Etude du mécanisme d'interaction des peptides vecteurs riches en arginine avec des membranes lipidiques modèles.

Cell-penetrating peptides (CPPs) are able to efficiently transport cargos acrosscell membranes in a receptor- and energy-independent manner, without being cytotoxic to cells and thus present a great potential in drug delivery and diagnosis. The understanding of the cellular internalization and membrane interaction mechanisms is thus fundamental for their pharmaceutical development. In this study, two Arginine-rich CPPs derived from penetratin have been investigated: the peptides RW16 (RRWRRWWRRWWRRWRR) andRW9 (RRWWRRWRR). Firstly, a complete biophysical study of the peptide/lipid (P/L)interactions of RW16 has been accomplished and a preferential interaction for anionic lipids was demonstrated. Secondly, peptides derived from RW9 have been synthesized where tryptophan residues have been systematically replaced by phenylalanine. Cellular internalization and P/L interactions have been characterized, and the importance of the number and position of tryptophan has been highlighted.Les peptides vecteurs riches en Arginine (Arg) ont la faculté de transporter des molécules à travers les membranes cellulaires, d'une manière récepteur- et énergie indépendante, sans toxicité envers la cellule et présentent ainsi un fort potentiel pour la libération de molécules thérapeutiques ou diagnostiques. La compréhension du mécanisme d'internalisation cellulaire et de l'interaction membranaire de ces peptides vecteurs est donc primordiale pour leur développement pharmaceutique. Dans cette étude, deux peptide svecteurs riches en Arg et dérivés de la pénétratine ont été étudiés : les peptides RW16(RRWRRWWRRWWRRWRR) et RW9 (RRWWRRWRR). Dans un premier temps,l'analyse biophysique complète de l'interaction peptide/lipide (P/L) a été réalisée pour le peptide RW16 et une interaction favorisée en présence de lipides anioniques a été révélée.Dans un second temps, des peptides dérivés de RW9 ont été synthétisés dans lesquels chaque tryptophane a été systématiquement remplacé par une phenylalanine. L'internalisation cellulaire et les interactions P/L de RW9 ont été étudiées, et l'importance de la position et du nombre de tryptophane dans la séquence peptidique a été mise en évidence

What can designing learning-by-concordance clinical reasoning cases teach us about instruction in the health sciences?

Introduction: Learning-by-concordance (LbC) is an online learning strategy to practice reasoning skills in clinical situations. Writing LbC clinical cases, comprising an initial hypothesis and supplementary data, differs from typical instructional design. We sought to gain a deeper understanding from experienced LbC designers to better support clinician educators’ broader uptake of LbC. Methods: A dialogic action research approach was selected because it yields triangulated data from a heterogeneous group. We conducted three 90-minute dialogue-group sessions with eight clinical educators. Discussions focused on the challenges and pitfalls of each LbC design stage described in the literature. Recordings were transcribed and analyzed thematically. Results: We identified three themes by thematic analysis about the challenges inherent in designing LbC that are unique for this type of learning strategy: 1) the distinction between pedagogical intent and learning outcome; 2) the contextual cues used to challenge students and advance their learning and 3) the integration of experiential with formalized knowledge for cognitive apprenticeship. Discussion: A clinical situation can be experienced and conceptualized in many ways, and multiple responses are appropriate. LbC designers use contextual cues from their experience and combine them with formalized knowledge and protocols to write effective LbC clinical reasoning cases. LbC focuses learners’ attention on decision-making in grey areas that characterize the nature of professional clinical work. This in-depth study on LbC design, indicating the integration of experiential knowledge, might call for new thinking about instructional design

Selective and Wash‐Resistant Fluorescent Dihydrocodeinone Derivatives Allow Single‐Molecule Imaging of μ‐Opioid Receptor Dimerization

μ‐Opioid receptors (μ‐ORs) play a critical role in the modulation of pain and mediate the effects of the most powerful analgesic drugs. Despite extensive efforts, it remains insufficiently understood how μ‐ORs produce specific effects in living cells. We developed new fluorescent ligands based on the μ‐OR antagonist E‐p‐nitrocinnamoylamino‐dihydrocodeinone (CACO), that display high affinity, long residence time and pronounced selectivity. Using these ligands, we achieved single‐molecule imaging of μ‐ORs on the surface of living cells at physiological expression levels. Our results reveal a high heterogeneity in the diffusion of μ‐ORs, with a relevant immobile fraction. Using a pair of fluorescent ligands of different color, we provide evidence that μ‐ORs interact with each other to form short‐lived homodimers on the plasma membrane. This approach provides a new strategy to investigate μ‐OR pharmacology at single‐molecule level

Selective and wash‐resistant fluorescent dihydrocodeinone derivatives allow single‐molecule imaging of μ‐opioid receptor dimerization

μ‐Opioid receptors (μ‐ORs) play a critical role in the modulation of pain and mediate the effects of the most powerful analgesic drugs. Despite extensive efforts, it remains insufficiently understood how μ‐ORs produce specific effects in living cells. We developed new fluorescent ligands based on the μ‐OR antagonist E‐p‐nitrocinnamoylamino‐dihydrocodeinone (CACO), that display high affinity, long residence time and pronounced selectivity. Using these ligands, we achieved single‐molecule imaging of μ‐ORs on the surface of living cells at physiological expression levels. Our results reveal a high heterogeneity in the diffusion of μ‐ORs, with a relevant immobile fraction. Using a pair of fluorescent ligands of different color, we provide evidence that μ‐ORs interact with each other to form short‐lived homodimers on the plasma membrane. This approach provides a new strategy to investigate μ‐OR pharmacology at single‐molecule level

