Ebola virus (EBOV) remains one of the most lethal transmissible infections and is responsible for high fatality rates and substantial morbidity during sporadic outbreaks. With increasing human incursions into endemic regions and the reported possibility of airborne transmission, EBOV is a high-priority public health threat for which no preventive or therapeutic options are currently available. Recent studies have demonstrated that cocktails of monoclonal antibodies are effective at preventing morbidity and mortality in nonhuman primates (NHPs) when administered as a post-exposure prophylactic within 1 or 2 days of challenge. To test whether one of these cocktails (MB-003) demonstrates efficacy as a therapeutic (after the onset of symptoms), we challenged NHPs with EBOV and initiated treatment upon confirmation of infection according to a diagnostic protocol for U.S. Food and Drug Administration Emergency Use Authorization and observation of a documented fever. Of the treated animals, 43% survived challenge, whereas both the controls and all historical controls with the same challenge stock succumbed to infection. These results represent successful therapy of EBOV infection in NHPs. INTRODUCTIONSince its discovery and initial characterization in the mid-1970s, Ebola virus (EBOV; formerly known as Zaire ebolavirus; genus: Ebolavirus, family: Filoviridae) has remained one of the most virulent and deadly pathogens known. With mortality rates approaching 90%, the virus quickly overwhelms the host, inducing a severe hemorrhagic fever and often death during sporadic outbreaks (1, 2). There are currently no licensed vaccines or therapeutics to prevent or treat infection with EBOV or any filovirus. With the increasing ease and speed of global travel and the potential for viral spread via the aerosol route (3), EBOV is a potential public health threat (4). Classification by the Centers for Disease Control as a category A agent also designates EBOV as a bioterrorism threat, making this virus a biodefense research priority (5).Research has identified phosphorodiamidate morpholino oligomers (PMOs), small interfering RNAs (siRNAs), and a vesicular stomatitis virus (VSV)-based vaccine as potential candidates for post-exposure treatment (6-8). These candidates have shown promising efficacy in reducing mortality when administered to nonhuman primates (NHPs) up to 1 hour after exposure. More recently, antibodies were demonstrated to be highly effective in post-exposure prophylaxis of NHPs against EBOV. Passive transfer of macaque hyperimmune globulin was shown to protect rhesus macaques when dosing began 2 days after exposure (9). Similarly, a cocktail of three murine monoclonal antibodies (mAbs) provided 100 and 50% efficacy in cynomolgus macaques when dosing began 1 or 2 days after exposure, respectively (10). Finally, a cocktail of three mAbs with human constant regions (MB-003) manufactured in Nicotiana benthamiana (11) provided 100 or 67% protection in the rhesus macaque model when treatment began 1 hour or 2 days after expo...
Middle East Respiratory Syndrome Coronavirus (MERS-CoV) was identified in 2012 as the causative agent of a severe, lethal respiratory disease occurring across several countries in the Middle East. To date there have been over 1,600 laboratory confirmed cases of MERS-CoV in 26 countries with a case fatality rate of 36%. Given the endemic region, it is possible that MERS-CoV could spread during the annual Hajj pilgrimage, necessitating countermeasure development. In this report, we describe the clinical and radiographic changes of rhesus monkeys following infection with 5×106 PFU MERS-CoV Jordan-n3/2012. Two groups of NHPs were treated with either a human anti-MERS monoclonal antibody 3B11-N or E410-N, an anti-HIV antibody. MERS-CoV Jordan-n3/2012 infection resulted in quantifiable changes by computed tomography, but limited other clinical signs of disease. 3B11-N treated subjects developed significantly reduced lung pathology when compared to infected, untreated subjects, indicating that this antibody may be a suitable MERS-CoV treatment.
SUMMARY Passive administration of monoclonal antibodies (mAbs) is a promising therapeutic approach for Ebola virus disease (EVD). However, all mAbs and mAb cocktails that have entered clinical development are specific for a single member of the Ebolavirus genus, Ebola virus (EBOV), and ineffective against outbreak-causing Bundibugyo virus (BDBV) and Sudan virus (SUDV). Here, we advance MBP134, a cocktail of two broadly neutralizing human mAbs, ADI-15878 from an EVD survivor and ADI-23774 from the same survivor but specificity-matured for SUDV GP binding affinity, as a candidate pan-ebolavirus therapeutic. MBP134 potently neutralized all ebolaviruses and demonstrated greater protective efficacy than ADI-15878 alone in EBOV-challenged guinea pigs. A second-generation cocktail, MBP134AF, engineered to effectively harness natural killer (NK) cells afforded additional improvement relative to its precursor in protective efficacy against EBOV and SUDV in guinea pigs. MBP134AF is an optimized mAb cocktail suitable for evaluation as a pan-ebolavirus therapeutic in nonhuman primates.
