Chloride Channel Research Articles

Efficacy and utility of isocycloseram a novel isoxazoline insecticide against urban pests and public health disease vectors

AbstractBACKGROUNDIsoxazolines inhibit γ‐aminobutyric acid chloride channels in insects and acarids by binding to postsynaptic receptors. This prevents chloride influx, leading to depolarization/hyperexcitation, paralysis, and death. Here, we evaluated the potential utility of a novel isoxazoline, isocycloseram, against several urban insect pests.RESULTSIsocycloseram was active at low doses against the German cockroach, Blattella germanica (L.) [median lethal dose (LD50) 5–15 ng per insect at 72 h, topical assays]; Argentine ant (Linepithema humile Mayr), Pharaoh ant (Monomorium pharaonis (L.), common bed bug (Cimex lectularius (L.) (approximately 40 mg m−2, residual surface spray); Eastern subterranean termite (Reticulitermes flavipes (Kollar) and Formosan subterranean termite (Coptotermes formosanus Shiraki) (5 μg g−1 w/w, tunneling assays); and mosquito, Anopheles stephensi Liston (120 and 150 mg m−2 treated surfaces, aged indoors for 9 months). Additionally, cockroach gel bait at 1% isocycloseram (w/w) caused 95–100% mortality in German, American (Periplaneta americana (L.), and oriental (Blatta orientalis (L.) cockroaches within 5–14 days.CONCLUSIONSIsocycloseram proved to be active against both laboratory and field populations of German cockroaches at doses lower or equal to those of other chemicals. Ants, bed bugs, and mosquitoes readily acquired lethal doses of isocycloseram from different surfaces treated with formulated products. Given its non‐repellent nature, delayed effects, and activity at low rates, isocycloseram can be a very effective compound against subsocial, social, and other human disease vector insect pests. © 2024 Society of Chemical Industry.

Comprehensive gene expression analysis in gallbladder mucosal epithelial cells of dogs with gallbladder mucocele

AbstractBackgroundGallbladder mucocele (GBM) is a common disease in the canine gallbladder. Although the pathogenesis of GBM remains unclear, we recently reported that the excessive accumulation of mucin in the gallbladder is not a result of overproduction by gallbladder epithelial cells (GBECs).Hypothesis/ObjectivesChanges in the function of GBECs other than the production of mucin are associated with the pathogenesis of GBM. We performed an RNA sequencing (RNA‐seq) analysis to comprehensively search for abnormalities in gene expression profiles of GBECs in dogs with GBM.AnimalsFifteen dogs with GBM and 8 dogs euthanized for reasons other than gallbladder disease were included.MethodsThe GBECs were isolated from gallbladder tissues to extract RNA. The RNA‐seq analysis was performed using the samples from 3 GBM cases and 3 dogs with normal gallbladders, and the gene expression profiles were compared between the 2 groups. Differences in mRNA expression levels of the extracted differentially expressed genes (DEGs) were validated by quantitative reverse transcription polymerase chain reaction (RT‐qPCR) using samples of 15 GBM cases and 8 dogs with normal gallbladders.ResultsComparison of gene expression profiles by RNA‐seq extracted 367 DEGs, including ANO1, a chloride channel associated with changes in mucin morphology, and HTR4, which regulates the function of chloride channels. The ANO1 and HTR4 genes were confirmed to be downregulated in the GBM group by RT‐qPCR.Conclusions and Clinical ImportanceOur results suggest that GBM may be associated with decreased function of chloride channels expressed in GBECs.

Knockdown of ANO1 decreases TGF-β- and IL-6-induced adhesion and migration of cardiac fibroblasts by inhibiting the expression of integrin and focal adhesion kinase

Ischemic cardiac injury triggers a significant inflammatory response, activating and mobilizing cardiac fibroblasts (CFs), which ultimately contributes to myocardial fibrosis. In this study, we investigated the role of ANO1, a calcium-activated chloride channel (CaCC) protein, in regulating CFs migration and adhesion under inflammatory conditions. Our results demonstrated that ANO1 knockdown significantly attenuated TGF-β- and IL-6-induced adhesion and migration of CFs. This inhibitory effect was mediated through the downregulation of integrin expression and reduced activation of focal adhesion kinase (FAK), key components in cellular adhesion and motility pathways. This study provides new insights into the mechanisms underlying CFs migration and adhesion, highlighting the potential of ANO1 as a therapeutic target for mitigating adverse fibrotic remodeling following myocardial infarction.

