Your search keyword '"Denton, Jerod S."' showing total 23 results

1. CO2 chemosensitivity in Helix aspersa: three potassium currents mediate pH-sensitive neuronal spike timing.

Author

Denton JS, McCann FV, and Leiter JC

Subjects

Action Potentials, Animals, Delayed Rectifier Potassium Channels antagonists & inhibitors, Electrophysiology, Esophagus innervation, Ganglia cytology, Hydrogen-Ion Concentration, Hypercapnia physiopathology, Neurons physiology, Potassium Channels metabolism, Reaction Time physiology, Carbon Dioxide metabolism, Chemoreceptor Cells physiology, Helix, Snails physiology, Neurons metabolism, Potassium Channels physiology

Abstract

Elevated levels of carbon dioxide increase lung ventilation in Helix aspersa. The hypercapnic response originates from a discrete respiratory chemosensory region in the dorsal subesophageal ganglia that contains CO(2)-sensitive neurons. We tested the hypothesis that pH-dependent inhibition of potassium channels in neurons in this region mediated the chemosensory response to CO(2). Cells isolated from the dorsal subesophageal ganglia retained CO(2) chemosensitivity and exhibited membrane depolarization and/or an increase in input resistance during an acid challenge. Isolated somata expressed two voltage-dependent potassium channels, an A-type and a delayed-rectifier-type channel (I(KA) and I(KDR)). Both conductances were inhibited during hypercapnia. The pattern of voltage dependence indicated that I(KA) was affected by extracellular or intracellular pH, but the activity of I(KDR) was modulated by extracellular pH only. Application of inhibitors of either channel mimicked many of the effects of acidification in isolated cells and neurons in situ. We also detected evidence of a pH-sensitive calcium-activated potassium channel (I(KCa)) in neurons in situ. The results of these studies support the hypothesis that I(KA) initiates the chemosensory response, and I(KDR) and I(KCa) prolong the period of activation of CO(2)-sensitive neurons. Thus multiple potassium channels are inhibited by acidosis, and the combined effect of pH-dependent inhibition of these channels enhances neuronal excitability and mediates CO(2) chemosensory responses in H. aspersa. We did not find a single "chemosensory channel," and the chemosensitive channels that we did find were not unique in any way that we could detect. The protein "machinery" of CO(2) chemosensitivity is probably widespread among neurons, and the selection process whereby a neuron acts or does not act as a respiratory CO(2) chemosensor probably depends on the resting membrane potential and synaptic connectivity.

Published

2007

2. Low potassium activation of proximal mTOR/AKT signaling is mediated by Kir4.2.

Author

Zhang, Yahua, Bock, Fabian, Ferdaus, Mohammed, Arroyo, Juan Pablo, L Rose, Kristie, Patel, Purvi, Denton, Jerod S., Delpire, Eric, Weinstein, Alan M., Zhang, Ming-Zhi, Harris, Raymond C., and Terker, Andrew S.

Subjects

PROXIMAL kidney tubules, POTASSIUM channels, POTASSIUM, THREE-dimensional imaging, SIGNALS & signaling, EPITHELIAL cells, CELL growth

Abstract

The renal epithelium is sensitive to changes in blood potassium (K+). We identify the basolateral K+ channel, Kir4.2, as a mediator of the proximal tubule response to K+ deficiency. Mice lacking Kir4.2 have a compensated baseline phenotype whereby they increase their distal transport burden to maintain homeostasis. Upon dietary K+ depletion, knockout animals decompensate as evidenced by increased urinary K+ excretion and development of a proximal renal tubular acidosis. Potassium wasting is not proximal in origin but is caused by higher ENaC activity and depends upon increased distal sodium delivery. Three-dimensional imaging reveals Kir4.2 knockouts fail to undergo proximal tubule expansion, while the distal convoluted tubule response is exaggerated. AKT signaling mediates the dietary K+ response, which is blunted in Kir4.2 knockouts. Lastly, we demonstrate in isolated tubules that AKT phosphorylation in response to low K+ depends upon mTORC2 activation by secondary changes in Cl- transport. Data support a proximal role for cell Cl- which, as it does along the distal nephron, responds to K+ changes to activate kinase signaling. The renal epithelium is sensitive to changes in blood K+. Here, Zhang et al. identify low K+ as a potent activator of proximal tubule mTOR/AKT signaling, which occurs through the K+ channel, Kir4.2 to modulate epithelial cell growth and Na+ transport. [ABSTRACT FROM AUTHOR]

Published

2024

3. Crosstalk between epithelial sodium channels (ENaC) and basolateral potassium channels (Kir4.1/Kir5.1) in the cortical collecting duct.

Author

Isaeva, Elena, Bohovyk, Ruslan, Fedoriuk, Mykhailo, Shalygin, Alexey, Klemens, Christine A., Zietara, Adrian, Levchenko, Vladislav, Denton, Jerod S., Staruschenko, Alexander, and Palygin, Oleg

Subjects

SODIUM channels, POTASSIUM channels, CHO cell, AMITRIPTYLINE, EPITHELIAL cells, KIDNEY tubules, FLUOXETINE