The filoviruses, which include the marburg- and ebolaviruses, have caused multiple outbreaks among humans this decade. Antibodies against the filovirus surface glycoprotein (GP) have been shown to provide life-saving therapy in nonhuman primates, but such antibodies are generally virus-specific. Many monoclonal antibodies (mAbs) have been described against Ebola virus. In contrast, relatively few have been described against Marburg virus. Here we present ten mAbs elicited by immunization of mice using recombinant mucin-deleted GPs from different Marburg virus (MARV) strains. Surprisingly, two of the mAbs raised against MARV GP also cross-react with the mucin-deleted GP cores of all tested ebolaviruses (Ebola, Sudan, Bundibugyo, Reston), but these epitopes are masked differently by the mucin-like domains themselves. The most efficacious mAbs in this panel were found to recognize a novel “wing” feature on the GP2 subunit that is unique to Marburg and does not exist in Ebola. Two of these anti-wing antibodies confer 90 and 100% protection, respectively, one hour post-exposure in mice challenged with MARV.
e Recent incidents in the United States and abroad have heightened concerns about the use of ricin toxin as a bioterrorism agent. In this study, we produced, using a robust plant-based platform, four chimeric toxin-neutralizing monoclonal antibodies that were then evaluated for the ability to passively protect mice from a lethal-dose ricin challenge. The most effective antibody, c-PB10, was further evaluated in mice as a therapeutic following ricin exposure by injection and inhalation. Ricin toxin is a member of the medically important A-B family of plant and bacterial ribosome-inactivating proteins (RIPs) (1). In its mature form, ricin is a 65-kDa heterodimeric glycoprotein that is a natural constituent of the seeds of the castor plant (Ricinus communis). The 267-amino-acid A subunit (RTA) of ricin is an RNA N-glycosidase that depurinates a conserved adenosine residue within the so-called sarcin-ricin loop (SRL) of eukaryotic 28S rRNA, which is required for activation of the elongation factor EF-Tu (2, 3). RTA is linked via a single disulfide bond to ricin's B subunit (RTB), a 262-amino-acid lectin that is specific for glycoproteins and glycolipids terminating in galactose and Nacetylgalactosamine (Gal/GalNAc). In addition to its role in attachment, RTB also mediates the retrograde transport of ricin to the trans-Golgi network (TGN) and endoplasmic reticulum (ER), where RTA is ultimately delivered across the ER membrane and into the cytoplasm (4, 5). The extraordinary capacity of RTA to inactivate ribosomes (k cat , 1,500/min) makes ricin one of the most potent known RIPs (6, 7). For example, in rodents and nonhuman primates, the 50% lethal dose (LD 50 ) of ricin by injection is approximately 5 g/kg, while the LD 50 of ricin by inhalation is estimated to be as low as 3 g/kg (8). The respiratory mucosa is especially sensitive to ricin, as even trace amounts of toxin are known to elicit widespread necrosis in the airways and alveoli, peribronchovascular edema, mixed inflammatory cell infiltrates, and massive pulmonary alveolar flooding (9-15).The U.S. Departments of Defense (DOD) and Health and Human Services (HHS) have ongoing initiatives to develop antibody-based products capable of providing passive protection against systemic and mucosal ricin exposure (16,17). In addition to protective efficacy, issues related to platform technology, scalability, and speed of manufacturing will ultimately dictate which product(s) will be pursued for advanced development and are consistent with the unique needs for biodefense. In this regard, the Nicotiana benthamiana-based rapid antibody-manufacturing platform (RAMP) provides the potential for extremely fast and high-yield monoclonal antibody (MAb) production that has already proven to be applicable to biodefense (18-21). The technology entails mass infiltration of mature Nicotiana plants with an Agrobacterium tumefaciens suspension carrying T-DNA encoding viral replicons and results in high MAb recovery from original DNA constructs within days (22). The Nicotiana-based RAMP...
Monoclonal antibodies (mAbs) and remdesivir, a small-molecule antiviral, are promising monotherapies for many viruses, including members of the genera Marburgvirus and Ebolavirus (family Filoviridae), and more recently, SARS-CoV-2. One of the major challenges of acute viral infections is the treatment of advanced disease. Thus, extending the window of therapeutic intervention is critical. Here, we explore the benefit of combination therapy with a mAb and remdesivir in a non-human primate model of Marburg virus (MARV) disease. While rhesus monkeys are protected against lethal infection when treatment with either a human mAb (MR186-YTE; 100%), or remdesivir (80%), is initiated 5 days post-inoculation (dpi) with MARV, no animals survive when either treatment is initiated alone beginning 6 dpi. However, by combining MR186-YTE with remdesivir beginning 6 dpi, significant protection (80%) is achieved, thereby extending the therapeutic window. These results suggest value in exploring combination therapy in patients presenting with advanced filovirus disease.
Milked venom from cone snails represent a novel biological resource with a proven track record for drug discovery. To strengthen this correlation, we undertook a chromatographic and mass spectrometric study of individual milked venoms from Conus purpurascens. Milked venoms demonstrate extensive peptide differentiation amongst individual specimens and during captivity. Individual snails were found to lack a consistent set of described conopeptides, but instead demonstrated the ability to change venom expression, composition and post-translational modification incorporation; all variations contribute to an increase in chemical diversity and prey targeting strategies. Quantitative amino acid analysis revealed that milked venom peptides are expressed at ranges up to 3.51–121.01 μM within single milked venom samples. This provides for a 6.37–20,965 fold-excess of toxin to induce apparent IC50 for individual conopeptides identified in this study. Comparative molecular mass analysis of duct venom, milked venom and radula tooth extracts from single C. purpurascens specimens demonstrated a level of peptide continuity. Numerous highly abundant and unique conopeptides remain to be characterized. This study strengthens the notion that approaches in conopeptide drug lead discovery programs will potentially benefit from a greater understanding of the toxinological nature of the milked venoms of Conus.
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