Your search keyword '"Ragnarsson, Lotten"' showing total 7 results

1. Changes in Potency and Subtype Selectivity of Bivalent Na V Toxins are Knot-Specific.

Author

Tran P, Tran HNT, McMahon KL, Deuis JR, Ragnarsson L, Norman A, Sharpe SJ, Payne RJ, Vetter I, and Schroeder CI

Subjects

Humans, Peptides pharmacology

Abstract

Disulfide-rich peptide toxins have long been studied for their ability to inhibit voltage-gated sodium channel subtype Na V 1.7, a validated target for the treatment of pain. In this study, we sought to combine the pore blocking activity of conotoxins with the gating modifier activity of spider toxins to design new bivalent inhibitors of Na V 1.7 with improved potency and selectivity. To do this, we created an array of heterodimeric toxins designed to target human Na V 1.7 by ligating a conotoxin to a spider toxin and assessed the potency and selectivity of the resulting bivalent toxins. A series of spider-derived gating modifier toxins (GpTx-1, ProTx-II, gHwTx-IV, JzTx-V, CcoTx-1, and Pn3a) and two pore-blocker μ-conotoxins, SxIIIC and KIIIA, were used for this study. We employed either enzymatic ligation with sortase A for C- to N-terminal ligation or click chemistry for N- to N-terminal ligation. The bivalent peptide resulting from ligation of ProTx-II and SxIIIC (Pro[LPATG 6 ]Sx) was shown to be the best combination as native ProTx-II potency at hNa V 1.7 was conserved following ligation. At hNa V 1.4, a synergistic effect between the pore blocker and gating modifier toxin moieties was observed, resulting in altered sodium channel subtype selectivity compared to the parent peptides. Further studies including mutant bivalent peptides and mutant hNa V 1.7 channels suggested that gating modifier toxins have a greater contribution to the potency of the bivalent peptides than pore blockers. This study delineated potential benefits and drawbacks of designing pharmacological hybrid peptides targeting hNa V 1.7.

Published

2023

2. Neurotoxic and cytotoxic peptides underlie the painful stings of the tree nettle Urtica ferox.

Author

Xie J, Robinson SD, Gilding EK, Jami S, Deuis JR, Rehm FBH, Yap K, Ragnarsson L, Chan LY, Hamilton BR, Harvey PJ, Craik DJ, Vetter I, and Durek T

Subjects

Humans, Pain, Patch-Clamp Techniques, Voltage-Gated Sodium Channels drug effects, Neurotoxins chemistry, Peptides chemistry, Peptides toxicity, Toxins, Biological chemistry, Urticaceae chemistry

Abstract

The stinging hairs of plants from the family Urticaceae inject compounds that inflict pain to deter herbivores. The sting of the New Zealand tree nettle (Urtica ferox) is among the most painful of these and can cause systemic symptoms that can even be life-threatening; however, the molecular species effecting this response have not been elucidated. Here we reveal that two classes of peptide toxin are responsible for the symptoms of U. ferox stings: Δ-Uf1a is a cytotoxic thionin that causes pain via disruption of cell membranes, while β/δ-Uf2a defines a new class of neurotoxin that causes pain and systemic symptoms via modulation of voltage-gated sodium (Na V ) channels. We demonstrate using whole-cell patch-clamp electrophysiology experiments that β/δ-Uf2a is a potent modulator of human Na V 1.5 (EC 50 : 55 nM), Na V 1.6 (EC 50 : 0.86 nM), and Na V 1.7 (EC 50 : 208 nM), where it shifts the activation threshold to more negative potentials and slows fast inactivation. We further found that both toxin classes are widespread among members of the Urticeae tribe within Urticaceae, suggesting that they are likely to be pain-causing agents underlying the stings of other Urtica species. Comparative analysis of nettles of Urtica, and the recently described pain-causing peptides from nettles of another genus, Dendrocnide, indicates that members of tribe Urticeae have developed a diverse arsenal of pain-causing peptides., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

3. Structure and allosteric activity of a single-disulfide conopeptide from Conus zonatus at human α3β4 and α7 nicotinic acetylcholine receptors.

Author

Mohan MK, Abraham N, R P R, Jayaseelan BF, Ragnarsson L, Lewis RJ, and Sarma SP

Subjects

Allosteric Regulation, Animals, COS Cells, Chlorocebus aethiops, HEK293 Cells, Humans, Structure-Activity Relationship, Conus Snail chemistry, Disulfides chemistry, Neurotoxins pharmacology, Peptides chemistry, Peptides pharmacology, Receptors, Nicotinic chemistry, Receptors, Nicotinic metabolism, alpha7 Nicotinic Acetylcholine Receptor chemistry, alpha7 Nicotinic Acetylcholine Receptor metabolism

