Your search keyword '"Pradhananga, Sabindra"' showing total 16 results

1. SGK1 inhibition attenuated the action potential duration in patient- and genotype-specific re-engineered heart cells with congenital long QT syndrome

Author

Kim, Maengjo, Das, Saumya, Tester, David J., Pradhananga, Sabindra, Hamrick, Samantha K., Gao, Xiaozhi, Srinivasan, Dinesh, Sager, Philip T., and Ackerman, Michael J.

Published

2023

2. SGK1 inhibition attenuates the action potential duration in reengineered heart cell models of drug-induced QT prolongation

Author

Kim, Maengjo, Sager, Philip T., Tester, David J., Pradhananga, Sabindra, Hamrick, Samantha K., Srinivasan, Dinesh, Das, Saumya, and Ackerman, Michael J.

Published

2023

3. Abstract 15963: A Novel SGK1 Inhibitor (SGK1-I), Prevents Obesity-Related Atrial Fibrillation

Author

Bapat, Aneesh, Pradhananga, Sabindra, Srinivasan, Dinesh, Sager, Philip, and Ellinor, Patrick T

Published

2023

4. Abstract 11027: SGK1 Inhibition and Attenuation of the Action Potential Duration in Re-Engineered Heart Cell Models of Drug-Induced QT Prolongation

Author

Tester, David J, Sager, Philip T, Kim, Maengjo, Pradhananga, Sabindra, Hamrick, Samantha K, Srinivasan, Dinesh, Das, Saumya, and Ackerman, Michael J

Published

2022

5. Abstract 10986: SGK1 Inhibition Attenuated the Action Potential Duration In-Patient and Genotype-Specific Re-Engineered Heart Cells With Congenital Long QT Syndrome

Author

Tester, David J, Das, Saumya, Kim, Maengjo, Pradhananga, Sabindra, Hamrick, Samantha K, Srinivasan, Dinesh, Sager, Philip, and Ackerman, Michael J

Published

2022

6. Gene- and variant-specific efficacy of serum/glucocorticoid-regulated kinase 1 inhibition in long QT syndrome types 1 and 2

Author

Giannetti, Federica, Barbieri, Miriam, Shiti, Assad, Casini, Simona, Sager, Philip T, Das, Saumya, Pradhananga, Sabindra, Srinivasan, Dinesh, Nimani, Saranda, Alerni, Nicolò, Louradour, Julien, Mura, Manuela, Gnecchi, Massimiliano, Brink, Paul, Zehender, Manfred, Koren, Gideon, Zaza, Antonio, Crotti, Lia, Wilde, Arthur A M, Schwartz, Peter J, Remme, Carol Ann, Gepstein, Lior, Sala, Luca, Odening, Katja E, Giannetti, F, Barbieri, M, Shiti, A, Casini, S, Sager, P, Das, S, Pradhananga, S, Srinivasan, D, Nimani, S, Alerni, N, Louradour, J, Mura, M, Gnecchi, M, Brink, P, Zehender, M, Koren, G, Zaza, A, Crotti, L, Wilde, A, Schwartz, P, Remme, C, Gepstein, L, Sala, L, and Odening, K

Subjects

Cellular electrophysiology, Physiology (medical), LQTS, Animal model, 610 Medicine & health, 610 Medizin und Gesundheit, Cardiology and Cardiovascular Medicine, Genotype-specific therapy, hiPSC, Mechanism-based therapy

