Genomic differences between guinea pig lethal and nonlethal Marburg virus variants.

The complete genome sequences of 2 closely related plaque-derived variants of Marburg virus (MARV) species Lake Victoria marburgvirus, strain Musoke, indicate only a few regions of the RNA genome as underlying the differences between the 2 viruses. One variant is >90% lethal for guinea pigs and the other much less virulent, when guinea pigs are challenged with 1000 pfu of virus. Only 4 mutations that result in amino acid changes were identified, 1 in viral matrix protein VP40 and 3 in L, the RNA-dependent RNA polymerase. In addition, 6 differences were identified in noncoding regions of transcribed mRNA, and 1 silent codon change was identified in the L gene. Interestingly, the amino acid mutation identified in VP40 occurs in a nonconserved loop structure between 2 domains that are homologues only among MARV species. The L gene mutations were equally intriguing, clustering near a highly conserved motif in viral RNA-dependent RNA polymerases.

Multiagent vaccines vectored by Venezuelan equine encephalitis virus replicon elicits immune responses to Marburg virus and protection against anthrax and botulinum neurotoxin in mice.

The development of multiagent vaccines offers the advantage of eliciting protection against multiple diseases with minimal inoculations over a shorter time span. We report here the results of using formulations of individual Venezuelan equine encephalitis (VEE) virus replicon-vectored vaccines against a bacterial disease, anthrax; a viral disease, Marburg fever; and against a toxin-mediated disease, botulism. The individual VEE replicon particles (VRP) expressed mature 83-kDa protective antigen (MAT-PA) from Bacillus anthracis, the glycoprotein (GP) from Marburg virus (MBGV), or the H(C) fragment from botulinum neurotoxin (BoNT H(C)). CBA/J mice inoculated with a mixture of VRP expressing BoNT H(C) serotype C (BoNT/C H(C)) and MAT-PA were 80% protected from a B. anthracis (Sterne strain) challenge and then 100% protected from a sequential BoNT/C challenge. Swiss mice inoculated with individual VRP or with mixtures of VRP vaccines expressing BoNT H(C) serotype A (BoNT/A H(C)), MAT-PA, and MBGV-GP produced antibody responses specific to the corresponding replicon-expressed protein. Combination of the different VRP vaccines did not diminish the antibody responses measured for Swiss mice inoculated with formulations of two or three VRP vaccines as compared to mice that received only one VRP vaccine. Swiss mice inoculated with VRP expressing BoNT/A H(C) alone or in combination with VRP expressing MAT-PA and MBGV GP, were completely protected from a BoNT/A challenge. These studies demonstrate the utility of combining individual VRP vaccines into multiagent formulations for eliciting protective immune responses to various types of diseases.

Induction of humoral and CD8+ T cell responses are required for protection against lethal Ebola virus infection.

Ebola virus (EBOV)-like particles (eVLP), composed of the EBOV glycoprotein and matrix viral protein (VP)40 with a lipid membrane, are a highly efficacious method of immunization against EBOV infection. The exact requirements for immunity against EBOV infection are poorly defined at this time. The goal of this work was to determine the requirements for EBOV immunity following eVLP vaccination. Vaccination of BALB/c or C57BL/6 mice with eVLPs in conjunction with QS-21 adjuvant resulted in mixed IgG subclass responses, a Th1-like memory cytokine response, and protection from lethal EBOV challenge. Further, this vaccination schedule led to the generation of both CD4(+) and CD8(+) IFN-gamma(+) T cells recognizing specific peptides within glycoprotein and VP40. The transfer of both serum and splenocytes, but not serum or splenocytes alone, from eVLP-vaccinated mice conferred protection against lethal EBOV infection in these studies. B cells were required for eVLP-mediated immunity to EBOV because B cell-deficient mice vaccinated with eVLPs were not protected from lethal EBOV challenge. We also found that CD8(+), but not CD4(+), T cells are absolutely required for eVLP-mediated protection against EBOV infection. Further, eVLP-induced protective mechanisms were perforin-independent, but IFN-gamma-dependent. Taken together, both EBOV-specific humoral and cytotoxic CD8(+) T cell responses are critical to mediate protection against filoviruses following eVLP vaccination.

