Trimer-to-Monomer Disruption Mechanism for a Potent, Protease-Resistant Antagonist of Tumor Necrosis Factor-α Signaling.

Aberrant tumor necrosis factor-α (TNFα) signaling is associated with many inflammatory diseases. The homotrimeric quaternary structure of TNFα is essential for receptor recognition and signal transduction. Previously, we described an engineered α/ß-peptide inhibitor that potently suppresses TNFα activity and resists proteolysis. Here, we present structural evidence that both the α/ß-peptide inhibitor and an all-α analogue bind to a monomeric form of TNFα. Calorimetry data support a 1:1 inhibitor/TNFα stoichiometry in solution. In contrast, previous cocrystal structures involving peptide or small-molecule inhibitors have shown the antagonists engaging a TNFα dimer. The structural data reveal why our inhibitors favor monomeric TNFα. Previous efforts to block TNFα-induced cell death with peptide inhibitors revealed that surfactant additives to the assay conditions cause a more rapid manifestation of inhibitory activity than is observed in the absence of additives. We attributed this effect to a loose surfactant TNFα association that lowers the barrier to trimer dissociation. Here, we used the new structural data to design peptide inhibitors bearing a surfactant-inspired appendage intended to facilitate TNFα trimer dissociation. The appendage modified the time course of protection from cell death.

Tumor Necrosis Factor-α Trimer Disassembly and Inactivation via Peptide-Small Molecule Synergy.

Aberrant signaling by tumor necrosis factor-α (TNFα) is associated with inflammatory diseases that can be treated with engineered proteins that inhibit binding of this cytokine to cell-surface receptors. Despite these clinical successes, there is considerable interest in the development of smaller antagonists of TNFα-receptor interactions. We describe a new 29-residue α/ß-peptide, a molecule that contains three ß-amino acid residues and three α-aminoisobutryic acid (Aib) residues, that displays potent inhibition of TNFα binding to TNFα receptor 1 (TNFR1) and rescues cells from TNFα-induced death. The complement of nonproteinogenic residues renders this α/ß-peptide highly resistant to proteolysis, relative to all-α analogues. The mechanism of inhibitory action of the new 29-mer involves disruption of the trimeric TNFα quaternary structure, which prevents productive binding to TNFα receptors. Unexpectedly, we discovered that peptide-induced trimer disruption can be promoted by structurally diverse small molecules, including a detergent commonly used during selection procedures. The discovery of this synergistic effect provides a new context for understanding previous reports on peptidic antagonists of TNFα-receptor interactions and suggests new avenues for future efforts to block signaling via proteins with an active form that is oligomeric, including other members of the TNFα family.

Differential Effects of ß3 - versus ß2 -Amino Acid Residues on the Helicity and Recognition Properties of Bim BH3-Derived α/ß-Peptides.

Oligomers containing α- and ß-amino acid residues (α/ß-peptides) have been shown to mimic the α-helical conformation of conventional peptides when the unnatural residues are derived from ß3 -amino acids or cyclic ß-amino acids, but the impact of incorporating ß2 residues has received little attention. The effects of ß2 residues on the conformation and recognition behavior of α/ß-peptides that mimic an isolated α-helix were investigated. This effort has focused on 26-mers based on the Bim BH3 domain; a set of isomers with identical α/ß backbones that differ only in the placement of certain side chains along the backbone (ß3 vs. ß2 substitution) was compared. Circular dichroism data suggest that ß2 residues can be helix-destabilizing relative to ß3 residues, although the size of this effect seems to depend on side chain identity. Binding data show that ß3 →ß2 substitution at sites that contact a partner protein, Bcl-xL , can influence affinity in a way that transcends effects on helicity.

α/ß-Peptide Foldamers Targeting Intracellular Protein-Protein Interactions with Activity in Living Cells.

Peptides can be developed as effective antagonists of protein-protein interactions, but conventional peptides (i.e., oligomers of l-α-amino acids) suffer from significant limitations in vivo. Short half-lives due to rapid proteolytic degradation and an inability to cross cell membranes often preclude biological applications of peptides. Oligomers that contain both α- and ß-amino acid residues ("α/ß-peptides") manifest decreased susceptibility to proteolytic degradation, and when properly designed these unnatural oligomers can mimic the protein-recognition properties of analogous "α-peptides". This report documents an extension of the α/ß-peptide approach to target intracellular protein-protein interactions. Specifically, we have generated α/ß-peptides based on a "stapled" Bim BH3 α-peptide, which contains a hydrocarbon cross-link to enhance α-helix stability. We show that a stapled α/ß-peptide can structurally and functionally mimic the parent stapled α-peptide in its ability to enter certain types of cells and block protein-protein interactions associated with apoptotic signaling. However, the α/ß-peptide is nearly 100-fold more resistant to proteolysis than is the parent stapled α-peptide. These results show that backbone modification, a strategy that has received relatively little attention in terms of peptide engineering for biomedical applications, can be combined with more commonly deployed peripheral modifications such as side chain cross-linking to produce synergistic benefits.

Introduction of cyclically constrained γ-residues stabilizes an α-peptide hairpin in aqueous solution.

The synthesis and structural characterization of hybrid α/γ-peptides resulting from a 1:1 α→γ residue substitution at cross-strand positions in a hairpin-forming α-peptide sequence are described. Cyclically constrained γ-residues based on 1,3-substituted cyclohexane or benzene scaffolds support a native-like hairpin fold in aqueous solution, and the unnatural residues stabilize the folded state by ∼0.2 kcal/mol per α→γ substitution.