Abstract

Aims Current long QT syndrome (LQTS) therapy, largely based on beta-blockade, does not prevent arrhythmias in all patients; therefore, novel therapies are warranted. Pharmacological inhibition of the serum/glucocorticoid-regulated kinase 1 (SGK1-Inh) has been shown to shorten action potential duration (APD) in LQTS type 3. We aimed to investigate whether SGK1-Inh could similarly shorten APD in LQTS types 1 and 2. Methods and results Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) and hiPSC-cardiac cell sheets (CCS) were obtained from LQT1 and LQT2 patients; CMs were isolated from transgenic LQT1, LQT2, and wild-type (WT) rabbits. Serum/glucocorticoid-regulated kinase 1 inhibition effects (300 nM–10 µM) on field potential durations (FPD) were investigated in hiPSC-CMs with multielectrode arrays; optical mapping was performed in LQT2 CCS. Whole-cell and perforated patch clamp recordings were performed in isolated LQT1, LQT2, and WT rabbit CMs to investigate SGK1-Inh (3 µM) effects on APD. In all LQT2 models across different species (hiPSC-CMs, hiPSC-CCS, and rabbit CMs) and independent of the disease-causing variant (KCNH2-p.A561V/p.A614V/p.G628S/IVS9-28A/G), SGK1-Inh dose-dependently shortened FPD/APD at 0.3–10 µM (by 20–32%/25–30%/44–45%). Importantly, in LQT2 rabbit CMs, 3 µM SGK1-Inh normalized APD to its WT value. A significant FPD shortening was observed in KCNQ1-p.R594Q hiPSC-CMs at 1/3/10 µM (by 19/26/35%) and in KCNQ1-p.A341V hiPSC-CMs at 10 µM (by 29%). No SGK1-Inh-induced FPD/APD shortening effect was observed in LQT1 KCNQ1-p.A341V hiPSC-CMs or KCNQ1-p.Y315S rabbit CMs at 0.3–3 µM. Conclusion A robust SGK1-Inh-induced APD shortening was observed across different LQT2 models, species, and genetic variants but less consistently in LQT1 models. This suggests a genotype- and variant-specific beneficial effect of this novel therapeutic approach in LQTS.

Published

2023

7. PO-01-046 ATTENUATION OF DRUG-INDUCED QT-PROLONGATION IN GUINEA PIG ISOLATED HEART AND ANESTHETIZED DOG MODELS OF DRUG-INDUCED QT PROLONGATION BY SERUM/GLUCOCORTICOID REGULATED KINASE 1 (SGK-1) INHIBITORS

Author

Gralinski, Michael R., Doherty, Kimbery, Pradhananga, Sabindra, Zammit, Melissa, Shilova, Olga, Johnson, Michelle, Srinivasan, Dinesh, Das, Saumya, Senese, Peter B., and Sager, Philip T.

Published

2024

8. SGK1 INHIBITOR LQT-1213 SIGNIFICANTLY ATTENUATES DOFETILIDE-INDUCED QT PROLONGATION IN HUMANS: RESULTS OF THE WAVE I CLINICAL STUDY

Author

Das, Saumya, Sager, Philip T., Shamszad, Pirouz, Pradhananga, Sabindra, Wight, Douglas, Brkovic, Alexandre, and Ackerman, Michael John

Published

2024

9. Caffeic acid exhibits anti-pruritic effects by inhibition of multiple itch transmission pathways in mice

Author

Pradhananga, Sabindra and Shim, Won-Sik

Published

2015

10. Protease‐dependent excitation of nodose ganglion neurons by commensal gut bacteria.

Author

Pradhananga, Sabindra, Tashtush, Ayssar A., Allen‐Vercoe, Emma, Petrof, Elaine O., and Lomax, Alan E.

Subjects

*BACTERIAL cell walls, *CENTRAL nervous system, *PATCH-clamp techniques (Electrophysiology), *NEURONS, *CYSTEINE proteinase inhibitors, *VAGUS nerve, *BACTERIAL cells, *CLONORCHIS sinensis, *MIRROR neurons

