Patient perspectives following initiation of elexacaftor-tezacaftor-ivacaftor in people with cystic fibrosis and advanced lung disease.

BACKGOUND: Elexacaftor-tezacaftor-ivacaftor partially restores cystic fibrosis transmembrane conductance regulator function, and has been shown to induce significant clinical improvement in patients with at least one Phe508del allele. Yet little data exist on patient perspectives following elexacaftor-tezacaftor-ivacaftor initiation. METHODS: A mixed methods study was conducted using an online 13-item questionnaire (including 9 closed questions and 4 open questions), submitted from July 10th to August 21th 2020 to French patients aged 12 years and older with advanced CF who were treated with elexacaftor-tezacaftor-ivacaftor. Their responses were summarized as numbers (%), and free-text items were analysed using a grounded theory approach. RESULTS: Of 245 patients who started elexacaftor-tezacaftor-ivacaftor in France, 101 (41%) participated. Median [IQR] age was 35 [28-41] years and duration of elexacaftor-tezacaftor-ivacaftor treatment was 4.3 [3.0-5.6] months. Patients generally reported a rapid impact on respiratory symptoms, sleep quality, general well-being and physical self-esteem, and a reduction in overall treatment burden. The majority of patients contrasted treatment burden, symptom severity, depression and a closed future marked by death or transplantation before elexacaftor-tezacaftor-ivacaftor, to renewed and unexpected physical strength, leading to greater self-confidence, autonomy and long-term planning, after treatment initiation. A small number of patients expressed concerns, mainly regarding changes in body representation and/or the fear of becoming dependent on the treatment. CONCLUSION: After initiation of elexacaftor-tezacaftor-ivacaftor, CF patients with advanced disease reported rapid and positive physical, psychological and social effects, which translated into improved quality of life and the formulation of new life goals.

Defining structural requirements for neuropeptide Y receptors using truncated and conformationally restricted analogues.

To further elucidate the minimum bioactive conformation of neuropeptide Y (NPY), a series of truncated and conformationally constrained analogues has been prepared. The synthesis and purification of these peptides was achieved using routine laboratory strategies and techniques. Parent molecules consisted of the native NPY N-terminal 1-4 and C-terminal 25-36 segments, having the residue 5-24 core replaced by either a single flexible omega-aminoalkanoic acid, or a more rigid Pro-Gly or Pro-DAla sequence which was expected to constrain a putative turn, and allow the N- and C-termini to align. Cross-linking between residues 2 and 27 through lactamization using side-chain length and chirality suggested by computer simulations, resulted in cyclo-(2/27)-des-AA7-24[Glu2,Gly6,DDpr27]NPY that exhibited very high affinity (Ki = 0.3 versus 0.3 nM for NPY) for the Y2 receptor using SK-N-BE2 human neuroblastoma cells, yet very low affinity for the Y1 receptor using SK-N-MC human neuroblastoma cells (Ki = 130 versus 2.0 nM for NPY). The added constraint resulting from bridging in this analogue as well as in others suggested that the combination of the deletion of residues 5-24 and the introduction of an internal ring produced exclusive selectivity for the Y2 receptor with little or no loss of affinity. The tolerance of structural recognition was further demonstrated as a second ring was introduced which was expected to constrain the amphiphilic alpha-helix, resulting in the full Y2 agonist dicyclo (2/27,28/32)-des-AA7-24 [Glu2,32,DAla6,DDpr27,Lys28]NPY. Improvement of Y1 binding activity was achieved only by including more residues (des-AA10-17) in the central PP-fold region, while allowing limited flexibility of the termini. Although the length of the bridge seemed to have little effect on binding potency, changes in the location of and chirality at the bridgehead resulted in analogues with different binding affinities. Combination of optimum structural modifications resulted in cyclo-(7/21)-des-AA10-18[Cys7,21]NPY, an analogue shortened by 25% but retaining comparable binding properties to that of native NPY at Y1 and Y2 receptor types (Ki = 5.1 and 1.3 nM, respectively).

Truncated, branched, and/or cyclic analogues of neuropeptide Y: importance of the pancreatic peptide fold in the design of specific Y2 receptor ligands.

Truncated, branched, and/or cyclic neuropeptide Y (NPY) analogues were tested for their ability to bind to the neuroblastoma cells, SK-N-MC (Y1 receptor) and SK-N-BE(2) (Y2 receptor). The design of such analogues was inspired by models of NPY based on the crystal structure of avian pancreatic polypeptide. The minimum length of the backbone was investigated using the following truncated analogues [binding affinity (nM) for Y1 and Y2 receptor subtypes respectively are given in parentheses]: des-AA10-17[D-Ala9]NPY (100, 0.9), des-AA7-23[D-Ala6]NPY (> 1000, 1.2), des-AA4-26[D-Ala3]NPY (> 1000, 120), cyclo(7,20)-des-AA10-17[Glu7,D- Ala9,D-Dpr20]NPY (100, nd), cyclo(2,27)-des-AA7-23[Glu2,D-Ala6,D-Dpr27]NPY (> 1000, 3.6), cyclo(2,30)- des-AA7-23[Glu2,D-Ala6,-D-Dpr30]NPY (> 1000, nd), cyclo(1,30)-des-AA4-26[Glu1,D-Ala3,D-Dpr30]NPY (> 1000, > 1000). A new family of branched NPY analogues corresponding to the partial deletion of the polyproline helix with conservation of the N-terminus was also examined: des-AA7-23[(Ac-NPY14-22)-epsilon-D-Lys6]NPY (> 1000, 2.1), des-AA7-23[(Ac-NPY7-22)-epsilon-D-Lys6]NPY (> 1000, 5.1), des-AA7-23-[(Ac-LEALEG-NPY14-22)-epsilon-D-Lys6]NPY (> 1000, 4.8). Finally, the role played by the flexible tail (residues 32-36) was studied with the following cyclic analogues: cyclo(30,34)-[Lys30,Glu34]NPY18-36 (> 1000, 360), cyclo(30,34)-[Orn30,Gly34]NPY18-36 (> 1000, 950), cyclo(30,34)-[Dpr30,Glu34]NPY18-36 (> 1000, 590), cyclo(33,36)-[Lys33,Glu36]NPY (> 1000, > 1000), cyclo(33,36)-[Lys33,Glu36]NPY18-36 (> 1000, > 1000). These results suggest that the Y1 receptor is highly discriminatory since deletion of residues 10-17, shown to have little effect on Y2 binding affinity, reduces Y1 affinity 50-fold. Bridging sites and constructs have been identified that may serve as useful leads in the design of more potent and selective analogues. We have identified two positions (9 and 6) where the introduction of a D amino acid is not detrimental to binding affinity. Whether this modification leads to the stabilization of a yet unidentified turn compatible with high Y2 receptor affinity will have to be determined by spectroscopic methods. Finally, stabilizing a putative alpha-helical conformation of the C-terminal heptapeptide of NPY18-36 has a deleterious effect on the Y1 and Y2 receptors.