Jonathan Audet

Successful Treatment of Ebola Virus–Infected Cynomolgus Macaques with Monoclonal Antibodies

Macaques survived infection with Ebola virus when treated starting at 24 hours after infection with mix of three neutralizing monoclonal antibodies. A Race Against Time Although rare, Ebola infection figures prominently in the public’s fear of an infectious disease outbreak because of its marked, rapid, and fatal manifestation. This fear is fueled by our complete helplessness when it comes to fighting Ebola—there’s no vaccine, and any treatment options we do have only work if administered within minutes—or at most hours—after infection. Qiu et al. address this impotence head-on by demonstrating that administration of a three-antibody cocktail to macaques within 24 hours of infection yields 100% survival. The authors treated the macaques 24 or 48 hours after Ebola virus challenge with a virus-neutralizing antibody cocktail (ZMab). The three antibodies in the mix each bind to distinct regions of the Ebola envelop glycoprotein (GP) and show efficacy in small-animal models. When the cocktail was given at 24 hours after infection, 100% of the monkeys survived; if the same dose of the cocktail was administered 48 hours after infection, the survival rate was 50%. Surviving macaques developed both Ebola-specific antibodies and T cell responses, which suggests that the passive neutralizing antibody transfer may keep the virus in check long enough for endogenous immunity to take over. Timing, dose, and composition must be optimized before this therapy moves into humans, but the new findings add sand to the hourglass and provide hope for an expanded treatment window for Ebola virus infection. Ebola virus (EBOV) is considered one of the most aggressive infectious agents and is capable of causing death in humans and nonhuman primates (NHPs) within days of exposure. Recent strategies have succeeded in preventing acquisition of infection in NHPs after treatment; however, these strategies are only successful when administered before or minutes after infection. The present work shows that a combination of three neutralizing monoclonal antibodies (mAbs) directed against the Ebola envelope glycoprotein (GP) resulted in complete survival (four of four cynomolgus macaques) with no apparent side effects when three doses were administered 3 days apart beginning at 24 hours after a lethal challenge with EBOV. The same treatment initiated 48 hours after lethal challenge with EBOV resulted in two of four cynomolgus macaques fully recovering. The survivors demonstrated an EBOV-GP–specific humoral and cell-mediated immune response. These data highlight the important role of antibodies to control EBOV replication in vivo, and support the use of mAbs against a severe filovirus infection.

mAbs and Ad-Vectored IFN-α Therapy Rescue Ebola-Infected Nonhuman Primates When Administered After the Detection of Viremia and Symptoms

Monoclonal antibodies and adenovirus-vectored IFN-α extend the treatment window for Zaire ebolavirus in macaques. Every Day Counts Ebola virus (EBOV) infections cause a deadly hemorrhagic disease for which there are no currently licensed vaccines or treatments. Recent studies have demonstrated the potential of antibody therapy cocktails (ZMAb) for treating EBOV infections; however, there is a limited time window for these therapies to be effective. Because early clinical symptoms of EBOV infection resemble other common pathogens, it is critical to extend this treatment window until positive cases can be confirmed. Now, Qui et al. combine ZMAb therapy with adenovirally delivered interferon-α (Ad-IFN) to extend the EBOV treatment window in nonhuman primates. The authors dosed macaques that had received a lethal dose of EBOV with a combination of ZMAb and Ad-IFN. Combination therapy with Ad-IFN and ZMAb was 75 and 100% protective in cynomolgus and rhesus macaques, respectively, when administered together at 3 days post-infection. Fifty percent of cynomolgus macaques were protected at 4 days post-infection when Ad-IFN was administered 1 day post-infection. These results suggest that the Ad-IFN and ZMAb combination treatment could be effective after confirmation of EBOV infection as well as could substantially reduce mortality rates of cases diagnosed early after symptom onset. ZMAb is a promising treatment against Ebola virus (EBOV) disease that has been shown to protect 50% (two of four) of nonhuman primates (NHPs) when administered 2 days post-infection (dpi). To extend the treatment window and improve protection, we combined ZMAb with adenovirus-vectored interferon-α (Ad-IFN) and evaluated efficacy in EBOV-infected NHPs. Seventy-five percent (three of four) and 100% (four of four) of cynomolgus and rhesus macaques survived, respectively, when treatment was initiated after detection of viremia at 3 dpi. Fifty percent (two of four) of the cynomolgus macaques survived when Ad-IFN was given at 1 dpi, followed by ZMAb starting at 4 dpi, after positive diagnosis. The treatment was able to suppress viremia reaching ~105 TCID50 (median tissue culture infectious dose) per milliliter, leading to survival and robust specific immune responses. This study describes conditions capable of saving 100% of EBOV-infected NHPs when initiated after the presence of detectable viremia along with symptoms.