Abstract

Key points: The vagus nerve has been implicated in mediating behavioural effects of the gut microbiota on the central nervous system. This study examined whether the secretory products of commensal gut bacteria can modulate the excitability of vagal afferent neurons with cell bodies in nodose ganglia.Cysteine proteases from commensal bacteria increased the excitability of vagal afferent neurons via activation of protease‐activated receptor 2 and modulation of the voltage dependence of Na+ conductance activation.Lipopolysaccharide, a component of the cell wall of gram‐negative bacteria, increased the excitability of nodose ganglia neurons via TLR4‐dependent activation of nuclear factor kappa B.Our study identified potential mechanisms by which gut microbiota influences the activity of vagal afferent pathways, which may in turn impact on autonomic reflexes and behaviour. Behavioural studies have implicated vagal afferent neurons as an important component of the microbiota‐gut‐brain axis. However, the mechanisms underlying the ability of the gut microbiota to affect vagal afferent pathways are unclear. We examined the effect of supernatant from a community of 33 commensal gastrointestinal bacterial derived from a healthy human donor (microbial ecosystem therapeutics; MET‐1) on the excitability of mouse vagal afferent neurons. Perforated patch clamp electrophysiology was used to measure the excitability of dissociated nodose ganglion (NG) neurons. NG neuronal excitability was assayed by measuring the amount of current required to elicit an action potential, the rheobase. MET‐1 supernatant increased the excitability of NG neurons by hyperpolarizing the voltage dependence of activation of Na+ conductance. The increase in excitability elicited by MET‐1 supernatant was blocked by the cysteine protease inhibitor E‐64 (30 nm). The protease activated receptor‐2 (PAR2) antagonist (GB 83, 10 μm) also blocked the effect of MET‐1 supernatant on NG neurons. Supernatant from Lactobacillus paracasei 6MRS, a component of MET‐1, recapitulated the effect of MET‐1 supernatant on NG neurons. Lastly, we compared the effects of MET‐1 supernatant and lipopolysaccharide (LPS) from Escherichia coli 05:B5 on NG neuron excitability. LPS increased the excitability of NG neurons in a toll‐like receptor 4 (TLR4)‐dependent and PAR2‐independent manner, whereas the excitatory effects of MET‐1 supernatant were independent of TLR4 activation. Together, our findings suggest that cysteine proteases from commensal bacteria increase the excitability of vagal afferent neurons by the activation of PAR2. Key points: The vagus nerve has been implicated in mediating behavioural effects of the gut microbiota on the central nervous system. This study examined whether the secretory products of commensal gut bacteria can modulate the excitability of vagal afferent neurons with cell bodies in nodose ganglia.Cysteine proteases from commensal bacteria increased the excitability of vagal afferent neurons via activation of protease‐activated receptor 2 and modulation of the voltage dependence of Na+ conductance activation.Lipopolysaccharide, a component of the cell wall of gram‐negative bacteria, increased the excitability of nodose ganglia neurons via TLR4‐dependent activation of nuclear factor kappa B.Our study identified potential mechanisms by which gut microbiota influences the activity of vagal afferent pathways, which may in turn impact on autonomic reflexes and behaviour. [ABSTRACT FROM AUTHOR]

Published

2020

11. Bacterial modulation of visceral sensation: mediators and mechanisms.

Author

Lomax, Alan E., Pradhananga, Sabindra, Sessenwein, Jessica L., and O'Malley, Dervla

Subjects

*SHORT-chain fatty acids, *GASTRIC inhibitory polypeptide, *DORSAL root ganglia, *ENTEROENDOCRINE cells, *AFFERENT pathways, *VISCERAL pain

Abstract

The potential role of the intestinal microbiota in modulating visceral pain has received increasing attention during recent years. This has led to the identification of signaling pathways that have been implicated in communication between gut bacteria and peripheral pain pathways. In addition to the wellcharacterized impact of the microbiota on the immune system, which in turn affects nociceptor excitability, bacteria can modulate visceral afferent pathways by effects on enterocytes, enteroendocrine cells, and the neurons themselves. Proteases produced by bacteria, or by host cells in response to bacteria, can increase or decrease the excitability of nociceptive dorsal root ganglion (DRG) neurons depending on the receptor activated. Short-chain fatty acids generated by colonic bacteria are involved in gut-brain communication, and intracolonic short-chain fatty acids have pronociceptive effects in rodents but may be antinociceptive in humans. Gut bacteria modulate the synthesis and release of enteroendocrine cell mediators, including serotonin and glucagon-like peptide-1, which activate extrinsic afferent neurons. Deciphering the complex interactions between visceral afferent neurons and the gut microbiota may lead to the development of improved probiotic therapies for visceral pain. [ABSTRACT FROM AUTHOR]

Published

2019

12. Deoxycholic acid activates colonic afferent nerves via 5-HT3 receptor-dependent and -independent mechanisms.

Author

Yang Yu, Villalobos-Hernandez, Egina C., Pradhananga, Sabindra, Baker, Corey C., Keating, Christopher, Grundy, David, Lomax, Alan E., and Reed, David E.