Acaricide resistance mechanisms and host plant responses in the tomato specialist Aculops lycopersici.

The mite Aculops lycopersici is a major tomato pest with extremely reduced gene families involved in chemoreception and detoxification. How this limited detoxification toolbox affects the evolution of resistance to acaricides in tomato russet mite(s) (TRM) remains enigmatic. Moreover, although a tomato specialist, TRM has been observed on other Solanaceae and Convolvulaceae plant species, raising questions about transcriptional plasticity underlying host exchange. We identified a field strain with strongly decreased susceptibility to both abamectin and spiromesifen. We detected target-site resistance caused by mutations at conserved positions in two glutamate-gated chloride channels (GluCl), as well as four overexpressed detoxification genes. We then examined transcriptional responses after host shift from tomato to two Solanaceae (potato and black nightshade) and two Convolvulaceae (sweet potato and hedge bindweed) species, as more challenging host plants. Transcriptional responses varied significantly between host plant families, with key differentially expressed genes (DEGs) related to proteolytic, metabolic and detoxification processes. Last, we also identified DEGs encoding for secreted proteins potentially involved in TRM-host plant interactions. Despite a limited detoxification toolbox, A. lycopersici might quickly evolve target-site resistance, probably facilitated by strong selection pressure on the genetic variation associated with enormous population size in field settings. Responses to host plant changes include plasticity in genes related to digestion and detoxification, while most responsive genes are of unknown function and remain to be investigated. © 2024 Society of Chemical Industry.

Targeting TMEM16A ion channels suppresses airway hyperreactivity, inflammation, and remodeling in an experimental Guinea pig asthma model

Asthma is a chronic inflammatory disease characterized by airway hyperresponsiveness, inflammation, and remodeling. Calcium (Ca2+)-activated chloride (Cl−) channels, such as TMEM16A, are inferred to be involved in asthma. Therefore, the present study investigated the therapeutic potential of TMEM16A inhibition in a guinea pig model of ovalbumin (OVA)-induced allergic asthma. Guinea pigs were treated with a specific blocker, CaCCinh-A01 (10 μM), administered via inhalation. A significant reduction in cough reflex sensitivity and specific airway resistance was observed in animals treated with CaCCinh-A01, highlighting its potential to improve airway function. Despite a reduction in ciliary beating frequency (CBF), CaCCinh-A01 reduced airway mucus viscosity by decreasing the production of mucin-5AC (MUC5AC). The nonspecific reduction in the Th1/Th2 cytokine spectrum following CaCCinh-A01 treatment indicated the suppression of airway inflammation. Additionally, markers associated with airway remodeling were diminished, suggesting that CaCCinh-A01 may counteract structural changes in airway tissues. Therefore, inhibition appears to mitigate the pathological aspects of asthma, including airway hyperresponsiveness, inflammation, and remodeling. However, further studies are required to comprehensively evaluate the potential of TMEM16A as a therapeutic target for asthma.

A quantitative analysis of bestrophin 1 cellular localization in mouse cerebral cortex.

Calcium-activated ligand-gated chloride channels, beyond their role in maintaining anion homeostasis, modulate neuronal excitability by facilitating nonvesicular neurotransmitter release. BEST1, a key member of this family, is permeable to γ-aminobutyric acid (GABA) and glutamate. While astrocytic BEST1 is well-studied and known to regulate neurotransmitter levels, its distribution and role in other brain cell types remain unclear. This study aimed to reassess the localization of BEST1 in the mouse cerebral cortex. We examined the localization and distribution of BEST1 in the mouse parietal cortex using light microscopy, confocal double-labeling with markers for astrocytes, neurons, microglia, and oligodendrocyte precursor cells, and 3D reconstruction techniques. In the cerebral cortex, BEST1 is more broadly distributed than previously thought. Neurons are the second most abundant BEST1+ cell type in the cerebral cortex, following astrocytes. BEST1 is diffusely expressed in neuronal somatic and neuropilar domains and is present at glutamatergic and GABAergic terminals, with a prevalence at GABAergic terminals. We also confirmed that BEST1 is expressed in cortical microglia and identified it in oligodendrocyte precursor cells, albeit to a lesser extent. Together, these findings suggest that BEST1's role in controlling neurotransmission may extend beyond astrocytes to include other brain cells. Understanding BEST1's function in these cells could offer new insights into the molecular mechanisms shaping cortical circuitry. Further research is needed to clarify the diverse roles of BEST1 in both normal and pathophysiological conditions.

