Mechanisms of Influenza Virus HA2 Peptide Interaction with Liposomes Studied by Dual-Wavelength MP-SPR

Belkilani, Meryem; Farre, Carole; Chevalier, Yves; Minot, Sylvain; Bessueille, François; Abdelghani, Adnane; Jaffrezic‐Renault, Nicole; Chaix, Carole

doi:10.1021/acsami.2c09039

Cited by 8 publications

(3 citation statements)

References 45 publications

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“…Notably, HA2 is a known endosomolytic peptide derived from the influenza virus hemagglutinin subunit [ 128 , 129 ]. It adopts a helical conformation in the acidic endosomal environment, promoting fusion with the endosomal bilayer, membrane destabilization, and subsequent release into the cytosol [ 130 ]. Interestingly, directly fusing the HA2 peptide to Cas9-T6N did not enhance gene editing.…”

Section: Methods For Intracellular Protein Deliverymentioning

confidence: 99%

Intracellular Protein Delivery: Approaches, Challenges, and Clinical Applications

Chan,

Tsourkas

2024

BME Front

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Protein biologics are powerful therapeutic agents with diverse inhibitory and enzymatic functions. However, their clinical use has been limited to extracellular applications due to their inability to cross plasma membranes. Overcoming this physiological barrier would unlock the potential of protein drugs for the treatment of many intractable diseases. In this review, we highlight progress made toward achieving cytosolic delivery of recombinant proteins. We start by first considering intracellular protein delivery as a drug modality compared to existing Food and Drug Administration-approved drug modalities. Then, we summarize strategies that have been reported to achieve protein internalization. These techniques can be broadly classified into 3 categories: physical methods, direct protein engineering, and nanocarrier-mediated delivery. Finally, we highlight existing challenges for cytosolic protein delivery and offer an outlook for future advances.

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Section: Methods For Intracellular Protein Deliverymentioning

confidence: 99%

Intracellular Protein Delivery: Approaches, Challenges, and Clinical Applications

Chan,

Tsourkas

2024

BME Front

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“…SPR is known to be highly sensitive to the interaction of liposome-like vesicles with a gold surface. , Furthermore, bacteria naturally secrete external membrane vesicles ranging from 20 to 400 nm in diameter . These are formed when a portion of the bacterial membrane protrudes and buds off under different vesiculation mechanisms, entrapping various biocomponents .…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Affinity of Aptamers for Bacteria by Surface Plasmon Resonance Imaging Using Nanosomes

Manceau,

Farre,

Lagarde

et al. 2024

ACS Appl. Mater. Interfaces

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The cell-SELEX method enables efficient selection of aptamers that bind whole bacterial cells. However, after selection, it is difficult to determine their binding affinities using common screening methods because of the large size of the bacteria. Here we propose a simple surface plasmon resonance imaging method (SPRi) for aptamer characterization using bacterial membrane vesicles, called nanosomes, instead of whole cells. Nanosomes were obtained from membrane fragments after mechanical cell disruption in order to preserve the external surface epitopes of the bacterium used for their production. The study was conducted on Bacillus cereus (B. cereus), a Gram-positive bacterium commonly found in soil, rice, vegetables, and dairy products. Four aptamers and one negative control were initially grafted onto a biochip. The binding of B. cereus cells and nanosomes to immobilized aptamers was then compared. The use of nanosomes instead of cells provided a 30-fold amplification of the SPRi signal, thus allowing the selection of aptamers with higher affinities. Aptamer SP15 was found to be the most sensitive and selective for B. cereus ATCC14579 nanosomes. It was then truncated into three new sequences (SP15M, SP15S1, and SP15S2) to reduce its size while preserving the binding site. Fitting the results of the SPRi signal for B. cereus nanosomes showed a similar trend for SP15 and SP15M, and a slightly higher apparent association rate constant k on for SP15S2, which is the truncation with a high probability of a G-quadruplex structure. These observations were confirmed on nanosomes from B. cereus ATCC14579 grown in milk and from the clinical strain B. cereus J066. The developed method was validated using fluorescence microscopy on whole B. cereus cells and the SP15M aptamer labeled with a rhodamine. This study showed that nanosomes can successfully mimic the bacterial membrane with great potential for facilitating the screening of specific ligands for bacteria.

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“…Most notably is that both are planar surfaces, lacking in curvature or curvature tuning, which have led to misrepresentation when compared to the natural structure of cells and the interactions they attempt to mimic . Although much knowledge has been gained on how the composition of planar lipid membrane affect biophysical interactions, ,, it is becoming more evident that curvature needs to be taken into account in the studies. − SAMs and SLBs have been effective in the examination of many types of biological interactions, ,, however, a large portion of these interactions and their properties still remains less investigated and poorly understood, especially in regards to the interactions that require curvature. − ,, Several methods have been developed to investigate the properties of these interactions using specific interfaces on the biosensor’s surface with surface functionalization. ,− However, they are limited by a number of factors, including the composition of the membrane, the degree of curvature, reproducibility, and the fluidity of the membrane. There is a compelling need for the development of new approaches that can reliably generate reproducible curved membranes through simple procedures for modification to be used in functional studies.…”

Section: Introductionmentioning

confidence: 99%

Curved Membrane Mimics for Quantitative Probing of Protein–Membrane Interactions by Surface Plasmon Resonance

Malinick,

Stuart,

Lambert

et al. 2023

ACS Appl. Mater. Interfaces

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A majority of biomimetic membranes used for current biophysical studies rely on planar structures such as supported lipid bilayer (SLB) and self-assembled monolayers (SAMs). While they have facilitated key information collection, the lack of curvature makes these models less effective for the investigation of curvature-dependent protein binding. Here, we report the development and characterization of curved membrane mimics on a solid substrate with tunable curvature and ease in incorporation of cellular membrane components for the study of protein-membrane interactions. The curved membranes were generated with an underlayer lipid membrane composed of DGS-Ni-NTA and POPC lipids on the substrate, followed by the attachment of histidine-tagged cholera toxin (his-CT) as a capture layer. Lipid vesicles containing different compositions of gangliosides, including GA 1 , GM 1 , GT 1b , and GQ 1b , were anchored to the capture layer, providing fixation of the curved membranes with intact structures. Characterization of the curved membrane was accomplished with surface plasmon resonance (SPR), fluorescence recovery after photobleaching (FRAP), and nano-tracking analysis (NTA). Further optimization of the interface was achieved through principal component analysis (PCA) to understand the effect of ganglioside type, percentage, and vesicle dimensions on their interactions with proteins. In addition, Monte Carlo simulations were employed to predict the distribution of the gangliosides and interaction patterns with single point and multipoint binding models. This work provides a reliable approach to generate robust, component-tuning, and curved membranes for investigating protein interactions more pertinently than what a traditional planar membrane offers.

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Mechanisms of Influenza Virus HA2 Peptide Interaction with Liposomes Studied by Dual-Wavelength MP-SPR

Cited by 8 publications

References 45 publications

Intracellular Protein Delivery: Approaches, Challenges, and Clinical Applications

Intracellular Protein Delivery: Approaches, Challenges, and Clinical Applications

Investigation of the Affinity of Aptamers for Bacteria by Surface Plasmon Resonance Imaging Using Nanosomes

Curved Membrane Mimics for Quantitative Probing of Protein–Membrane Interactions by Surface Plasmon Resonance

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