Abstract

Background and Purpose: Inwardly rectifying K+ (Kir) channels located on the basolateral membrane of epithelial cells of the distal nephron play a crucial role in K+ handling and BP control, making these channels an attractive target for the treatment of hypertension. The purpose of the present study was to determine how the inhibition of basolateral Kir4.1/Kir5.1 heteromeric K+ channel affects epithelial sodium channel (ENaC)‐mediated Na+ transport in the principal cells of cortical collecting duct (CCD). Experimental Approach The effect of fluoxetine, amitriptyline and recently developed Kir inhibitor, VU0134992, on the activity of Kir4.1, Kir4.1/Kir5.1 and ENaC were tested using electrophysiological approaches in CHO cells transfected with respective channel subunits, cultured polarized epithelial mCCDcl1 cells and freshly isolated rat and human CCD tubules. To test the effect of pharmacological Kir4.1/Kir5.1 inhibition on electrolyte homeostasis in vivo and corresponding changes in distal tubule transport, Dahl salt‐sensitive rats were injected with amitriptyline (15 mg·kg−1·day−1) for 3 days. Key Results: We found that inhibition of Kir4.1/Kir5.1, but not the Kir4.1 channel, depolarizes the cell membrane, induces the elevation of intracellular Ca2+ concentration and suppresses ENaC activity. Furthermore, we demonstrate that amitriptyline administration leads to a significant drop in plasma K+ level, triggering sodium excretion and diuresis. Conclusion and Implications: The present data uncover a specific role of the Kir4.1/Kir5.1 channel in the modulation of ENaC activity and emphasize the potential for using Kir4.1/Kir5.1 inhibitors to regulate electrolyte homeostasis and BP. [ABSTRACT FROM AUTHOR]

Published

2022

4. Special collection on inward rectifying K+ channels.

Author

Denton, Jerod S. and Delpire, Eric

Subjects

*POTASSIUM channels, *BIOPHYSICS, *PANCREATIC beta cells, *CARDIOVASCULAR system, *G protein coupled receptors, *VASCULAR resistance, *THERAPEUTICS

Published

2023

5. The Molecular Physiology and Toxicology of Inward Rectifier Potassium Channels in Insects.

Author

Piermarini, Peter M., Denton, Jerod S., and Swale, Daniel R.

Subjects

*POTASSIUM channels, *INSECT physiology, *TOXICOLOGY, *INSECTS, *ARTHROPOD vectors, *ARTHROPOD pests

Abstract

Inward rectifier K+ (Kir) channels have been studied extensively in mammals, where they play critical roles in health and disease. In insects, Kir channels have recently been found to be key regulators of diverse physiological processes in several tissues. The importance of Kir channels in insects has positioned them to serve as emerging targets for the development of insecticides with novel modes of action. In this article, we provide the first comprehensive review of insect Kir channels, highlighting the rapid progress made in understanding their molecular biology, physiological roles, pharmacology, and toxicology. In addition, we highlight key gaps in our knowledge and suggest directions for future research to advance our understanding of Kir channels and their roles in insect physiology. Further knowledge of their functional roles will also facilitate their exploitation as targets for controlling arthropod pests and vectors of economic, medical, and/or veterinary relevance. [ABSTRACT FROM AUTHOR]

Published

2022

6. Next-generation inward rectifier potassium channel modulators: discovery and molecular pharmacology.

Author

Weaver, C. David and Denton, Jerod S.

Subjects

*MOLECULAR pharmacology, *POTASSIUM channels, *HIGH throughput screening (Drug development), *DRUG target, *SMALL molecules, *PHARMACEUTICAL chemistry

Abstract

Inward rectifying potassium (Kir) channels play important roles in both excitable and nonexcitable cells of various organ systems and could represent valuable new drug targets for cardiovascular, metabolic, immune, and neurological diseases. In nonexcitable epithelial cells of the kidney tubule, for example, Kir1.1 (KCNJ1) and Kir4.1 (KCNJ10) are linked to sodium reabsorption in the thick ascending limb of Henle's loop and distal convoluted tubule, respectively, and have been explored as novel-mechanism diuretic targets for managing hypertension and edema. G protein-coupled Kir channels (Kir3) channels expressed in the central nervous system are critical effectors of numerous signal transduction pathways underlying analgesia, addiction, and respiratory-depressive effects of opioids. The historical dearth of pharmacological tool compounds for exploring the therapeutic potential of Kir channels has led to a molecular target-based approach using high-throughput screen (HTS) of small-molecule libraries and medicinal chemistry to develop "next-generation" Kir channel modulators that are both potent and specific for their targets. In this article, we review recent efforts focused specifically on discovery and improvement of target-selective molecular probes. The reader is introduced to fluorescence-based thallium flux assays that have enabled much of this work and then provided with an overview of progress made toward developing modulators of Kir1.1 (VU590, VU591), Kir2.x (ML133), Kir3. X (ML297, GAT1508, GiGA1, VU059331), Kir4.1 (VU0134992), and Kir7.1 (ML418). We discuss what is known about the small molecules' molecular mechanisms of action, in vitro and in vivo pharmacology, and then close with our view of what critical work remains to be done. [ABSTRACT FROM AUTHOR]

Published

2021

7. Discovery and Characterization of a Potent and Selective Inhibitor of Aedes aegypti Inward Rectifier Potassium Channels.

Author

Raphemot, Rene, Rouhier, Matthew F., Swale, Daniel R., Days, Emily, Weaver, C. David, Lovell, Kimberly M., Konkel, Leah C., Engers, Darren W., Bollinger, Sean F., Hopkins, Corey, Piermarini, Peter M., and Denton, Jerod S.

