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Your search keyword '"Tran, Hue N. T."' showing total 11 results
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11 results on '"Tran, Hue N. T."'

1. 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., Tran, Hue N. T., Chin, Yanni K.-Y., Zhu, Yifei, Liu, Junyu, Crawford, Theo, Purushothamvasan, Saipriyaa, Habib, Abdella M., Andersson, David A., Rash, Lachlan D., Wood, John N., Zhao, Jing, Stehbens, Samantha J., Mobli, Mehdi, Leffler, Andreas, Jiang, Daohua, Cox, James J., Waxman, Stephen G., Dib-Hajj, Sulayman D., Neely, G. Gregory, Durek, Thomas, and Vetter, Irina

Published
2023
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5. On the Utility of Chemical Strategies to Improve Peptide Gut Stability

Author

Kremsmayr, Thomas, Aljnabi, Aws, Blanco-Canosa, Juan B., Tran, Hue N. T., Emidio, Nayara Braga, Muttenthaler, Markus, and European Commission

Subjects
Scaffolds, Degradation, Chemical Strategies, Cyclization, Monomers, Drug Discovery, Molecular Medicine, Cyclotides, Peptides and proteins, Amino Acid Sequence, Peptides, Stability
Abstract

Inherent susceptibility of peptides to enzymatic degradation in the gastrointestinal tract is a key bottleneck in oral peptide drug development. Here, we present a systematic analysis of (i) the gut stability of disulfide-rich peptide scaffolds, orally administered peptide therapeutics, and well-known neuropeptides and (ii) medicinal chemistry strategies to improve peptide gut stability. Among a broad range of studied peptides, cyclotides were the only scaffold class to resist gastrointestinal degradation, even when grafted with non-native sequences. Backbone cyclization, a frequently applied strategy, failed to improve stability in intestinal fluid, but several site-specific alterations proved efficient. This work furthermore highlights the importance of standardized gut stability test conditions and suggests defined protocols to facilitate cross-study comparison. Together, our results provide a comparative overview and framework for the chemical engineering of gut-stable peptides, which should be valuable for the development of orally administered peptide therapeutics and molecular probes targeting receptors within the gastrointestinal tract., We thank Marina Kujundzic and Johanna Nemec for their help in collecting some of the stability data and peptide synthesis. We are grateful to the laboratory of Prof. David Craik (The University of Queensland) for providing Vc1.1 and cVc1.1. We thank Prof. Christian F.W. Becker (Institute of Biological Chemistry, University of Vienna) for his support of this work. We also thank Dr. Martin Zehl and the Mass Spectrometry Centre at the University of Vienna (a member of Vienna Life-Science Instruments) for assistance with HR-MS analysis. We are grateful to the NIMH PDSP (National Institute of Mental Health’s Psychoactive Drug Screening Program, Contract # HHSN-271-2018-00023-C), which is directed by Bryan L. Roth at the University of North Carolina at Chapel Hill and Project Officer Jamie Driscoll at NIMH, Bethesda MD, USA, for providing agonist functional activity data of OT variants. This research was supported by the European Research Council under the European Union’s Horizon 2020 research and innovation program (grant agreements no. 714366), by the Australian Research Council Discovery Project (DP190101667) and by the Vienna Science and Technology Fund (WWTF) through project LS18-053. T. Kremsmayr was supported by the Austrian Academy of Sciences through a DOC Fellowship (25139). J.B.B.-C. thanks the Spanish Ministry of Science and Innovation (RTI2018-096323-B-100).

Published
2022

6. On the Utility of Chemical Strategies to Improve Peptide Gut Stability

Author

European Commission, 0000-0003-0630-2555, 0000-0001-5738-6993, 0000-0001-5181-1899, 0000-0001-7835-9636, 0000-0003-1996-4646, Kremsmayr, Thomas, Aljnabi, Aws, Blanco-Canosa, Juan Bautista, Tran, Hue N T, Emidio, Nayara Braga, Muttenthaler, Markus, European Commission, 0000-0003-0630-2555, 0000-0001-5738-6993, 0000-0001-5181-1899, 0000-0001-7835-9636, 0000-0003-1996-4646, Kremsmayr, Thomas, Aljnabi, Aws, Blanco-Canosa, Juan Bautista, Tran, Hue N T, Emidio, Nayara Braga, and Muttenthaler, Markus

