The entry into host cells of Sindbis virus, vesicular stomatitis virus and Sendai virus.

We have compared the mechanisms of entry into host cells of three enveloped viruses: Sendai virus, vesicular stomatitis virus (VSV) and Sindbis virus. Virus entry by membrane fusion should antigenically modify the surface of a newly infected cell in such a way that it will be killed by anti-viral antibody and complement. On the other hand, virus entry by a mechanism involving uptake by the cell of the whole virion should not make cells sensitive to antibody and complement. As expected, cells newly infected with Sendai virus were readily and completely lysed by anti-Sendai antibody and complement. In marked contrast, however, cells newly infected with either Sindbis virus or VSV were killed by anti-viral antibody and complement only when infected at an extremely high multiplicity of infection, in excess of 1000 plaque-forming units per cell. We favor the following explanation for these results with Sindbis virus and VSV: a very large majority of the Sindbis and VSV virions entered the infected cells by some means other than membrane fusion, presumably engulfment of the whole particle. Efficient entry by way of membrane fusion may therefore not be a general characteristic of enveloped viruses.     

Polyoma virus. The early region and its T-antigens.

The DNA sequence of the early coding region of polyoma virus is presented. It consists of 2739 nucleotides. The sequence predicts that more than one reading frame can be used to code for the three known polyoma virus early proteins (designated small, middle and large T-antigens). From the DNA sequence, the 'splicing' signals used in the processing of viral RNA to functional messenger RNAs can be predicted, as well as the sizes and sequences of the three proteins. Other unusual aspects of the DNA sequence are noted. Comparisons are made between the DNA sequences and the predicted amino acid sequences of the respective large T-antigens of polyoma virus and the related virus Simian Virus (SV) 40.     

The UL20 gene product of pseudorabies virus functions in virus egress.

The UL20 open reading frame is positionally conserved in different alphaherpesvirus genomes and is predicted to encode an integral membrane protein. A previously described UL20- mutant of herpes simplex virus type 1 (HSV-1) exhibited a defect in egress correlating with retention of virions in the perinuclear space (J. D. Baines, P. L. Ward, G. Campadelli-Fiume, and B. Roizman, J. Virol. 65:6414-6424, 1991). To analyze UL20 function in a related but different herpesvirus, we constructed a UL20- pseudorabies virus (PrV) mutant by insertional mutagenesis. Similar to HSV-1, UL20- PrV was found to be severely impaired in both cell-to-cell spread and release from cultured cells. The severity of this defect appeared to be cell type dependent, being more prominent in Vero than in human 143TK- cells. Surprisingly, electron microscopy revealed the retention of enveloped virus particles in cytoplasmic vesicles of Vero cells infected with UL20- PrV. This contrasts with the situation in the UL20- HSV-1 mutant, which accumulated virions in the perinuclear cisterna of Vero cells. Therefore, the UL20 gene products of PrV and HSV-1 appear to be involved in distinct steps of viral egress, acting in different intracellular compartments. This might be caused either by different functions of the UL20 proteins themselves or by generally different egress pathways of PrV and HSV-1 mediated by other viral gene products.     

The 30S Moloney sarcoma virus RNA contains leukemia virus nucleotide sequences.

The 50S-70S RNA of a Moloney sarcoma-leukemia virus [Mo-MSV(MLV)] complex produced by a particular mouse cell line was shown by gel electrophoresis to contain a major (97%) 30S sarcoma-specific subunit species and a minor (3%) 38S leukemia virus-specific subunit. On the basis of its sedimentation coefficient and known complexity, the 30S Mo-MSV RNA was estimated to be a unique RNA molecule of about 6000 nucleotides. Hybridization experiments using viral RNA and DNA complementary to viral RNA (cDNA) made by viral DNA polymerase indicated that the 30S Mo-MSV RNA shared 70% of its sequences with Mo-MLV, 30% with another MLV derived from Mo-MLV, and 30% with Kirsten sarcoma-xenotropic leukemia virus. The 30S Mo-MSV RNA sequences shared with these viruses were not additive. The Tm of a Mo-MSV RNA-MLV cDNA hybrid was 83 degrees C, indicating that large contiguous nucleotide sequences were shared between the two nucleic acids. Mo-MSV RNA and Mo-MLV RNA shared possibly seven of 20-30 RNAase T1-resistant oligonucleotides, while Mo-MSV RNA contained three, and Mo-MLV RNA contained at least five specific oligonucleotides. We conclude that the 30S Mo-MSV RNA molecule consists of approximately 70% (about 4200 nucleotides) Mo-MLV-specific sequences and of 30% (1800 nucleotides) Mo-MSV-specific sequences covalently linked. Our results favor the hypothesis that 30S Mo-MSV RNA was generated by recombination between Mo-MLV and other genetic elements. We discuss whether all or only the MSV-specific sequences of the 30S Mo-MSV RNA function as sarcoma genes. Mo-MLV cDNA was hybridized about 45% by unfractionated Mo-MSV (MLV) RNA at RNA/DNA ratios of up to 10, about 50% by electrophoretically purified 30S Mo-MSV RNA at RNA/DNA ratios up to 500, but close to 100% by unfractionated Mo-MSV(MLV) RNA at RNA/DNA ratios over 900. This indicated that unfractionated RNA of our Mo-MSV(MLV) contained a complete complement of Mo-MLV, albeit at a low ratio.     

The persistence of bovine viral diarrhea virus.

Bovine viral diarrhoea virus (BVDV) has a unique capacity to cause persistent infections of foetuses exposed within the first 150 days of gestation. Preventing foetal BVDV infection will aid in improved control. This unique ability gives BVDV a selective advantage allowing continual mutation and antigenic variation within cattle populations. Therefore, BVDV has become widespread and causes economic losses due to respiratory, reproductive and enteric disease. Vaccination (modified-live or killed) can provide some protection from acute disease and the development of persistently infected foetuses. However, vaccination programmes alone cannot control or eliminate BVDV. In naturally exposed and vaccinated herds, BVDV infections are not self-limiting and may persistent over time. This underscores the ability of the BVDV genome to remain fluid and adapt under selective pressures. Factors influencing persistence of BVDV infections in cattle populations include: non-lytic infections; evasion of host immune responses; foetal infections; acute infections; management practices; contaminated biologics; secondary hosts; defective replicated intermediates; antigenic variation; and replication in privileged anatomical sites.