Infectivity of visna virus DNA

Integration of visna virus DNA occurs and may be necessary for productive infection

Proviral integration is thought to be an obligate step of the retroviral replication cycle but the lentivirus visna has been reported to replicate in sheep choroid plexus (SCP) cultures in the absence of proviral integration. Because of new evidence that visna virus has a functional integrase, we reexamined visna virus infection of SCP cultures and found that proviral integration does indeed occur in this setting. While the majority of viral DNA remains unintegrated, integrated proviruses arise early in infection and accumulate over time. The sequences of the resulting host-virus DNA junctions show that, like other retroviruses, visna loses terminal nucleotides from its DNA upon integration. However, unlike other retroviruses, in over half the host-U3 junctions analyzed only a single nucleotide was lost such that the universally conserved CA dinucleotide, two nucleotides from the end of unintegrated viral DNA, did not directly abut host sequences in the provirus. We analyzed the role of integration in visna replication by introducing a series of five mutations into the integrase gene of molecularly cloned visna virus LV1-1KS1. Each mutation abolished viral replication, suggesting that integration may be an obligatory step in replication. We also documented productive infection of SCP cultures in which cell division had been blocked by g-irradiation. The ability of visna to integrate and to replicate in nondividing cells points to the possible utility of visna-based vectors for gene transfer into differentiated cells.

Isolation of replication-competent molecular clones of visna virus

Visna virus is the prototypic member of a subfamily of retroviruses responsible for slow infections of animals and humans. As a part of our investigation of the functions of viral gene products in virus replication, we have isolated three infectious molecular clones and determined the complete nucleotide sequences of two of the clones. We have also characterized the progeny of the biologically cloned viral stocks and of the infectious clones and document considerable heterogeneity in plaque size and antigenic phenotype of the former that is reduced to near homogeneity in the progeny of the infectious clones. It thus should now be possible to trace the emergence of antigenic variants of visna virus as well as ascribe defined functions to structural and regulatory genes of the virus in determining neurovirulence and the slow tempo of infection.

Pathogenesis of lentivirus infections

Following infection of animals or humans, lentiviruses play a prolonged game of hide and seek with the host's immune system which results in a slowly developing multi-system disease. Emerging knowledge of the disease processes is of some relevance to acquired immune deficiency syndrome (AIDS), which is caused by a virus possessing many of the characteristics of a lentivirus.

Synthesis in cell culture of the gapped linear duplex DNA of the slow virus visna

Visna virus is a nontransforming retrovirus that causes slow infections in animals and a rapidly progressive-lytic infection in cell culture. The results of an analysis of the synthesis of viral DNA in cell culture are reported. Region- and strand-specific probes cloned in M13 have been used to define the dynamics of DNA synthesis and the major nucleic acid species formed. It is shown that (i) within the first hours of infection, a full-length copy of the viral RNA genome is synthesized by reverse transcription, (ii) early in infection a major species of DNA is formed that extends from a site near the center of the molecule to the 3' end, (iii) somewhat later a second major species of plus-strand DNA is generated that extends from the 5' end to the middle of the genome. As a consequence, most viral DNA molecules consist of a full-length minus strand, and two plus strands separated by a gap or nick in the center of the molecule (J. D. Harris, J. V. Scott, B. Traynor, M. Brahic, L. Stowring, P. Ventura, A. T. Haase, and R. Peluso (1981). Virology 113, 573-583). The implications of this viral DNA structure for one unusual aspect of the lentivirus life cycle, the production of viral RNA, and virions from extrachromosomal DNA are discussed (J. D. Harris, H. Blum, J. Scott, B. Traynor, P. Ventura, and A. T. Haase (1984). Proc. Natl. Acad. Sci. USA 81, 7212-7215).

Slow virus visna: reproduction in vitro of virus from extrachromosomal DNA

Under permissive conditions of growth in tissue culture, the retrovirus visna multiples over the course of a few days to high titer and kills the host cell. We show that in this lytic life cycle, viral DNA is tightly associated with, but not covalently linked to, chromosomal DNA. This finding provides explanations for a number of the unusual properties of the lentivirus subfamily of retroviruses, and suggests potential mechanisms for the block in virus gene expression in vivo responsible for the slow infection in nature.

Human spumavirus replication in human cells

It was previously reported that the replication of the human syncytium-forming virus (HSFV), a spumavirus, occurred only in fibroblast-like cell lines (human fetal diploid lung #645 [HFDL]) but not in epithelial-like lines (recovered amnion) [RA]. Factors that may be involved in such a phenomenon were the subject of this investigation. While both permissive (HFDL) and nonpermissive (RA) cell lines supported the replication of several representative animal viruses and adsorbed HSFV equally well, immunofluorescent staining of HSFV antigens revealed markedly fewer fluorescing cells in nonpermissive cultures. Infectious center assays of infected nonpermissive cells indicated the formation of significantly fewer infectious centers. The rate of DNA synthesis was markedly greater in the permissive cell lines. In addition, in the permissive cell line, the amount of proviral DNA revealed by the Hirt procedure and isopycnic banding in CsCl was significantly increased and was infectious as determined by the calcium phosphate-DMSO transfection assay. These results indicate that resistance of HSFV infection in nonpermissive cell cultures is probably an intracellular event.

Novel proteinaceous infectious particles cause scrapie

After infection and a prolonged incubation period, the scrapie agent causes a degenerative disease of the central nervous system in sheep and goats. Six lines of evidence including sensitivity to proteases demonstrate that this agent contains a protein that is required for infectivity. Although the scrapie agent is irreversibly inactivated by alkali, five procedures with more specificity for modifying nucleic acids failed to cause inactivation. The agent shows heterogeneity with respect to size, apparently a result of its hydrophobicity; the smallest form may have a molecular weight of 50,000 or less. Because the novel properties of the scrapie agent distinguish it from viruses, plasmids, and viroids, a new term "prion" is proposed to denote a small proteinaceous infectious particle which is resistant to inactivation by most procedures that modify nucleic acids. Knowledge of the scrapie agent structure may have significance for understanding the causes of several degenerative diseases.

Slow persistent infection caused by visna virus: role of host restriction

Proviral DNA has been demonstrated by in situ hybridization in foci of cells of a lamb infected with the RNA slow virus visna. A few of these cells also contain the major virion structural antigen p30. This restriction in virus gene expression in the infected animal provides a mechanism for persistence of virus in this chronic infection.

Formation and structure of infectious DNA of spleen necrosis virus

The kinetics of formation and the structure of infectious DNA of spleen necrosis virus were determined. Nonintegrated infectious viral DNA first appeared 18 to 24 h after infection of dividing cells and persisted for more than 14 days. The nonintegrated infectious viral DNA was in the form of either a double-stranded linear DNA with a molecular weight of 6 X 10(6), detected in both the cytoplasm and nucleus, or a closed circular DNA of the same molecular weight, detected primarily in the nucleus. Integrated infectious viral DNA appeared soon after the nonintegrated infectious viral DNA and was the predominant form of infectious viral DNA late after infection. Integration of the spleen necrosis virus DNA into the chicken cell genome was demonstrated by three independent criteria. Nucleic acid hybridization indicated that the linear infectious viral DNA had a 5- to 10-fold higher specific infectivity than either the closed circular or integrated infectious viral DNA. Infectious viral DNA did not appear in infected stationary cells, indicating some cellular influence on the formation of infectious viral DNA.