Sustained protection against Ebola virus infection following treatment of infected nonhuman primates with ZMAb

Ebola virus (EBOV) is one of the most lethal filoviruses, with mortality rates of up to 90% in humans. Previously, we demonstrated 100% and 50% survival of EBOV-infected cynomologus macaques with a combination of 3 EBOV-GP-specific monoclonal antibodies (ZMAb) administered at 24 or 48 hours post-exposure, respectively. The survivors demonstrated EBOV-GP–specific humoral and cell-mediated immune responses. In order to evaluate whether the immune response induced in NHPs during the ZMAb treatment and EBOV challenge is sufficient to protect survivors against a subsequent exposure, animals that survived the initial challenge were rechallenged at 10 or 13 weeks after the initial challenge. The animals rechallenged at 10 weeks all survived whereas 4 of 6 animals survived a rechallenge at 13 weeks. The data indicate that a robust immune response was generated during the successful treatment of EBOV-infected NHPs with EBOV, which resulted in sustained protection against a second lethal exposure.

Ebola GP-Specific Monoclonal Antibodies Protect Mice and Guinea Pigs from Lethal Ebola Virus Infection

Ebola virus (EBOV) causes acute hemorrhagic fever in humans and non-human primates with mortality rates up to 90%. So far there are no effective treatments available. This study evaluates the protective efficacy of 8 monoclonal antibodies (MAbs) against Ebola glycoprotein in mice and guinea pigs. Immunocompetent mice or guinea pigs were given MAbs i.p. in various doses individually or as pools of 3–4 MAbs to test their protection against a lethal challenge with mouse- or guinea pig-adapted EBOV. Each of the 8 MAbs (100 µg) protected mice from a lethal EBOV challenge when administered 1 day before or after challenge. Seven MAbs were effective 2 days post-infection (dpi), with 1 MAb demonstrating partial protection 3 dpi. In the guinea pigs each MAb showed partial protection at 1 dpi, however the mean time to death was significantly prolonged compared to the control group. Moreover, treatment with pools of 3–4 MAbs completely protected the majority of animals, while administration at 2–3 dpi achieved 50–100% protection. This data suggests that the MAbs generated are capable of protecting both animal species against lethal Ebola virus challenge. These results indicate that MAbs particularly when used as an oligoclonal set are a potential therapeutic for post-exposure treatment of EBOV infection.

Molecular Characterization of the Monoclonal Antibodies Composing ZMAb: A Protective Cocktail Against Ebola Virus

Ebola virus (EBOV) causes severe viral hemorrhagic fever in humans and non-human primates, with a case fatality rate of up to 88% in human outbreaks. Over the past 3 years, monoclonal antibody (mAb) cocktails have demonstrated high efficacy as treatments against EBOV infection. One such cocktail is ZMAb, which consists of three mouse antibodies, 1H3, 2G4, and 4G7. Here, we present the epitope binding properties of mAbs 1H3, 2G4, and 4G7. We showed that these antibodies have different variable region sequences, suggesting that the individual mAbs are not clonally related. All three antibodies were found to neutralize EBOV variant Mayinga. Additionally, 2G4 and 4G7 were shown to cross-inhibit each other in vitro and select for an escape mutation at the same position on the EBOV glycoprotein (GP), at amino acid 508. 1H3 selects an escape mutant at amino acid 273 on EBOV GP. Surface plasmon resonance studies showed that all three antibodies have dissociation constants on the order of 10−7. In combination with previous studies evaluating the binding sites of other protective antibodies, our results suggest that antibodies targeting the GP1-GP2 interface and the glycan cap are often selected as efficacious antibodies for post-exposure interventions against EBOV.