Subjects

AEDES aegypti, VIRUS disease transmission, POTASSIUM channels, DISEASE vectors, INSECTICIDE resistance, ELECTROPHYSIOLOGY

Abstract

Vector-borne diseases such as dengue fever and malaria, which are transmitted by infected female mosquitoes, affect nearly half of the world's population. The emergence of insecticide-resistant mosquito populations is reducing the effectiveness of conventional insecticides and threatening current vector control strategies, which has created an urgent need to identify new molecular targets against which novel classes of insecticides can be developed. We previously demonstrated that small molecule inhibitors of mammalian Kir channels represent promising chemicals for new mosquitocide development. In this study, high-throughput screening of approximately 30,000 chemically diverse small-molecules was employed to discover potent and selective inhibitors of Aedes aegypti Kir1 (AeKir1) channels heterologously expressed in HEK293 cells. Of 283 confirmed screening ‘hits’, the small-molecule inhibitor VU625 was selected for lead optimization and in vivo studies based on its potency and selectivity toward AeKir1, and tractability for medicinal chemistry. In patch clamp electrophysiology experiments of HEK293 cells, VU625 inhibits AeKir1 with an IC50 value of 96.8 nM, making VU625 the most potent inhibitor of AeKir1 described to date. Furthermore, electrophysiology experiments in Xenopus oocytes revealed that VU625 is a weak inhibitor of AeKir2B. Surprisingly, injection of VU625 failed to elicit significant effects on mosquito behavior, urine excretion, or survival. However, when co-injected with probenecid, VU625 inhibited the excretory capacity of mosquitoes and was toxic, suggesting that the compound is a substrate of organic anion and/or ATP-binding cassette (ABC) transporters. The dose-toxicity relationship of VU625 (when co-injected with probenecid) is biphasic, which is consistent with the molecule inhibiting both AeKir1 and AeKir2B with different potencies. This study demonstrates proof-of-concept that potent and highly selective inhibitors of mosquito Kir channels can be developed using conventional drug discovery approaches. Furthermore, it reinforces the notion that the physical and chemical properties that determine a compound's bioavailability in vivo will be critical in determining the efficacy of Kir channel inhibitors as insecticides. [ABSTRACT FROM AUTHOR]

Published

2014

8. The inwardly rectifying K+ channel KIR7.1 controls uterine excitability throughout pregnancy.

Author

McCloskey, Conor, Rada, Cara, Bailey, Elizabeth, McCavera, Samantha, Berg, Hugo A, Atia, Jolene, Rand, David A, Shmygol, Anatoly, Chan, Yi‐Wah, Quenby, Siobhan, Brosens, Jan J, Vatish, Manu, Zhang, Jie, Denton, Jerod S, Taggart, Michael J, Kettleborough, Catherine, Tickle, David, Jerman, Jeff, Wright, Paul, and Dale, Timothy

Abstract

Abnormal uterine activity in pregnancy causes a range of important clinical disorders, including preterm birth, dysfunctional labour and post-partum haemorrhage. Uterine contractile patterns are controlled by the generation of complex electrical signals at the myometrial smooth muscle plasma membrane. To identify novel targets to treat conditions associated with uterine dysfunction, we undertook a genome-wide screen of potassium channels that are enriched in myometrial smooth muscle. Computational modelling identified Kir7.1 as potentially important in regulating uterine excitability during pregnancy. We demonstrate Kir7.1 current hyper-polarizes uterine myocytes and promotes quiescence during gestation. Labour is associated with a decline, but not loss, of Kir7.1 expression. Knockdown of Kir7.1 by lentiviral expression of mi RNA was sufficient to increase uterine contractile force and duration significantly. Conversely, overexpression of Kir7.1 inhibited uterine contractility. Finally, we demonstrate that the Kir7.1 inhibitor VU590 as well as novel derivative compounds induces profound, long-lasting contractions in mouse and human myometrium; the activity of these inhibitors exceeds that of other uterotonic drugs. We conclude Kir7.1 regulates the transition from quiescence to contractions in the pregnant uterus and may be a target for therapies to control uterine contractility. [ABSTRACT FROM AUTHOR]

Published

2014

9. Pharmacological Validation of an Inward-Rectifier Potassium (Kir) Channel as an Insecticide Target in the Yellow Fever Mosquito Aedes aegypti.

Author

Rouhier, Matthew F., Raphemot, Rene, Denton, Jerod S., and Piermarini, Peter M.

Subjects

DENGUE, THERAPEUTICS, PHARMACOLOGY, POTASSIUM channels, INSECTICIDES, AEDES aegypti, MOSQUITO vectors, MALARIA treatment

Abstract

Mosquitoes are important disease vectors that transmit a wide variety of pathogens to humans, including those that cause malaria and dengue fever. Insecticides have traditionally been deployed to control populations of disease-causing mosquitoes, but the emergence of insecticide resistance has severely limited the number of active compounds that are used against mosquitoes. Thus, to improve the control of resistant mosquitoes there is a need to identify new insecticide targets and active compounds for insecticide development. Recently we demonstrated that inward rectifier potassium (Kir) channels and small molecule inhibitors of Kir channels offer promising new molecular targets and active compounds, respectively, for insecticide development. Here we provide pharmacological validation of a specific mosquito Kir channel (AeKir1) in the yellow fever mosquito Aedes aegypti. We show that VU590, a small-molecule inhibitor of mammalian Kir1.1 and Kir7.1 channels, potently inhibits AeKir1 but not another mosquito Kir channel (AeKir2B) in vitro. Moreover, we show that a previously identified inhibitor of AeKir1 (VU573) elicits an unexpected agonistic effect on AeKir2B in vitro. Injection of VU590 into the hemolymph of adult female mosquitoes significantly inhibits their capacity to excrete urine and kills them within 24 h, suggesting a mechanism of action on the excretory system. Importantly, a structurally-related VU590 analog (VU608), which weakly blocks AeKir1 in vitro, has no significant effects on their excretory capacity and does not kill mosquitoes. These observations suggest that the toxic effects of VU590 are associated with its inhibition of AeKir1. [ABSTRACT FROM AUTHOR]

Published

2014

10. Development and Validation of Fluorescence-Based and Automated Patch Clamp-Based Functional Assays for the Inward Rectifier Potassium Channel Kir4.1.

