Type I interferons (IFN-I) are important cytokines linking innate and adaptive immunity(1). Plasmacytoid dendritic cells make high levels of IFN-I in response to viral infection and are thought to be the major source of the cytokines in vivo(2). Here, we show that conventional non-plasmacytoid dendritic cells taken from mice infected with a dendritic-cell-tropic strain of lymphocytic choriomeningitis virus make similarly high levels of IFN-I on subsequent culture. Similarly, non-plasmacytoid dendritic cells secrete high levels of IFN-I in response to double-stranded RNA (dsRNA), a major viral signature(3), when the latter is introduced into the cytoplasm to mimic direct viral infection. This response is partially dependent on the cytosolic dsRNA-binding enzyme protein kinase R-4 and does not require signalling through toll-like receptor (TLR) 3, a surface receptor for dsRNA(5). Furthermore, we show that sequestration of dsRNA by viral NS1 (refs 6,7) explains the inability of conventional dendritic cells to produce IFN-I on infection with influenza. Our results suggest that multiple dendritic cell types, not just plasmacytoid cells, can act as specialized interferon-producing cells in certain viral infections, and reveal the existence of a TLR-independent pathway for dendritic cell activation that can be the target of viral interference.

Various pathogens have been shown to infect antigen-presenting cells and affect their capacity to interact with and stimulate T-cell responses. We have used an antigenically identical pair of noncytopathic (ncp) and cytopathic (cp) bovine viral diarrhoea virus (BVDV) isolates to determine how the two biotypes affect monocyte and dendritic cell (DC) function. We have shown that monocytes and DCs are both susceptible to infection with ncp BVDV and cp BVDV in vitro. In addition, monocytes infected with ncp BVDV were compromised in their ability to stimulate allogeneic and memory CD4(+) T cell responses, but DCs were not affected. This was not due to down-regulation of a number of recognized co-stimulatory molecules including CD80, CD86 and CD40. Striking differences in the response of the two cell types to infection with cytopathic virus were seen. Dendritic cells were not susceptible to the cytopathic effect caused by cp BVDV, whereas monocytes were killed. Analysis of interferon (IFN)-alpha/beta production showed similar levels in monocytes and DCs exposed to cp BVDV, but none was detected in cells exposed to ncp BVDV. We conclude that the prevention of cell death in DCs is not associated with enhanced production of IFN-alpha/beta, as proposed for influenza virus, but is by a distinct mechanism.

Twenty pigs were inoculated with a virulent isolate (Quillota strain) of classical swine fever (CSF) virus to determine the chronological development of lesions in bone marrow. Histopathologic, ultrastructural and immunohistochemical (detection of viral antigen gp55, myeloid-histiocyte antigen, CD3 antigen, and FVIII-rag), and morphometric techniques were employed. Viral antigen was detected from 2 days postinfection (dpi) in stromal and haematopoitic cells, and severe atrophy related to apoptosis of haematopoitic cells was observed. Megakaryocytes (MKs) did not show significant changes in number, but there were important qualitative changes including 1) increased numbers of cloud-nuclei MKs, microMKs, apoptotic MKs, and atypical nucleated MKs and 2) decreased number of typical nucleated MKs. Morphometric study of these cells showed a decrease in cytoplasmic area. MK infection was detected from 2 dpi, but in a small percentage of cells. Myeloid cells showed quantitative changes, with an increase in granulocyte numbers. Apoptosis of lymphocytes and viral infection of erythroblasts were also observed. The main changes in stroma were depletion of T lymphocytes in the middle phase of the experiment and macrophages. Viral infection was also observed in these cells. MK lesions suggest dysmegakaryocytopoiesis, which would aggravate the thrombocytopenia already present and could be responsible for it. Granulocyte changes would lead to the appearance of circulating immature forms, whereas lymphocyte apoptosis in bone marrow would contribute to lymphopenia.

The gene encoding the phosphoprotein of the vaccine strain of Peste des petits ruminants (PPR) virus (Nigeria 75/1 vaccine strain) has been cloned and its nucleotide sequence been determined. This gene is 1655 nucleotides long and encodes two overlapping open reading frames (ORFs). Translation from the first AUG would produce a polypeptide of 509 amino acid residues with a predicted molecular mass of 54.9 kDa, the longest of the published morbillivirus P proteins. Translation from the second AUG would produce a protein of 177 amino acid residues with a predicted molecular mass of 20.3 kDa, analogous to the C proteins of other morbilliviruses. Evidence was found for the production of two types of P mRNA transcript, one a faithful transcript of the gene and the other with an extra G residue inserted at position 751. Translation from the first AUG of this second mRNA would produce a protein of 298 amino acids, with a predicted molecular mass 32.3 kDa, analogous to the V protein produced by other morbilliviruses. Sequences of the predicted P, C and V proteins were compared with those of the other morbillivirus sequences available to date. The P protein was found to be the most poorly conserved of the morbillivirus proteins, the amino acid identity ranging from 54% in case of Canine distemper virus (CDV) to 60% in the case of the Dolphin morbillivirus (DMV).