Adverse effect of ethanol on insulin dimer stability

TL;DR

This study investigates how ethanol affects insulin dimer stability by computing free energy surfaces, revealing ethanol reduces dissociation barriers and alters pathways, which may impact diabetes understanding.

Contribution

It provides detailed computational analysis of insulin dimer dissociation in ethanol-water mixtures, highlighting ethanol's destabilizing effects and new intermediate states.

Findings

Ethanol decreases dissociation energy barrier by ~40%.

Ethanol smoothens the free energy surface ruggedness.

A stable intermediate state is identified in ethanol mixtures.

Abstract

Alcohol is widely believed to have an effect on diabetes, often considered beneficial in small amounts but detrimental in excess. The reasons are not fully known but questions have been asked about the stability of insulin oligomers in the presence of ethanol. We compute the free energy surface (FES) and the pathway of insulin dimer dissociation in water and in 5% and 10% water-ethanol mixture. We find that in the presence of ethanol the barrier energy of dissociation reaction decreases by about 40% even in 5% water-ethanol solution. In addition, ethanol induces a significant change in the reaction pathway. We obtain estimates of the rate of reaction and binding energy for all the three systems and those agree well with the previous experimental results for the insulin dimer dissociation in water. The computed FES in water exhibits ruggedness due to the existence of a number of intermediate states surrounded by high and broad transition state region. However, the presence of ethanol smoothens out the ruggedness. We extracted the conformations of the intermediate states along the minimum energy pathway in all the three systems and analyzed the change in microscopic structures in the presence of ethanol. Interestingly, we discover a stable intermediate state in water-ethanol mixtures where the monomers are separated (center-to-center) by about 3 nm and the contact order parameter is close to zero. This intermediate is stabilized by the distribution of ethanol and water molecules at the interface and which, significantly, serves to reduce the dissociation rate constant .The solvation of the two monomers during the dissociation and proteins' departure from native state configuration are analyzed to obtain insight into the dimer dissociation processes.