Site-Selective Oxidative Coupling Reactions for the Attachment of Enzymes to Glass Surfaces through DNA-Directed Immobilization.

Enzymes are able to maintain remarkably high selectivity toward their substrates while still retaining high catalytic rates. By immobilizing enzymes onto surfaces we can heterogenize these biological catalysts, making it practical to study, use, and combine them in an easily controlled system. In this work, we developed a platform that allows for the simple and oriented immobilization of proteins through DNA-directed immobilization. First, we modified a glass surface with single-stranded DNA. We then site-selectively attached the complementary DNA strand to the N-terminus of a protein. Both DNA modifications were carried out using an oxidative coupling strategy, and the DNA strands served as easily tunable and reversible chemical handles to hybridize the protein-DNA conjugates onto the surface. We have used the aldolase enzyme as a model protein to conduct our studies. We characterized each step of the protein immobilization process using fluorescent reporters as well as atomic force microscopy. We also conducted activity assays on the surfaces with DNA-linked aldolase to validate that, despite being modified with DNA and undergoing subsequent immobilization, the enzyme was still able to retain its catalytic activity and the surfaces were reusable in subsequent cycles.

Optimization and expansion of a site-selective N-methylpyridinium-4-carboxaldehyde-mediated transamination for bacterially expressed proteins.

Site-selective bioconjugation methods are valuable because of their ability to confer new properties to proteins by the chemical attachment of specific functional groups. Well-defined bioconjugates obtained through these methods have found utility for the study of protein function and the creation of protein-based materials. We have previously reported a protein modification strategy to modify the N-terminus of peptides and proteins using N-methylpyridinium-4-carboxaldehyde benzenesulfonate (Rapoport's salt, RS) as a transamination reagent, which oxidizes the N-terminal amino group to provide a uniquely reactive aldehyde or ketone. This functional handle can subsequently be modified with an alkoxyamine reagent of choice. Previous work had found glutamate terminal sequences to be highly reactive toward RS-mediated transamination. However, proteins of interest are often recombinantly expressed in E. coli, where the expression of a glutamate-terminal protein is rendered difficult because the N-terminal methionine derived from the start codon is not cleaved when Glu is in the second position. In this work, we describe a way to overcome this difficulty via the insertion of a Factor Xa proteolytic cleavage site to acquire the optimal glutamate residue at the N-terminus. Additionally, we present studies on alternative high-yielding sequences containing N-terminal residues that can be expressed directly. We have used site-directed mutagenesis to validate these findings on a model cellulase enzyme, an endoglucanase from the thermophilic Pyrococcus horikoshii. Activity assays performed with these mutants show that RS transamination and subsequent modification with alkoxyamines have no negative impact on cellulolytic ability.

Site-specific protein transamination using N-methylpyridinium-4-carboxaldehyde.

The controlled attachment of synthetic groups to proteins is important for a number of fields, including therapeutics, where antibody-drug conjugates are an emerging area of biologic medicines. We have previously reported a site-specific protein modification method using a transamination reaction that chemoselectively oxidizes the N-terminal amine of a polypeptide chain to a ketone or an aldehyde group. The newly introduced carbonyl can be used for conjugation to a synthetic group in one location through the formation of an oxime or a hydrazone linkage. To expand the scope of this reaction, we have used a combinatorial peptide library screening platform as a method to explore new transamination reagents while simultaneously identifying their optimal N-terminal sequences. N-Methylpyridinium-4-carboxaldehyde benzenesulfonate salt (Rapoport's salt, RS) was identified as a highly effective transamination reagent when paired with glutamate-terminal peptides and proteins. This finding establishes RS as a transamination reagent that is particularly well suited for antibody modification. Using a known therapeutic antibody, herceptin, it was demonstrated that RS can be used to modify the heavy chains of the wild-type antibody or to modify both the heavy and the light chains after N-terminal sequence mutation to add additional glutamate residues.

Use of the environmentally sensitive fluorophore 4-N,N-dimethylamino-1,8-naphthalimide to study peptoid helix structures.

Peptoids, oligomers of N-substituted glycine, have been valuable targets for study and diverse application as peptidomimetics and as nanomaterials. Their conformational heterogeneity has made the study of peptoid structures using high-resolution analyses challenging, limiting our understanding of the physiochemical features that mediate peptoid folding. Here, we introduce a new method for the study of peptoid structure that relies on the environmentally sensitive fluorescence properties of 4-N,N-dimethylamino-1,8-naphthalimide (4-DMN). We have prepared a 4-DMN-functionalized primary amine that is compatible with the traditional submonomer peptoid synthesis methods and incorporated it sequence-specifically into 11 of 13 new peptoids. When included as a peptoid side chain modification, the fluorescence emission intensity of 4-DMN correlates with predictions of the fluorophore's local polarity within a putative structure. 4-DMN fluorescence is maximized when the fluorophore is placed in the middle of the hydrophobic face of an amphiphilic helical peptoid. When the fluorophore is placed near the peptoid terminus or on a polar face of an amphiphilic sequence, 4-DMN fluorescence is diminished. Disruption of the peptoid secondary structure or amphiphilicity also modulates 4-DMN fluorescence. The peptoids' helical secondary structures are moderately disrupted by inclusion of a 4-DMN-modified side chain as evaluated by changes in the peptoids' CD spectral features. This new method for peptoid structure evaluation should be a valuable complement to existing peptoid structural analysis tools.