Effect of Cholesterol on Biomimetic Membrane Curvature and Coronavirus Fusion Peptide Encapsulation

Milogrodzka, Izabela; Pham, Duy Tue Nguyen; Sama, Gopal R.; Samadian, Hajar; Zhai, Jiali; Campo, Liliana de; Kirby, Nigel; Scott, Timothy F.; Holl, Mark M. Banaszak; Hag, Leonie van ‘t

doi:10.1021/acsnano.3c01095

Cited by 7 publications

(5 citation statements)

References 86 publications

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“…Also, the lack of acidic phospholipids in the outer membrane layer of erythrocytes probably makes them less sensitive to our protein nanoparticles. To further support these, it was recently reported that adding cholesterol to cubic-phase nanoparticles dramatically ameliorated their toxicity to HeLa cells . Notwithstanding, it is important to note that the cell culture models used in this study may not wholly mimic the in vivo toxicity characteristics.…”

Section: Resultsmentioning

confidence: 77%

“…To further support these, it was recently reported that adding cholesterol to cubic-phase nanoparticles dramatically ameliorated their toxicity to HeLa cells. 62 Notwithstanding, it is important to note that the cell culture models used in this study may not wholly mimic the in vivo toxicity characteristics. Regardless, for immediate use, these antibacterial nanoparticles could be used for the topical treatment of bacterial infections.…”

Section: Resultsmentioning

confidence: 99%

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Coassembled Multicomponent Protein Nanoparticles Elicit Enhanced Antibacterial Activity

Dzuvor,

Shen,

Haritos

et al. 2024

ACS Nano

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The waning pipeline of the useful antibacterial arsenal has necessitated the urgent development of more effective antibacterial strategies with distinct mechanisms to rival the continuing emergence of resistant pathogens, particularly Gram-negative bacteria, due to their explicit drugimpermeable, two-membrane-sandwiched cell wall envelope. Herein, we have developed multicomponent coassembled nanoparticles with strong bactericidal activity and simultaneous bacterial cell envelope targeting using a peptide coassembly strategy. Compared to the single-component self-assembled nanoparticle counterparts or cocktail mixtures of these at a similar concentration, coassembled multicomponent nanoparticles showed higher bacterial killing efficiency against Acinetobacter baumannii, Pseudomonas aeruginosa, and Escherichia coli by several orders of magnitude (about 100−1,000,000-fold increase). Comprehensive confocal and electron microscopy suggest that the superior antibacterial activity of the coassembled nanoparticles proceeds via multiple complementary mechanisms of action, including membrane destabilization, disruption, and cell wall hydrolysis, actions that were not observed with the single nanoparticle counterparts. To understand the fundamental working mechanisms behind the improved performance of coassembled nanoparticles, we utilized a "dilution effect" system where the antibacterial components are intermolecularly mixed and coassembled with a non-antibacterial protein in the nanoparticles. We suggest that coassembled nanoparticles mediate enhanced bacterial killing activity by attributes such as optimized local concentration, high avidity, cooperativity, and synergy. The nanoparticles showed no cytotoxic or hemolytic activity against tested eukaryotic cells and erythrocytes. Collectively, these findings reveal potential strategies for disrupting the impermeable barrier that Gram-negative pathogens leverage to restrict antibacterial access and may serve as a platform technology for potential nano-antibacterial design to strengthen the declining antibiotic arsenal.

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Section: Resultsmentioning

confidence: 77%

Section: Resultsmentioning

confidence: 99%

Coassembled Multicomponent Protein Nanoparticles Elicit Enhanced Antibacterial Activity

Dzuvor,

Shen,

Haritos

et al. 2024

ACS Nano

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“…Cholesterols, which are multifunctional lipids unique to the eukaryotic membrane, are distributed in various tissues with amounts varying from approximately 20 to 50% The rigid steroid ring structure of cholesterol restricts the motion of other membrane lipid tails, which thereby modulates biophysical properties of mammalian plasma membranes, such as membrane thickness, fluidity, , and flexibility. , Despite the role of cholesterols in biosystems having been reported by a large amount of literature studies, , much remains unknown about the exact roles of cholesterols and their molecular interactions on the membrane function. , Based on their effect on the membrane permeability and molecular transport ability, Canepa et al reported that the passive uptake of amphiphilic nanoparticles into fluid lipid membranes can be significantly hindered by cholesterols . Lorents et al.…”

