomal membrane permeabilization (LMP) and leakage. Nevertheless, the mechanisms by which P2X7 receptor activation induces LMP and leakage are unclear. This study investigated cellular mechanisms associated with endosomal and lysosomal leakage triggered by P2X7 receptor activation. We found that ATP at 500 μM and 5 mM (but not 50 μM) induced LMP in non-stimulated peritoneal macrophages. This effect was not observed in P2X7-deficient or A740003-pretreated macrophages. We found that the P2X7 receptor and pannexin-1 channels mediate calcium influx that might be important for activating specific ion channels (TRPM2 and two-pore channels) on the membranes of late endosomes and lysosomes leading to LMP leakage and consequent cathepsin release. These findings suggest the critical role of the P2X7 receptor in inflammatory and infectious diseases via lysosomal dysfunction.

Intrapore lipids hydrophobically gate pannexin-1 channels.

Large-pore channels such as pannexin-1 (PANX1) typically lack pore-lining constriction points, leaving only speculations on how these channels functionally "close." In this issue of Science Signaling, Kuzuya et al. found that rearrangements in the PANX1 amino-terminal helix mediate channel gating by a surprising mechanism in which lipids block the ion conduction pathway, creating a hydrophobic gate.

Pannexin channel 1, P2×7 receptors, and Dimethyl Sulfoxide mediate pain responses in zebrafish

The zebrafish has been considered an ideal model for studies of complex behaviors since its behavioral repertoire is well described. Therefore, this study evaluated the perceived pain through behavioral changes in zebrafish larvae. Here we investigated the Acetic Acid (AA) effects on zebrafish larvae exposed in a short-time period (60 s) and the preventive effect from routinely used compounds, Dimethyl Sulfoxide (DMSO), Ethanol (EtOH), Ibuprofen (IBP), and Paracetamol (PAR). In addition, the effect of P2×7 antagonist, A740003, and pannexin channel 1 (PANX-1) inhibitor Probenecid (PROB) on AA-induced behavioral changes were evaluated. AA impaired the distance covered, acceleration, movement, and latency to the first entry in the center from 5 dpf exposed larvae. At 0.050% AA, PAR prevented alterations from the distance covered, acceleration, and movement. Surprisingly, 0.3% DMSO prevented behavioral changes induced by AA. However, the effects from 0.2% DMSO were not prominent. We used 0.2% DMSO as a PROB diluent. PROB prevented the changes in distance and movement observed at both AA concentrations (0.0025% and 0.05%) tested. Since EtOH had no analgesic properties, we used it as an A740003 vehicle to observe the analgesic effects of this compound. As noted, A740003 did not prevent the behavioral changes in the AA-induced pain model. In contrast, 0.2% DMSO and PROB prevented AA-induced behavioral changes. These data enforce that zebrafish could be used in translational studies since this species has behavioral responses related to pain in the early stages of development and responses to analgesics similar to observed in mammals.

Mechanisms of Pannexin 1 (PANX1) Channel Mechanosensitivity and Its Pathological Roles.

Pannexins (PANX) were cloned based on their sequence homology to innexins (Inx), invertebrate gap junction proteins. Although there is no sequence homology between PANX and connexins (Cx), these proteins exhibit similar configurations. The PANX family has three members, PANX1, PANX2 and PANX3. Among them, PANX1 has been the most extensively studied. The PANX1 channels are activated by many factors, including high extracellular K+ ([K+]e), high intracellular Ca2+ ([Ca2+]i), Src family kinase (SFK)-mediated phosphorylation, caspase cleavage and mechanical stimuli. However, the mechanisms mediating this mechanosensitivity of PANX1 remain unknown. Both force-from-lipids and force-from-filaments models are proposed to explain the gating mechanisms of PANX1 channel mechanosensitivity. Finally, both the physiological and pathological roles of mechanosensitive PANX1 are discussed.

Gap Junctions and Hemichannels Composed of Connexins and Pannexins Mediate the Secondary Brain Injury Following Intracerebral Hemorrhage.

Simple SummaryIntracerebral hemorrhage (ICH) is a leading medical problem without effective treatment options. The poor prognosis is attributed to the primary brain injury of the mechanical compression caused by hematoma, and secondary brain injury (SBI) that includes inflammation, glutamate excitotoxicity, oxidative stress and disruption of the blood brain barrier (BBB). Evidences suggests that gap junctions and hemichannels composed of connexins and pannexins regulate the inflammation and excitotoxicity insult in the pathological process of central nervous system disease, such as cerebral ischemia and neurodegeneration disease. In this manuscript, we discuss the fact that connexins- and pannexins-based channels could be involved in secondary brain injury of ICH, particularly through mediating inflammation, oxidative stress, BBB disruption and cell death. The details provided in this manuscript may help develop potential targets for therapeutic intervention of ICH.Intracerebral hemorrhage (ICH) is a devastating disease with high mortality and morbidity; the mortality rate ranges from 40% at 1 month to 54% at 1 year; only 12–39% achieve good outcomes and functional independence. ICH affects nearly 2 million patients worldwide annually. In ICH development, the blood leakage from ruptured vessels generates sequelae of secondary brain injury (SBI). This mechanism involves activated astrocytes and microglia, generation of reactive oxygen species (ROS), the release of reactive nitrogen species (RNS), and disrupted blood brain barrier (BBB). In addition, inflammatory cytokines and chemokines, heme compounds, and products of hematoma are accumulated in the extracellular spaces, thereby resulting in the death of brain cells. Recent evidence indicates that connexins regulate microglial activation and their phenotypic transformation. Moreover, communications between neurons and glia via gap junctions have crucial roles in neuroinflammation and cell death. A growing body of evidence suggests that, in addition to gap junctions, hemichannels (composed of connexins and pannexins) play a key role in ICH pathogenesis. However, the precise connection between connexin and pannexin channels and ICH remains to be resolved. This review discusses the pathological roles of gap junctions and hemichannels in SBI following ICH, with the intent of discovering effective therapeutic options of strategies to treat ICH.