Author

Raphemot, Rene, Kadakia, Rishin J., Olsen, Michelle L., Banerjee, Sreedatta, Days, Emily, Smith, Stephen S., Weaver, C. David, and Denton, Jerod S.

Subjects

FLUORESCENCE, PATCH-clamp techniques (Electrophysiology), POTASSIUM channels, BIOLOGICAL assay, FLUOXETINE, TEMPORAL lobe epilepsy, HYPERTENSION, MOLECULAR pharmacology

Abstract

The inward rectifier potassium (Kir) channel Kir4.1 plays essential roles in modulation of neurotransmission and renal sodium transport and may represent a novel drug target for temporal lobe epilepsy and hypertension. The molecular pharmacology of Kir4.1 is limited to neurological drugs, such as fluoxetine (Prozac©), exhibiting weak and nonspecific activity toward the channel. The development of potent and selective small-molecule probes would provide critically needed tools for exploring the integrative physiology and therapeutic potential of Kir4.1. A fluorescence-based thallium (Tl+) flux assay that utilizes a tetracycline-inducible T-Rex-HEK293-Kir4.1 cell line to enable high-throughput screening (HTS) of small-molecule libraries was developed. The assay is dimethyl sulfoxide tolerant and exhibits robust screening statistics (Z′=0.75±0.06). A pilot screen of 3,655 small molecules and lipids revealed 16 Kir4.1 inhibitors (0.4% hit rate). 3,3-Diphenyl-N-(1-phenylethyl)propan-1-amine, termed VU717, inhibits Kir4.1-mediated thallium flux with an IC50 of ∼6 μM. An automated patch clamp assay using the IonFlux HT workbench was developed to facilitate compound characterization. Leak-subtracted ensemble 'loose patch' recordings revealed robust tetracycline-inducible and Kir4.1 currents that were inhibited by fluoxetine (IC50=10 μM), VU717 (IC50=6 μM), and structurally related calcium channel blocker prenylamine (IC50=6 μM). Finally, we demonstrate that VU717 inhibits Kir4.1 channel activity in cultured rat astrocytes, providing proof-of-concept that the Tl+ flux and IonFlux HT assays can enable the discovery of antagonists that are active against native Kir4.1 channels. [ABSTRACT FROM AUTHOR]

Published

2013

11. Eliciting Renal Failure in Mosquitoes with a Small-Molecule Inhibitor of Inward-Rectifying Potassium Channels

Author

Raphemot, Rene, Rouhier, Matthew F., Hopkins, Corey R., Gogliotti, Rocco D., Lovell, Kimberly M., Hine, Rebecca M., Ghosalkar, Dhairyasheel, Longo, Anthony, Beyenbach, Klaus W., Denton, Jerod S., and Piermarini, Peter M.

Subjects

KIDNEY failure, MOSQUITOES, POTASSIUM channels, MALARIA, DENGUE, NERVOUS system

Abstract

Mosquito-borne diseases such as malaria and dengue fever take a large toll on global health. The primary chemical agents used for controlling mosquitoes are insecticides that target the nervous system. However, the emergence of resistance in mosquito populations is reducing the efficacy of available insecticides. The development of new insecticides is therefore urgent. Here we show that VU573, a small-molecule inhibitor of mammalian inward-rectifying potassium (Kir) channels, inhibits a Kir channel cloned from the renal (Malpighian) tubules of Aedes aegypti (AeKir1). Injection of VU573 into the hemolymph of adult female mosquitoes (Ae. aegypti) disrupts the production and excretion of urine in a manner consistent with channel block of AeKir1 and renders the mosquitoes incapacitated (flightless or dead) within 24 hours. Moreover, the toxicity of VU573 in mosquitoes (Ae. aegypti) is exacerbated when hemolymph potassium levels are elevated, suggesting that Kir channels are essential for maintenance of whole-animal potassium homeostasis. Our study demonstrates that renal failure is a promising mechanism of action for killing mosquitoes, and motivates the discovery of selective small-molecule inhibitors of mosquito Kir channels for use as insecticides. [ABSTRACT FROM AUTHOR]

Published

2013

12. CO2 chemosensitivity in Helix aspersa: three potassium currents mediate pH-sensitive neuronal spike timing.

Author

Denton, Jerod S., McCann, F. V., and Leiter, J. C.

Subjects

CARBON dioxide, HYPERCAPNIA, RESPIRATION, SENSORY neurons, POTASSIUM channels, BROWN garden snail

