The Budapest Amyloid Predictor and Its Applications

Keresztes, László; Evelin, Szogi,; Varga, Bálint; Farkas, Viktor; Perczel, András; Grolmusz, Vince

doi:10.3390/biom11040500

Cited by 23 publications

(35 citation statements)

References 25 publications

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“…As a starting point to uncover possible physical explanations for the dependence on even/odd spacing, we analyzed representative sequences -- 60:Q 3 N, 60:Q 4 N, 60:Q 5 N, 60:Q, 60:N -- with state-of-the-art amyloid predictors (Charoenkwan et al, 2021; Keresztes et al, 2021; Prabakaran et al, 2021). Using their respective default parameters, we found that most predictors failed entirely to detect amyloid propensity among these sequences.…”

Section: Resultsmentioning

confidence: 99%

The polyglutamine amyloid nucleus in living cells is a monomer with competing dimensions of order

Kandola

Zhang

Venkatesan

et al. 2021

Preprint

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A long-standing goal of the study of amyloids has been to characterize the physical nature of the rate-determining nucleating event. However, the transience and rarity of that event within the heterogeneous ensemble of states populated by amyloid-forming proteins make it inaccessible to classical biochemistry, structural biology, and computational approaches. Here, we address these limitations by measuring the dependence of amyloid formation on concentration and conformational templates in living cells, whose volumes are sufficiently small to resolve independent nucleation events. We characterized over one hundred rationally designed sequence variants of polyglutamine (polyQ), a polypeptide that precipitates Huntingtons and other amyloid-associated neurodegenerative diseases when its length exceeds a characteristic threshold. We deduce that amyloid formation by polyQ begins with a steric zipper embryo of approximately twelve interdigitated glutamine side chains within an individual polypeptide molecule. Formation of the embryo was limited to polypeptides longer than the pathogenic threshold, and involved neither phase separation nor oligomerization. We found that different amyloid propensities of polyQ sequence variants can be rationalized by steric zipper ordering orthogonally to the axis of polymerization, and validated this intuition using all-atom molecular dynamics simulations. The unique ability of the polyQ sequence to fold in this fashion not only allowed for polyQ amyloid to nucleate from low concentrations; it also stalled amyloid growth with a concomitant accumulation of partially-ordered oligomers. By illuminating the structural mechanism of polyQ amyloid formation in cells, our findings reveal a potential molecular etiology for polyQ diseases, and may provide a roadmap for the design of new therapies.

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Section: Resultsmentioning

confidence: 99%

The polyglutamine amyloid nucleus in living cells is a monomer with competing dimensions of order

Kandola

Zhang

Venkatesan

et al. 2021

Preprint

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“…We have introduced the Budapest Amyloid Predictor webserver in the work [14] by applying linear Support Vector Machines as the underlying prediction tool [15], and the Waltz dataset [16,17] for training and testing purposes. The Waltz dataset consists of 1415 hexapeptides, from which 514 peptides are experimentally labeled as "amyloidogenic" and 901 hexapeptides as "nonamyloidogenic".…”

Section: Methodsmentioning

confidence: 99%

“…Therefore, a hexapeptide was represented by a length 6 × 553 = 3318 vector z. We note that this highly redundant representation has given somewhat better predictions than more concise ones [14] and has not caused any difficulties in what follows.…”

Section: Methodsmentioning

confidence: 99%

“…Recently we built a Support Vector Machine for amyloidogenecity prediction of hexapeptides [14]. The training set was the Waltz dataset [16,17] of experimentally identified 514 amyloidogenic and 901 non-amyloidogenic hexapeptides.…”

Section: Introductionmentioning

confidence: 99%

“…. , y m were assigned to each hexapeptide, and using this multi-dimensional representation, we have prepared an SVM, called Budapest Amyloid Predictor (abbreviated as BAP), described in detail in [14], and freely available at the address https://pitgroup.org/bap.…”

Section: Introductionmentioning

confidence: 99%

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Succinct Amyloid and Non-Amyloid Patterns in Hexapeptides

Keresztes¹,

Evelin²,

Varga³

et al. 2022

Preprint

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Hexapeptides are widely applied as a model system for studying amyloidforming properties of polypeptides, including proteins. Recently, large experimental databases have become publicly available with amyloidogenic labels. Using these datasets for training and testing purposes, one may build artificial intelligence (AI)-based classifiers for predicting the amyloid state of peptides. In our previous work (Biomolecules, 11(4) 500, ( 2021)) we described the Support Vector Machine (SVM)-based Budapest Amyloid Predictor (https://pitgroup.org/bap). Here we apply the Budapest Amyloid Predictor for discovering numerous amyloidogenic and non-amyloidogenic hexapeptide patterns with accuracy between 80% and 84%, as surprising and succinct novel rules for further understanding the amyloid state of peptides. For example, we have shown that for any independently mutated residue (position marked by "x"), the patterns CxFLWx, FxFLFx, or xxIVIV are predicted to be amyloidogenic, while those of PxDxxx, xxKxEx, and xxPQxx non-amyloidogenic at all. We note that each amyloidogenic pattern with two x's (e.g.,CxFLWx) describes succinctly 20 2 = 400 hexapeptides, while the non-amyloidogenic patterns comprising four point mutations (e.g.,PxDxxx) gives 20 4 = 160, 000 hexapeptides in total. We also examine restricted substitutions for positions "x" from subclasses of proteinogenic amino acid residues; for example, if "x" is substituted with hydrophobic amino acids, then there exist patterns containing three x's, like MxVVxx, predicted to be amyloidogenic. If we can choose for the x positions any hydrophobic amino acids, except the "structure breaker" proline, then we get amyloid patterns with five x positions, e.g., xxxFxx, each corresponding to 32,768 hexapeptides. To our knowledge, no similar applications of artificial intelligence tools or succinct amyloid patterns were described before the present work.

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