Litcius/Paper detail

<scp>PEG–mCherry</scp> interactions beyond classical macromolecular crowding

Liam Haas‐Neill, Khalil Joron, Eitan Lerner, Sarah Rauscher

2025Protein Science10 citationsDOIOpen Access PDF

Abstract

The dense cellular environment influences bio-macromolecular structure, dynamics, interactions, and function. Despite advancements in understanding protein-crowder interactions, predicting their precise effects on protein structure and function remains challenging. Here, we elucidate the effects of PEG-induced crowding on the fluorescent protein mCherry using molecular dynamics simulations and fluorescence-based experiments. We identify and characterize specific PEG-induced structural and dynamical changes in mCherry. Importantly, we find interactions in which PEG molecules wrap around specific surface-exposed residues in a binding mode previously observed in protein crystal structures. Fluorescence correlation spectroscopy experiments capture PEG-induced changes, including aggregation, suggesting a potential role for the specific PEG-mCherry interactions identified in simulations. Additionally, mCherry fluorescence lifetimes are influenced by PEG and not by the bulkier crowder dextran or by another linear polymer, polyvinyl alcohol, highlighting the importance of crowder-protein soft interactions. This work augments our understanding of macromolecular crowding effects on protein structure and dynamics.

Topics & Concepts

mCherryMacromolecular crowdingBiophysicsPEG ratioMacromoleculeChemistryMolecular dynamicsBiomoleculeIntrinsically disordered proteinsFunction (biology)FluorescenceProtein dynamicsFluorescence correlation spectroscopyProtein structureGreen fluorescent proteinMoleculeBiochemistryCell biologyBiologyComputational chemistryPhysicsQuantum mechanicsFinanceEconomicsGeneOrganic chemistryEnzyme Structure and FunctionProtein Structure and DynamicsPhotosynthetic Processes and Mechanisms