Abstract

Conopeptides are neurotoxic peptides in the venom of marine cone snails and have broad therapeutic potential for managing pain and other conditions. Here, we identified the single-disulfide peptides Czon1107 and Cca1669 from the venoms of Conus zonatus and Conus caracteristicus , respectively. We observed that Czon1107 strongly inhibits the human α3β4 (IC 50 15.7 ± 3.0 μm) and α7 (IC 50 77.1 ± 0.05 μm) nicotinic acetylcholine receptor (nAChR) subtypes, but the activity of Cca1669 remains to be identified. Czon1107 acted at a site distinct from the orthosteric receptor site. Solution NMR experiments revealed that Czon1107 exists in equilibrium between conformational states that are the result of a key Ser 4 -Pro 5 cis-trans isomerization. Moreover, we found that the X-Pro amide bonds in the inter-cysteine loop are rigidly constrained to cis conformations. Structure-activity experiments of Czon1107 and its variants at positions P5 and P7 revealed that the conformation around the X-Pro bonds ( cis-trans ) plays an important role in receptor subtype selectivity. The cis conformation at the Cys 6 -Pro 7 species for similar, short bioactive peptides that allosterically modulate ligand-gated receptor function.Conus species for similar, short bioactive peptides that allosterically modulate ligand-gated receptor function., Competing Interests: The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Mohan et al.)

Published

2020

4. Conopeptide ρ-TIA defines a new allosteric site on the extracellular surface of the α1B-adrenoceptor.

Author

Ragnarsson L, Wang CI, Andersson Å, Fajarningsih D, Monks T, Brust A, Rosengren KJ, and Lewis RJ

Subjects

Adrenergic alpha-1 Receptor Antagonists metabolism, Allosteric Site, Amino Acid Sequence, Amino Acids metabolism, Animals, Computer Simulation, Cricetinae, Humans, Models, Molecular, Molecular Sequence Data, Mutation, Nuclear Magnetic Resonance, Biomolecular, Peptides metabolism, Protein Structure, Secondary, Protein Structure, Tertiary, Rats, Receptors, Adrenergic, alpha-1 genetics, Receptors, Adrenergic, alpha-1 metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Static Electricity, Structure-Activity Relationship, Turkeys, Adrenergic alpha-1 Receptor Antagonists chemistry, Amino Acids chemistry, Peptides chemistry, Receptors, Adrenergic, alpha-1 chemistry

Abstract

The G protein-coupled receptor (GPCR) superfamily is an important drug target that includes over 1000 membrane receptors that functionally couple extracellular stimuli to intracellular effectors. Despite the potential of extracellular surface (ECS) residues in GPCRs to interact with subtype-specific allosteric modulators, few ECS pharmacophores for class A receptors have been identified. Using the turkey β(1)-adrenergic receptor crystal structure, we modeled the α(1B)-adrenoceptor (α(1B)-AR) to help identify the allosteric site for ρ-conopeptide TIA, an inverse agonist at this receptor. Combining mutational radioligand binding and inositol 1-phosphate signaling studies, together with molecular docking simulations using a refined NMR structure of ρ-TIA, we identified 14 residues on the ECS of the α(1B)-AR that influenced ρ-TIA binding. Double mutant cycle analysis and docking confirmed that ρ-TIA binding was dominated by a salt bridge and cation-π between Arg-4-ρ-TIA and Asp-327 and Phe-330, respectively, and a T-stacking-π interaction between Trp-3-ρ-TIA and Phe-330. Water-bridging hydrogen bonds between Asn-2-ρ-TIA and Val-197, Trp-3-ρ-TIA and Ser-318, and the positively charged N terminus and Glu-186, were also identified. These interactions reveal that peptide binding to the ECS on transmembrane helix 6 (TMH6) and TMH7 at the base of extracellular loop 3 (ECL3) is sufficient to allosterically inhibit agonist signaling at a GPCR. The ligand-accessible ECS residues identified provide the first view of an allosteric inhibitor pharmacophore for α(1)-adrenoceptors and mechanistic insight and a new set of structural constraints for the design of allosteric antagonists at related GPCRs.

Published

2013

5. Pain-causing stinging nettle toxins target TMEM233 to modulate NaV1.7 function.

Author

Jami, Sina, Deuis, Jennifer R., Klasfauseweh, Tabea, Cheng, Xiaoyang, Kurdyukov, Sergey, Chung, Felicity, Okorokov, Andrei L., Li, Shengnan, Zhang, Jiangtao, Cristofori-Armstrong, Ben, Israel, Mathilde R., Ju, Robert J., Robinson, Samuel D., Zhao, Peng, Ragnarsson, Lotten, Andersson, Åsa, Tran, Poanna, Schendel, Vanessa, McMahon, Kirsten L., and Tran, Hue N. T.

