Cholesterol Changes the Mechanisms of Aβ Peptide Binding to the DMPC Bilayer

Lockhart, Christopher; Klimov, Dmitri K.

doi:10.1021/acs.jcim.7b00431

Cited by 22 publications

(40 citation statements)

References 67 publications

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“…412 The sensitivity to cholesterol of different Aβ peptides has also been addressed by simulations describing different cholesterol hot-spots depending on their length. 765−767 Cholesterol bound at the tandem glycine motif might compete with helix dimerization, 768 but other sites have also been proposed to promote helix–helix interactions. 769 More in general, the lipid environment and composition greatly affect helix orientation and dimerization of precursors of different lengths, 770,771 an aspect that has been addressed with MD simulations as well.…”

Section: C99 and γ-Secretasementioning

confidence: 99%

Emerging Diversity in Lipid–Protein Interactions

et al. 2019

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Membrane lipids interact with proteins in a variety of ways, ranging from providing a stable membrane environment for proteins to being embedded in to detailed roles in complicated and well-regulated protein functions. Experimental and computational advances are converging in a rapidly expanding research area of lipid–protein interactions. Experimentally, the database of high-resolution membrane protein structures is growing, as are capabilities to identify the complex lipid composition of different membranes, to probe the challenging time and length scales of lipid–protein interactions, and to link lipid–protein interactions to protein function in a variety of proteins. Computationally, more accurate membrane models and more powerful computers now enable a detailed look at lipid–protein interactions and increasing overlap with experimental observations for validation and joint interpretation of simulation and experiment. Here we review papers that use computational approaches to study detailed lipid–protein interactions, together with brief experimental and physiological contexts, aiming at comprehensive coverage of simulation papers in the last five years. Overall, a complex picture of lipid–protein interactions emerges, through a range of mechanisms including modulation of the physical properties of the lipid environment, detailed chemical interactions between lipids and proteins, and key functional roles of very specific lipids binding to well-defined binding sites on proteins. Computationally, despite important limitations, molecular dynamics simulations with current computer power and theoretical models are now in an excellent position to answer detailed questions about lipid–protein interactions.

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Section: C99 and γ-Secretasementioning

confidence: 99%

Emerging Diversity in Lipid–Protein Interactions

et al. 2019

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“…The molecular docking results showed that the U-shaped oligomers inserted into the membrane and formed ion-permeable pores [ 67 ], which is consistent with the report that Aβ can insert into lipid bilayers and assemble into a β-barrel pore under optimized detergent micelle conditions [ 68 ]. Aβos can also interact with lipids and cholesterol in the membrane to exert their toxicity [ 69 , 70 , 71 , 72 , 73 ]. For example, Aβos strongly bind to GM1 ganglioside located at the external face of the cell membrane to promote LTP impairment, which requires the existence of sialic acid residues of GM1 [ 71 ].…”

Section: The Neurotoxicological Mechanisms Of Aβosmentioning

confidence: 99%

“…The effect of cholesterol on the toxicity of Aβos to membrane is controversial. Cholesterol can change the structures of Aβos and facilitate the interaction between Aβ and the membrane, on the other hand, cholesterol increases the membrane rigidity and has a protective effect against Aβos-mediated damage [ 69 , 72 ].…”

Section: The Neurotoxicological Mechanisms Of Aβosmentioning

confidence: 99%

The Toxicity and Polymorphism of β-Amyloid Oligomers

Huang

Liu

2020

IJMS

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It is widely accepted that β-amyloid oligomers (Aβos) play a key role in the progression of Alzheimer’s disease (AD) by inducing neuron damage and cognitive impairment, but Aβos are highly heterogeneous in their size, structure and cytotoxicity, making the corresponding studies tough to carry out. Nevertheless, a number of studies have recently made remarkable progress in the describing the characteristics and pathogenicity of Aβos. We here review the mechanisms by which Aβos exert their neuropathogenesis for AD progression, including receptor binding, cell membrane destruction, mitochondrial damage, Ca2+ homeostasis dysregulation and tau pathological induction. We also summarize the characteristics and pathogenicity such as the size, morphology and cytotoxicity of dimers, trimers, Aβ*56 and spherical oligomers, and suggest that Aβos may play a different role at different phases of AD pathogenesis, resulting in differential consequences on neuronal synaptotoxicity and survival. It is warranted to investigate the temporal sequence of Aβos in AD human brain and examine the relationship between different Aβos and cognitive impairment.

