Protein folding, misfolding and aggregation: The importance of two-electron stabilizing interactions

Cieplak, Andrzej Stanislaw

doi:10.1371/journal.pone.0180905

Cited by 15 publications

(21 citation statements)

References 360 publications

(452 reference statements)

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“…External factors are also taken into account as affecting structural changes in proteins [22][23][24][25]. Oligomerization is also recognized as a phenomenon that stimulates the adoption of different structural forms of metamorphic proteins [26].…”

Section: Introductionmentioning

confidence: 99%

Structure of the Hydrophobic Core Determines the 3D Protein Structure—Verification by Single Mutation Proteins

et al. 2020

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Four de novo proteins differing in single mutation positions, with a chain length of 56 amino acids, represent diverse 3D structures: monomeric 3α and 4β + α folds. The reason for this diversity is seen in the different structure of the hydrophobic core as a result of synergy leading to the generation of a system in which the polypeptide chain as a whole participates. On the basis of the fuzzy oil drop model, where the structure of the hydrophobic core is expressed by means of the hydrophobic distribution function in the form of a 3D Gaussian distribution, it has been shown that the composition of the hydrophobic core in these two structural forms is different. In addition, the use of a model to determine the structure of the early intermediate in the folding process allows to indicate differences in the polypeptide chain geometry, which, combined with the construction of a common hydrophobic nucleus as an effect of specific synergy, may indicate the reason for the diversity of the folding process of the polypeptide chain. The results indicate the need to take into account the presence of an external force field originating from the water environment and that its active impact on the formation of a hydrophobic core whose participation in the stabilization of the tertiary structure is fundamental.

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Section: Introductionmentioning

confidence: 99%

Structure of the Hydrophobic Core Determines the 3D Protein Structure—Verification by Single Mutation Proteins

et al. 2020

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“…Unfortunately, our current understanding of protein folding and misfolding is limited for want of a physicochemical theory of protein secondary and tertiary structure (Baldwin and Rose, 1999). Recognizing these limitations, an attempt was recently made to construct such a theory, using the PMO theory-informed approach and focusing on the electronic configuration and hyperconjugation of the peptide amide bonds (Cieplak, 2017). To capture the effect of polarization of peptide linkages on the conformational and H-bonding propensity of the polypeptide backbone, a function of the NMR shielding tensors of the C α atoms was introduced as the folding potential function FP i .…”

Section: Introductionmentioning

confidence: 99%

“…The FP i function proved to be an effective tool to investigate conformational behavior of the intrinsically disordered and pleiomorphic proteins, revealing a common pattern of backbone density distribution in the amyloidogenic regions of several highly pleiomorphic proteins associated with neurodegenerative diseases: amyloid beta Aβ, tau, α-synuclein αS, and mammalian prions PrP C . A common molecular model of aggregation of these proteins was consequently proposed (Cieplak, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The folding potential function FP i is a function of the NMR shielding tensors of the C α atoms, σ (C α ) Xaa , which were obtained by quantum mechanical modeling of protein secondary structure. The calculations were carried out using the oligopeptides AcGXaaGGGNH 2 and AcGGGGGXaaNHMe as the models of the 3 10 -helix and the hairpin with the type Ib reverse turn, respectively, at the B3LYP/D95 ** level of the theory [Gaussian 98, Revisions A.3, A.7, A11.2 (Frisch et al, 1998)], according to the protocol described previously in Cieplak (2017). The canonical and covalently modified residues Xaa (the L-amino acid series) of the hexapeptide hairpin and the pentapeptide helix were systematically varied, taking into account side chain conformations (Kyte, 1995) and ionization state when appropriate, to yield the total of 141 congener structures.…”

Section: Introductionmentioning

confidence: 99%

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Tau Inclusions in Alzheimer's, Chronic Traumatic Encephalopathy and Pick's Disease. A Speculation on How Differences in Backbone Polarization Underlie Divergent Pathways of Tau Aggregation

Cieplak

2019

Front. Neurosci.