Subjects

DEOXYCHOLIC acid, AFFERENT pathways, DORSAL root ganglia, NERVES, NEURONS, BILE acids, VAGUS nerve

Abstract

Increased bile acids in the colon can evoke increased epithelial secretion resulting in diarrhea, but little is known about whether colonic bile acids contribute to abdominal pain. This study aimed to investigate the mechanisms underlying activation of colonic extrinsic afferent nerves and their neuronal cell bodies by a major secondary bile acid, deoxycholic acid (DCA). All experiments were performed on male C57BL/6 mice. Afferent sensitivity was evaluated using in vitro extracellular recordings from mesenteric nerves in the proximal colon (innervated by vagal and spinal afferents) and distal colon (spinal afferents only). Neuronal excitability of cultured dorsal root ganglion (DRG) and nodose ganglion (NG) neurons was examined with perforated patch clamp. Colonic 5-HT release was assessed using ELISA, and 5-HT immunoreactive enterochromaffin (EC) cells were quantified. Intraluminal DCA increased afferent nerve firing rate concentration dependently in both proximal and distal colon. This DCA-elicited increase was significantly inhibited by a 5-HT3 antagonist in the proximal colon but not in the distal colon, which may be in part due to lower 5-HT immunoreactive EC cell density and lower 5-HT levels in the distal colon following DCA stimulation. DCA increased the excitability of DRG neurons, whereas it decreased the excitability of NG neurons. DCA potentiated mechanosensitivity of high-threshold spinal afferents independent of 5-HT release. Together, this study suggests that DCA can excite colonic afferents via direct and indirect mechanisms but the predominant mechanism may differ between vagal and spinal afferents. Furthermore, DCA increased mechanosensitivity of high-threshold spinal afferents and may be a mechanism of visceral hypersensitivity.NEW & NOTEWORTHY Deoxycholic acid (DCA) directly excites spinal afferents and, to a lesser extent, indirectly via mucosal 5-HT release. DCA potentiates mechanosensitivity of high-threshold spinal afferents independent of 5-HT release. DCA increases vagal afferent firing in proximal colon via 5-HT release but directly inhibits the excitability of their cell bodies. [ABSTRACT FROM AUTHOR]

Published

2019

13. Protease-Mediated Suppression of DRG Neuron Excitability by Commensal Bacteria.

Author

Sessenwein, Jessica L., Baker, Corey C., Pradhananga, Sabindra, Maitland, Megan E., Petrof, Elaine O., Allen-Vercoe, Emma, Noordhof, Curtis, Reed, David E., Vanner, Stephen J., and Lomax, Alan E.

Subjects

GASTROINTESTINAL cancer, PHENOTYPES, GENETIC pleiotropy, GUT microbiome, IMMUNE response, APOPTOSIS

