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Literature DB >> 29073476

CFTR potentiators: from bench to bedside.

Kang-Yang Jih¹, Wen-Ying Lin², Yoshiro Sohma³, Tzyh-Chang Hwang⁴.

Abstract

One major breakthrough in cystic fibrosis research in the past decade is the development of drugs that target the root cause of the disease-dysfunctional CFTR protein. One of the compounds, Ivacaftor or Kalydeco, which has been approved for clinical use since 2012, acts by promoting the gating function of CFTR. Our recent studies have led to a gating model that features energetic coupling between nucleotide-binding domain (NBD) dimerization and gate opening/closing in CFTR's transmembrane domains (TMDs). Based on this model, we showed that ATP analogs can enhance CFTR gating by facilitating NBD dimerization, whereas Ivacaftor works by stabilizing the open channel conformation of the TMDs. This latter idea also explains the near omnipotence of Ivacaftor. Furthermore, this model identifies multiple approaches to synergistically boost the open probability of CFTR by influencing distinct molecular events that control gating conformational changes. Published by Elsevier Ltd.

Entities: Chemical Disease Gene Mutation Species

Mesh：

Substances：

Year: 2017 PMID： 29073476 PMCID： PMC5723237 DOI： 10.1016/j.coph.2017.09.015

Source DB: PubMed Journal: Curr Opin Pharmacol ISSN： 1471-4892 Impact factor: 5.547

58 in total

1. Chloride conductance expressed by delta F508 and other mutant CFTRs in Xenopus oocytes.

Authors: M L Drumm; D J Wilkinson; L S Smit; R T Worrell; T V Strong; R A Frizzell; D C Dawson; F S Collins
Journal: Science Date: 1991-12-20 Impact factor: 47.728

2. Ivacaftor in subjects with cystic fibrosis who are homozygous for the F508del-CFTR mutation.

Authors: Patrick A Flume; Theodore G Liou; Drucy S Borowitz; Haihong Li; Karl Yen; Claudia L Ordoñez; David E Geller
Journal: Chest Date: 2012-09 Impact factor: 9.410

3. Curcumin and genistein additively potentiate G551D-CFTR.

Authors: Ying-Chun Yu; Haruna Miki; Yumi Nakamura; Akiko Hanyuda; Yohei Matsuzaki; Yoichiro Abe; Masato Yasui; Kazuhiko Tanaka; Tzyh-Chang Hwang; Silvia G Bompadre; Yoshiro Sohma
Journal: J Cyst Fibros Date: 2011-03-26 Impact factor: 5.482

4. Identification of the cystic fibrosis gene: cloning and characterization of complementary DNA.

Authors: J R Riordan; J M Rommens; B Kerem; N Alon; R Rozmahel; Z Grzelczak; J Zielenski; S Lok; N Plavsic; J L Chou
Journal: Science Date: 1989-09-08 Impact factor: 47.728

5. High affinity ATP/ADP analogues as new tools for studying CFTR gating.

Authors: Zhen Zhou; Xiaohui Wang; Min Li; Yoshiro Sohma; Xiaoqin Zou; Tzyh-Chang Hwang
Journal: J Physiol Date: 2005-10-13 Impact factor: 5.182

6. Defective function of the cystic fibrosis-causing missense mutation G551D is recovered by genistein.

Authors: B Illek; L Zhang; N C Lewis; R B Moss; J Y Dong; H Fischer
Journal: Am J Physiol Date: 1999-10

7. Curcumin, a major constituent of turmeric, corrects cystic fibrosis defects.

Authors: Marie E Egan; Marilyn Pearson; Scott A Weiner; Vanathy Rajendran; Daniel Rubin; Judith Glöckner-Pagel; Susan Canny; Kai Du; Gergely L Lukacs; Michael J Caplan
Journal: Science Date: 2004-04-23 Impact factor: 47.728

8. Cystic fibrosis transmembrane conductance regulator (CFTR) potentiator VX-770 (ivacaftor) opens the defective channel gate of mutant CFTR in a phosphorylation-dependent but ATP-independent manner.

Authors: Paul D W Eckford; Canhui Li; Mohabir Ramjeesingh; Christine E Bear
Journal: J Biol Chem Date: 2012-08-31 Impact factor: 5.157

9. On the mechanism of gating defects caused by the R117H mutation in cystic fibrosis transmembrane conductance regulator.

Authors: Ying-Chun Yu; Yoshiro Sohma; Tzyh-Chang Hwang
Journal: J Physiol Date: 2016-03-23 Impact factor: 5.182

10. A single amino acid substitution in CFTR converts ATP to an inhibitory ligand.

Authors: Wen-Ying Lin; Kang-Yang Jih; Tzyh-Chang Hwang
Journal: J Gen Physiol Date: 2014-09-15 Impact factor: 4.086

14 in total

1. Molecular Dynamics and Theratyping in Airway and Gut Organoids Reveal R352Q-CFTR Conductance Defect.

Authors: Sharon L Wong; Nikhil T Awatade; Miro A Astore; Katelin M Allan; Michael J Carnell; Iveta Slapetova; Po-Chia Chen; Jeffry Setiadi; Elvis Pandzic; Laura K Fawcett; John R Widger; Renee M Whan; Renate Griffith; Chee Y Ooi; Serdar Kuyucak; Adam Jaffe; Shafagh A Waters
Journal: Am J Respir Cell Mol Biol Date: 2022-07 Impact factor: 7.748

Review 2. Structural mechanisms of CFTR function and dysfunction.

Authors: Tzyh-Chang Hwang; Jiunn-Tyng Yeh; Jingyao Zhang; Ying-Chun Yu; Han-I Yeh; Samantha Destefano
Journal: J Gen Physiol Date: 2018-03-26 Impact factor: 4.086

3. Residual function of cystic fibrosis mutants predicts response to small molecule CFTR modulators.

Authors: Sangwoo T Han; Andras Rab; Matthew J Pellicore; Emily F Davis; Allison F McCague; Taylor A Evans; Anya T Joynt; Zhongzhou Lu; Zhiwei Cai; Karen S Raraigh; Jeong S Hong; David N Sheppard; Eric J Sorscher; Garry R Cutting
Journal: JCI Insight Date: 2018-07-26

4. Differential thermostability and response to cystic fibrosis transmembrane conductance regulator potentiators of human and mouse F508del-CFTR.

Authors: Samuel J Bose; Marcel J C Bijvelds; Yiting Wang; Jia Liu; Zhiwei Cai; Alice G M Bot; Hugo R de Jonge; David N Sheppard
Journal: Am J Physiol Lung Cell Mol Physiol Date: 2019-04-10 Impact factor: 5.464

5. Identifying the molecular target sites for CFTR potentiators GLPG1837 and VX-770.

Authors: Han-I Yeh; Liming Qiu; Yoshiro Sohma; Katja Conrath; Xiaoqin Zou; Tzyh-Chang Hwang
Journal: J Gen Physiol Date: 2019-06-04 Impact factor: 4.086

Review 6. Cystic fibrosis transmembrane conductance regulator (CFTR): Making an ion channel out of an active transporter structure.

Authors: Paul Linsdell
Journal: Channels (Austin) Date: 2018 Impact factor: 2.581