The solution conformations of macrocycles. Applications in the exploration of weak interactions and in drug development
Abstract
Understanding the solution conformation and dynamics of molecules with biological relevance, as well as the impact of their conformation stabilizing weak interactions, is for example important for drug design. Macrocycles have attractive pharmaceutical properties, and are of special interest as drug leads for targets with large, flat and featureless binding sites like protein-protein interfaces. As they are usually flexible and adopt a variety of solution geometries, the description of their ensembles is of high value. Most macrocyclic drugs are peptides or macrolides. Peptides, and in particular β-hairpin peptides, are suitable model systems for studying weak interactions. Due to their resemblance to proteins, studying peptides by solution state experiments provides knowledge gained in a biologically relevant environment. In this thesis, nuclear magnetic resonance (NMR) spectroscopy has been used for investigation of the solution ensembles of various macrocycles. Using a cyclic β-hairpin model system and NMR analysis of molecular flexibility in solution (NAMFIS), a single interstrand hydrogen bond was shown to provide significant stabilization of the folded conformation. In addition, it was shown that a chlorine-centered halogen bond stabilizes the β-hairpin to a comparable extent. Further, the solution ensembles of four cyclic β-hairpin inhibitors of the MDM2/p53 protein-protein interaction were described, and a higher conformational flexibility was found to correlate with an increased inhibitory activity. In contrast, for cyclic azapeptide inhibitors of the cluster of differentiation 36 (CD36) receptor, higher flexibility correlated to decreased inhibitory activity. An increased population of one of the conformational families in solution was found to be beneficial for the CD36 inhibitory activity. Lastly, roxithromycin, a macrolide antibacterial agent, was described to convert from a more open conformation in polar media to a more closed and less flexible conformation in non-polar media. This thesis demonstrates that macrocycles are applicable as model systems for the study of weak interaction forces, which have a large influence on their conformational behavior. Furthermore, the obtained results show that the conformational stability of macrocycles vastly influences their bioactivity.
Parts of work
Insight into β-Hairpin Stability: Interstrand Hydrogen Bonding
Emma Danelius, Ulrika Brath, Máté Erdélyi
Synlett, 2013, 24, 2407–2410 ::doi::10.1055/s-0033-1339670 Assessing the Ability of Spectroscopic Methods to Determine the
Difference in the Folding Propensities of Highly Similar β-
Hairpins
Hanna Andersson, Emma Danelius, Patrik Jarvoll, Stephan Niebling,
Ashley J. Hughes, Sebastian Westenhoff, Ulrika Brath, Máté Erdélyi
ACS Omega, 2017, 2, 508–516 ::doi::10.1021/acsomega.6b00484 Halogen Bonding: a Powerful Tool for Modulation of Peptide
Conformation
Emma Danelius, Hanna Andersson, Patrik Jarvoll, Kajsa Lood, Jürgen
Gräfenstein, Máté Erdélyi
Biochemistry, 2017, 56, 3265–3272 ::doi::10.1021/acs.biochem.7b00429 Flexibility is Important for Inhibition of the MDM2/p53
Protein−Protein Interaction by Cyclic β-Hairpins
Emma Danelius, Mariell Pettersson, Matilda Bred, Jaeki Min, M. Brett
Waddell, R. Kiplin Guy, Morten Grøtli, Máté Erdélyi
Organic and Biomolecular Chemistry, 2016, 14, 10386–10393 ::doi::10.1039/C6OB01510G Conformational Preferences of Macrocyclic Azapeptide
Inhibitors of CD36 in Aqueous Solution
Emma Danelius, Ahsanullah Ahsanullah, Máté Erdélyi, William Lubell
Manuscript
Degree
Doctor of Philosophy
University
University of Gothenburg. Faculty of Science
Institution
Department of Chemistry and Molecular Biology ; Institutionen för kemi och molekylärbiologi
Disputation
Fredagen den 20 oktober 2017 kl 09:15, KC Kemihuset Chalmers, Kemigården 4, Göteborg
Date of defence
2017-10-20
emma.danelius@chem.gu.se
emma.danelius@gmail.com
Date
2017-09-26Author
Danelius, Emma
Keywords
Kemi
Organisk kemi
Publication type
Doctoral thesis
ISBN
978-91-629-0274-2
978-91-629-0275-9
Language
eng