Ebola viral load at diagnosis associates with patient outcome and outbreak evolution

BACKGROUND Ebola virus (EBOV) causes periodic outbreaks of life-threatening EBOV disease in Africa. Historically, these outbreaks have been relatively small and geographically contained; however, the magnitude of the EBOV outbreak that began in 2014 in West Africa has been unprecedented. The aim of this study was to describe the viral kinetics of EBOV during this outbreak and identify factors that contribute to outbreak progression. METHODS From July to December 2014, one laboratory in Sierra Leone processed over 2,700 patient samples for EBOV detection by quantitative PCR (qPCR). Viremia was measured following patient admission. Age, sex, and approximate time of symptom onset were also recorded for each patient. The data was analyzed using various mathematical models to find trends of potential interest. RESULTS The analysis revealed a significant difference (P = 2.7 × 10(-77)) between the initial viremia of survivors (4.02 log10 genome equivalents [GEQ]/ml) and nonsurvivors (6.18 log10 GEQ/ml). At the population level, patient viral loads were higher on average in July than in November, even when accounting for outcome and time since onset of symptoms. This decrease in viral loads temporally correlated with an increase in circulating EBOV-specific IgG antibodies among individuals who were suspected of being infected but shown to be negative for the virus by PCR. CONCLUSIONS Our results indicate that initial viremia is associated with outcome of the individual and outbreak duration; therefore, care must be taken in planning clinical trials and interventions. Additional research in virus adaptation and the impacts of host factors on EBOV transmission and pathogenesis is needed.

DNA vaccination protects mice against Zika virus-induced damage to the testes

Zika virus (ZIKV) is an emerging pathogen causally associated with serious sequelae in fetuses, inducing fetal microcephaly and other neurodevelopment defects. ZIKV is primarily transmitted by mosquitoes, but can persist in human semen and sperm, and sexual transmission has been documented. Moreover, exposure of type-I interferon knockout mice to ZIKV results in severe damage to the testes, epididymis and sperm. Candidate ZIKV vaccines have shown protective efficacy in preclinical studies carried out in animal models, and several vaccines have entered clinical trials. Here, we report that administration of a synthetic DNA vaccine encoding ZIKV pre-membrane and envelope (prME) completely protects mice against ZIKV-associated damage to the testes and sperm and prevents viral persistence in the testes following challenge with a contemporary strain of ZIKV. These data suggest that DNA vaccination merits further investigation as a potential means to reduce ZIKV persistence in the male reproductive tract.

Two-mAb cocktail protects macaques against the Makona variant of Ebola virus.

A two–monoclonal antibody cocktail protects nonhuman primates against Ebola virus 3 days after lethal exposure. One-two punch for Ebola Antibody cocktails are an appealing therapeutic option for emerging infections such as the recent Ebola virus outbreak in West Africa because of their scalability and specificity. Qiu et al. report that the antibody cocktail used in Ebola virus–infected patients can be further simplified to only two antibodies and that these antibodies can be produced in engineered Chinese hamster ovary cells. This cocktail protected nonhuman primates against the virus responsible for the 2014–2015 outbreak up to 3 days after exposure. Combining these antibodies with those specific for other strains may lead to a broad ebolavirus therapy. The 2014–2015 Ebola virus (EBOV) outbreak in West Africa highlighted the urgent need for specific therapeutic interventions for infected patients. The human-mouse chimeric monoclonal antibody (mAb) cocktail ZMapp, previously shown to be efficacious in EBOV (variant Kikwit) lethally infected nonhuman primates (NHPs) when administration was initiated up to 5 days, was used in some patients during the outbreak. We show that a two-antibody cocktail, MIL77E, is fully protective in NHPs when administered at 50 mg/kg 3 days after challenge with a lethal dose of EBOV variant Makona, the virus responsible for the ongoing 2014–2015 outbreak, whereas a similar formulation of ZMapp protected two of three NHPs. The chimeric MIL77E mAb cocktail is produced in engineered Chinese hamster ovary cells and is based on mAbs c13C6 and c2G4 from ZMapp. The use of only two antibodies in MIL77E opens the door to a pan-ebolavirus cocktail.