The Tmem16a chloride channel is required for mucin maturation after secretion from goblet-like cells in the Xenopus tropicalis tadpole skin

The TMEM16A chloride channel is proposed as a therapeutic target in cystic fibrosis, where activation of this ion channel might restore airway surface hydration and mitigate respiratory symptoms. While TMEM16A is associated with increased mucin production under stimulated or pro-inflammatory conditions, its role in baseline mucin production, secretion and/or maturation is less well understood. Here, we use the Xenopus tadpole skin mucociliary surface as a model of human upper airway epithelium to study Tmem16a function in mucus production. We found that Xenopus tropicalis Tmem16a is present at the apical membrane surface of tadpole skin small secretory cells that express canonical markers of mammalian “goblet cells” such as Foxa1 and spdef. X. tropicalis Tmem16a functions as a voltage-gated, calcium-activated chloride channel when transfected into mammalian cells in culture. Depletion of Tmem16a from the tadpole skin results in dysregulated mucin maturation post-secretion, with secreted mucins having a disrupted molecular size distribution and altered morphology assessed by sucrose gradient centrifugation and electron microscopy, respectively. Our results show that in the Xenopus tadpole skin, Tmem16a is necessary for normal mucus barrier formation and demonstrate the utility of this model system to discover new biology relevant to human mucosal biology in health and disease.

CLCN2-related leukoencephalopathy with novel compound heterozygous variants followed with magnetic resonance imaging over 17 years: a case report

BackgroundCLCN2-related leukoencephalopathy (CC2L) is a rare autosomal recessive disorder caused by biallelic variants of CLCN2, which encodes chloride channel 2. Although CC2L is associated with distinct radiological features, it presents with a wide range of clinical features.Case presentationA 34-year-old woman presented to our hospital with a sudden onset of vertigo with headache. The patient reported intermittent headaches and tingling in both arms since the age of 31 years. On the first visit, the patient was alert and neurologically intact, except for slight hyperreflexia of the limbs without laterality. Head magnetic resonance imaging (MRI) showed high-intensity signals on axial T2-weighted fluid-attenuated inversion recovery and diffusion-weighted images bilaterally in the posterior limbs of the internal capsules, cerebral peduncles, superior and middle cerebellar peduncles, decussation of superior cerebellar peduncles, and central tegmental tract. All the patient’s symptoms were resolved or eased following supportive care. The patient stopped attending our hospital at the age of 46 years. At 51 years of age, the patient revisited our hospital because of the recurrence of vertigo, headache, and nausea. She did not present with any abnormalities by neurological examination. Head MRI showed widespread high-intensity signals similar to those 17 years ago. Genetic testing revealed compound heterozygous variants in CLCN2 (NM_004366.6): a novel variant c.1828 C > T, p.(Arg 610*) from her father and c.61dup, p.(Leu21Profs*27) from her mother. The patient was finally diagnosed with CC2L. She received supportive treatment, which made her symptoms manageable.ConclusionsThis is a detailed report of a patient with adult-onset CC2L who was successfully diagnosed and followed up with head MRI. This report provides new insights into CC2L and highlights its persistent, distinct, and stable characteristics observed in head MRI over one decade and the difficulty in forming a diagnosis without MRI when patients have minimal and common symptoms, such as in the present case.

The mayfly Neocloeon triangulifer senses decreasing oxygen availability (PO2) and responds by reducing ion uptake and altering gene expression.

