HSV-2 ΔgD elicits FcγR-effector antibodies that protect against clinical isolates
Christopher D. Petro, Brian Weinrick, Nazanin Khajoueinejad, Clare Burn, Rani Sellers, William R. Jacobs Jr, Betsy C. Herold
Christopher D. Petro, Brian Weinrick, Nazanin Khajoueinejad, Clare Burn, Rani Sellers, William R. Jacobs Jr, Betsy C. Herold
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Research Article Vaccines Virology

HSV-2 ΔgD elicits FcγR-effector antibodies that protect against clinical isolates

Abstract

A single-cycle herpes simplex virus (HSV) deleted in glycoprotein D (ΔgD-2) elicited high titer HSV-specific antibodies (Abs) that (i) were rapidly transported into the vaginal mucosa; (ii) elicited antibody-dependent cell-mediated cytotoxicity but little neutralization; (iii) provided complete protection against lethal intravaginal challenge; and (iv) prevented establishment of latency in mice. However, clinical isolates may differ antigenically and impact vaccine efficacy. To determine the breadth and further define mechanisms of protection of this vaccine candidate, we tested ΔgD-2 against a panel of clinical isolates in a murine skin challenge model. The isolates were genetically diverse, as evidenced by genomic sequencing and in vivo virulence. Prime and boost immunization (s.c.) with live but not heat- or UV-inactivated ΔgD-2 completely protected mice from challenge with the most virulent HSV-1 and HSV-2 isolates. Furthermore, mice were completely protected against 100 times the lethal dose that typically kills 90% of animals (LD90) of a South African isolate (SD90), and no latent virus was detected in dorsal root ganglia. Immunization was associated with rapid recruitment of HSV-specific FcγRIII- and FcγRIV-activating IgG2 Abs into the skin, resolution of local cytokine and cellular inflammatory responses, and viral clearance by day 5 after challenge. Rapid clearance and the absence of latent virus suggest that ΔgD-2 elicits sterilizing immunity.

Authors

Christopher D. Petro, Brian Weinrick, Nazanin Khajoueinejad, Clare Burn, Rani Sellers, William R. Jacobs Jr, Betsy C. Herold

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Figure 5

Inactivation of ΔgD-2 leads to reduction in vaccine efficacy.

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Inactivation of ΔgD-2 leads to reduction in vaccine efficacy. (A) Vero c...
(A) Vero cells were infected with an MOI of 5 PFU/cell of ΔgD-2 or an equivalent amount of UV-inactivated (UVΔgD-2) or heat-inactivated (HIΔgD-2) virus and viral gene expression for infected cell protein-0 (ICP0, upper panel) and thymidine kinase (TK, lower panel) assessed at 2 hours (closed symbols) and 6 hours (open symbols) after infection (HPI). Data are presented as threshold cycle (Ct). Each point represents Ct values from individual experiment; lines equals mean ±SD from replicate experiments, with the dotted line indicating the Ct values for mock-infected cells. The asterisks indicate results for 2-way ANOVA comparing UVΔgD-2, HIΔgD-2, and ΔgD-2 Ct values at each time after infection (*P < 0.05, **P < 0.01, ***P < 0.001). (B and C) Mice were prime-boost vaccinated with 5 × 106 PFU of live or equivalent concentrations of UVΔgD-2, HIΔgD-2, ΔgD-2, or VD60 lysates (control) and subsequently challenged with an LD90 of HSV-2(SD90) on the skin (n = 5/group). Mice were monitored for (B) survival and (C) skin disease scores. Kaplan Meier analysis was used for survival curves of ΔgD-2–, UVΔgD-2–, HIΔgD-2–, and control-vaccinated mice. (D) At day 5 after challenge, mice were euthanized and DRGs were extracted for qPCR analysis of HSV DNA (n = 3/group for UV-, HI-, or ΔgD-2–immunized mice or n = 5 for control-treated mice; lines represent the mean). **P < 0.01, ***P < 0.001 by 2-way ANOVA, ΔgD-2–vaccinated groups vs. control-vaccinated group.