Mixed Macromolecular Crowding: A Protein and Solvent Perspective.

In the living cell, biomolecules perform their respective functions in the presence of not only one type of macromolecules but rather in the presence of various macromolecules with different shapes and sizes. In this study, we have investigated the effects of five single macromolecular crowding agents, Dextran 6, Dextran 40, Dextran 70, Ficoll 70, and PEG 8000 and their binary mixtures on the modulation in the domain separation of human serum albumin using a Förster resonance energy transfer-based approach and the translational mobility of a small fluorescent probe fluorescein isothiocyanate (FITC) using fluorescence correlation spectroscopy (FCS). Our observations suggest that mixed crowding induces greater cooperativity in the domain movement as compared to the components of the mixtures. Thermodynamic analyses of the same provide evidence of crossovers from enthalpy-based interactions to effects dominated by hard-sphere potential. When compared with those obtained for individual crowders, both domain movements and FITC diffusion studies show significant deviations from ideality, with an ideal solution being considered to be that arising from the sum of the contributions of those obtained in the presence of individual crowding agents. Considering the fact that domain movements are local (on the order of a few angstroms) in nature while translational movements span much larger lengthscales, our results imply that the observed deviation from simple additivity exists at several possible levels or lengthscales in such mixtures. Moreover, the nature and the type of deviation not only depend on the identities of the components of the crowder mixtures but are also influenced by the particular face of the serum protein (either the domain I-II or the domain II-III face) that the crowders interact with, thus providing further insights into the possible existence of microheterogeneities in such solutions.

Crowder-Induced Rigidity in a Multidomain Protein: Insights from Solvation.

Global changes in the conformations of proteins in the presence of macromolecular crowding agents have been well documented. Here, we have used solvation dynamics to monitor the changes in a specific domain of the multidomain protein human serum albumin (HSA) in the presence of various crowders. The solvation probe 6-bromoacetyl-2-dimethylaminonaphthalene was site-specifically attached to the cysteine-34 of domain I of HSA. Analyses of the time-resolved Stokes shift of this probe in the presence of crowding agents revealed a significant retardation of the solvent coordinate, particularly in a crowder-dependent manner. We attribute the observed slowing primarily to the increased internal protein friction in the presence of these polymers, implying considerable stiffness of the protein matrix. We have discussed our findings with regard to recent reports on cellular interiors and have also made an attempt to assess the importance of the physiological concentration of macromolecules in protein dynamics and function.

Correlated and Anticorrelated Domain Movement of Human Serum Albumin: A Peek into the Complexity of the Crowded Milieu.

Protein dynamics in cells have been shown to be markedly different from that in dilute solutions because of the highly crowded cellular interior. The volume exclusion arising from the high concentration of macromolecules present can affect both equilibrium and kinetic processes involving protein conformational changes. While global changes in structure leading to modulations in the stability of the protein have been well-documented, local changes that can have a large bearing on the functional aspects of these biomolecules are rare to come across. Using the multidomain serum protein human serum albumin and a fluorescence resonance energy transfer (FRET)-based approach, with fluorescent reporters in each of its three domains, we, in this article, have provided a detailed mapping of variations in the interdomain distances (as a function of pH) in the presence of five macromolecular crowding agents, differing based on their constituent monomers and average molecular weight(s). From the observation of correlated domain movements for dextran based crowding agents to anticorrelated motion induced by Ficoll 70, and both correlated and anticorrelated action for PEG8000 (PEG8), our results reveal the inherent complexity of a crowded milieu with the serum protein serving as an able sensor for decoding such variations. Differences in the manner in which the macromolecular crowders of similar average molecular weights influence the protein conformational ensemble also provide insights into the possible variations at the molecular level that these polymeric molecules possess. Evidence is presented in support of the fact that for the large molecular weight crowding agents and PEG8, soft interactions predominate over hard sphere potentials. Finally, the nature of domain movements encountered for the serum protein are of immense significance with respect to the function of human serum albumin (HSA) as a prolific binder and transporter of small molecules.