Abstract

Peripheral pain signaling reflects a balance of pro and anti-nociceptive influences; the contribution by the gastrointestinal (GI) microbiota to this balance has received little attention. Disorders such as inflammatory bowel disease and irritable bowel syndrome are associated with exaggerated visceral nociceptive actions that may involve altered microbial signaling, particularly given the evidence for bacterial dysbiosis. Thus, we tested whether a community of commensal GI bacteria derived from a healthy human donor (microbial ecosystem therapeutics; MET-1) can affect the excitability of male mouse dorsal root ganglion (DRG) neurons. MET-1 reduced the excitability of DRG neurons by significantly increasing rheobase, decreasing responses to capsaicin (2μM) and reducing action potential discharge from colonic afferent nerves. The increase in rheobase was accompanied by an increase in the amplitude of voltage-gated K+ currents. A cocktail of bacterial protease inhibitors abrogated the effect of MET-1 effects on DRG neuron rheobase. A serine protease inhibitor but not inhibitors of cysteine proteases, acid proteases, metalloproteases, or aminopeptidases abolished the effects of MET-1. The serine protease cathepsin G recapitulated the effects of MET-1 on DRG neurons. Inhibition of protease-activated receptor (PAR)-4, but not PAR-2, blocked the effects of MET-1. Furthermore, Faecalibacterium prausnitzii recapitulated the effects of MET-1 on excitability of DRG neurons. We conclude that serine proteases derived from commensal bacteria can directly impact the excitability of DRG neurons, through PAR-4 activation. The ability of microbiota-neuronal interactions to modulate afferent signaling suggests that therapies that induce or correct microbial dysbiosis may impact visceral pain. [ABSTRACT FROM AUTHOR]

Published

2017

14. Plasticity of neuroeffector transmission during bowel inflammation.

Author

Lomax, Alan E., Pradhananga, Sabindra, and Bertrand, Paul P.

Subjects

*MATERIAL plasticity, *INFLAMMATORY bowel diseases

Abstract

Altered gastrointestinal (GI) function contributes to the debilitating symptoms of inflammatory bowel diseases (IBD). Nerve circuits contained within the gut wall and outside of the gut play important roles in modulating motility, mucosal fluid transport, and blood flow. The structure and function of these neuronal populations change during IBD. Superimposed on this plasticity is a diminished responsiveness of effector cells -- smooth muscle cells, enterocytes, and vascular endothelial cells -- to neurotransmitters. The net result is a breakdown in the precisely orchestrated coordination of motility, fluid secretion, and GI blood flow required for health. In this review, we consider how inflammation-induced changes to the effector innervation of these tissues, and changes to the tissues themselves, contribute to defective GI function in models of IBD. We also explore the evidence that reversing neuronal plasticity is sufficient to normalize function during IBD. [ABSTRACT FROM AUTHOR]

Published

2017

15. Gene- and variant-specific efficacy of serum/glucocorticoid-regulated kinase 1 inhibition in long QT syndrome types 1 and 2.

Author

Giannetti F, Barbieri M, Shiti A, Casini S, Sager PT, Das S, Pradhananga S, Srinivasan D, Nimani S, Alerni N, Louradour J, Mura M, Gnecchi M, Brink P, Zehender M, Koren G, Zaza A, Crotti L, Wilde AAM, Schwartz PJ, Remme CA, Gepstein L, Sala L, and Odening KE

Subjects

Animals, Humans, Rabbits, Glucocorticoids, KCNQ1 Potassium Channel genetics, Arrhythmias, Cardiac genetics, Myocytes, Cardiac physiology, Action Potentials physiology, Long QT Syndrome drug therapy, Long QT Syndrome genetics, Induced Pluripotent Stem Cells

