Helix-Grafted Pleckstrin Homology Domains Suppress HIV-1 Infection of CD4-Positive Cells

Evolved Proteins Inhibit Entry of Enfuvirtide-Resistant HIV-1

Drugs that block HIV-1 entry are relatively limited. Enfuvirtide is a 36-residue synthetic peptide that targets gp41 and blocks viral fusion. However, Enfuvirtide-resistant HIV has been reported, and this peptide drug requires daily injection. Previously, we have reported helix-grafted display proteins, consisting of HIV-1 gp41 C-peptide helix grafted onto Pleckstrin Homology domains. Some of these biologics inhibit HIV-1 entry with relatively modest and varied potency (IC₅₀ = 190 nM to >1 μM). Here, we report that gp41 C-peptide helix-grafted Sac7d (Sac7d-Cpep) potently suppresses HIV-1 entry in a live virus assay (IC₅₀ = 1.9-12.4 nM). Yeast display sequence optimization of solvent exposed helix residues led to new biologics with improved expression in E. coli (a common biosimilar expression host), with no appreciable change in entry inhibition. Evolved proteins inhibit the entry of a clinically relevant mutant of HIV-1 that is gp41 C-peptide sensitive and Enfuvirtide resistant. Fusion proteins designed for serum stability also potently suppress HIV-1 entry. Collectively, we report several evolved biologics that are functional against an Enfuvirtide-resistant strain and are designed for serum stability.

Evaluation of sequence variability in HIV-1 gp41 C-peptide helix-grafted proteins

Many therapeutically-relevant protein-protein interactions (PPIs) have been reported that feature a helix and helix-binding cleft at the interface. Given this, different approaches to disrupting such PPIs have been developed. While short peptides (<15 amino acids) typically do not fold into a stable helix, researchers have reported chemical approaches to constraining helix structure. However, these approaches rely on laborious, and often expensive, chemical synthesis and purification. Our premise is that protein-based solutions that stabilize a therapeutically-relevant helix offer a number of advantages. In contrast to chemically constrained helical peptides, or minimal/miniature proteins, which must be synthesized (at great expense and labor), a protein can be expressed in a cellular system (like all current protein therapeutics). If selected properly, the protein scaffold can stabilize the therapeutically-relevant helix. We recently reported a protein engineering strategy, which we call "helix-grafted display", and applied it to the challenge of suppressing HIV entry. We have reported helix-grafted display proteins that inhibit formation of an intramolecular PPI involving HIV gp41 C-peptide helix, and HIV gp41 N-peptide trimer, which contain C-peptide helix-binding clefts. Here, we used yeast display to screen a library of grafted C-peptide helices for N-peptide trimer recognition. Using 'hits' from yeast display library screening, we evaluated the effect helix mutations have on structure, expression, stability, function (target recognition), and suppression of HIV entry.