Virus-like particles exhibit potential as a pan-filovirus vaccine for both Ebola and Marburg viral infections.

A safe and effective pan-filovirus vaccine is highly desirable since the filoviruses Ebola virus (EBOV) and Marburg virus (MARV) cause highly lethal disease typified by unimpeded viral replication and severe hemorrhagic fever. Previously, we showed that expression of the homologous glycoprotein (GP) and matrix protein VP40 from a single filovirus, either EBOV or MARV, resulted in formation of wild-type virus-like particles (VLPs) in mammalian cells. When used as a vaccine, the wild-type VLPs protected from homologous filovirus challenge. The aim of this work was to generate a multi-agent vaccine that would simultaneously protect against multiple and diverse members of the Filoviridae family. Our initial approach was to construct hybrid VLPs containing heterologous viral proteins, of EBOV and MARV, and test the efficacy of the hybrid VLPs in a guinea pig model. Our data indicate that vaccination with GP was required and sufficient to protect against a homologous filovirus challenge, as heterologous wild-type VLPs or hybrid VLPs that did not contain the homologous GP failed to protect. Alternately, we vaccinated guinea pigs with a mixture of wild-type Ebola and Marburg VLPs. Vaccination with a single dose of the multivalent VLP vaccine elicited strong immune responses to both viruses and protected animals against EBOV and MARV challenge. This work provides a critical foundation towards the development of a pan-filovirus vaccine that is safe and effective for use in primates and humans.

Marburg virus-like particles protect guinea pigs from lethal Marburg virus infection.

Ongoing outbreaks of filoviruses in Africa and concerns about their use in bioterrorism attacks have led to intense efforts to find safe and effective vaccines to prevent the high mortality associated with these viruses. We previously reported the generation of virus-like particles (VLPs) for the filoviruses, Marburg (MARV) and Ebola (EBOV) virus, and that vaccinating mice with Ebola VLPs (eVLPs) results in complete survival from a lethal EBOV challenge. The objective of this study was to determine the efficacy of Marburg VLPs (mVLPs) as a potential vaccine against lethal MARV infection in a guinea pig model. Guinea pigs vaccinated with mVLPs or inactivated MARV developed MARV-specific antibody titers, as tested by ELISA or plaque-reduction and neutralization assays and were completely protected from a MARV challenge over 2000 LD50. While eVLP vaccination induced high EBOV-specific antibody responses, it did not cross-protect against MARV challenge in guinea pigs. Vaccination with mVLP or eVLP induced proliferative responses in vitro only upon re-exposure to the homologous antigen and this recall proliferative response was dependent on the presence of CD4+ T cells. Taken together with our previous work, these findings suggest that VLPs are a promising vaccine candidate for the deadly filovirus infections.

Virus inactivation by nucleic acid extraction reagents.

Many assume that common methods to extract viral nucleic acids are able to render a sample non-infectious. It may be that inactivation of infectious virus is incomplete during viral nucleic acid extraction methods. Accordingly, two common viral nucleic acid extraction techniques were evaluated for the ability to inactivate high viral titer specimens. In particular, the potential for TRIzol LS Reagent (Invitrogen Corp., Carlsbad, CA) and AVL Buffer (Qiagen, Valencia, CA) were examined to render suspensions of alphaviruses, flaviviruses, filoviruses and a bunyavirus non-infectious to tissue culture assay. The dilution series for both extraction reagents consistently caused cell death through a 100-fold dilution. Except for the DEN subtype 4 positive control, all viruses had titers of at least 10(6)pfu/ml. No plaques were detected in any extraction reagent plus virus combination in this study, therefore, the extraction reagents appeared to inactivate completely each of the high-titer viruses used in this study. These results support the reliance upon either TRIzol LS Reagent or AVL Buffer to render clinical or environmental samples non-infectious, which has implications for the handling and processing of samples under austere field conditions and low level containment.