An Antiviral Response Directed by PKR Phosphorylation of the RNA Helicase A

The double-stranded RNA-activated protein kinase R (PKR) is a key regulator of the innate immune response. Activation of PKR during viral infection culminates in phosphorylation of the α subunit of the eukaryotic translation initiation factor 2 (eIF2α) to inhibit protein translation. A broad range of regulatory functions has also been attributed to PKR. However, as few additional PKR substrates have been identified, the mechanisms remain unclear. Here, PKR is shown to interact with an essential RNA helicase, RHA. Moreover, RHA is identified as a substrate for PKR, with phosphorylation perturbing the association of the helicase with double-stranded RNA (dsRNA). Through this mechanism, PKR can modulate transcription, as revealed by its ability to prevent the capacity of RHA to catalyze transactivating response (TAR)–mediated type 1 human immunodeficiency virus (HIV-1) gene regulation. Consequently, HIV-1 virions packaged in cells also expressing the decoy RHA peptides subsequently had enhanced infectivity. The data demonstrate interplay between key components of dsRNA metabolism, both connecting RHA to an important component of innate immunity and delineating an unanticipated role for PKR in RNA metabolism

Interleukin-12p40 Modulates Human Metapneumovirus-Induced Pulmonary Disease in an Acute Mouse Model of Infection

The mechanisms that regulate the host immune response induced by human metapneumovirus (hMPV), a newly-recognized member of the Paramyxoviridae family, are largely unknown. Cytokines play an important role in modulating inflammatory responses during viral infections. IL-12p40, a known important mediator in limiting lung inflammation, is induced by hMPV and its production is sustained after the resolution phase of infection suggesting that this cytokine plays a role in the immune response against hMPV. In this work, we demonstrated that in mice deficient in IL-12p40, hMPV infection induced an exacerbated pulmonary inflammatory response and mucus production, altered cytokine response, and decreased lung function. However, hMPV infection in these mice does not have an effect on viral replication. These results identify an important regulatory role of IL-12p40 in hMPV infection

Selective transformation of host lymphocytes in vivo by retrovirus-producing macrophages

Macrophage-mediated retroviral transformation of host cells was studied in vivo utilizing the cloned murine macrophage-line GG2EE, generated by in vitro infection of bone marrow cells from C3H/HeJ mice (H-2(k)) with the acute transforming retrovirus J2 bearing the v-myc and v-raf oncogenes. Because GG2EE macrophages produce the J2 retrovirus, the development of secondary, J2 virus-induced tumors after the injection of the cell line into several strains of mice was evaluated. GG2EE cells proliferated and gave rise to histiocytic tumors in syngeneic mice and in allogeneic athymic Swiss mice. The inoculum of GG2EE cells in allogeneic DBA/2 mice (H-2(d)) and, to a lesser extent, in BALB/c (H-2(d)) and BALB/k (H-2(k)) mice gave rise to a small, solid mass at the injection site. Although the initial tumor was slowly rejected, secondary lymphomas belonging to the B or T cell lineage developed, leading to mouse death. Extensive phenotypic, functional, and chromosomal analyses proved that lymphomas were derived from host T and B cell transformation. Southern and Northern blot studies showed that J2 virus was integrated and expressed in lymphoma cells, demonstrating that the virus was transmitted to the host lymphocytes and suggesting that it was causal in lymphoma development. The existence of close and protracted interactions between GG2EE macrophages and allogeneic host lymphocytes and the presence of viral particles in the area of macrophage-lymphocyte contact were demonstrated by histologic and ultrastructural analysis. Rejection of J2 virus-infected lymphocytes in allogeneic mice suggested that host lymphocyte transformation was dependent upon the macrophage cell type. These results demonstrate that macrophage-derived J2 retrovirus transforms host lymphocytes in vivo in allogeneic mice and that a condition of host alloreactivity is critical for such event