Abstract

Elevated levels of carbon dioxide increase lung ventilation in Helix aspersa. The hypercapnic response originates from a discrete respiratory chemosensory region in the dorsal subesophageal ganglia that contains CO2-sensitive neurons. We tested the hypothesis that pH-dependent inhibition of potassium channels in neurons in this region mediated the chemosensory response to CO2. Cells isolated from the dorsal subesophageal ganglia retained CO2 chemosensitivity and exhibited membrane depolarization and/or an increase in input resistance during an acid challenge. Isolated somata expressed two voltage-dependent potassium channels, an A-type and a delayed-rectifier-type channel (IRA and IKDR). Both conductances were inhibited during hypercapnia. The pattern of voltage dependence indicated that IKA was affected by extracellular or intracellular pH, but the activity of IKDR was modulated by extracellular pH only. Application of inhibitors of either channel mimicked many of the effects of acidification in isolated cells and neurons in situ. We also detected evidence of a pH-sensitive calcium-activated potassium channel (IKCa) in neurons in situ. The results of these studies support the hypothesis that IKA initiates the chemosensory response, and IKDR and IKCa prolong the period of activation of CO2-sensitive neurons. Thus multiple potassium channels are inhibited by acidosis, and the combined effect of pH-dependent inhibition of these channels enhances neuronal excitability and mediates CO2 chemosensory responses in H. aspersa. We did not find a single ‘chemosensory channel,’ and the chemosensitive channels that we did find were not unique in any way that we could detect. The protein ‘machinery’ of CO2 chemosensitivity is probably widespread among neurons, and the selection process whereby a neuron acts or does not act as a respiratory CO2 chemosensor probably depends on the resting membrane potential and synaptic connectivity. [ABSTRACT FROM AUTHOR]

Published

2007

13. A computational analysis of central CO2 chemosensitivity in Helix aspersa.

Author

Chernov, Mykyta M., Daubenspeck, Andrew, Denton, Jerod S., Pfeiffer, Jason R., Putnam, Robert W., and Leiter, J. C.

Subjects

CARBON dioxide, SENSORY neurons, BROWN garden snail, COMPUTATIONAL biology, DIFFERENTIAL equations, MATHEMATICAL analysis

Abstract

We created a single-compartment computer model of a CO2 chemosensory neuron using differential equations adapted from the Hodgkin-Huxley model and measurements of currents in CO2 chemosensory neurons from Helix aspersa. We incorporated into the model two inward currents, a sodium current and a calcium current, three outward potassium currents, an A-type current (IKA), a delayed rectifier current (IKDR), a calcium-activated potassium current (IKCa), and a proton conductance found in invertebrate cells. All of the potassium channels were inhibited by reduced pH. We also included the pH regulatory process to mimic the effect of the sodium-hydrogen exchanger (NHE) described in these cells during hypercapnic stimulation. The model displayed chemosensory behavior (increased spike frequency during acid stimulation), and all three potassium channels participated in the chemosensory response and shaped the temporal characteristics of the response to acid stimulation, pH-dependent inhibition of IKA initiated the response to CO2, but hypercapnic inhibition of IKDR and IKCa affected the duration of the excitatory response to hypercapnia. The presence or absence of NHE activity altered the chemosensory response over time and demonstrated the inadvisability of effective intracellular pH (pHi) regulation in cells designed to act as chemostats for acid-base regulation. The results of the model indicate that multiple channels contribute to CO2 chemosensitivity, but the primary sensor is probably IKA. pHi may be a sufficient chemosensory stimulus, but it may not be a necessary stimulus: either pHi or extracellular pH can be an effective stimuli if chemosensory neurons express appropriate pH-sensitive channels. The lack of pHi regulation is a key feature determining the neuronal activity of chemosensory cells over time, and the balanced lack of pHi regulation during hypercapnia probably depends on intracellular activation of pHi regulation but extracellular inhibition of pHi regulation. These general principles are applicable to all CO2 chemosensory cells in vertebrate and invertebrate neurons. [ABSTRACT FROM AUTHOR]

Published

2007

14. The LRRC8 volume‐regulated anion channel inhibitor, DCPIB, inhibits mitochondrial respiration independently of the channel.

Author

Afzal, Aqeela, Figueroa, Eric E., Kharade, Sujay V., Bittman, Kevin, Matlock, Brittany K., Flaherty, David K., and Denton, Jerod S.

Subjects

RESPIRATION, MITOCHONDRIAL membranes, MEMBRANE potential, POTASSIUM channels, CELL morphology, POTASSIUM antagonists

Abstract

There has been a resurgence of interest in the volume‐regulated anion channel (VRAC) since the recent cloning of the LRRC8A‐E gene family that encodes VRAC. The channel is a heteromer comprised of LRRC8A and at least one other family member; disruption of LRRC8A expression abolishes VRAC activity. The best‐in‐class VRAC inhibitor, DCPIB, suffers from off‐target activity toward several different channels and transporters. Considering that some anion channel inhibitors also suppress mitochondrial respiration, we systematically explored whether DCPIB inhibits respiration in wild type (WT) and LRRC8A‐knockout HAP‐1 and HEK‐293 cells. Knockout of LRRC8A had no apparent effects on cell morphology, proliferation rate, mitochondrial content, or expression of several mitochondrial genes in HAP‐1 cells. Addition of 10 µM DCPIB, a concentration typically used to inhibit VRAC, suppressed basal and ATP‐linked respiration in part through uncoupling the inner mitochondrial membrane (IMM) proton gradient and membrane potential. Additionally, DCPIB inhibits the activity of complex I, II, and III of the electron transport chain (ETC). Surprisingly, the effects of DCPIB on mitochondrial function are also observed in HAP‐1 and HEK‐293 cells which lack LRRC8A expression. Finally, we demonstrate that DCPIB activates ATP‐inhibitable potassium channels comprised of heterologously expressed Kir6.2 and SUR1 subunits. These data indicate that DCPIB suppresses mitochondrial respiration and ATP production by dissipating the mitochondrial membrane potential and inhibiting complexes I‐III of the ETC. They further justify the need for the development of sharper pharmacological tools for evaluating the integrative physiology and therapeutic potential of VRAC in human diseases. [ABSTRACT FROM AUTHOR]

Published

2019

15. Pharmacological Inhibition of Inward Rectifier Potassium Channels Induces Lethality in Larval Aedes aegypti.

Author

Rusconi Trigueros, Renata, Hopkins, Corey R., Denton, Jerod S., and Piermarini, Peter M.

