Groups of 15 laboratory-bred beagles were vaccinated and boosted with either a placebo or adjuvanted bivalent bacterin comprised of a traditional Borrelia burgdorferi strain and a unique ospA- and ospB-negative B. burgdorferi strain that expressed high levels of OspC and then challenged with B. burgdorferi-infected Ixodes scapularis ticks. The vaccinated dogs produced high titers of anti-OspA and anti-OspC borreliacidal antibodies, including borreliacidal antibodies specific for an epitope within the last seven amino acids at the OspC carboxy terminus (termed OspC7) that was conserved among pathogenic Borrelia genospecies. In addition, spirochetes were eliminated from the infected ticks that fed on the bacterin recipients, B. burgdorferi was not isolated from the skin or joints, and antibody responses associated specifically with canine infection with B. burgdorferi were not produced. In contrast, B. burgdorferi was recovered from engorged ticks that fed on 13 (87%) placebo-vaccinated dogs (P<0.0001), skin biopsy specimens from 14 (93%) dogs (P<0.0001), and joint tissue specimens from 8 (53%) dogs (P=0.0022). In addition, 14 (93%) dogs developed specific antibody responses against B. burgdorferi proteins, including 11 (73%) with C6 peptide antibodies (P<0.0001). Moreover, 10 (67%) dogs developed Lyme disease-associated joint abnormalities (P<0.0001), including 4 (27%) dogs that developed joint stiffness or lameness and 6 (40%) that developed chronic joint inflammation (synovitis). The results therefore confirmed that the bacterin provided a high level of protection against Lyme disease shortly after immunization.
Recombinant vaccinia viruses were constructed and used in conjunction with site-specific antisera to study the coding capacity and detailed expression strategy of the M segment of the Phlebovirus Rift Valley fever virus (RVFV). The M segment could be completely and faithfully expressed in recombinant RVFV-vaccinia virus-infected cells, the gene products apparently being correctly processed and modified in the absence of the RVFV L and S genomic segments. The proteins encoded by the RVFV M segment included, in addition to the viral glycoproteins G2 and Gl, two previously uncharacterized polypeptides of 78 and 14 kilodaltons (kDa). By manipulation of RVFV sequences present in the recombinant vaccinia viruses and use of specific antibody reagents, it was found that the 78-kDa protein initiated at the first initiation codon of the open reading frame and encompassed the entire preglycoprotein and glycoprotein G2 coding sequences. The 14-kDa protein appeared to begin from the second in-phase ATG and was composed of only the preglycoprotein sequences. Both viral glycoproteins G2 and Gl could be synthesized and correctly processed in the absence of the 78-and 14-kDa proteins, as well as a large portion of the preglycoprotein sequences. However, the hydrophobic amino acid sequence immediately preceding the mature glycoprotein coding sequences was required for authentic glycoprotein production. The M-segment expression strategy involving aspects of translational initiation and protein processing are discussed. The functional roles of the 78-and 14-kDa proteins remain unclear. Rift Valley fever is an important disease of both livestock and humans in much of sub-Saharan Africa, causing acute febrile disease, abortions, and death in cattle and sheep and a denguelike illness in humans. Rift Valley fever virus (RVFV), a member of the Phlebovirus genus of the Bunyaviridae family, is the etiologic agent of this disease. RVFV, like all viruses of the Bunyaviridae (1), possesses a tripartite RNA genome consisting of L, M, and S segments (11, 28, 32). The expression strategy of the genomic segments of members of this family of viruses has been under investigation. For expression of the S RNA, viruses of the Bunyavirus (La Crosse, snowshoe hare, Germiston, and Akabane) and Uukuvirus (Uukuniemi) genera use a "negative-sense" strategy in that viral-complementary subgenomic RNA species encode, in overlapping reading frames, the nucleocapsid protein (N) and a nonstructural protein (NSs)
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