Sequence-based prediction of pH-dependent protein solubility using CamSol

Oeller, Marc; Kang, Ryan; Bell, Rosie; Ausserwöger, Hannes; Sormanni, Pietro; Vendruscolo, Michele

doi:10.1093/bib/bbad004

Cited by 25 publications

(24 citation statements)

References 31 publications

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“…However, experimental methods to evaluate the developability of peptides containing mAAs are typically costly, and current computational approaches lack the capability of capturing the effects of mAAs on the solubility of peptides. To address this problem, we have presented CamSol-PTM, a software that predicts the solubility of peptides and proteins containing non-canonical amino acids based on the physico-chemical properties of their amino acid sequences [74][75][76] .…”

Section: Discussionmentioning

confidence: 99%

“…In this work we exploited the CamSol framework for the accurate prediction of the solubility of proteins [74][75][76] to introduce a method able to predict the effect of mAAs on the solubility of peptides. The original CamSol method predicts the solubility of proteins by combining tabulated values of hydrophobicity, charge, and α-helical and β-sheet propensities of the 20 standard amino acids.…”

Section: Computational Predictionsmentioning

confidence: 99%

“…To bridge this gap, here we exploited the CamSol framework for the prediction of solubility [74][75][76] to develop the CamSol-PTM method, which can handle peptides containing mAAs. CamSol-PTM is capable of assessing the effect of any kind of small-size non-canonical amino acid on the solubility of peptides by combining a range of different physico-chemical property predictors.…”

Section: Introductionmentioning

confidence: 99%

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Sequence-based prediction of the solubility of peptides containing non-natural amino acids

Oeller

Kang

Bolt

et al. 2023

Preprint

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Non-natural amino acids are increasingly used as building blocks in the development of peptide-based drugs, as they expand the available chemical space to tailor function, half-life and other key properties. However, while the chemical space of modified amino acids (mAAs) is potentially vast, experimental methods for measuring the developability properties of mAA-containing peptides are expensive and time consuming. To facilitate developability programs through computational methods, we present CamSol-PTM, a method that enables the fast and reliable sequence-based prediction of the solubility of mAA-containing peptides. From a computational screening of 50,000 mAA-containing variants of three peptides, we selected five different mAAs for a total number of 30 peptide variants for experimental validation. We demonstrate the accuracy of the predictions by comparing the calculated and experimental solubility values. Our results indicate that the computational screening of mAA-containing peptides can extend by over four orders of magnitude the ability to explore the solubility chemical space of peptides. This method is available as a web server athttps://www-cohsoftware.ch.cam.ac.uk/index.php/camsolptm.

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Section: Discussionmentioning

confidence: 99%

Section: Computational Predictionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sequence-based prediction of the solubility of peptides containing non-natural amino acids

Oeller

Kang

Bolt

et al. 2023

Preprint

Self Cite

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“…Despite the lack of a consensus formalism to model log D pH as a function of

{P_{{\rm{IP}}}^{{\rm{app}}} }

, and considering that different theoretical approaches have shown similar trends, [14,21,22] Equation 2 has been successfully used for modeling the lipophilicity of ionized compounds in many areas of basic and applied sciences. For instance, to study the aggregation of naphthenic acids in aqueous environments with different saline concentrations, [50] in log D pH calculations for lignin derivatives and small datasets of drug‐like compounds in different solvents by QM and statistical thermodynamical methods, [51] partitioning of antioxidants, [52] aquatic hazard assessment of ionizable organic chemicals, [53] sorption mechanisms of antimicrobials in the soil, [54] and physicochemical properties of peptides and proteins [15–18] …”

Section: Introductionmentioning

confidence: 99%

Critical Assessment of pH‐Dependent Lipophilicity Profiles of Small Molecules: Which One Should We Use and In Which Cases?

Bertsch,

Suñer,

Pinheiro

et al. 2023

ChemPhysChem

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Lipophilicity is a physicochemical property with wide relevance in drug design, computational biology, and food, environmental and medicinal chemistry. Lipophilicity is commonly expressed as the partition coefficient for neutral molecules, whereas for molecules with ionizable groups, the distribution coefficient (D) at a given pH is used. The logDpH is usually predicted using a pH correction, while often ignoring the apparent ionic partition [[EQUATION]]. In this work, we studied the impact of [[EQUATION]] on the prediction of both the experimental lipophilicity of small molecules and experimental lipophilicity‐based applications and metrics such as lipophilic efficiency (LipE), distribution of spiked drugs in milk products, and pH‐dependent partition of water contaminants in synthetic passive samples such as silicones. Our findings show that better predictions are obtained by considering the apparent ionic partition. In this context, we developed machine learning algorithms to determine the cases that [[EQUATION]] should be considered. The results indicate that small, rigid, and unsaturated molecules with logPN close to zero, which present a significant proportion of ionic species in the aqueous phase, were better modeled using the apparent ionic partition [[EQUATION]]). Finally, our findings can serve as guidance to the scientific community working in early‐stage drug design, food, and environmental chemistry

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“…Both algorithms have separately been validated on experimental data for a wide range of proteins and antibodies (CamSol Refs. 4,14,23,37,[39][40][41][42][43][44]34,[45][46][47][48]. Our method also includes an ad-hoc recipe to obtain and exploit suitable phylogenetic information for immunoglobulin variable domains, as these are a key class of biologics that, because of their modular nature, cannot be handled with standard tools for searching homologs.…”

mentioning

confidence: 99%

Automated optimisation of solubility and conformational stability of antibodies and proteins

et al. 2023

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Biologics, such as antibodies and enzymes, are crucial in research, biotechnology, diagnostics, and therapeutics. Often, biologics with suitable functionality are discovered, but their development is impeded by developability issues. Stability and solubility are key biophysical traits underpinning developability potential, as they determine aggregation, correlate with production yield and poly-specificity, and are essential to access parenteral and oral delivery. While advances for the optimisation of individual traits have been made, the co-optimization of multiple traits remains highly problematic and time-consuming, as mutations that improve one property often negatively impact others. In this work, we introduce a fully automated computational strategy for the simultaneous optimisation of conformational stability and solubility, which we experimentally validate on six antibodies, including two approved therapeutics. Our results on 42 designs demonstrate that the computational procedure is highly effective at improving developability potential, while not affecting antigen-binding. We make the method available as a webserver at www-cohsoftware.ch.cam.ac.uk.

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Sequence-based prediction of pH-dependent protein solubility using CamSol

Cited by 25 publications

References 31 publications

Sequence-based prediction of the solubility of peptides containing non-natural amino acids

Sequence-based prediction of the solubility of peptides containing non-natural amino acids

Critical Assessment of pH‐Dependent Lipophilicity Profiles of Small Molecules: Which One Should We Use and In Which Cases?

Automated optimisation of solubility and conformational stability of antibodies and proteins

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