Metastability of Native Proteins and the Phenomenon of Amyloid Formation

Baldwin, Andrew J.; Knowles, Tuomas P. J.; Tartaglia, Gian Gaetano; Fitzpatrick, Anthony; Devlin, Glyn L.; Shammas, Sarah L.; Waudby, Christopher A.; Mossuto, Maria F.; Meehan, Sarah; Gras, Sally L.; Christodoulou, John; Anthony-Cahill, Spencer J.; Barker, Paul D.; Vendruscolo, Michele

doi:10.1021/ja2017703

Cited by 385 publications

(475 citation statements)

References 23 publications

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“…An alternative, and it should be noted, equally speculative, explanation would involve pointing out that through mutation, we may not only be altering the ground state energetics but the energies of transition states as well, which would surely affect the metastability of the oligomerized state opening up irreversibility which manifests as aggregation. 37 Our mutants may be useful tools to understand these mechanisms and states. In addition, as our stated long-term goal is to convert a mini-ferritin-forming monomer into one that assembles into a maxiferritin, and vice versa, this research where we have learned how to logically disassemble a miniferritin into an intermediate that may be common to both types of cages would be a reasonable initial step.…”

Section: Discussionmentioning

confidence: 99%

Rational disruption of the oligomerization of the mini‐ferritin E. coli DPS through protein‐protein interface mutation

Zhang

Chee

et al. 2011

Protein Science

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DNA-binding protein from starved cells (DPS), a mini-ferritin capable of self-assembling into a 12-meric nano-cage, was chosen as the basis for an alanine-shaving mutagenesis study to investigate the importance of key amino acid residues, located at symmetry-related protein-protein interfaces, in controlling protein stability and self-assembly. Nine mutants were designed through simple inspection, synthesized, and subjected to transmission electron microscopy, circular dichroism, size exclusion chromatography, and ''virtual alanine scanning'' computational analysis. The data indicate that many of these residues may be hot spot residues. Most remarkably, two residues, R83 and R133, were observed to shift the oligomerization state to~50% dimer. Based on the hypothesis that these two residues constitute a ''hot strip,'' located at the ferritin-like threefold axis, the double mutant was generated which completely shuts down detectable formation of 12-mer in solution, favoring a cooperatively folded dimer. The fact that this effect logically builds upon the single mutants emphasizes that complex self-assembly has the potential to be manipulated rationally. This study should have an impact on the fundamental understanding of the assembly of DPS protein cages specifically and protein quaternary structure in general. In addition, as there is much interest in applying these and similar systems to the templation of nano-materials and drug delivery, the ability to control this ferritin's oligomerization state and stability could prove especially valuable.

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Section: Discussionmentioning

confidence: 99%

Rational disruption of the oligomerization of the mini‐ferritin E. coli DPS through protein‐protein interface mutation

Zhang

Chee

et al. 2011

Protein Science

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“…While these parameters were obtained in a carbohydrate system, the overall binding strength is comparable to that found in amyloids 38 and the explicit enthalpy and entropy contributions will permit the exploration of temperature effects. I take N β = 21 as suggested by Jiménez et al 28 and use the total number of amino acids on both peptide strands for the length L = 51.…”

Section: A Growth Rates Are Limited By the Low Probability Of In-regmentioning

confidence: 98%

“…Insulin is somewhat challenging to model because of the unknown fibril structure and the conformational constraints imposed by the disulfide bonds. Also, while the stability of insulin fibrils is known 38 this value is a combination of both intermolecular bonds and intramolecular contacts between the two peptide strands. Rather than attempt a blind deconvolution of these factors in the absence of a structure, I will neglect the attractive contribution from sidechain packing interactions and the repulsive contribution from conformational entropy and assume that the intermolecular H-bonds have the same thermodynamic properties as the bonds studied in detail by Ross and Rekharsky,39 …”

Section: A Growth Rates Are Limited By the Low Probability Of In-regmentioning

confidence: 99%

Kinetic theory of amyloid fibril templating

Schmit

2013

The Journal of Chemical Physics

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The growth of amyloid fibrils requires a disordered or partially unfolded protein to bind to the fibril and adapt the same conformation and alignment established by the fibril template. Since the H-bonds stabilizing the fibril are interchangeable, it is inevitable that H-bonds form between incorrect pairs of amino acids which are either incorporated into the fibril as defects or must be broken before the correct alignment can be found. This process is modeled by mapping the formation and breakage of H-bonds to a one-dimensional random walk. The resulting microscopic model of fibril growth is governed by two timescales: the diffusion time of the monomeric proteins, and the time required for incorrectly bound proteins to unbind from the fibril. The theory predicts that the Arrhenius behavior observed in experiments is due to off-pathway states rather than an on-pathway transition state. The predicted growth rates are in qualitative agreement with experiments on insulin fibril growth rates as a function of protein concentration, denaturant concentration, and temperature. These results suggest a templating mechanism where steric clashes due to a single mis-aligned molecule prevent the binding of additional molecules.

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“…The fact that the cross-b structure is a characteristic arrangement of polypeptide chains is supported by the results of computer simulations (Auer et al 2008), as well as by theoretical analysis and by the results of investigations of the role of the arrays of hydrogen bonds that are features of this molecular architecture (Knowles et al 2007). Although the specific protein sequence does not itself define this overall architecture, it does play a major role in defining the relative propensity of a given protein to convert from its normal functional state to the polymeric amyloid state, a feature that turns out to be crucial in enabling proteins in living systems to avoid rapid conversion into their amyloid states that in many cases may be thermodynamically the most stable state of a protein molecule (Baldwin et al 2011). …”

Section: The Generic Nature Of the Amyloid Statementioning

confidence: 99%

“…One of the key advances in our understanding of Alzheimer's disease and related conditions has been the realisation that for many proteins, particularly those that are relatively small or have been fragmented by proteolytic enzymes, the amyloid state can be more stable thermodynamically than the native state even under physiological conditions (Baldwin et al 2011). The reason for the ability of such species to resist the conversion from their soluble forms into the amyloid state is, therefore, strongly dependent on the kinetics of this transition, the details of which are now beginning to emerge.…”

Section: Towards Therapeutic Intervention In Amyloid Diseasesmentioning

confidence: 99%

Alzheimer’s disease: addressing a twenty-first century plague

Dobson

2015

Rend. Fis. Acc. Lincei

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Alzheimer's disease represents one of the greatest challenges to the social fabric and health care systems of the world since the great plagues of the Middle Ages. At the present time, there are some 40 million sufferers from this disease worldwide, but it is predicted that this number will rise to nearly 150 million by 2050. The predominant reason for this rapidly increasing prevalence is the increase in longevity that has resulted from the tremendous advances in public health and hygiene and in medical and surgical interventions over the last century. This article discusses recent progress in our understanding of the molecular origins of Alzheimer's disease and emerging ideas for new and rational therapeutic strategies by which to combat its onset and progression.

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Metastability of Native Proteins and the Phenomenon of Amyloid Formation

Cited by 385 publications

References 23 publications

Rational disruption of the oligomerization of the mini‐ferritin E. coli DPS through protein‐protein interface mutation

Rational disruption of the oligomerization of the mini‐ferritin E. coli DPS through protein‐protein interface mutation

Kinetic theory of amyloid fibril templating

Alzheimer’s disease: addressing a twenty-first century plague

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