Oxygen availability is central to the energetic budget of aquatic animals and may vary naturally and/or in response to anthropogenic activities. Yet, we know little about how oxygen availability is linked to fundamental processes such as ion transport in aquatic insects. We hypothesized and observed that ion (22Na and 35SO4) uptake would be significantly decreased at O2 partial pressures below the mean Pcrit (5.4 kPa) where metabolic rates (MO2) are compromised, and ATP production is limited. However, we were surprised to observe marked reductions in ion uptake at oxygen partial pressures well above the Pcrit, where MO2 was stable. For example, SO4 uptake decreased by 51% at 11.7kPa, and 82% at the Pcrit (5.4kPa) while Na uptake decreased by 19% at 11.7kPa, and 60% at the Pcrit. Nymphs held for longer time periods at reduced PO2 exhibited stronger reductions in ion uptake rates. Fluids from whole body homogenates exhibited a 29% decrease in osmolality in the most hypoxic condition. The differential expression of atypical guanylyl cyclase (gcy-88e) in response to changing PO2 conditions provides evidence for its potential role as an oxygen sensor. Several ion transport genes (e.g., chloride channel and sodium-potassium ATPase) and hypoxia-associated genes (e.g., ldh and egl-9) were also impacted by decreased oxygen availability. Together, our work suggests that N. triangulifer can sense decreased oxygen availability and perhaps conserves energy accordingly, even when MO2 is not impacted.

ClC-Kb pore mutation disrupts glycosylation and triggers distal tubular remodeling.

Mutations in the CLCNKB gene (1p36), encoding a basolateral chloride channel, ClC-Kb, cause type 3 Bartter's syndrome. We identified a family with a mixed Bartter's / Gitelman's phenotype and early-onset kidney failure and employing a candidate gene approach, discovered a homozygous mutation (CLCNKB c.499G>T [p.Gly167Cys]) in exon 6 of CLCNKB in the index patient. We then validated these results with Sanger and whole exome sequencing. Compared to wild-type ClC-Kb, the Gly167Cys mutant conducted less current and impaired, complex N-linked glycosylation in vitro. We demonstrated that loss of Gly-167, rather than gain of a mutant Cys, impairs complex glycosylation but that surface expression remains intact. Moreover, Asn364 was necessary for channel function and complex glycosylation. Morphologic evaluation of human kidney biopsies revealed typical basolateral localization of mutant Gly167Cys ClC-Kb in cortical distal tubular epithelia. However, we detected attenuated expression of distal sodium transport proteins, changes in abundance of distal tubule segments, and hypokalemia-associated intracellular condensates from the index patient compared to control nephrectomy specimens. The present data establish what we believe, are novel regulatory mechanisms of ClC-Kb activity and demonstrate nephron remodeling in man, caused by mutant ClC-Kb, with implications for renal electrolyte handling, blood pressure control, and kidney disease.

Genome-wide CRISPR screens identify CLC-2 as a drug target for anti-herpesvirus therapy: tackling herpesvirus drug resistance.

The emergence of drug resistance to virus (i.e., acyclovir (ACV) to herpesviruses) has been termed one of the common clinical issues, emphasizing the discovery of new antiviral agents. To address it, a genome-wide clustered regularly interspaced short palindromic repeats (CRISPR) screening was performed in mouse haploid embryonic stem cells infected with pseudorabies virus (PRV), an α-herpesvirus causing human and pig diseases. The results demonstrated that type 2 voltage-gated chloride channels (CLC-2) encoded by one of the identified genes, CLCN2, is a potential drug target for anti-herpesvirus therapy. CLC-2 inhibitors, omeprazole (OME) and 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), can efficiently inhibit infection of multiple herpesviruses in cellulo (i.e., PRV, HSV and EBV), and effectively treat murine herpes simplex encephalitis (HSE). Additionally, DIDS was found to inhibit HSV-1 replication by blocking the PI3K/Akt pathway. Most importantly, both DIDS and OME were able to inhibit ACV-resistant HSV-1 strain infection. The study's findings suggest that targeting host-cell factors such as CLC-2 may be a promising approach to tackling herpesvirus drug resistance. The discovery of CLC-2 as a potential drug target for anti-herpesvirus therapy provides a new direction for the development of novel antiviral agents.

