Thermostable cross-protective subunit vaccine against Brucella species.

A subunit vaccine candidate was produced from Brucella suis 145 (biovar 4; expressing both the A antigen of Brucella abortus and the M antigen of Brucella melitensis). The preparation consisted mostly of polysaccharide (PS; >90% [wt/wt]; both cell-associated PS and exo-PS were combined) and a small amount of protein (1 to 3%) with no apparent nucleic acids. Vaccinated mice were protected (these had a statistically significant reduction in bacterial colonization compared to that of unvaccinated controls) when challenged with representative strains of three Brucella species most pathogenic for humans, i.e., B. abortus, B. melitensis, and B. suis. As little as 1 ng of the vaccine, without added adjuvant, protected mice against B. suis 145 infection (5 × 10(5) CFU), and a single injection of 1 µg of this subunit vaccine protected mice from B. suis 145 challenge for at least 14 months. A single immunization induced a serum IgG response to Brucella antigens that remained elevated for up to 9 weeks. The use of heat (i.e., boiling-water bath, autoclaving) in the vaccine preparation showed that it was thermostable. This method also ensured safety and security. The vaccine produced was immunogenic and highly protective against multiple strains of Brucella and represents a promising candidate for further evaluation.

Envelope protein E1 as vaccine target for western equine encephalitis virus.

Western equine encephalitis virus (WEEV) is a mosquito-borne RNA virus which causes lethal infection in humans and equines. There are no commercial vaccines or anti-WEEV drugs available for humans. We used replication-defective, human adenovirus serotype-5 (HAd5) as a delivery vector for developing WEEV vaccine. Our previous study found delivery of both E1 and E2 envelope proteins of WEEV by HAd5 vector offers complete protection against lethal challenge of WEEV. In this paper, we constructed a HAd5-vectored E1 vaccine, Ad5-E1. Mice given single-dose vaccination of Ad5-E1 were completely protected against both homologous and heterologous WEEV strains. The protection was rapid, which was achieved as early as day 7 after vaccination. In addition, Ad5-E1 induced a strong WEEV-specific T cell response. Our data suggest E1 is a potential target for developing single-dose, fast-acting, HAd5-vectored vaccine for WEEV.

Identification of Western equine encephalitis virus structural proteins that confer protection after DNA vaccination.

DNA vaccines encoding different portions of the structural proteins of western equine encephalitis virus were tested for the efficacy of their protection in a 100% lethal mouse model of the virus. The 6K-E1 structural protein encoded by the DNA vaccine conferred complete protection against challenge with the homologous strain and limited protection against challenge with a heterologous strain.

Pre- and post-exposure protection against Western equine encephalitis virus after single inoculation with adenovirus vector expressing interferon alpha.

Western equine encephalitis virus (WEEV) is a positive-sense, single-stranded RNA virus which is transmitted to equines and humans through mosquito bites. WEEV infects the central nervous system with severe complications and even death. There are no human vaccine and antiviral drugs. We investigated whether adenovirus-mediated expression of interferon alpha could be used for pre- and post-exposure protection against a lethal WEEV challenge in mice. A human adenoviral vector (Ad5-mIFNalpha) expressing mouse interferon alpha was constructed. We found that Ad5-mIFNalpha provided 100% protection against various WEEV strains in mice after a single intramuscular inoculation at 24 h, 48 h or 1 week before the challenge. When given as a single inoculation at 6 h after the challenge, Ad5-mIFNalpha delayed the progress of WEEV infection and provided about 60% protection. Our findings suggest that adenovirus-mediated expression of interferon alpha can be an alternative approach for the prevention and treatment of WEEV infection.

Single-dose, fast-acting vaccine candidate against western equine encephalitis virus completely protects mice from intranasal challenge with different strains of the virus.

Western equine encephalitis virus (WEEV) causes a fatal infection of the central nervous system in humans and horses. However, neither human vaccine nor antiviral drug is available. We found previously that immunization of mice with two doses of an adenovirus-vectored WEEV vaccine, Ad5-WEEV, confers complete protection against homologous WEEV challenge. In this paper, we report that a single-dose injection of Ad5-WEEV completely protected mice against both homologous and heterologous strains of WEEV at 1 week after immunization. In addition, mice immunized with Ad5-WEEV were protected when challenged at 13 weeks after a single-dose immunization. Therefore, the protection conferred by Ad5-WEEV is rapid, cross-protective, and long-lasting. These results warrant further development of Ad5-WEEV into an emergency vaccine that can be used during a natural outbreak or a bioterrorism attack.

Complete protection of mice against a lethal dose challenge of western equine encephalitis virus after immunization with an adenovirus-vectored vaccine.

Western equine encephalitis virus (WEEV) is an important pathogen for both humans and equines. The virus is also listed as a bioterrorism agent due to its ability for aerosol transmission with high mortality. No commercial vaccines or antiviral drugs are available for the prevention and treatment of WEEV infection in humans. In this paper, we constructed a recombinant WEEV vaccine, designated as Ad5-WEEV, using a replication defective, human adenovirus serotype 5 (HAd5) as a delivery vector. Ad5-WEEV contains the E3-E2-6K-E1 structural protein gene of the 71V-1658 strain of WEEV and the E1 and E2 proteins were synthesized in cells inoculated with Ad5-WEEV. After intramuscular immunization of mice with two doses of Ad5-WEEV, neutralizing antibodies against WEEV were generated and the mice were completely protected from a lethal dose challenge of 71V-1658. In addition, we showed that passive transfer of serum from the Ad5-WEEV-immunized mice could partially control WEEV infection. These results demonstrate that HAd5 vectors are promising for WEEV vaccine development.