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Tau-related dementias appear to involve specific to each disease aggregation pathways and morphologies of filamentous tau assemblies. To understand etiology of these differences, here we elucidate molecular mechanism of formation of tau PHFs based on the PMO theory of misfolding and aggregation of pleiomorphic proteins associated with neurodegenerative diseases. In this model, fibrillization of tau is initiated by the coupled binding and folding of the MTB domains that yields antiparallel homodimers, in analogy to folding of split inteins. The free energy of binding is minimized when the antiparallel alignment brings about backbone-backbone H-bonding between the MTBD segments of similar “strand” propensities. To assess these propensities, a function of the NMR shielding tensors of the C α atoms is introduced as the folding potential function FP i ; the C α tensors are obtained by the quantum mechanical modeling of protein secondary structure (GIAO//B3LYP/D95 ** ). The calculated FP i plots show that the “strand” propensities of the MBTD segments, and hence the homodimer's register, can be affected by the relatively small changes in the environment's pH, as a result of protonation of MBTD's conserved histidines. The assembly of the antiparallel tau dimers into granular aggregates and their subsequent conversion into the parallel cross-β structure of paired helical filaments is expected to follow the same path as the previously described fibrillization of Aβ. Consequently, the core structure of the nascent tau fibril is determined by the register of the tau homodimer. This model accounts for the reported differences in (i) fibril-core structure of in vivo and in vitro filaments, (ii) cross-seeding of isoforms, (iii) effects of reducing/non-reducing conditions, (iv) effects of PHF6 mutations, and (v) homologs' aggregation properties. The proposed model also suggests that in contrast to Alzheimer's and chronic traumatic encephalopathy disease, the assembly of tau prions in Pick's disease would be facilitated by a moderate drop in pH that accompanies e.g., transit in the endosomal system, inflammation response or an ischemic injury.

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“…Furthermore, each strand forms H-bonds with the adjacent strand (β1 with β6 and β2 with β15). These lateral H-bonds were peculiar for the β-jellyroll fold 18 . Furthermore, we observed a H-bond between the polar side chains of Arg 34 (β1) and Asp 165 (β16), and another one between the polar side chains of Glu 41 (β2) and Asn 148 (β15) (Fig.…”

mentioning

confidence: 96%

Mutational analysis of the essential lipopolysaccharide-transport protein LptH of Pseudomonas aeruginosa to uncover critical oligomerization sites

Scala

Matteo

Coluccia

et al. 2020

Sci Rep

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Lipopolysaccharide (LpS) is a critical component of the outer membrane (oM) of many Gramnegative bacteria. LpS is translocated to the oM by the LpS transport (Lpt) system. in the human pathogen Pseudomonas aeruginosa, the periplasmic Lpt component, LptH, is essential for LpS transport, planktonic and biofilm growth, OM stability and infectivity. LptH has been proposed to oligomerize and form a protein bridge that accommodates LPS during transport. Based on the known LptH crystal structure, here we predicted by in silico modeling five different sites likely involved in LptH oligomerization. The relevance of these sites for LptH activity was verified through plasmidmediated expression of site-specific mutant proteins in a P. aeruginosa lptH conditional mutant. complementation and protein expression analyses provided evidence that all mutated sites are important for LptH activity in vivo. It was observed that the lptH conditional mutant overcomes the lethality of nonfunctional lptH variants through RecA-mediated homologous recombination between the wild-type lptH gene in the genome and mutated copies in the plasmid. finally, biochemical assays on purified recombinant proteins showed that some LptH variants are indeed specifically impaired in oligomerization, while others appear to have defects in protein folding and/or stability. The cell envelope of diderm (Gram-negative) bacteria consists of two concentric membranes, the inner (IM) and outer membrane (OM), which confine an aqueous compartment, the periplasmic space, in which a thin layer of peptidoglycan is embedded. While the IM is a typical phospholipids bilayer, the OM of most diderm bacteria is an asymmetric membrane composed of lipopolysaccharide (LPS) and phospholipids in the outer and inner leaflets, respectively 1. LPS is a negatively charged glycolipid that forms a tightly packed layer at the cell surface. The LPS layer is important for the structural stability of the OM, and provides an effective permeability barrier to the entry of potentially noxious compounds 2. LPS is synthesized in the cytoplasm, matured in the periplasm and translocated to the OM by the Lpt (Lipopolysaccharide transport) system that, in the model organism Escherichia coli, is composed of seven essential proteins (LptABCDEFG). The Lpt protein complex spans the entire cell envelope and consists of two subassemblies, LptB 2 CFG at the IM and LptDE at the OM, connected by the periplasmic protein LptA 3-5. LptB 2 FG is an ATP-binding cassette (ABC) transporter that, in association with the bitopic protein LptC, powers LPS transport to the cell surface, while the β-barrel protein LptD and the lipoprotein LptE constitute the OM translocon that inserts LPS into the outer leaflet of the OM 3-5 (Fig. 1A).

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Protein folding, misfolding and aggregation: The importance of two-electron stabilizing interactions

Cited by 15 publications

References 360 publications

Structure of the Hydrophobic Core Determines the 3D Protein Structure—Verification by Single Mutation Proteins

Structure of the Hydrophobic Core Determines the 3D Protein Structure—Verification by Single Mutation Proteins

Tau Inclusions in Alzheimer's, Chronic Traumatic Encephalopathy and Pick's Disease. A Speculation on How Differences in Backbone Polarization Underlie Divergent Pathways of Tau Aggregation

Mutational analysis of the essential lipopolysaccharide-transport protein LptH of Pseudomonas aeruginosa to uncover critical oligomerization sites

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