TY - JOUR
T1 - Inverse Conformational Selection in Lipid–Protein Binding
AU - Bacle, Amélie
AU - Buslaev, Pavel
AU - Garcia-Fandino, Rebeca
AU - Favela-Rosales, Fernando
AU - Ferreira, Tiago Mendes
AU - Fuchs, Patrick
AU - Gushchin, Ivan
AU - Javanainen, Matti
AU - Kiirikki, Anne M.
AU - Madsen, Jesper Jonasson
AU - Melcr, Josef
AU - Rodríguez, Paula Milán
AU - Miettinen, Markus S.
AU - Ollila, Samuli
AU - Papadopoulos, Chris G.
AU - Peón, Antonio
AU - Piggot, Thomas J.
AU - Piñeiro, Ángel
AU - Virtanen, Salla
PY - 2021/8/16
Y1 - 2021/8/16
N2 - Interest in lipid interactions with proteins and other biomolecules is emerging not only in fundamental biochemistry but also in the field of nanobiotechnology where lipids are commonly used, for example, in carriers of mRNA vaccines. The outward-facing components of cellular membranes and lipid nanoparticles, the lipid headgroups, regulate membrane interactions with approaching substances, such as proteins, drugs, RNA, or viruses. Because lipid headgroup conformational ensembles have not been experimentally determined in physiologically relevant conditions, an essential question about their interactions with other biomolecules remains unanswered: Do headgroups exchange between a few rigid structures, or fluctuate freely across a practically continuous spectrum of conformations? Here, we combine solid-state NMR experiments and molecular dynamics simulations from the NMRlipids Project to resolve the conformational ensembles of headgroups of four key lipid types in various biologically relevant conditions. We find that lipid headgroups sample a wide range of overlapping conformations in both neutral and charged cellular membranes, and that differences in the headgroup chemistry manifest only in probability distributions of conformations. Furthermore, the analysis of 894 protein-bound lipid structures from the Protein Data Bank suggests that lipids can bind to proteins in a wide range of conformations, which are not limited by the headgroup chemistry. We propose that lipids can select a suitable headgroup conformation from the wide range available to them to fit the various binding sites in proteins. The proposed inverse conformational selection model will extend also to lipid binding to targets other than proteins, such as drugs, RNA, and viruses.
AB - Interest in lipid interactions with proteins and other biomolecules is emerging not only in fundamental biochemistry but also in the field of nanobiotechnology where lipids are commonly used, for example, in carriers of mRNA vaccines. The outward-facing components of cellular membranes and lipid nanoparticles, the lipid headgroups, regulate membrane interactions with approaching substances, such as proteins, drugs, RNA, or viruses. Because lipid headgroup conformational ensembles have not been experimentally determined in physiologically relevant conditions, an essential question about their interactions with other biomolecules remains unanswered: Do headgroups exchange between a few rigid structures, or fluctuate freely across a practically continuous spectrum of conformations? Here, we combine solid-state NMR experiments and molecular dynamics simulations from the NMRlipids Project to resolve the conformational ensembles of headgroups of four key lipid types in various biologically relevant conditions. We find that lipid headgroups sample a wide range of overlapping conformations in both neutral and charged cellular membranes, and that differences in the headgroup chemistry manifest only in probability distributions of conformations. Furthermore, the analysis of 894 protein-bound lipid structures from the Protein Data Bank suggests that lipids can bind to proteins in a wide range of conformations, which are not limited by the headgroup chemistry. We propose that lipids can select a suitable headgroup conformation from the wide range available to them to fit the various binding sites in proteins. The proposed inverse conformational selection model will extend also to lipid binding to targets other than proteins, such as drugs, RNA, and viruses.
UR - http://www.scopus.com/inward/record.url?scp=85114164673&partnerID=8YFLogxK
U2 - 10.1021/jacs.1c05549
DO - 10.1021/jacs.1c05549
M3 - Article
SN - 0002-7863
VL - 143
SP - 13701
EP - 13709
JO - Journal of the American Chemical Society
JF - Journal of the American Chemical Society
IS - 34
ER -