Calcium-activated chloride channels. Role of potassium ions

Using the patch-clamp method in the whole-cell configuration, it was shownthat external potassium ions play an important role in the regulation of calcium-activated chloride currents. A clear dependence of the amplitude of chloride currents on changes in the concentration of external potassium is shown. Changes in concentration of sodium, magnesium and calcium ions from membrane outside have no so significant effect, like outside potassium ions. The effect of potassium on the amplitudes of chloride currents is significantly greater than the effect it has on other cell ionic currents — sodium, potassium, cation. There is reason to believe that a change in the amplitudes of chloride currents contributes to the pathophysiological processes characteristic of hypokalemia and hyperkalemia.

Amplification of olfactory transduction currents implements sparse stimulus encoding.

Sensory systems must perform the dual and opposing tasks of being sensitive to weak stimuli while also maintaining information content in dense and variable sensory landscapes. This occurs in the olfactory system, where OSNs are highly sensitive to low concentrations of odors and maintain discriminability in complex odor environments. How olfactory sensory neurons (OSNs) maintain both sensitivity and sparsity is not well understood. Here, we investigated whether the calcium-activated chloride channel, TMEM16B, may support these dual roles in OSNs. We used multiphoton microscopy to image the stimulus-response density of OSNs in the olfactory epithelium. In TMEM16B knockout mice, we found that sensory representations were denser, and the magnitude of OSN responses was increased. Behaviorally, these changes in sensory representations were associated with an increased aversion to the odorant trimethylamine, which switches perceptual valence as its concentration increases, and a decreased efficiency of olfactory-guided navigation. Together, our results indicate that the calcium-activated chloride channel TMEM16B sparsens sensory representations in the peripheral olfactory system and contributes to efficient integrative olfactory-guided behaviors.

MiR-210 is essential to retinal homeostasis in fruit flies and mice

BackgroundmiR-210 is one of the most evolutionarily conserved microRNAs. It is known to be involved in several physiological and pathological processes, including response to hypoxia, angiogenesis, cardiovascular diseases and cancer. Recently, new roles of this microRNA are emerging in the context of eye and visual system homeostasis. Recent studies in Drosophila melanogaster unveiled that the absence of miR-210 leads to a progressive retinal degeneration characterized by the accumulation of lipid droplets and disruptions in lipid metabolism. However, the possible conservation of miR-210 knock-out effect in the mammalian retina has yet to be explored.ResultsWe further investigated lipid anabolism and catabolism in miR-210 knock-out (KO) flies, uncovering significant alterations in gene expression within these pathways. Additionally, we characterized the retinal morphology of flies overexpressing (OE) miR-210, which was not affected by the increased levels of the microRNA. For the first time, we also characterized the retinal morphology of miR-210 KO and OE mice. Similar to flies, miR-210 OE did not affect retinal homeostasis, whereas miR-210 KO mice exhibited photoreceptor degeneration. To explore other potential parallels between miR-210 KO models in flies and mice, we examined lipid metabolism, circadian behaviour, and retinal transcriptome in mice, but found no similarities. Specifically, RNA-seq confirmed the lack of involvement of lipid metabolism in the mice’s pathological phenotype, revealing that the differentially expressed genes were predominantly associated with chloride channel activity and extracellular matrix homeostasis. Simultaneously, transcriptome analysis of miR-210 KO fly brains indicated that the observed alterations extend beyond the eye and may be linked to neuronal deficiencies in signal detection and transduction.ConclusionsWe provide the first morphological characterization of the retina of miR-210 KO and OE mice, investigating the role of this microRNA in mammalian retinal physiology and exploring potential parallels with phenotypes observed in fly models. Although the lack of similarities in lipid metabolism, circadian behaviour, and retinal transcriptome in mice suggests divergent mechanisms of retinal degeneration between the two species, transcriptome analysis of miR-210 KO fly brains indicates the potential existence of a shared upstream mechanism contributing to retinal degeneration in both flies and mammals.

