CFTR potentiators: from bench to bedside

Kang Yang Jih; Wen Ying Lin; Yoshiro Sohma; Tzyh Chang Hwang

doi:10.1016/j.coph.2017.09.015

CFTR potentiators: from bench to bedside

Kang Yang Jih, Wen Ying Lin, Yoshiro Sohma, Tzyh Chang Hwang

Institute of Pharmacology

Research output: Contribution to journal › Review article › peer-review

30 Scopus citations

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 an energetic coupling between NBD dimerization and gate opening/closing in CFTR's 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 marks multiple approaches to synergistically boost the open probability of CFTR by influencing distinct molecular events that control gating conformational changes.

Original language	English
Pages (from-to)	98-104
Number of pages	7
Journal	Current Opinion in Pharmacology
Volume	34
DOIs	https://doi.org/10.1016/j.coph.2017.09.015
State	Published - Jun 2017

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10.1016/j.coph.2017.09.015

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title = "CFTR potentiators: from bench to bedside",

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 an energetic coupling between NBD dimerization and gate opening/closing in CFTR's 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 marks multiple approaches to synergistically boost the open probability of CFTR by influencing distinct molecular events that control gating conformational changes.",

author = "Jih, {Kang Yang} and Lin, {Wen Ying} and Yoshiro Sohma and Hwang, {Tzyh Chang}",

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doi = "10.1016/j.coph.2017.09.015",

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T1 - CFTR potentiators

T2 - from bench to bedside

AU - Jih, Kang Yang

AU - Lin, Wen Ying

AU - Sohma, Yoshiro

AU - Hwang, Tzyh Chang

PY - 2017/6

Y1 - 2017/6

N2 - 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 an energetic coupling between NBD dimerization and gate opening/closing in CFTR's 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 marks multiple approaches to synergistically boost the open probability of CFTR by influencing distinct molecular events that control gating conformational changes.

AB - 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 an energetic coupling between NBD dimerization and gate opening/closing in CFTR's 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 marks multiple approaches to synergistically boost the open probability of CFTR by influencing distinct molecular events that control gating conformational changes.

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U2 - 10.1016/j.coph.2017.09.015

DO - 10.1016/j.coph.2017.09.015

M3 - Review article

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SN - 1471-4892

VL - 34

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JO - Current Opinion in Pharmacology

JF - Current Opinion in Pharmacology

ER -

CFTR potentiators: from bench to bedside

Abstract

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