Abstract

Aims: Current long QT syndrome (LQTS) therapy, largely based on beta-blockade, does not prevent arrhythmias in all patients; therefore, novel therapies are warranted. Pharmacological inhibition of the serum/glucocorticoid-regulated kinase 1 (SGK1-Inh) has been shown to shorten action potential duration (APD) in LQTS type 3. We aimed to investigate whether SGK1-Inh could similarly shorten APD in LQTS types 1 and 2., Methods and Results: Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) and hiPSC-cardiac cell sheets (CCS) were obtained from LQT1 and LQT2 patients; CMs were isolated from transgenic LQT1, LQT2, and wild-type (WT) rabbits. Serum/glucocorticoid-regulated kinase 1 inhibition effects (300 nM-10 µM) on field potential durations (FPD) were investigated in hiPSC-CMs with multielectrode arrays; optical mapping was performed in LQT2 CCS. Whole-cell and perforated patch clamp recordings were performed in isolated LQT1, LQT2, and WT rabbit CMs to investigate SGK1-Inh (3 µM) effects on APD. In all LQT2 models across different species (hiPSC-CMs, hiPSC-CCS, and rabbit CMs) and independent of the disease-causing variant (KCNH2-p.A561V/p.A614V/p.G628S/IVS9-28A/G), SGK1-Inh dose-dependently shortened FPD/APD at 0.3-10 µM (by 20-32%/25-30%/44-45%). Importantly, in LQT2 rabbit CMs, 3 µM SGK1-Inh normalized APD to its WT value. A significant FPD shortening was observed in KCNQ1-p.R594Q hiPSC-CMs at 1/3/10 µM (by 19/26/35%) and in KCNQ1-p.A341V hiPSC-CMs at 10 µM (by 29%). No SGK1-Inh-induced FPD/APD shortening effect was observed in LQT1 KCNQ1-p.A341V hiPSC-CMs or KCNQ1-p.Y315S rabbit CMs at 0.3-3 µM., Conclusion: A robust SGK1-Inh-induced APD shortening was observed across different LQT2 models, species, and genetic variants but less consistently in LQT1 models. This suggests a genotype- and variant-specific beneficial effect of this novel therapeutic approach in LQTS., Competing Interests: Conflict of interest: None declared., (© The Author(s) 2023. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published

2023

16. Deoxycholic acid activates colonic afferent nerves via 5-HT 3 receptor-dependent and -independent mechanisms.

Author

Yu Y, Villalobos-Hernandez EC, Pradhananga S, Baker CC, Keating C, Grundy D, Lomax AE, and Reed DE

Subjects

Action Potentials physiology, Animals, Ganglia, Spinal drug effects, Ganglia, Spinal physiology, Male, Mice, Inbred C57BL, Neurons drug effects, Neurons, Afferent physiology, Nodose Ganglion drug effects, Peripheral Nervous System drug effects, Serotonin metabolism, Afferent Pathways drug effects, Colon drug effects, Deoxycholic Acid pharmacology, Receptors, Serotonin, 5-HT3 drug effects

Abstract

Increased bile acids in the colon can evoke increased epithelial secretion resulting in diarrhea, but little is known about whether colonic bile acids contribute to abdominal pain. This study aimed to investigate the mechanisms underlying activation of colonic extrinsic afferent nerves and their neuronal cell bodies by a major secondary bile acid, deoxycholic acid (DCA). All experiments were performed on male C57BL/6 mice. Afferent sensitivity was evaluated using in vitro extracellular recordings from mesenteric nerves in the proximal colon (innervated by vagal and spinal afferents) and distal colon (spinal afferents only). Neuronal excitability of cultured dorsal root ganglion (DRG) and nodose ganglion (NG) neurons was examined with perforated patch clamp. Colonic 5-HT release was assessed using ELISA, and 5-HT immunoreactive enterochromaffin (EC) cells were quantified. Intraluminal DCA increased afferent nerve firing rate concentration dependently in both proximal and distal colon. This DCA-elicited increase was significantly inhibited by a 5-HT 3 antagonist in the proximal colon but not in the distal colon, which may be in part due to lower 5-HT immunoreactive EC cell density and lower 5-HT levels in the distal colon following DCA stimulation. DCA increased the excitability of DRG neurons, whereas it decreased the excitability of NG neurons. DCA potentiated mechanosensitivity of high-threshold spinal afferents independent of 5-HT release. Together, this study suggests that DCA can excite colonic afferents via direct and indirect mechanisms but the predominant mechanism may differ between vagal and spinal afferents. Furthermore, DCA increased mechanosensitivity of high-threshold spinal afferents and may be a mechanism of visceral hypersensitivity. NEW & NOTEWORTHY Deoxycholic acid (DCA) directly excites spinal afferents and, to a lesser extent, indirectly via mucosal 5-HT release. DCA potentiates mechanosensitivity of high-threshold spinal afferents independent of 5-HT release. DCA increases vagal afferent firing in proximal colon via 5-HT release but directly inhibits the excitability of their cell bodies.

Published

2019