High resolution structure of a partially folded insulin aggregation intermediate

Ratha, Bhisma N; Kar, Rup Kumar; Brender, Jeffrey R.; Sahoo, Bankanidhi; Kalita, Sujan; Bhunia, Anirban

doi:10.1101/716845

2019

DOI: 10.1101/716845

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High resolution structure of a partially folded insulin aggregation intermediate

Bhisma N Ratha

Rup Kumar Kar

Jeffrey R. Brender

et al.

Abstract: Insulin has long served as a model for protein aggregation, both because of the importance of aggregation in insulin manufacture and because the structural biology of insulin has been extensively characterized. Despite intensive study, details about the initial triggers for aggregation have remained elusive at the molecular level. We show here that at acidic pH, the aggregation of insulin is likely initiated by a partially folded monomeric intermediate whose concentration is controlled by an off-pathway micell… Show more

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Mechanistic Studies of the Stabilization of Insulin Helical Structure by Coomassie Brilliant Blue

Dolui¹,

Pariary

Saha³

et al. 2020

Preprint

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Human insulin (HI) is an essential protein hormone and its biological activity mostly depends on folded and active conformation in the monomeric state. The present investigation established that Coomassie Brilliant Blue G-250 (CBBG), a small multicyclic hydroxyl compound can reversibly bind to the hormonal protein dimer and maintained most of α-helical folds crucial for biological function of the enzyme. The solution-state 1D NMR and isothermal calorimetric analysis showed a sub-micromolar binding affinity of the molecule to HI. 2D NOESY NMR established that the HI dimer undergoes residue level local conformational change upon binding to CBBG. The chemical shift perturbation and the NOE parameters of active protons of amino acid residues throughout the polypeptides further suggested that CBBG upon binding the protein stabilize α-helixes of both the A and B subunits of the hormonal protein. The changes in Gibb’s free energy (∆G) of the binding was of ~−11.1 kcal/mol and suggested a thermodynamically favourable process. The changes in enthalpy (∆H) and entropy term (T∆S) were −57.2 kcal/mol and −46.1 kcal/mol, respectively. The negative changes in entropy and the NOE transfer effectiveness of several residues in the presence of CBBG molecules indicated that the binding was an enthalpy driven favourable equilibrium process. The NMR-based atomic resolution data and molecular docking studies confirmed that the CBBG binds to HI at the dimeric stage and prevents the availability of the crucial residue segments that partake directly in further oligomerization and subsequent fibrillation. Extended computational analysis based on chemical shift perturbation of protons of active residues further established receptor-ligand based pharmacophore model comprised of 5 hydrophobic and a hydrogen bond acceptor features that can anchor the residues at the A and B chains of HI and inhibit the partial unfolding and hydrophobic collapse to nucleate the fibrillation. Taken together, the results demonstrated that CBBG and their close analogues might be useful to develop a formulation that will maintain the active and functional form of the hormonal protein for a significantly longer time.TOC

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Mechanistic Studies of the Stabilization of Insulin Helical Structure by Coomassie Brilliant Blue

Dolui¹,

Pariary

Saha³

et al. 2020

Preprint

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show abstract

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High resolution structure of a partially folded insulin aggregation intermediate

Cited by 1 publication

References 67 publications

Mechanistic Studies of the Stabilization of Insulin Helical Structure by Coomassie Brilliant Blue

Mechanistic Studies of the Stabilization of Insulin Helical Structure by Coomassie Brilliant Blue

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