Section: Introductionmentioning

confidence: 99%

Cholesterols Induced Distinctive Entry of the Graphene Nanosheet into the Cell Membrane

Tan,

Hu,

2024

ACS Omega

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Graphene nanosheets are highly valued in the biomedical field due to their potential applications in drug delivery, biological imaging, and biosensors. Their biological effects on mammalian cells may be influenced by cholesterols, which are crucial components in cell membranes that take part in many vital processes. Therefore, it is particularly important to investigate the effect of cholesterols on the transport mechanism of graphene nanosheets in the cell membrane as well as the final stable configuration of graphene, which may have an impact on cytotoxicity. In this paper, the molecular details of a graphene nanosheet interacting with a 1,2-dipalmitoyl-sn-glycero-3-phosphorylcholine (DPPC) membrane with cholesterols were studied using molecular dynamics simulations. Results showed that the structure of the graphene nanosheet transits from the cut-in state in a pure DPPC membrane to being sandwiched between two DPPC leaflets when cholesterols reach a certain concentration. The underlying mechanism showed that cholesterols are preferentially adsorbed on the graphene nanosheet, which causes a larger disturbance to the nearby DPPC tails and thus guides the graphene nanosheet into the core of lipid bilayers to form a sandwiched structure. Our results are helpful for understanding the fundamental interaction mechanism between the graphene nanosheet and cell membrane and to explore the potential applications of the graphene nanosheet in biomedical sciences.

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“…In addition to changes in vibrational modes, deuterium possesses dramatically different nuclear properties when compared to protium, such as a reduced Larmor frequency (76.773 vs 500.130 MHz at 11.747 T), a 40 × decrease in the incoherent neutron scattering cross section [ 4 ], and a positive coherent neutron scattering length [ 5 ]. These nuclear properties, its low natural abundance and the similarity of C-H and C-D bonds make deuterated molecules invaluable as a tracers in metabolic studies and as contrast agents in neutron and nuclear magnetic resonance spectroscopic techniques [ 6 – 15 ]. Deuterated molecules can be synthesized using commercially available deuterated precursors (e.g., CD 3 I, CD 3 OD, DCO 2 D, CD 3 NH 2 , LiAlD 4 , NaBD 4 ) in standard chemistry techniques to produce site specific deuterated molecules [ 2 , 16 , 17 ].…”

Section: Introductionmentioning

confidence: 99%

DGet! An open source deuteration calculator for mass spectrometry data

Lockwood,

Angeloski

2024

J Cheminform

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DGet! is an open-source analysis package written in Python for calculating the degree of deuterium enrichment in isotopically labelled molecules using mass spectrometric data. The nuclear properties of deuterium make it a valuable tracer in metabolic studies and an excellent contrast agent in nuclear spectroscopies. Determination of molecular deuteration levels is typically performed using mass spectrometry, however software options to perform these calculations are scarce. The in-house scripts and spreadsheets currently used rarely account for isotopic interferences from 13C or multi-isotopic elements that impact deuteration calculations. DGet! removes isotopic interferences using de-convolution and both the isotopological makeup and overall deuteration level can be accurately recovered. The software is available as command line and web applications that take a molecular formula and mass spectrometry data and output a graphical representation of the degree of deuteration as well as the distribution of partially deuterated analogues. These applications are designed to be easy to use and enable superior characterisation of deuterated molecules for users of all levels of expertise, without the limitations of techniques currently used by the majority of deuteration laboratories and researchers. Graphical Abstract

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Effect of Cholesterol on Biomimetic Membrane Curvature and Coronavirus Fusion Peptide Encapsulation

Cited by 7 publications

References 86 publications

Coassembled Multicomponent Protein Nanoparticles Elicit Enhanced Antibacterial Activity

Coassembled Multicomponent Protein Nanoparticles Elicit Enhanced Antibacterial Activity

Cholesterols Induced Distinctive Entry of the Graphene Nanosheet into the Cell Membrane

DGet! An open source deuteration calculator for mass spectrometry data

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