Establishment and Characterization of a Lethal Mouse Model for the Angola Strain of Marburg Virus

ABSTRACT Infections with Marburg virus (MARV) and Ebola virus (EBOV) cause severe hemorrhagic fever in humans and nonhuman primates (NHPs) with fatality rates up to 90%. A number of experimental vaccine and treatment platforms have previously been shown to be protective against EBOV infection. However, the rate of development for prophylactics and therapeutics against MARV has been lower in comparison, possibly because a small-animal model is not widely available. Here we report the development of a mouse model for studying the pathogenesis of MARV Angola (MARV/Ang), the most virulent strain of MARV. Infection with the wild-type virus does not cause disease in mice, but the adapted virus (MARV/Ang-MA) recovered from liver homogenates after 24 serial passages in severe combined immunodeficient (SCID) mice caused severe disease when administered intranasally (i.n.) or intraperitoneally (i.p.). The median lethal dose (LD50) was determined to be 0.015 50% TCID50 (tissue culture infective dose) of MARV/Ang-MA in SCID mice, and i.p. infection at a dose of 1,000× LD50 resulted in death between 6 and 8 days postinfection in SCID mice. Similar results were obtained with immunocompetent BALB/c and C57BL/6 mice challenged i.p. with 2,000× LD50 of MARV/Ang-MA. Virological and pathological analyses of MARV/Ang-MA-infected BALB/c mice revealed that the associated pathology was reminiscent of observations made in NHPs with MARV/Ang. MARV/Ang-MA-infected mice showed most of the clinical hallmarks observed with Marburg hemorrhagic fever, including lymphopenia, thrombocytopenia, marked liver damage, and uncontrolled viremia. Virus titers reached 108 TCID50/ml in the blood and between 106 and 1010 TCID50/g tissue in the intestines, kidney, lungs, brain, spleen, and liver. This model provides an important tool to screen candidate vaccines and therapeutics against MARV infections. IMPORTANCE The Angola strain of Marburg virus (MARV/Ang) was responsible for the largest outbreak ever documented for Marburg viruses. With a 90% fatality rate, it is similar to Ebola virus, which makes it one of the most lethal viruses known to humans. There are currently no approved interventions for Marburg virus, in part because a small-animal model that is vulnerable to MARV/Ang infection is not available to screen and test potential vaccines and therapeutics in a quick and economical manner. To address this need, we have adapted MARV/Ang so that it causes illness in mice resulting in death. The signs of disease in these mice are reminiscent of wild-type MARV/Ang infections in humans and nonhuman primates. We believe that this will be of help in accelerating the development of life-saving measures against Marburg virus infections.

Ferrets Infected with Bundibugyo Virus or Ebola Virus Recapitulate Important Aspects of Human Filovirus Disease

ABSTRACT Bundibugyo virus (BDBV) is the etiological agent of a severe hemorrhagic fever in humans with a case-fatality rate ranging from 25 to 36%. Despite having been known to the scientific and medical communities for almost 1 decade, there is a dearth of studies on this pathogen due to the lack of a small animal model. Domestic ferrets are commonly used to study other RNA viruses, including members of the order Mononegavirales. To investigate whether ferrets were susceptible to filovirus infections, ferrets were challenged with a clinical isolate of BDBV. Animals became viremic within 4 days and succumbed to infection between 8 and 9 days, and a petechial rash was observed with moribund ferrets. Furthermore, several hallmarks of human filoviral disease were recapitulated in the ferret model, including substantial decreases in lymphocyte and platelet counts and dysregulation of key biochemical markers related to hepatic/renal function, as well as coagulation abnormalities. Virological, histopathological, and immunohistochemical analyses confirmed uncontrolled BDBV replication in the major organs. Ferrets were also infected with Ebola virus (EBOV) to confirm their susceptibility to another filovirus species and to potentially establish a virus transmission model. Similar to what was seen with BDBV, important hallmarks of human filoviral disease were observed in EBOV-infected ferrets. This study demonstrates the potential of this small animal model for studying BDBV and EBOV using wild-type isolates and will accelerate efforts to understand filovirus pathogenesis and transmission as well as the development of specific vaccines and antivirals. IMPORTANCE The 2013-2016 outbreak of Ebola virus in West Africa has highlighted the threat posed by filoviruses to global public health. Bundibugyo virus (BDBV) is a member of the genus Ebolavirus and has caused outbreaks in the past but is relatively understudied, likely due to the lack of a suitable small animal model. Such a model for BDBV is crucial to evaluating vaccines and therapies and potentially understanding transmission. To address this, we demonstrated that ferrets are susceptible models to BDBV infection as well as to Ebola virus infection and that no virus adaptation is required. Moreover, these animals develop a disease that is similar to that seen in humans and nonhuman primates. We believe that this will improve the ability to study BDBV and provide a platform to test vaccines and therapeutics.