Ribosomal frameshifting selectively modulates the assembly, function, and pharmacological rescue of a misfolded CFTR variant

The cotranslational misfolding of the cystic fibrosis transmembrane conductance regulator chloride channel (CFTR) plays a central role in the molecular basis of CF. The misfolding of the most common CF variant (ΔF508) remodels both the translational regulation and quality control of CFTR. Nevertheless, it is unclear how the misassembly of the nascent polypeptide may directly influence the activity of the translation machinery. In this work, we identify a structural motif within the CFTR transcript that stimulates efficient -1 ribosomal frameshifting and triggers the premature termination of translation. Though this motif does not appear to impact the interactome of wild-type CFTR, silent mutations that disrupt this RNA structure alter the association of nascent ΔF508 CFTR with numerous translation and quality control proteins. Moreover, disrupting this RNA structure enhances the functional gating of the ΔF508 CFTR channel at the plasma membrane and its pharmacological rescue by the CFTR modulators contained in the CF drug Trikafta. The effects of the RNA structure on ΔF508 CFTR appear to be attenuated in the absence of the ER membrane protein complex, which was previously found to modulate ribosome collisions during "preemptive quality control" of a misfolded CFTR homolog. Together, our results reveal that ribosomal frameshifting selectively modulates the assembly, function, and pharmacological rescue of a misfolded CFTR variant. These findings suggest that interactions between the nascent chain, quality control machinery, and ribosome may dynamically modulate ribosomal frameshifting in order to tune the processivity of translation in response to cotranslational misfolding.

TMEM16A regulates satellite cell-mediated skeletal muscle regeneration by ensuring a moderate level of caspase 3 activity.

It has been documented that caspase 3 activity is necessary for skeletal muscle regeneration, but how its activity is regulated is largely unknown. Our previous report shows that intracellular TMEM16A, a calcium activated chloride channel, significantly regulates caspase 3 activity in myoblasts during skeletal muscle development. By using a mouse line with satellite cell (SC)-specific deletion of TMEM16A, we examined the role of TMEM16A in regulating caspase 3 activity in SC (or SC-derived myoblast) as well as skeletal muscle regeneration. The mutant animals displayed apparently impaired regeneration capacity in adult muscle along with enhanced ER stress and elevated caspase 3 activity in Tmem16a-/- SC derived myoblasts. Blockade of either excessive ER stress or caspase 3 activity by small molecules significantly restored the inhibited myogenic differentiation of Tmem16a-/- SCs, indicating that excessive caspase 3 activity resulted from TMEM16A deletion contributes to the impaired muscle regeneration and the upstream regulator of caspase 3 was ER stress. Our results revealed an essential role of TMEM16A in satellite cell-mediated skeletal muscle regeneration by ensuring a moderate level of caspase 3 activity.

6692 Proarrhythmic Risk Of Hypoglycemia; A Case Of Insulin-Induced Hypoglycemia Provoking Torsade De Pointes-Cardiac Arrest