Subjects

POTASSIUM channels, PHARMACOLOGY, AEDES aegypti, INSECT larvae, MOSQUITO physiology, INSECTICIDE analysis, INSECTS

Abstract

The inward rectifier potassium (Kir) channels play key roles in the physiology of mosquitoes and other insects. Our group, among others, previously demonstrated that small molecule inhibitors of Kir channels are promising lead molecules for developing new insecticides to control adult female mosquitoes. However, the potential use of Kir channel inhibitors as larvicidal agents is unknown. Here we tested the hypothesis that pharmacological inhibition of Kir channels in the larvae of Aedes aegypti, the vector of several medically important arboviruses, induces lethality. We demonstrated that adding barium, a non-specific blocker of Kir channels, or VU041, a specific small-molecule inhibitor of mosquito Kir1 channels, to the rearing water (deionized H2O) of first instar larvae killed them within 48 h. We further showed that the toxic efficacy of VU041 within 24 h was significantly enhanced by increasing the osmolality of the rearing water to 100 mOsm/kg H2O with NaCl, KCl or mannitol; KCl provided the strongest enhancement compared to NaCl and mannitol. These data suggest: (1) the important role of Kir channels in the acclimation of larvae to elevated ambient osmolality and KCl concentrations; and (2) the disruption of osmoregulation as a potential mechanism of the toxic action of VU041. The present study provides the first evidence that inhibition of Kir channels is lethal to larval mosquitoes and broadens the potential applications of our existing arsenal of small molecule inhibitors of Kir channels, which have previously only been considered for developing adulticides. [ABSTRACT FROM AUTHOR]

Published

2018

16. Pharmacological Validation of an Inward-Rectifier Potassium (Kir) Channel as an Insecticide Target in the Yellow Fever Mosquito Aedes aegypti.

Author

Rouhier, Matthew F., Raphemot, Rene, Denton, Jerod S., and Piermarini, Peter M.

Subjects

*DENGUE, *THERAPEUTICS, *PHARMACOLOGY, *POTASSIUM channels, *INSECTICIDES, *AEDES aegypti, *MOSQUITO vectors, *MALARIA treatment

Abstract

Mosquitoes are important disease vectors that transmit a wide variety of pathogens to humans, including those that cause malaria and dengue fever. Insecticides have traditionally been deployed to control populations of disease-causing mosquitoes, but the emergence of insecticide resistance has severely limited the number of active compounds that are used against mosquitoes. Thus, to improve the control of resistant mosquitoes there is a need to identify new insecticide targets and active compounds for insecticide development. Recently we demonstrated that inward rectifier potassium (Kir) channels and small molecule inhibitors of Kir channels offer promising new molecular targets and active compounds, respectively, for insecticide development. Here we provide pharmacological validation of a specific mosquito Kir channel (AeKir1) in the yellow fever mosquito Aedes aegypti. We show that VU590, a small-molecule inhibitor of mammalian Kir1.1 and Kir7.1 channels, potently inhibits AeKir1 but not another mosquito Kir channel (AeKir2B) in vitro. Moreover, we show that a previously identified inhibitor of AeKir1 (VU573) elicits an unexpected agonistic effect on AeKir2B in vitro. Injection of VU590 into the hemolymph of adult female mosquitoes significantly inhibits their capacity to excrete urine and kills them within 24 h, suggesting a mechanism of action on the excretory system. Importantly, a structurally-related VU590 analog (VU608), which weakly blocks AeKir1 in vitro, has no significant effects on their excretory capacity and does not kill mosquitoes. These observations suggest that the toxic effects of VU590 are associated with its inhibition of AeKir1. [ABSTRACT FROM AUTHOR]

Published

2014

17. Cardiac and renal inward rectifier potassium channel pharmacology: emerging tools for integrative physiology and therapeutics.

Author

Swale, Daniel R, Kharade, Sujay V, and Denton, Jerod S

Subjects

*POTASSIUM channels, *PHARMACOLOGY, *TARGETED drug delivery, *HEART physiology, *KIDNEY physiology, *BIOCHEMICAL mechanism of action

Abstract

Highlights: [•] Some Kir channels are putative drug targets, but their pharmacology is limited. [•] Newly discovered inhibitors or activators of Kir2.x, 4.1, and 7.1 are discussed. [•] Mechanisms of action involve pore-lining residues that control rectification. [•] This work is a critical first step toward developing more specific modulators. [ABSTRACT FROM AUTHOR]

Published

2014

18. Towards a TREK-1/2 (TWIK-Related K+ Channel 1 and 2) dual activator tool compound: Multi-dimensional optimization of BL-1249.

Author

Iwaki, Yuzo, Yashiro, Kentaro, Kokubo, Masaya, Mori, Takahiro, Wieting, Joshua M., McGowan, Kevin M., Bridges, Thomas M., Engers, Darren W., Denton, Jerod S., Kurata, Haruto, and Lindsley, Craig W.

