Importance of interferons in recovery from mousepox.

Gamma interferon is shown to be critical in recovery of C57BL/6 mice from mousepox. Anti-gamma interferon treatment of mice infected in the footpad with ectromelia virus resulted in enhanced spread to and efficient virus replication in the spleen, lungs, ovaries, and, especially, liver. All treated, infected mice died within a mean of 7 days, 2.5 days earlier than mice with severe combined immunodeficiency that were given a comparable infection. On the other hand, alpha interferon appeared not to have a major role in controlling virus replication in tissues examined, and beta interferon was important for virus clearance in the liver and ovaries but not the spleen. Either anti-alpha, beta interferon or anti-beta interferon antibody therapy resulted in only 25% mortality. Infected control mice survived but showed persistence of ectromelia virus at the site of infection (the footpad) and transient presence of the virus in the spleen, liver, lungs, and ovaries and in the fibroreticular but not lymphoid cells of the draining popliteal lymph node. Depletion of gamma interferon but not alpha and/or beta interferon resulted in a significant reduction in the numbers of splenic T (especially gamma delta-TCR+), B, and Mac-1+ cells, although the proportion of Mac-1+ cells in the spleen increased compared with control values. Depletion of alpha, beta, or gamma interferons did not severely affect the generation of virus-specific cytotoxic T-lymphocyte responses or natural killer cell cytolytic activity. This study, in which a natural virus disease model was used, underscores the crucial importance of gamma interferon in virus clearance at all stages of infection and in all tissues tested except the primary site of infection, where virus clearance appears to be delayed.

Methionine overcomes neural tube defects in rat embryos cultured on sera from laminin-immunized monkeys.

Sera from laminin-immunized monkeys were previously found to cause neural tube defects in cultures of whole rat embryos by unknown mechanisms. In the present study, adding L-methionine to either the culture media or to the diets of the monkeys overcame the toxicity of the serum from one of these monkeys (LAM3) but not the other (LAM4). The antilaminin antibody levels and avidities for isolated murine laminin of sera from the two monkeys were comparable. However, when yolk sac homogenates were tested on ELISA, antibodies from LAM4 had greater binding than LAM3, which was further supported by immunoelectron microscopy. These differences in antibody binding were explained by the findings that antibodies from LAM4 recognized more epitopes than LAM3 and that LAM4 recognized specific epitopes not recognized by LAM3. These antibodies caused reductions in the number of microvilli on the cells and the cell sizes of the yolk sac endoderm. In addition, uptake of [14C]methionine, [14C]sucrose and [14C]valine by yolk sacs from embryos cultured on serum from LAM4 was less than that for LAM3. We suggest that the neural tube defects caused by the antilaminin antibodies were a result of reduced nutrient flow caused by the reduction in the number of microvilli on the cells of the yolk sac endoderm.

Acute inflammatory response to cowpox virus infection of the chorioallantoic membrane of the chick embryo.

The chick embryo chorioallantoic membrane was used to study the acute inflammatory response in the absence of contributions from the immune system. In preliminary experiments, lesions of wild-type cowpox virus strain Brighton (CPV-BR) and a 38K gene deletion mutant of CPV-BR (CPV-BR.D1) were compared with vaccinia virus (strains WR and Copenhagen), fowlpox virus, laryngotracheitis virus, and infectious tenosynovitis virus, and were ranked for degree of induced inflammation. The maximal and minimal inflammatory responses were observed with CPV-BR.D1 and CPV-BR viruses, respectively. CPV-BR.D1 lacks a 38K gene which encodes an anti-inflammatory 38-kDa protein that has homology to SERPINs. The kinetics and character of the inflammatory response were examined further in the wild-type CPV-BR and mutant CPV-BR.D1 infections using cell counts, electron microscopy, and assays for inflammatory cell activation. CPV-BR virus infection rapidly spread through the ectoderm, uniformly infecting all cells with the production of large amounts of virions and viral-induced cytopathic effect, but evoking little or no inflammatory response until 144 hr p.i. The CPV-BR.D1 infection, on the other hand, was rapidly contained by a dexamethasone-sensitive inflammatory response mainly of activated heterophils which was advanced by 36 hr p.i. Both infections resulted in disseminated disease with similar numbers of liver lesions and only a slight difference in the LD50, with the CPV-BR.D1 values being higher than that for CPV-BR virus. In this model, the acute inflammatory response alone is unable to prevent disseminated disease and associated mortality.