Abstract Disclosure: A.M. San Hernandez: None. A. Adelkhanova: None. H. Ashraf: None. J. Aguayo Herrera: None. M.F. Siddiqui: None. Introduction: Torsade de Pointes is a life-threatening polymorphic ventricular tachycardia which is associated with QTc prolongation caused by medications, metabolic and electrolyte abnormalities. Very few cases of hypoglycemia causing QTc prolongation and Torsades de Pointes have been reported in the literature. Although the mechanism is unclear, the effects of low blood glucose have been proposed to induce a sympathetic response, hypokalemia and calcium disturbances. We report a case of an insulin-induced hypoglycemia causing Torsades de Pointes cardiac arrest, highlighting the proarrhythmic risk of hypoglycemia. Case presentation: A 57-year-old female with a history of Insulin-dependent Type 2 Diabetes Mellitus (DM) was brought in by EMS due to severe symptomatic hypoglycemia (POC blood glucose of 30 mg/dL), requiring treatment with dextrose. Patient reported reduced oral intake due to vomiting for 1 week and continued insulin administration without self-monitoring of blood glucose. Laboratory work up on presentation revealed severe hypoglycemia VBG= 55 mg/dL and mild hypomagnesemia Mg=1.4mg/dL (Ref Range 1.7-2.2mg/dl) which was treated. There was no hypokalemia or hypocalcemia. ECG showed sinus rhythm with prolonged QTc interval of 573ms and non-specific ST changes.Few hours later, patient developed torsades de pointes, requiring ACLS resuscitation. ROSC was achieved after two rounds of CPR. Patient received dextrose infusion to maintain euglycemic state. She was not taking any QTc prolonging medication. There was no history of autoimmune disease. Except for hypoglycemia, no other metabolic abnormality could be identified. Cardiac and pulmonary etiologies of cardiac arrest were ruled out. Post-ROSC ECG showed sinus tachycardia with normalization of QTc to 454ms. Thus, Insulin-induced hypoglycemia was appointed as the main culprit for her cardiac arrest, in the setting of QTc prolongation. Patient received diabetes self-management and hypoglycemia education. Conclusion: Several studies support strong correlation between hypoglycemia and arrhythmic events during bedtime in people with diabetes “The dead in bed syndrome”. Hypoglycemia causes an acquired long QT syndrome independent of other risk factors such as cardiac autonomic neuropathy. Possible mechanisms include; sympathoadrenal activation, which regulates potassium, calcium and chloride channels or altered autonomic regulation caused by hypoglycemia itself regardless of the effect of insulin or hypokalemia. QT prolongation is a risk factor for sudden cardiac death by causing torsades de pointes ventricular tachycardia (VT).People with insulin dependent diabetes are at high risk of hypoglycemia and should be cautioned about the proarrhythmic risk of hypoglycemia. Education is crucial, and Continuous glucose monitor (CGM) is a valuable tool to be use in such a patient population. Presentation: 6/3/2024

7753 Anoctamin 4 in the Area Postrema Regulates Glucose and Energy Homeostasis

Abstract Disclosure: L. Tu: None. Y. Xu: None. Located on the floor of the 4th ventricle within the dorsal surface of the medulla oblongata, the area postrema (AP) is a circumventricular organ where a proper blood-brain barrier is missing. Numerous studies reveal that neurons in the AP are implicated into suppression of food intake (e.g., glucagon-like peptide 1 (GLP-1)-mediated anorexia), but the role of AP neurons in whole-body glucose homeostasis is less investigated. Here we identified and fully characterized the physiological functions of anoctamin-4 (Ano4, a calcium activated chloride channel)1 in the AP. CRISPR-mediated deletion of Ano4 in the AP caused a lower body weight and reduced blood glucose, concurrent with an improved glucose tolerance and increased insulin sensitivity. Chemogenetic activation of Ano4-expressing neurons in the AP (APAno4) increased food intake and blood glucose, and did not induce conditioned flavor avoidance. Both Ano4 neurons and non-Ano4 neurons (i.e., neurons do not express Ano4) sent projections to the lateral parabrachial nucleus (LPBN). Optogenetic stimulation of APAno4 ◊ LPBN circuit promoted feeding behavior and increased blood glucose, whereas stimulation of APnon-Ano4 ◊ LPBN circuit inhibited food intake and did not influence glucose homeostasis. Finally, RNAscope studies reveal that 45.7% of APAno4 neurons are glutamatergic neurons, and 41.8% of them are GABAergic neurons. Furthermore, APAno4 neurons showed only a 2.6% overlap with Glp-1r-expressing neurons in the AP, but had a 60.8% co-localization with protein tyrosine phosphatase receptor δ2, which serves as orexigenic asprosin receptor. Together, our results indicate that Ano4 neurons in the AP are the first reported orexigenic neurons, and represent potential therapeutic targets for human diseases with glucose imbalance and abnormal feeding behavior. Reference: (1) Tu, L. et al. Anoctamin 4 channel currents activate glucose-inhibited neurons in the mouse ventromedial hypothalamus during hypoglycemia. J Clin Invest 133,14. (2023). (2) Mishra, I. et al. Protein tyrosine phosphatase receptor δ serves as the orexigenic asprosin receptor. Cell Metab 34, 549-563. (2022). Presentation: 6/2/2024

