The implications of CFTR structural studies for cystic fibrosis drug development

被引:12
|
作者
Callebaut, Isabelle [1 ]
Hoffmann, Brice [1 ]
Mornon, Jean-Paul [1 ]
机构
[1] Univ Pierre & Marie Curie Paris 6, MNHN IRD IUC, Sorbonne Univ, CNRS UMR7590, Paris, France
来源
CURRENT OPINION IN PHARMACOLOGY | 2017年 / 34卷
关键词
TRANSMEMBRANE CONDUCTANCE REGULATOR; NUCLEOTIDE-BINDING DOMAINS; X-RAY-SCATTERING; CONFORMATIONAL-CHANGES; INTERMOLECULAR INTERACTIONS; MOLECULAR-DYNAMICS; CHLORIDE CHANNEL; CORRECTOR VX-809; R REGION; NBD1;
D O I
10.1016/j.coph.2017.09.006
中图分类号
R9 [药学];
学科分类号
1007 ;
摘要
Development of Cystic Fibrosis Transmembrane conductance Regulator (CFTR) modulators, targeting the root cause of cystic fibrosis (CF), represents a challenge in the era of personalized medicine, as CFTR mutations lead to a variety of phenotypes, which likely require different, specific treatments. CF drug development is also complicated by the need to preserve the right balance between stability and flexibility, required for optimal function of the CFTR protein. In this review, we highlight how structural data can be exploited in this context to understand the molecular mechanisms of disease-associated mutations, to characterize the mechanisms of action of known modulators and to rationalize the search for novel, specific compounds.
引用
收藏
页码:112 / 118
页数:7
相关论文
共 50 条
  • [1] Cystic fibrosis and CFTR
    R. Greger
    R. Schreiber
    M. Mall
    A. Wissner
    A. Hopf
    M. Briel
    M. Bleich
    R. Warth
    K. Kunzelmann
    [J]. Pflügers Archiv, 2001, 443 (Suppl 1): : S3 - S7
  • [2] Cystic fibrosis and CFTR
    Greger, R
    Schreiber, R
    Mall, M
    Wissner, A
    Hopf, A
    Briel, M
    Bleich, M
    Warth, R
    Kunzelmann, K
    [J]. PFLUGERS ARCHIV-EUROPEAN JOURNAL OF PHYSIOLOGY, 2001, 443 : S3 - S7
  • [3] Drug development for cystic fibrosis
    Sanders, Don B.
    Chmiel, James F.
    [J]. PEDIATRIC PULMONOLOGY, 2021, 56 : S10 - S22
  • [4] DRUG REPURPOSING FOR CYSTIC FIBROSIS SUBJECTS WITH RARE CFTR MUTATIONS
    Hagemeijer, M. C.
    de Poel, E.
    van Mourik, P.
    Vonk, A. M.
    Oppelaar, H.
    de Winter-de Groot, K. M.
    Heida-Michel, S.
    Geerdink, M.
    van der Ent, C. K.
    Beekman, J. M.
    [J]. PEDIATRIC PULMONOLOGY, 2017, 52 : S316 - S317
  • [5] The effect of CFTR modulators on structural lung disease in cystic fibrosis
    Mok, L. Clara
    Garcia-Uceda, Antonio
    Cooper, Matthew N.
    Kemner Van De Corput, Mariette
    De Bruijne, Marleen
    Feyaerts, Nathalie
    Rosenow, Tim
    De Boeck, Kris
    Stick, Stephen
    Tiddens, Harm A. W. M.
    [J]. FRONTIERS IN PHARMACOLOGY, 2023, 14
  • [6] THE EFFECT OF CFTR MODULATORS ON STRUCTURAL LUNG DISEASE IN CYSTIC FIBROSIS
    Mok, L.
    Juarez, Garcia-Uceda A.
    Andrinopoulou, E.
    Kemner-Van de Corput, M.
    De Boeck, C.
    Rosenow, T.
    Stick, S.
    Tiddens, H.
    [J]. RESPIROLOGY, 2019, 24 : 136 - 136
  • [7] CFTR and disease: implications for drug development
    Super, M
    [J]. LANCET, 2000, 355 (9218): : 1840 - 1842
  • [8] Modelling studies of the cystic fibrosis transmembrane conductance regulator (CFTR)
    Ivetac, Anthony
    Campbell, Jeff
    Dawson, David C.
    Sansom, Mark S.
    [J]. BIOPHYSICAL JOURNAL, 2007, : 392A - 392A
  • [9] CFTR gene and cystic fibrosis
    Gaskin, KJ
    [J]. JOURNAL OF GASTROENTEROLOGY AND HEPATOLOGY, 2004, 19 (02) : 228 - 228
  • [10] CFTR structure and cystic fibrosis
    Cant, Natasha
    Pollock, Naomi
    Ford, Robert C.
    [J]. INTERNATIONAL JOURNAL OF BIOCHEMISTRY & CELL BIOLOGY, 2014, 52 : 15 - 25
12345