Antibody therapies to prevent or limit filovirus infections have received modest interest in recent years, in part because of early negative experimental evidence. We have overcome the limitations of this approach, leveraging the use of antibody from nonhuman primates (NHPs) that survived challenge to filoviruses under controlled conditions. By using concentrated, polyclonal IgG antibody from these survivors, we treated filovirus-infected NHPs with multiple doses administered over the clinical phase of disease. In the first study, Marburg virus (MARV)-infected NHPs were treated 15 to 30 min postexposure with virus-specific IgG, with additional treatments on days 4 and 8 postexposure. The postexposure IgG treatment was completely protective, with no signs of disease or detectable viremia. MARV-specific IgM antibody responses were generated, and all macaques survived rechallenge with MARV, suggesting that they generated an immune response to virus replication. In the next set of studies, NHPs were infected with MARV or Ebola virus (EBOV), and treatments were delayed 48 h, with additional treatments on days 4 and 8 postexposure. The delayed treatments protected both MARV- and EBOV-challenged NHPs. In both studies, two of the three IgG-treated NHPs had no clinical signs of illness, with the third NHP developing mild and delayed signs of disease followed by full recovery. These studies clearly demonstrate that postexposure antibody treatments can protect NHPs and open avenues for filovirus therapies for human use using established Food and Drug Administration-approved polyclonal or monoclonal antibody technologies.
Sudan virus (genus ebolavirus) is lethal, yet no monoclonal antibody is known to neutralize it. Here we describe antibody 16F6 that neutralizes Sudan virus and present its structure bound to the trimeric viral glycoprotein. Unexpectedly, the 16F6 epitope overlaps that of KZ52, the only other antibody against the GP1,2 core to be visualized. Further, both antibodies against this key GP1–GP2-bridging epitope neutralize at a post-internalization step, likely fusion.
A major obstacle in ebolavirus research is the lack of a small-animal model for Sudan virus (SUDV), as well as other wild-type (WT) ebolaviruses. Here, we expand on research by Bray and by Lever et al suggesting that WT ebolaviruses are pathogenic in mice deficient for the type 1 interferon (IFN) α/β receptor (IFNα/βR-/-). We examined the disease course of several WT ebolaviruses: Boneface (SUDV/Bon) and Gulu variants of SUDV, Ebola virus (EBOV), Bundibugyo virus (BDBV), Taï Forest virus, and Reston virus (RESTV). We determined that exposure to WT SUDV or EBOV results in reproducible signs of disease in IFNα/βR-/- mice, as measured by weight loss and partial lethality. Vaccination with the SUDV or EBOV glycoprotein (GP)-expressing Venezuelan equine encephalitis viral replicon particle vaccine protected these mice from SUDV/Bon and EBOV challenge, respectively. Treatment with SUDV- or EBOV-specific anti-GP antibodies protected mice from challenge when delivered 1-3 days after infection. Serial sampling experiments revealed evidence of disseminated intravascular coagulation in the livers of mice infected with the Boneface variant of SUDV, EBOV, and BDBV. Taken together, these data solidify the IFNα/βR-/- mouse as an important and useful model for the study of WT EBOV disease.
The ebolaviruses cause severe and
rapidly progressing hemorrhagic
fever. There are five ebolavirus species; although much is known about
Zaire ebolavirus (EBOV) and its neutralization by antibodies, little
is known about Sudan ebolavirus (SUDV), which is emerging with increasing
frequency. Here we describe monoclonal antibodies containing a human
framework that potently inhibit infection by SUDV and protect mice
from lethal challenge. The murine antibody 16F6, which binds the SUDV
envelope glycoprotein (GP), served as the starting point for design.
Sequence and structural alignment revealed similarities between 16F6
and YADS1, a synthetic antibody with a humanized scaffold. A focused
phage library was constructed and screened to impart 16F6-like recognition
properties onto the YADS1 scaffold. A panel of 17 antibodies were
characterized and found to have a range of neutralization potentials
against a pseudotype virus infection model. Neutralization correlated
with GP binding as determined by ELISA. Two of these clones, E10 and
F4, potently inhibited authentic SUDV and conferred protection and
memory immunity in mice from lethal SUDV challenge. E10 and F4 were
further shown to bind to the same epitope on GP as 16F6 with comparable
affinities. These antibodies represent strong immunotherapeutic candidates
for treatment of SUDV infection.
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