Robert A. Davey’s research while affiliated with Boston University and other places

Human CD4 (cluster of differentiation 4) is well known as the primary receptor for human immunodeficiency virus (HIV) entry into the cells. The virus binds to CD4 molecules to induce a conformational change in the viral glycoprotein (GP) gp120, which exposes the co-receptor binding site for coreceptors CCR5 or CXCR4. The co-receptor binding then leads to membrane fusion for viral entry. Since the CD4 molecule has a high affinity for gp120, soluble CD4 (sCD4) and CD4-mimetic small molecules (CD4mcs) have been extensively studied as potential inhibitors for HIV infection. Surprisingly, we have found that human sCD4 and some CD4mcs are able to inhibit Ebola virus (EBOV) infection. Evidence is provided that the compounds block viral entry by targeting the GP binding site for the endosomal receptor Niemann-Pick C1 (NPC1). This finding reveals virus-receptor binding similarities between two remote viruses (HIV and EBOV) and suggests new possibilities for EBOV entry inhibitors.

Ebola virus (EBOV), the causative agent of Ebola virus disease (EVD), remains one of WHO's top ten threats to global health. Infectious EBOV virions can be found on the surface of skin late during systemic infection and passed from the deceased through skin-to-skin contact. Here, we assess viral load and antigen expression in the skin of EBOV-infected non-human primates (NHP) and mouse adapted-EBOV (ma-EBOV) -infected mice and use the low containment viral model, rVSV/EBOV GP, to mechanistically define skin infection in mice. Viral RNA peaked within the skin proximal to the site of injection in EBOV-infected NHPs on day 6. In contrast, mouse skin sites distal to the site of ma-EBOV injection achieved maximal viral loads by day 3. At late times of infection, viral antigen-positive cells co-localized with markers for endothelial, stromal, and immune cells in the dermis. Epidermal cells within and surrounding hair follicles also harbored viral antigen, suggesting a potential mechanism of virus trafficking to the epidermal surface. Despite robust viral infection, distal skin sites of ma-EBOV-infected mice had low expression of proinflammatory stimulated genes. A similar cellular tropism was observed in the skin of mice infected with rVSV/EBOV GP, with focal areas of intense infection surrounded by uninfected areas. When virus was applied to the surface of gently abraded skin to remove the stratum corneum, epidermal keratinocytes were robustly infected, followed by systemic viral dissemination. To define cell surface receptors critical for virus trafficking to and replication within the skin, mice lacking the phosphatidylserine receptors were infected intraperitoneally with rVSV/EBOV GP. At day 3 of infection, skin distal to the site of infection of TIM-1 knock out (KO) mice had significantly lower levels of infectious virus than the control mice, suggesting that TIM-1 is essential for efficient distribution of virus to the skin. Our findings reveal that EBOV targets specific skin cell populations at late times of viral infection and that the host receptor TIM-1 is required for optimal viral dissemination.

Ebola virus (EBOV) causes severe human disease. During late infection, EBOV virions are on the skin’s surface; however, the permissive skin cell types and the route of virus translocation to the epidermal surface are unknown. We describe a human skin explant model and demonstrate that EBOV infection of human skin via basal media increases in a time-dependent and dose-dependent manner. In the dermis, cells of myeloid, endothelial, and fibroblast origin were EBOV antigen–positive whereas keratinocytes harbored virus in the epidermis. Infectious virus was detected on the apical epidermal surface within 3 days, indicating that virus propagates and traffics through the explants. Purified human fibroblasts and keratinocytes supported EBOV infection ex vivo and both cell types required the phosphatidylserine receptor, AXL, and the endosomal protein, NPC1, for virus entry. This platform identified susceptible cell types and demonstrated dynamic trafficking of EBOV virions. These findings may explain person-to-person transmission via skin contact.

The Ebola filovirus (EBOV) poses a serious threat to global health and national security. Nanobodies, a type of single-domain antibody, have demonstrated promising therapeutic potential. We identified two anti-EBOV nanobodies, Nanosota-EB1 and Nanosota-EB2, which specifically target the EBOV glycoprotein (GP). Cryo-EM and biochemical data revealed that Nanosota-EB1 binds to the glycan cap of GP1, preventing its protease cleavage, while Nanosota-EB2 binds to critical membrane-fusion elements in GP2, stabilizing it in the pre-fusion state. Nanosota-EB2 is a potent neutralizer of EBOV infection in vitro and offers excellent protection in a mouse model of EBOV challenge, while Nanosota-EB1 provides moderate neutralization and protection. Nanosota-EB1 and Nanosota-EB2 are the first nanobodies shown to inhibit authentic EBOV. Combined with our newly developed structure-guided in vitro evolution approach, they lay the foundation for nanobody-based therapies against EBOV and other viruses within the ebolavirus genus.

Diphyllin is a naturally occurring lignan comprised of an aryl naphthalene lactone scaffold that demonstrates beneficial biological activities in disease models of cancer, obesity, and viral infection. A target of diphyllin and naturally occurring derivatives is the vacuolar ATPase (V-ATPase) complex. Although diphyllin-related natural products are active with in vitro models for viral entry, the potencies and unknown pharmacokinetic properties limit well-designed in vivo evaluations. Previous studies demonstrated that diphyllin derivatives have the utility of blocking the Ebola virus cell entry pathway. However, diphyllin shows limited potency and poor oral bioavailability in mice. An avenue to improve the potency was used in a new library of synthetic derivatives of diphyllin. Diphyllin derivatives exploiting ether linkages at the 4-position with one-to-three carbon spacers to an oxygen or nitrogen atom provided compounds with EC50 values ranging from 7 to 600 nM potency and selectivity up to >500 against Ebola virus in infection assays. These relative potencies are reflected in the Ebola virus infection of primary macrophages, a cell type involved in early pathogenesis. A target engagement study reveals that reducing the ATPV0a2 protein expression enhanced the potency of diphyllin derivatives to block EBOV entry, consistent with effects on the endosomal V-ATPase function. Despite the substantial enhancement of antiviral potencies, limitations were identified, including rapid clearance predicted by in vitro microsome stability assays. However, compounds with similar or improved half-lives relative to diphyllin demonstrated improved pharmacokinetic profiles in vivo. Importantly, these derivatives displayed suitable plasma levels using oral administration, establishing the feasibility of in vivo antiviral testing.