Subjects

SODIUM channels, STINGING nettle, TOXINS, MEMBRANE proteins, PEPTIDES, SENSORY neurons

Abstract

Voltage-gated sodium (NaV) channels are critical regulators of neuronal excitability and are targeted by many toxins that directly interact with the pore-forming α subunit, typically via extracellular loops of the voltage-sensing domains, or residues forming part of the pore domain. Excelsatoxin A (ExTxA), a pain-causing knottin peptide from the Australian stinging tree Dendrocnide excelsa, is the first reported plant-derived NaV channel modulating peptide toxin. Here we show that TMEM233, a member of the dispanin family of transmembrane proteins expressed in sensory neurons, is essential for pharmacological activity of ExTxA at NaV channels, and that co-expression of TMEM233 modulates the gating properties of NaV1.7. These findings identify TMEM233 as a previously unknown NaV1.7-interacting protein, position TMEM233 and the dispanins as accessory proteins that are indispensable for toxin-mediated effects on NaV channel gating, and provide important insights into the function of NaV channels in sensory neurons. Voltage-gated sodium channels function as multiprotein signaling complexes. Here, authors show that the dispanin TMEM233 is essential for activity of stinging nettle toxins and that co-expression of TMEM233 modulates the gating properties of NaV1.7. [ABSTRACT FROM AUTHOR]

Published

2023

6. The Tarantula Venom Peptide Eo1a Binds to the Domain II S3-S4 Extracellular Loop of Voltage-Gated Sodium Channel NaV1.8 to Enhance Activation.

Author

Deuis, Jennifer R., Ragnarsson, Lotten, Robinson, Samuel D., Dekan, Zoltan, Chan, Lerena, Jin, Ai-Hua, Tran, Poanna, McMahon, Kirsten L., Li, Shengnan, Wood, John N., Cox, James J., King, Glenn F., Herzig, Volker, and Vetter, Irina

Subjects

SODIUM channels, PEPTIDES, VENOM, TARANTULAS, CONUS, BINDING sites

Abstract

Venoms from cone snails and arachnids are a rich source of peptide modulators of voltage-gated sodium (NaV) channels, however relatively few venom-derived peptides with activity at the mammalian NaV1.8 subtype have been isolated. Here, we describe the discovery and functional characterisation of β-theraphotoxin-Eo1a, a peptide from the venom of the Tanzanian black and olive baboon tarantula Encyocratella olivacea that modulates NaV1.8. Eo1a is a 37-residue peptide that increases NaV1.8 peak current (EC50 894 ± 146 nM) and causes a large hyperpolarising shift in both the voltage-dependence of activation (ΔV50–20.5 ± 1.2 mV) and steady-state fast inactivation (ΔV50–15.5 ± 1.8 mV). At a concentration of 10 μM, Eo1a has varying effects on the peak current and channel gating of NaV1.1–NaV1.7, although its activity is most pronounced at NaV1.8. Investigations into the binding site of Eo1a using NaV1.7/NaV1.8 chimeras revealed a critical contribution of the DII S3-S4 extracellular loop of NaV1.8 to toxin activity. Results from this work may form the basis for future studies that lead to the rational design of spider venom-derived peptides with improved potency and selectivity at NaV1.8. [ABSTRACT FROM AUTHOR]

Published

2022

7. Neurotoxic and cytotoxic peptides underlie the painful stings of the tree nettle Urtica ferox.

Author

Jing Xie, Robinson, Samuel D., Gilding, Edward K., Jami, Sina, Deuis, Jennifer R., Rehm, Fabian B. H., Yap, Kuok, Ragnarsson, Lotten, Lai Yue Chan, Hamilton, Brett R., Harvey, Peta J., Craik, David J., Vetter, Irina, and Durek, Thomas

Subjects

*STINGING nettle, *PEPTIDES, *SODIUM channels, *ACTIVATION energy, *CELL membranes, *TOXINS

Abstract

The stinging hairs of plants from the family Urticaceae inject compounds that inflict pain to deter herbivores. The sting of the New Zealand tree nettle (Urtica ferox) is among the most painful of these and can cause systemic symptoms that can even be life-threatening; however, the molecular species effecting this response have not been elucidated. Here we reveal that two classes of peptide toxin are responsible for the symptoms of U. ferox stings: Δ-Uf1a is a cytotoxic thionin that causes pain via disruption of cell membranes, while β/δ-Uf2a defines a new class of neurotoxin that causes pain and systemic symptoms via modulation of voltage-gated sodium (NaV) channels. We demonstrate using whole-cell patch-clamp electrophysiology experiments that β/δ-Uf2a is a potent modulator of human NaV1.5 (EC50: 55 nM), NaV1.6 (EC50: 0.86 nM), and NaV1.7 (EC50: 208 nM), where it shifts the activation threshold to more negative potentials and slows fast inactivation. We further found that both toxin classes are widespread among members of the Urticeae tribe within Urticaceae, suggesting that they are likely to be pain-causing agents underlying the stings of other Urtica species. Comparative analysis of nettles of Urtica, and the recently described pain-causing peptides from nettles of another genus, Dendrocnide, indicates that members of tribe Urticeae have developed a diverse arsenal of pain-causing peptides. [ABSTRACT FROM AUTHOR]

Published

2022