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“…There are also contradictory data on the role of Chol in Aβ42-binding to bilayers, from those that suggest a positive role in Aβ42 binding and aggregation [19,38] to those who propose a negative influence [39] or a dual effect depending on Chol concentration [40]. In general, Chol appears to have a negative effect on Aβ binding and aggregation particularly in the absence of sphingolipids [41,42].…”

Section: Discussionmentioning

confidence: 99%

The Binding of Aβ42 Peptide Monomers to Sphingomyelin/Cholesterol/Ganglioside Bilayers Assayed by Density Gradient Ultracentrifugation

Ahyayauch

Arada

Masserini

et al. 2020

IJMS

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The binding of Aβ42 peptide monomers to sphingomyelin/cholesterol (1:1 mol ratio) bilayers containing 5 mol% gangliosides (either GM1, or GT1b, or a mixture of brain gangliosides) has been assayed by density gradient ultracentrifugation. This procedure provides a direct method for measuring vesicle-bound peptides after non-bound fraction separation. This centrifugation technique has rarely been used in this context previously. The results show that gangliosides increase by about two-fold the amount of Aβ42 bound to sphingomyelin/cholesterol vesicles. Complementary studies of the same systems using thioflavin T fluorescence, Langmuir monolayers or infrared spectroscopy confirm the ganglioside-dependent increased binding. Furthermore these studies reveal that gangliosides facilitate the aggregation of Aβ42 giving rise to more extended β-sheets. Thus, gangliosides have both a quantitative and a qualitative effect on the binding of Aβ42 to sphingomyelin/cholesterol bilayers.Early data [8,9] supported the idea that β-secretase associates with liquid-ordered (Lo) nanodomains in the membrane and that integrity of those raft-like domains is required for β-cleavage of APP to occur. This explains why many studies on Aβ-membrane interaction have been performed with bilayers enriched in sphingomyelin (SM) and cholesterol (Chol), a lipid mixture that exists usually in the Lo phase [10]. Moreover, various reports [11,12] have shown that anionic lipids promote fibril elongation. In our previous study [13] we explored the initial stages of the interaction of Aβ42 in the monomeric form with lipid monolayers and with bilayers composed mainly of SM and Chol, i.e., in the liquid-ordered (Lo) state, in the absence and presence of negatively charged phospholipids. In the absence of negatively charged lipids, the interaction was weak. However, in the presence of phosphatidic acid, or of cardiolipin, an interaction could be detected by different methods, including isothermal calorimetry, thioflavin T (ThT) fluorescence and infrared spectroscopy, as well as molecular dynamics simulations. Low (2.5-5 mol %) concentrations of phosphatidic acid or cardiolipin allowed better interaction than 20 mol % of the same lipids.For many years gangliosides have been associated to plaque formation [14], perhaps because of their presumed implication in raft structure [15]. Numerous studies have explored model membranes composed of SM, Chol and gangliosides. Selected examples include those based on molecular dynamics [16][17][18], atomic force microscopy (AFM) [19,20], infrared spectroscopy [21], and other biophysical techniques [22,23]. To our knowledge Aβ42 binding to bilayers after separation of the free and lipid-bound forms of the peptide by density gradient centrifugation have rarely been performed. Vesicle-bound peptide floats in the density gradient whereas the non-bound protein/peptide, after aggregation, sediments [24,25]. The centrifugation method is quite unique in providing direct, quantitative equilibrium measurements of binding, in the abs...

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Cholesterol Changes the Mechanisms of Aβ Peptide Binding to the DMPC Bilayer

Cited by 22 publications

References 67 publications

Emerging Diversity in Lipid–Protein Interactions

Emerging Diversity in Lipid–Protein Interactions

The Toxicity and Polymorphism of β-Amyloid Oligomers

The Binding of Aβ42 Peptide Monomers to Sphingomyelin/Cholesterol/Ganglioside Bilayers Assayed by Density Gradient Ultracentrifugation

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