Rapid generation of an anthrax immunotherapeutic from goats using a novel non-toxic muramyl dipeptide adjuvant.

BACKGROUND: There is a clear need for vaccines and therapeutics for potential biological weapons of mass destruction and emerging diseases. Anthrax, caused by the bacterium Bacillus anthracis, has been used as both a biological warfare agent and bioterrorist weapon previously. Although antibiotic therapy is effective in the early stages of anthrax infection, it does not have any effect once exposed individuals become symptomatic due to B. anthracis exotoxin accumulation. The bipartite exotoxins are the major contributing factors to the morbidity and mortality observed in acute anthrax infections. METHODS: Using recombinant B. anthracis protective antigen (PA83), covalently coupled to a novel non-toxic muramyl dipeptide (NT-MDP) derivative we hyper-immunized goats three times over the course of 14 weeks. Goats were plasmapheresed and the IgG fraction (not affinity purified) and F(ab')2 derivatives were characterized in vitro and in vivo for protection against lethal toxin mediated intoxication. RESULTS: Anti-PA83 IgG conferred 100% protection at 7.5 mug in a cell toxin neutralization assay. Mice exposed to 5 LD50 of Bacillus anthracis Ames spores by intranares inoculation demonstrated 60% survival 14 d post-infection when administered a single bolus dose (32 mg/kg body weight) of anti-PA83 IgG at 24 h post spore challenge. Anti-PA83 F(ab')2 fragments retained similar neutralization and protection levels both in vitro and in vivo. CONCLUSION: The protection afforded by these GMP-grade caprine immunotherapeutics post-exposure in the pilot murine model suggests they could be used effectively to treat post-exposure, symptomatic human anthrax patients following a bioterrorism event. These results also indicate that recombinant PA83 coupled to NT-MDP is a potent inducer of neutralizing antibodies and suggest it would be a promising vaccine candidate for anthrax. The ease of production, ease of covalent attachment, and immunostimulatory activity of the NT-MDP indicate it would be a superior adjuvant to alum or other traditional adjuvants in vaccine formulations.

The CODE RED Solution: biothreat response training for first responders.

The terrorist events of 2001 brought to light the need for a close working relationship between the first responder communities and the public health laboratories in New York State (NYS). Since 2002, the Wadsworth Center's Biodefense Laboratory (BDL) has been providing outreach training to first responders in New York, to enable them to respond safely, correctly, and confidently to biothreat events. A pocket trifold was developed, titled "CODE RED," which describes sampling protocols, risk analysis criteria, and important contact information for use during an emergency response to a potential bioterrorism situation. In addition, the BDL has provided training to more than 1,000 first responders in the basic knowledge of biothreat agents, routes of dissemination, sampling and decontamination methods, contamination control protocols, biothreat risk assessment, and legal chain of custody procedures. The training methods have been established for use by first responders wearing personal protective equipment (PPE). All states can benefit from highly trained first responders who are capable of efficient, safe, and effective biothreat response, resulting in increased safety of the first responders and laboratorians, as well as decreased turnaround times for laboratory results. The CODE RED trifold provides a working model for training first responders at the state and county levels for emergency biothreat response.

Isolation of avian paramyxovirus 1 from a patient with a lethal case of pneumonia.

An unknown virus was isolated from a lung biopsy sample and multiple other samples from a patient who developed a lethal case of pneumonia following a peripheral blood stem cell transplant. A random PCR-based molecular screening method was used to identify the infectious agent as avian paramyxovirus 1 (APMV-1; a group encompassing Newcastle disease virus), which is a highly contagious poultry pathogen that has only rarely been found in human infections. Immunohistochemical analysis confirmed the presence of APMV-1 antigen in sloughed alveolar cells in lung tissue from autopsy. Sequence from the human isolate showed that it was most closely related to virulent pigeon strains of APMV-1. This is the most completely documented case of a systemic human infection caused by APMV-1 and is the first report of an association between this virus and a fatal disease in a human.

Laboratory confirmation of generalized vaccinia following smallpox vaccination.

The reinitiation of smallpox vaccination has renewed interest in implementing modern diagnostic methods to assess orthopoxvirus infection and adverse events following vaccination. We report here the laboratory confirmation of vaccinia virus in pustular lesions of a healthy adult vaccinee by use of a two-tier algorithm incorporating TaqMan PCR and electron microscopy.

Laboratory-confirmed transmission of vaccinia virus infection through sexual contact with a military vaccinee.

A laboratory-confirmed, inadvertent transmission of vaccinia virus from an unusual source highlights the importance of epidemiologic tracing, proper biosafety practices in the clinical diagnostic laboratories, and educating clinicians and laboratorians to potential bioterrorism-initiated outbreaks as well as look-alike disease discrimination.