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Membrane Association Modes of Natural Anticancer Peptides: Mechanistic Details on Helicity, Orientation, and Surface Coverage

Quemé-Peña, Mayra ; Juhász, Tünde ; Kohut, Gergely ; [et al.]

MDPI AG ; 2021

In: International Journal of Molecular Sciences Vol. 22, No. 16 ( 2021-08-10), p. 8613-

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In: International Journal of Molecular Sciences, MDPI AG, Vol. 22, No. 16 ( 2021-08-10), p. 8613-

Abstract: Anticancer peptides (ACPs) could potentially offer many advantages over other cancer therapies. ACPs often target cell membranes, where their surface mechanism is coupled to a conformational change into helical structures. However, details on their binding are still unclear, which would be crucial to reach progress in connecting structural aspects to ACP action and to therapeutic developments. Here we investigated natural helical ACPs, Lasioglossin LL-III, Macropin 1, Temporin-La, FK-16, and LL-37, on model liposomes, and also on extracellular vesicles (EVs), with an outer leaflet composition similar to cancer cells. The combined simulations and experiments identified three distinct binding modes to the membranes. Firstly, a highly helical structure, lying mainly on the membrane surface; secondly, a similar, yet only partially helical structure with disordered regions; and thirdly, a helical monomeric form with a non-inserted perpendicular orientation relative to the membrane surface. The latter allows large swings of the helix while the N-terminal is anchored to the headgroup region. These results indicate that subtle differences in sequence and charge can result in altered binding modes. The first two modes could be part of the well-known carpet model mechanism, whereas the newly identified third mode could be an intermediate state, existing prior to membrane insertion.

Type of Medium: Online Resource

ISSN: 1422-0067

URL: Article

DOI: 10.3390/ijms22168613

Language: English

Publisher: MDPI AG

Publication Date: 2021

detail.hit.zdb_id: 2019364-6

SSG: 12

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Structural Water Stabilizes Protein Motifs in Liquid Protein Phase: The Folding Mechanism of Short β-Sheets Coupled to Phase Transition

Papp, Dóra ; Szigyártó, Imola Csilla ; Nordén, Bengt ; [et al.]

MDPI AG ; 2021

In: International Journal of Molecular Sciences Vol. 22, No. 16 ( 2021-08-10), p. 8595-

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In: International Journal of Molecular Sciences, MDPI AG, Vol. 22, No. 16 ( 2021-08-10), p. 8595-

Abstract: Macromolecular associates, such as membraneless organelles or lipid-protein assemblies, provide a hydrophobic environment, i.e., a liquid protein phase (LP), where folding preferences can be drastically altered. LP as well as the associated phase change from water (W) is an intriguing phenomenon related to numerous biological processes and also possesses potential in nanotechnological applications. However, the energetic effects of a hydrophobic yet water-containing environment on protein folding are poorly understood. Here, we focus on small β-sheets, the key motifs of proteins, undergoing structural changes in liquid–liquid phase separation (LLPS) and also model the mechanism of energy-coupled unfolding, e.g., in proteases, during W → LP transition. Due to the importance of the accurate description for hydrogen bonding patterns, the employed models were studied by using quantum mechanical calculations. The results demonstrate that unfolding is energetically less favored in LP by ~0.3–0.5 kcal·mol−1 per residue in which the difference further increased by the presence of explicit structural water molecules, where the folded state was preferred by ~1.2–2.3 kcal·mol−1 per residue relative to that in W. Energetics at the LP/W interfaces was also addressed by theoretical isodesmic reactions. While the models predict folded state preference in LP, the unfolding from LP to W renders the process highly favorable since the unfolded end state has 〉 1 kcal·mol−1 per residue excess stabilization.

Type of Medium: Online Resource

ISSN: 1422-0067

URL: Article

DOI: 10.3390/ijms22168595

Language: English

Publisher: MDPI AG

Publication Date: 2021

detail.hit.zdb_id: 2019364-6

SSG: 12

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