Abstract

Inherent susceptibility of peptides to enzymatic degradation in the gastrointestinal tract is a key bottleneck in oral peptide drug development. Here, we present a systematic analysis of (i) the gut stability of disulfide-rich peptide scaffolds, orally administered peptide therapeutics, and well-known neuropeptides and (ii) medicinal chemistry strategies to improve peptide gut stability. Among a broad range of studied peptides, cyclotides were the only scaffold class to resist gastrointestinal degradation, even when grafted with non-native sequences. Backbone cyclization, a frequently applied strategy, failed to improve stability in intestinal fluid, but several site-specific alterations proved efficient. This work furthermore highlights the importance of standardized gut stability test conditions and suggests defined protocols to facilitate cross-study comparison. Together, our results provide a comparative overview and framework for the chemical engineering of gut-stable peptides, which should be valuable for the development of orally administered peptide therapeutics and molecular probes targeting receptors within the gastrointestinal tract.

Published
2022

7. 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
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8. Changes in Potency and Subtype Selectivity of Bivalent NaVToxins are Knot-Specific

Author

Tran, Poanna, Tran, Hue N. T., McMahon, Kirsten L., Deuis, Jennifer R., Ragnarsson, Lotten, Norman, Alexander, Sharpe, Simon J., Payne, Richard J., Vetter, Irina, and Schroeder, Christina I.

Abstract

Disulfide-rich peptide toxins have long been studied for their ability to inhibit voltage-gated sodium channel subtype NaV1.7, 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 NaV1.7 with improved potency and selectivity. To do this, we created an array of heterodimeric toxins designed to target human NaV1.7 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[LPATG6]Sx) was shown to be the best combination as native ProTx-II potency at hNaV1.7 was conserved following ligation. At hNaV1.4, 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 hNaV1.7 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 hNaV1.7.

Published
2023
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10. Structural and functional insights into the inhibition of human voltage-gated sodium channels by μ-conotoxin KIIIA disulfide isomers.

Author

Tran, Hue N. T., McMahon, Kirsten L., Deuis, Jennifer R., Vetter, Irina, and Schroeder, Christina I.

Subjects
*CONOTOXINS, *DISULFIDES, *SODIUM channels, *ISOMERS, *CONUS, *MOLECULAR structure, *MOLECULAR docking
Abstract

μ-Conotoxins are components of cone snail venom, wellknown for their analgesic activity through potent inhibition of voltage-gated sodium channel (NaV) subtypes, including NaV1.7. These small, disulfide-rich peptides are typically stabilized by three disulfide bonds arranged in a 'native' CysICysIV, CysII-CysV, CysIII-CysVI pattern of disulfide connectivity. However, μ-conotoxin KIIIA, the smallest and most studied μ-conotoxin with inhibitory activity at NaV1.7, forms two distinct disulfide bond isomers during thermodynamic oxidative folding, including Isomer 1 (CysI-CysV, CysII-CysIV, CysIII-CysVI) and Isomer 2 (CysI-CysVI, CysII-CysIV, CysIIICysV), but not the native μ-conotoxin arrangement. To date, there has been no study on the structure and activity of KIIIA comprising the native μ-conotoxin disulfide bond arrangement. Here, we evaluated the synthesis, potency, sodium channel subtype selectivity, and 3D structure of the three isomers of KIIIA. Using a regioselective disulfide bond-forming strategy, we synthetically produced the three μ-conotoxin KIIIA isomers displaying distinct bioactivity and NaV subtype selectivity across human NaV channel subtypes 1.2, 1.4, and 1.7. We show that Isomer 1 inhibits NaV subtypes with a rank order of potency of NaV1.4 > 1.2 > 1.7 and Isomer 2 in the order of NaV1.4≈1.2 > 1.7, while the native isomer inhibited NaV1.4 > 1.7≈1.2. The three KIIIA isomers were further evaluated by NMR solution structure analysis and molecular docking with hNaV1.2. Our study highlights the importance of investigating alternate disulfide isomers, as disulfide connectivity affects not only the overall structure of the peptides but also the potency and subtype selectivity of μ-conotoxins targeting therapeutically relevant NaV subtypes. [ABSTRACT FROM AUTHOR]

Published
2022
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11. 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
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