Subjects

*POTASSIUM channels, *ROBUST optimization, *STRUCTURE-activity relationships, *ION channels, *POTASSIUM ions

Abstract

• First detailed SAR account around TREK1/2 activators. • First optimization campaign directed at BL-1249. • Discovery of new in vitro and in vivo tool compound, ONO-2960632/VU6011992. This letter describes a focused, multi-dimensional optimization campaign around BL-1249, a fenamate class non-steroidal anti-inflammatory and a known activator of the K 2P potassium channels TREK-1 (K 2P 2.1) and TREK-2 (K 2P 10.1). While BL-1249 has been widely profiled in vitro as a dual TREK-1/2 activator, poor physicochemical and DMPK properties have precluded a deeper understanding of the therapeutic potential of these key K 2P channels across a broad spectrum of peripheral and central human disease. Here, we report multi-dimensional SAR that led to a novel TREK-1/2 dual activator chemotype, exemplified by ONO-2960632/VU6011992, with improved DMPK properties, representing a new lead for further optimization towards robust in vivo tool compounds. [ABSTRACT FROM AUTHOR]

Published

2019

19. G protein-coupled receptors differentially regulate glycosylation and activity of the inwardly rectifying potassium channel Kir7.1.

Author

Carrington, Sheridan J., Hernandez, Ciria C., Swale, Daniel R., Aluko, Oluwatosin A., Denton, Jerod S., and Cone, Roger D.

Subjects

*G protein coupled receptors, *GLYCOSYLATION, *POTASSIUM channels, *WESTERN immunoblotting, *MELANOCORTIN receptors

Abstract

Kir7.1 is an inwardly rectifying potassium channel with important roles in the regulation of the membrane potential in retinal pigment epithelium, uterine smooth muscle, and hypothalamic neurons. Regulation of G protein-coupled inwardly rectifying potassium (GIRK) channels by G protein-coupled receptors (GPCRs) via the G protein βγ subunits has been well characterized. However, how Kir channels are regulated is incompletely understood. We report here that Kir7.1 is also regulated by GPCRs, but through a different mechanism. Using Western blotting analysis, we observed that multiple GPCRs tested caused a striking reduction in the complex glycosylation of Kir7.1. Further, GPCR-mediated reduction of Kir7.1 glycosylation in HEK293T cells did not alter its expression at the cell surface but decreased channel activity. Of note, mutagenesis of the sole Kir7.1 glycosylation site reduced conductance and open probability, as indicated by single-channel recording. Additionally, we report that the L241P mutation of Kir7.1 associated with Lebers congenital amaurosis (LCA), an inherited retinal degenerative disease, has significantly reduced complex glycosylation. Collectively, these results suggest that Kir7.1 channel glycosylation is essential for function, and this activity within cells is suppressed by most GPCRs. The melanocortin-4 receptor (MC4R), a GPCR previously reported to induce ligand-regulated activity of this channel, is the only GPCR tested that does not have this effect on Kir7.1. [ABSTRACT FROM AUTHOR]

Published

2018

20. Inward rectifier potassium (Kir) channels in the soybean aphid Aphis glycines: Functional characterization, pharmacology, and toxicology.

Author

Piermarini, Peter M., Inocente, Edna Alfaro, Acosta, Nuris, Hopkins, Corey R., Denton, Jerod S., and Michel, Andrew P.

Subjects

*SOYBEAN diseases & pests, *APHIDS, *INSECT genomes, *APHIS glycines, *POTASSIUM channels, *PHARMACOLOGY, *TOXICOLOGY

Abstract

Graphical abstract Highlights • The genome of Aphis glycines possessed 2 Kir channel genes: ApKir1 and ApKir2. • ApKir1 and ApKir2 formed barium-inhibitable Kir channels in Xenopus oocytes. • ApKir1 produced larger K+-currents with stronger rectification compared to ApKir2. • ApKir1 was more sensitive to barium compared to ApKir2. • Small molecule inhibition of Kir channels in vivo was lethal to aphids within 24 h. Abstract Inward rectifier K+ (Kir) channels contribute to a variety of physiological processes in insects and are emerging targets for insecticide development. Previous studies on insect Kir channels have primarily focused on dipteran species (e.g., mosquitoes, fruit flies). Here we identify and functionally characterize Kir channel subunits in a hemipteran insect, the soybean aphid Aphis glycines , which is an economically important insect pest and vector of soybeans. From the transcriptome and genome of Ap. glycines we identified two cDNAs, ApKir1 and ApKir2, encoding Kir subunits that were orthologs of insect Kir1 and Kir2, respectively. Notably, a gene encoding a Kir3 subunit was absent from the transcriptome and genome of Ap. glycines , similar to the pea aphid Acyrthosiphon pisum. Heterologous expression of ApKir1 and ApKir2 in Xenopus laevis oocytes enhanced K+-currents in the plasma membrane; these currents were inhibited by barium and the small molecule VU041. Compared to ApKir2, ApKir1 mediated currents that were larger in magnitude, more sensitive to barium, and less inhibited by small molecule VU041. Moreover, ApKir1 exhibited stronger inward rectification compared to ApKir2. Topical application of VU041 in adult aphids resulted in dose-dependent mortality within 24 h that was more efficacious than flonicamid, an established insecticide also known to inhibit Kir channels. We conclude that despite the apparent loss of Kir3 genes in aphid evolution, Kir channels are important to aphid survival and represent a promising target for the development of new insecticides. [ABSTRACT FROM AUTHOR]

Published

2018

21. Synthesis and SAR of a novel Kir6.2/SUR1 channel opener scaffold identified by HTS.

Author

Dodd, Cayden J., Chronister, Keagan S., Rathnayake, Upendra, Parr, Lauren C., Li, Kangjun, Chang, Sichen, Mi, Dehui, Days, Emily L., Bauer, Joshua A., Cho, Hyekyung P., Boutaud, Olivier, Denton, Jerod S., Lindsley, Craig W., and Han, Changho

Subjects

*POTASSIUM channels, *NEUROPEPTIDES, *STRUCTURE-activity relationships, *ION channels, *SECRETION, *ADENOSINE triphosphate

Abstract

[Display omitted] Kir6.2/SUR1 is an ATP-regulated potassium channel that acts as an intracellular metabolic sensor, controlling insulin and appetite-stimulatory neuropeptides secretion. In this Letter, we present the SAR around a novel Kir6.2/SUR1 channel opener scaffold derived from an HTS screening campaign. New series of compounds with tractable SAR trends and favorable potencies are reported. [ABSTRACT FROM AUTHOR]

Published

2023

22. Pharmacological Correction of Trafficking Defects in ATP-sensitive Potassium Channels Caused by Sulfonylurea Receptor 1 Mutations.

