Multiple peptides homologous to herpes simplex virus type 1 glycoprotein B inhibit viral infection.

The 773-residue ectodomain of the herpes simplex virus type 1 (HSV-1) glycoprotein B (gB) has been resistant to the use of mutagenic strategies because the majority of the induced mutations result in defective proteins. As an alternative strategy for the identification of functionally important regions and novel inhibitors of infection, we prepared a library of overlapping peptides homologous to the ectodomain of gB and screened for the ability of the peptides to block infection. Seven of 138 15-mer peptides inhibited infection by more than 50% at a concentration of 100 microM. Three peptides (gB94, gB122, and gB131) with 50% effective concentrations (EC(50)s) below 20 microM were selected for further studies. The gB131 peptide (residues 681 to 695 in HSV-1 gB [gB-1]) was a specific entry inhibitor (EC(50), approximately 12 microM). The gB122 peptide (residues 636 to 650 in gB-1) blocked viral entry (EC(50), approximately 18 microM), protected cells from infection (EC(50), approximately 72 microM), and inactivated virions in solution (EC(50), approximately 138 microM). We were unable to discern the step or steps inhibited by the gB94 peptide, which is homologous to residues 496 to 510 in gB-1. Substitution of a tyrosine in the gB122 peptide (Y640 in full-length gB-1) reduced the antiviral activity eightfold, suggesting that this residue is critical for inhibition. This peptide-based strategy could lead to the identification of functionally important regions of gB or other membrane proteins and identify novel inhibitors of HSV-1 entry.

Inhibition of herpes simplex virus type 1 infection by cationic beta-peptides.

Previously, it was shown that cationic alpha-peptides derived from the human immunodeficiency virus TAT protein transduction domain blocked herpes simplex virus type 1 (HSV-1) entry. We now show that cationic oligomers of beta-amino acids ("beta-peptides") inhibit HSV-1 infection. Among three cationic beta-peptides tested, the most effective inhibition was observed for the one with a strong propensity to adopt a helical conformation in which cationic and hydrophobic residues are segregated from one another ("globally amphiphilic helix"). The antiviral effect was not cell type specific. Inhibition of virus infection by the beta-peptides occurred at the postattachment penetration step, with a 50% effective concentration of 3 muM for the most-effective beta-peptide. The beta-peptides did not inactivate virions in solution, nor did they induce resistance to infection when cells were pretreated with the beta-peptides. The beta-peptides showed little if any toxicity toward Vero cells. These results raise the possibility that cationic beta-peptides may be useful antiviral agents for HSV-1 and demonstrate the potential of beta-peptides as novel antiviral drugs.

Evaluation of a theta-defensin in a Murine model of herpes simplex virus type 1 keratitis.

PURPOSE: To test the activity of a synthetic theta-defensin, retrocyclin (RC)-2, in a murine herpes simplex virus (HSV)-1 keratitis model. METHODS: The in vitro antiviral activity of RC-2 against HSV-1 KOS was determined by yield reduction and viral inactivation assays. Efficacy in an experimental murine HSV-1 keratitis model was tested using pre- or postinfection treatment with 0.1% peptide in PBS with or without 2% methylcellulose. Viral titers in the tear film were determined by plaque assay. RESULTS: RC-2 inhibited HSV-1 KOS in vitro with an EC(50) of 10 microM (~20 microg/mL) in yield-reduction assays, but was not directly virucidal. RC-106 (a less active analogue) did not inhibit HSV-1 KOS in culture. Incubating the virus with RC-2 or applying the peptide in 2% methylcellulose to the cornea before viral infection significantly reduced the severity of ocular disease, but postinfection treatment with 0.1% RC-2 in PBS with or without 2% methylcellulose did not. Viral titers were significantly reduced on some days after infection in the preincubation and prophylaxis groups. CONCLUSIONS: RC-2 was active against HSV-1 KOS in cultures and showed protective activity in vivo when used in a prophylactic mode, but the peptide showed limited activity in a postinfection herpes keratitis model. These findings support data obtained from experiments with HIV-1, HSV-2, and influenza A, indicating that RCs inhibit the entry of viruses rather than their replication.

Corneal toxicity of cell-penetrating peptides that inhibit Herpes simplex virus entry.

Cell-penetrating peptides (CPPs) inhibit Herpes simplex virus entry at low micromolar concentrations and may be useful either as prophylactic or therapeutic agents for herpetic keratitis. The aim of this study was to assess the in vitro and in vivo toxicity of three CPPs-EB, TAT-C, and HOM (penetratin)-for the cornea. Incubation of primary (HK320) or immortalized (THK320) human keratocytes with the EB peptide (up to 100 microM), bHOMd (up to 200 microM), or TAT-C (up to 400 microM) resulted in no evidence of toxicity using a formazan dye-reduction assay. Similar results were obtained with a human trabecular meshwork cell line (TM-1), primary human foreskin fibroblasts (DP-9), Vero, and HeLa cells with EB and TATC. The bHOMd peptide showed some toxicity in Vero and HeLa cells, with CC50 values of 70 and 93 microM, respectively. The EB peptide did not inhibit macromolecular synthesis in Vero cells at concentrations below 150 microM, although cell proliferation was blocked at concentrations of EB above 50 microM. In vivo toxicity was assessed by applying peptides in Dulbecco's modified Eagle's medium to the cornea 4 times daily for 7 d. At concentrations 1000 times the IC50 values, the EB and bHOM peptides showed no toxicity, whereas TAT-C caused some mild eyelid swelling. Some slight epithelial cell sloughing was seen with the bKLA peptide in vivo. These results suggest that these CPPs-and EB in particular-have a favorable toxicity profile, and that further development is warranted.