Cationic polyelectrolytes prevent the aggregation of l-lactate dehydrogenase under unstable conditions.

Unstructured biological macromolecules have attracted attention as protein aggregation inhibitors in living cells. Some are characterized by their free structural configuration, highly charged, and water-soluble. However, the importance of these properties in inhibiting protein aggregation remains unclear. In this study, we investigated the effect of charged poly (amino acids), which mimic these properties, on aggregation of l-lactate dehydrogenase (LDH) and compared their effects to monomeric amino acids and folded proteins. LDH was stable and active at a neutral pH (~7) but formed inactive aggregates at acidic pH (< 6). Adding cationic polyelectrolytes of poly-l-lysine and poly-l-arginine suppressed the acid-induced aggregation and inactivation of LDH under acidic pH values. Adding monomeric amino acids and cationic folded proteins also prevented LDH aggregation but with lower efficacy than cationic polyelectrolytes. These results indicate that unstructured polyelectrolytes effectively stabilize unstable enzymes because they interact flexibly and multivalently with them. Our findings provide a simple method for stabilizing enzymes under unstable conditions.

Activation of oxidoreductases by the formation of enzyme assembly.

Biological properties of protein molecules depend on their interaction with other molecules, and enzymes are no exception. Enzyme activities are controlled by their interaction with other molecules in living cells. Enzyme activation and their catalytic properties in the presence of different types of polymers have been studied in vitro, although these studies are restricted to only a few enzymes. In this study, we show that addition of poly-l-lysine (PLL) can increase the enzymatic activity of multiple oxidoreductases through formation of enzyme assemblies. Oxidoreductases with an overall negative charge, such as l-lactate oxidase, d-lactate dehydrogenase, pyruvate oxidase, and acetaldehyde dehydrogenase, each formed assemblies with the positively charged PLL via electrostatic interactions. The enzyme activities of these oxidoreductases in the enzyme assemblies were several-folds higher than those of the enzyme in their natural dispersed state. In the presence of PLL, the turnover number (kcat) improved for all enzymes, whereas the decrease in Michaelis constant (KM) was enzyme dependent. This type of enzyme function regulation through the formation of assemblies via simple addition of polymers has potential for diverse applications, including various industrial and research purposes.

Transient formation of multi-phase droplets caused by the addition of a folded protein into complex coacervates with an oppositely charged surface relative to the protein.

Complex coacervates have received increasing attention due to their use as simple models of membrane-less organelles and microcapsule platforms. The incorporation of proteins into complex coacervates is recognized as a crucial event that enables understanding of membrane-less organelles in cells and controlling microcapsules. Here, we investigated the incorporation of proteins into complex coacervates with a focus on the progress of the incorporation process. This stands in contrast to most previous studies, which have been focused the endpoint of the incorporation process. For that purpose, client proteins, i.e., lysozyme, ovalbumin, and pyruvate oxidase, were mixed with complex coacervate scaffolds consisting of two polyelectrolytes, i.e., the positively charged poly(diallyldimethylammonium chloride) and the negatively charged carboxymethyl dextran sodium salt, and the process was studied. Spectroscopic analysis and microscopic imaging demonstrated that electrostatic factors are the primary driving force of the incorporation of the client proteins into the complex coacervate scaffolds. Moreover, we discovered the formation of multi-phase droplets when a charged protein was incorporated into a complex coacervate whose surface was charged oppositely relative to that of the protein. The droplets inside the complex coacervates were found to be the diluted phase trapped as internal vacuoles. These findings provide fundamental insight into the temporal changes at the droplet interface during the incorporation of proteins into complex coacervates. This knowledge will facilitate the understanding of biological events associated with membrane-less organelles and will contribute to the industrial development of the use of microcapsules.

Activation of L-lactate oxidase by the formation of enzyme assemblies through liquid-liquid phase separation.

The assembly state of enzymes is gaining interest as a mechanism for regulating the function of enzymes in living cells. One of the current topics in enzymology is the relationship between enzyme activity and the assembly state due to liquid-liquid phase separation. In this study, we demonstrated enzyme activation via the formation of enzyme assemblies using L-lactate oxidase (LOX). LOX formed hundreds of nanometer-scale assemblies with poly-L-lysine (PLL). In the presence of ammonium sulfate, the LOX-PLL clusters formed micrometer-scale liquid droplets. The enzyme activities of LOX in clusters and droplets were one order of magnitude higher than those in the dispersed state, owing to a decrease in KM and an increase in kcat. Moreover, the clusters exhibited a higher activation effect than the droplets. In addition, the conformation of LOX changed in the clusters, resulting in increased enzyme activation. Understanding enzyme activation and assembly states provides important information regarding enzyme function in living cells, in addition to biotechnology applications.