9207 Anoctamin 4 in the Area Postrema Regulates Glucose and Energy Homeostasis

Abstract Disclosure: L. Tu: None. Y. Xu: None. Located on the floor of the 4th ventricle within the dorsal surface of the medulla oblongata, the area postrema (AP) is a circumventricular organ where a proper blood-brain barrier is missing. Numerous studies reveal that neurons in the AP are implicated into suppression of food intake (e.g., glucagon-like peptide 1 (GLP-1)-mediated anorexia), but the role of AP neurons in whole-body glucose homeostasis is less investigated. Here we identified and fully characterized the physiological functions of anoctamin-4 (Ano4, a calcium activated chloride channel)1 in the AP. CRISPR-mediated deletion of Ano4 in the AP caused a lower body weight and reduced blood glucose, concurrent with an improved glucose tolerance and increased insulin sensitivity. Chemogenetic activation of Ano4-expressing neurons in the AP (APAno4) increased food intake and blood glucose, and did not induce conditioned flavor avoidance. Both Ano4 neurons and non-Ano4 neurons (i.e., neurons do not express Ano4) sent projections to the lateral parabrachial nucleus (LPBN). Optogenetic stimulation of APAno4 ◊ LPBN circuit promoted feeding behavior and increased blood glucose, whereas stimulation of APnon-Ano4 ◊ LPBN circuit inhibited food intake and did not influence glucose homeostasis. Finally, RNAscope studies reveal that 45.7% of APAno4 neurons are glutamatergic neurons, and 41.8% of them are GABAergic neurons. Furthermore, APAno4 neurons showed only a 2.6% overlap with Glp-1r-expressing neurons in the AP, but had a 60.8% co-localization with protein tyrosine phosphatase receptor δ2, which serves as orexigenic asprosin receptor. Together, our results indicate that Ano4 neurons in the AP are the first reported orexigenic neurons, and represent potential therapeutic targets for human diseases with glucose imbalance and abnormal feeding behavior. Reference: (1) Tu, L. et al. Anoctamin 4 channel currents activate glucose-inhibited neurons in the mouse ventromedial hypothalamus during hypoglycemia. J Clin Invest 133,14. (2023). (2) Mishra, I. et al. Protein tyrosine phosphatase receptor δ serves as the orexigenic asprosin receptor. Cell Metab 34, 549-563. (2022). Presentation: 6/2/2024

Lubiprostone Improves Distal Segment-Specific Colonic Contractions through TRPC4 Activation Stimulated by EP3 Prostanoid Receptor

Background: Prokinetic agents are effective in increasing gastrointestinal (GI) contractility and alleviating constipation, often caused by slow intestinal motility. Lubiprostone (LUB), known for activating CLC-2 chloride channels, increases the chloride ion concentration in the GI tract, supporting water retention and stool movement. Despite its therapeutic efficacy, the exact mechanisms underlying its pharmacological action are poorly understood. Here, we investigated whether LUB activates the canonical transient receptor potential cation channel type 4 (TRPC4) through stimulation with E-type prostaglandin receptor (EP) type 3. Methods: Using isotonic tension recordings on mouse colon strips, we examined LUB-induced contractility in both proximal and distal colon segments. Quantitative real-time polymerase chain reaction (qRT-PCR) was conducted to determine mRNA levels of EP1-4 receptor subtypes in distal colonic muscular strips and isolated myocytes. The effects of a TRPC4 blocker and EP3 antagonist on LUB-stimulated contractions were also evaluated. Results: LUB showed significant contraction in the distal segment compared to the proximal segment. EP3 receptor mRNA levels were highly expressed in the distal colon tissue, which correlated with the observed enhanced contraction. Furthermore, LUB-induced spontaneous contractions in distal colon muscles were reduced by a TRPC4 blocker or EP3 antagonist, indicating that LUB-stimulated EP3 receptor activation may lead to TRPC4 activation and increased intracellular calcium in colonic smooth muscle. Conclusions: These findings suggest that LUB improves mass movement through indirect activation of the TRPC4 channel in the distal colon. The segment-specific action of prokinetic agents like LUB provides compelling evidence for a personalized approach to symptom management, supporting the defecation reflex.