Author

Martin, Gregory M., Rex, Emily A., Devaraneni, Prasanna, Denton, Jerod S., Boodhansingh, Kara E., DeLeon, Diva D., Stanley, Charles A., and Shyng, Show-Ling

Subjects

*POTASSIUM channels, *ADENOSINE triphosphate, *SULFONYLUREAS, *GENETIC mutation, *MEMBRANE potential

Abstract

ATP-sensitive potassium (KATP) channels play a key role in mediating glucose-stimulated insulin secretion by coupling metabolic signals to β-cell membrane potential. Loss of KATP channel function due to mutations in ABCC8 or KCNJ11, genes encoding the sulfonylurea receptor 1 (SUR1) or the inwardly rectifying potassium channel Kir6.2, respectively, results in congenital hyperinsulinism. Many SUR1 mutations prevent trafficking of channel proteins from the endoplasmic reticulum to the cell surface. Channel inhibitors, including sulfonylureas and carbamazepine, have been shown to correct channel trafficking defects. In the present study, we identified 13 novel SUR1 mutations that cause channel trafficking defects, the majority of which are amenable to pharmacological rescue by glibenclamide and carbamazepine. By contrast, none of the mutant channels were rescued by KATP channel openers. Cross-linking experiments showed that KATP channel inhibitors promoted interactions between the N terminus of Kir6.2 and SUR1, whereas channel openers did not, suggesting the inhibitors enhance intersubunit interactions to overcome channel biogenesis and trafficking defects. Functional studies of rescued mutant channels indicate that most mutants rescued to the cell surface exhibited WT-like sensitivity to ATP, MgADP, and diazoxide. In intact cells, recovery of channel function upon trafficking rescue by reversible sulfonylureas or carbamazepine was facilitated by theKATP channel opener diazoxide. Our study expands the list of KATP channel trafficking mutations whose function can be recovered by pharmacological ligands and provides further insight into the structural mechanism by which channel inhibitors correct channel biogenesis and trafficking defects. [ABSTRACT FROM AUTHOR]

Published

2016

23. Localization and role of inward rectifier K+ channels in Malpighian tubules of the yellow fever mosquito Aedes aegypti.

Author

Piermarini, Peter M., Dunemann, Sonja M., Rouhier, Matthew F., Calkins, Travis L., Raphemot, Rene, Denton, Jerod S., Hine, Rebecca M., and Beyenbach, Klaus W.

Subjects

*YELLOW fever, *AEDES, *EXANTHEMA, *AEDES aegypti, *EPITHELIAL cells

Abstract

Malpighian tubules of adult female yellow fever mosquitoes Aedes aegypti express three inward rectifier K + (Kir) channel subunits: Ae Kir1, Ae Kir2B and Ae Kir3. Here we 1) elucidate the cellular and membrane localization of these three channels in the Malpighian tubules, and 2) characterize the effects of small molecule inhibitors of Ae Kir1 and Ae Kir2B channels (VU compounds) on the transepithelial secretion of fluid and electrolytes and the electrophysiology of isolated Malpighian tubules. Using subunit-specific antibodies, we found that Ae Kir1 and Ae Kir2B localize exclusively to the basolateral membranes of stellate cells and principal cells, respectively; Ae Kir3 localizes within intracellular compartments of both principal and stellate cells. In isolated tubules bathed in a Ringer solution containing 34 mM K + , the peritubular application of VU590 (10 μM), a selective inhibitor of Ae Kir1, inhibited transepithelial fluid secretion 120 min later. The inhibition brings rates of transepithelial KCl and fluid secretion to 54% of the control without a change in transepithelial NaCl secretion. VU590 had no effect on the basolateral membrane voltage (V bl ) of principal cells, but it significantly reduced the cell input conductance (g in ) to values 63% of the control within ∼90 min. In contrast, the peritubular application of VU625 (10 μM), an inhibitor of both Ae Kir1 and Ae Kir2B, started to inhibit transepithelial fluid secretion as early as 60 min later. At 120 min after treatment, VU625 was more efficacious than VU590, inhibiting transepithelial KCl and fluid secretion to ∼35% of the control without a change in transepithelial NaCl secretion. Moreover, VU625 caused the V bl and g in of principal cells to respectively drop to values 62% and 56% of the control values within only ∼30 min. Comparing the effects of VU590 with those of VU625 allowed us to estimate that Ae Kir1 and Ae Kir2B respectively contribute to 46% and 20% of the transepithelial K + secretion when the tubules are bathed in a Ringer solution containing 34 mM K + . Thus, we uncover an important role of Ae Kir1 and stellate cells in transepithelial K + transport under conditions of peritubular K + challenge. The physiological role of Ae Kir3 in intracellular membranes of both stellate and principal cells remains to be determined. [ABSTRACT FROM AUTHOR]

Published

2015