Phase Separation Behavior of Supercharged Proteins and Polyelectrolytes.

Membraneless organelles, like membrane-bound organelles, are essential to cell homeostasis and provide discrete cellular subcompartments. Unlike classical organelles, membraneless organelles possess no physical barrier but rather arise by phase separation of the organelle components from the surrounding cytoplasm or nucleoplasm. Complex coacervation, the liquid-liquid phase separation of oppositely charged polyelectrolytes, is one of several phenomena that are hypothesized to drive the formation and regulation of some membraneless organelles.

ATRP-grown protein-polymer conjugates containing phenylpiperazine selectively enhance transepithelial protein transport.

Despite its patient-friendliness, the oral route is not yet a viable strategy for the delivery of biomacromolecular therapeutics. This is, in part, due to the large size of proteins, which greatly limits their absorption across the intestinal epithelium. Although chemical permeation enhancers can improve macromolecular transport, their positive impact is often accompanied by toxicity.

Design of Stomach Acid-Stable and Mucin-Binding Enzyme Polymer Conjugates.

The reduced immunogenicity and increased stability of protein-polymer conjugates has made their use in therapeutic applications particularly attractive. However, the physicochemical interactions between polymer and protein, as well as the effect of this interaction on protein activity and stability, are still not fully understood. In this work, polymer-based protein engineering was used to examine the role of polymer physicochemical properties on the activity and stability of the chymotrypsin-polymer conjugates and their degree of binding to intestinal mucin.

Polymer-Based Protein Engineering Enables Molecular Dissolution of Chymotrypsin in Acetonitrile.

While most effective in aqueous environments, enzymes are also able to catalyze reactions in essentially anhydrous organic media. Enzyme activity in organic solvents is limited as a result of inefficient substrate binding, lack of solubility, and inactivation by hydrophilic anhydrous solvents. With these facts in mind, atom transfer radical polymerization was used to synthesize chymotrypsin-poly(2-(dimethylamino)ethyl methacrylate) (CT-pDMAEMA) conjugates designed to be soluble and active in acetonitrile.

Rational tailoring of substrate and inhibitor affinity via ATRP polymer-based protein engineering.

Atom transfer radical polymerization (ATRP)-based protein engineering of chymotrypsin with a cationic polymer was used to tune the substrate specificity and inhibitor binding. Poly(quaternary ammonium) was grown from the surface of the enzyme using ATRP after covalent attachment of a protein reactive, water-soluble ATRP-initiator. This "grafting from" conjugation approach generated a high density of cationic ammonium ions around the biocatalytic core.

Polymer-based protein engineering can rationally tune enzyme activity, pH-dependence, and stability.

The attachment of inert polymers, such as polyethylene glycol, to proteins has driven the emergence of a multibillion dollar biotechnology industry. In all cases, proteins have been stabilized or altered by covalently coupling the pre-existing polymer to the surface of the protein. This approach is inherently limited by a lack of exquisite control of polymer architecture, site and density of attachment.