Filamin A organizes γ‑aminobutyric acid type B receptors at the plasma membrane

The γ-aminobutyric acid type B (GABA(B)) receptor is a prototypical family C G protein-coupled receptor (GPCR) that plays a key role in the regulation of synaptic transmission. Although growing evidence suggests that GPCR signaling in neurons might be highly organized in time and space, limited information is available about the mechanisms controlling the nanoscale organization of GABA(B) receptors and other GPCRs on the neuronal plasma membrane. Using a combination of biochemical assays in vitro, single-particle tracking, and super-resolution microscopy, we provide evidence that the spatial organization and diffusion of GABA(B) receptors on the plasma membrane are governed by dynamic interactions with filamin A, which tethers the receptors to sub-cortical actin filaments. We further show that GABA(B) receptors are located together with filamin A in small nanodomains in hippocampal neurons. These interactions are mediated by the first intracellular loop of the GABA(B1) subunit and modulate the kinetics of Gα(i) protein activation in response to GABA stimulation

Single-molecule imaging reveals receptor-G protein interactions at cell surface hot spots

G-protein-coupled receptors mediate the biological effects of many hormones and neurotransmitters and are important pharmacological targets. They transmit their signals to the cell interior by interacting with G proteins. However, it is unclear how receptors and G proteins meet, interact and couple. Here we analyse the concerted motion of G-protein-coupled receptors and G proteins on the plasma membrane and provide a quantitative model that reveals the key factors that underlie the high spatiotemporal complexity of their interactions. Using two-colour, single-molecule imaging we visualize interactions between individual receptors and G proteins at the surface of living cells. Under basal conditions, receptors and G proteins form activity-dependent complexes that last for around one second. Agonists specifically regulate the kinetics of receptor-G protein interactions, mainly by increasing their association rate. We find hot spots on the plasma membrane, at least partially defined by the cytoskeleton and clathrin-coated pits, in which receptors and G proteins are confined and preferentially couple. Imaging with the nanobody Nb37 suggests that signalling by G-protein-coupled receptors occurs preferentially at these hot spots. These findings shed new light on the dynamic interactions that control G-protein-coupled receptor signalling

Interaction mechanism study of arginine-rich cell-penetrating peptides with lipid membrane models

Les peptides vecteurs riches en Arginine (Arg) ont la faculté de transporter des molécules à travers les membranes cellulaires, d'une manière récepteur- et énergie indépendante, sans toxicité envers la cellule et présentent ainsi un fort potentiel pour la libération de molécules thérapeutiques ou diagnostiques. La compréhension du mécanisme d'internalisation cellulaire et de l'interaction membranaire de ces peptides vecteurs est donc primordiale pour leur développement pharmaceutique. Dans cette étude, deux peptide svecteurs riches en Arg et dérivés de la pénétratine ont été étudiés : les peptides RW16(RRWRRWWRRWWRRWRR) et RW9 (RRWWRRWRR). Dans un premier temps,l'analyse biophysique complète de l'interaction peptide/lipide (P/L) a été réalisée pour le peptide RW16 et une interaction favorisée en présence de lipides anioniques a été révélée.Dans un second temps, des peptides dérivés de RW9 ont été synthétisés dans lesquels chaque tryptophane a été systématiquement remplacé par une phenylalanine. L'internalisation cellulaire et les interactions P/L de RW9 ont été étudiées, et l'importance de la position et du nombre de tryptophane dans la séquence peptidique a été mise en évidence.Cell-penetrating peptides (CPPs) are able to efficiently transport cargos acrosscell membranes in a receptor- and energy-independent manner, without being cytotoxic to cells and thus present a great potential in drug delivery and diagnosis. The understanding of the cellular internalization and membrane interaction mechanisms is thus fundamental for their pharmaceutical development. In this study, two Arginine-rich CPPs derived from penetratin have been investigated: the peptides RW16 (RRWRRWWRRWWRRWRR) andRW9 (RRWWRRWRR). Firstly, a complete biophysical study of the peptide/lipid (P/L)interactions of RW16 has been accomplished and a preferential interaction for anionic lipids was demonstrated. Secondly, peptides derived from RW9 have been synthesized where tryptophan residues have been systematically replaced by phenylalanine. Cellular internalization and P/L interactions have been characterized, and the importance of the number and position of tryptophan has been highlighted

Label-free quantification of cell-penetrating peptide translocation into liposomes

Cell penetrating peptides (CPPs) are small molecules capable of crossing lipid membranes and transporting cargos of varied sizes and nature inside cells. Two cellular uptake mechanisms have been identified: endocytosis and direct translocation through the cellular membrane. Several methods have been proposed to follow and quantify CPP internalization ability both in cells and liposomes, most of them requiring the addition of some sort of label to the CPP. Herein we propose a protocol to test and quantify the translocation ability of CPPs through liposomes by measuring their intrinsic Trp fluorescence and their quenching by acrylamide. Although restrained to CPPs that possess at least one Trp residue in their sequence, the protocol remains applicable to a great number of CPPs. The protocol was applied to three CPPs, including one of the first discovered (penetratin), for their internalization into zwitterionic and anionic liposomes and upon different incubation times. While penetratin and one of its analogs were able to translocate into anionic liposomes, none of the peptides translocated into zwitterionic ones. The newly developed protocol allows for the detection of nanomolar amounts of CPPs inside liposomes. The results obtained are in very good agreement with those determined by other quantification methods