Biological membrane interfaces involved in diseases : a biophysical study

Lindström, Fredrick

January 2006

Interactions between peptides and biological lipid membranes play a crucial role in many cellular processes such as in the mechanism behind Alzheimer’s disease where amyloid-beta peptide (Abeta)is thought to be a key component. The initial step of binding between a surface active peptide and its target membrane or membrane receptor can involve a non specific electrostatic association where positively charged amino acid residues and a negatively charged membrane surface interact. Here, the use of high resolution MAS NMR provides a highly sensitive and non perturbing way of studying the electrostatic potential present at lipid membrane surfaces and the changes resulting from the association of peptides. The interaction between pharmacologically relevant peptides and lipid membranes can also involve incorporation of the peptide into the membrane core and by complementing the NMR approach with differential scanning calorimetry (DSC) the hydrophobic incorporation can be studied in a non invasive way. By using 14N MAS NMR on biological lipid systems for the first time, in addition to 31P, 2H NMR and differential scanning calorimetry (DSC), gives a full picture of the changes all along the phospholipid following interactions at the membrane interface region. Being able to monitor the full length of the phospholipid enables us to differentiate between interactions related to either membrane surface association or hydrophobic core incorporation. This approach was used to establish that the interaction between nociceptin and negatively charged lipid membranes is electrostatic and hence that nociceptin can initially associate with a membrane surface before binding to its receptor. Also, it was found that Abeta can interact with phospholipid membranes via two types of interactions with fundamentally adverse effects. The results reveal that Abeta can associate with the surface of a neuronal membrane promoting accelerated aggregation of the peptide leading to neuronal apoptotic cell death. Furthermore it is also shown that Abeta can anchor itself into the membrane and suppress the neurotoxic aggregation of Abeta.

Solid-state NMR

DSC

Amyloid-beta peptide

Nociceptin

DMPC

DMPG

DDAB

peptide-lipid interaction

branched-chain fatty acid.

Biophysical chemistry

Biofysikalisk kemi

Biophysical investigations of the LAH4 family peptides : enhancer of gene delivery, from peptide-peptide interactions to peptide-membrane interactions / Etude biophysique de peptides de la famille du LAH4 : un amplificateur de systèmes de transport de gènes, de l’interaction peptide-peptide à l’interaction peptide-membrane

Wolf, Justine

20 September 2018

Les peptides de la famille du LAH4 sont des peptides cationiques capables de se replier en hélice α amphiphile. Ces peptides sont riches en histidines ce qui permet de moduler les interactions de ces peptides de manière pH dépendante et dans une gamme physiologique. Leurs capacités à interagir et perturber les membranes ont été utilisées pour divers applications biologique, et notamment pour l'amélioration de systèmes de transport de gènes.Le travail de cette thèse a été divisé en trois parties dans le but de caractériser de manière biophysique les différentes interactions ayant lieu lors de la livraison du système de transport de gènes à l’intérieur d’une cellule. L’interaction peptide-peptide : avec l’étude de l’agrégation en fibrilles de la VF1 ; l’interaction peptide-membrane : avec l’effet du LAH4L1 en présence de membranes ; et l’interaction peptide-ADN : avec le suivit de l’interaction entre le LAH4L1 et de l'ADN. / The LAH4 family consists of cationic amphiphilic peptides with propensity to fold in α-helical secondary structures. They contain histidines allowing the modulation of their interactions in a pH dependent manner in the physiological range. In membranes, at neutral or acidic pH the peptide assumes a transmembrane or an in planar configuration, respectively.In the field of gene delivery systems, peptides like LAH4 are used. They are able to firstly interact with different cargoes in order to form stable complexes, then interact with the cell membrane, and finally, promote to escape from the endosome.This PhD has been divided into three parts in order to characterize, with biophysical methods, the interactions occurring during the delivery of these gene systems: peptide-peptide interactions with a focus on the study of VF1 fibre formation; peptide-membrane interactions: with the investigation of the effect of LAH4L1 in different membranes; and peptide-DNA interactions, where the interactions of LAH4L1 with a small DNA fragment were measured.

Peptide membranaire

RMN du solide

Interaction peptide-peptide

Fibres

Interaction peptide-acides nucléiques

Système de transport de gènes

Cell-penetrating peptide

Solid-state NMR

Peptide-peptide interaction

Peptide-lipid interaction

Peptide-nucleic acid interaction

Gene delivery systems

571.4