Direct functional screening of a cDNA expression library derived from primary porcine alveolar macrophages (PAM) revealed that CD163 is capable of conferring a porcine reproductive and respiratory syndrome virus (PRRSV)-permissive phenotype when introduced into nonpermissive cells. Transient-transfection experiments showed that full-length CD163 cDNAs from PAM, human U937 cells (histiocytic lymphoma), African green monkey kidney cells (MARC-145 and Vero), primary mouse peritoneal macrophages, and canine DH82 (histocytosis) cells encode functional virus receptors. In contrast, CD163 splice variants without the C-terminal transmembrane anchor domain do not provide PRRSV receptor function. We established several stable cell lines expressing CD163 cDNAs from pig, human, and monkey, using porcine kidney (PK 032495), feline kidney (NLFK), or baby hamster kidney (BHK-21) as the parental cell lines. These stable cell lines were susceptible to PRRSV infection and yielded high titers of progeny virus. Cell lines were phenotypically stable over 80 cell passages, and PRRSV could be serially passed at least 60 times, yielding in excess of 10 5 50% tissue culture infective doses/ml.
Innate immunity is the first line of defense against viral infection, and in turn, viruses have evolved to evade host immune surveillance. As a result, viruses may persist in host and develop chronic infections. Type I interferons (IFN-α/β) are among the most potent antiviral cytokines triggered by viral infections. Porcine reproductive and respiratory syndrome (PRRS) is a disease of pigs that is characterized by negligible induction of type I IFNs and viral persistence for an extended period. For IFN production, RIG-I/MDA5 and JAK-STAT pathways are two major signaling pathways, and recent studies indicate that PRRS virus is armed to modulate type I IFN responses during infection. This review describes the viral strategies for modulation of type I IFN responses. At least three non–structural proteins (Nsp1, Nsp2, and Nsp11) and a structural protein (N nucleocapsid protein) have been identified and characterized to play roles in the IFN suppression and NF-κB pathways. Nsp’s are early proteins while N is a late protein, suggesting that additional signaling pathways may be involved in addition to the IFN pathway. The understanding of molecular bases for virus-mediated modulation of host innate immune signaling will help us design new generation vaccines and control PRRS.
Reverse genetic systems were developed for a highly virulent 'atypical' porcine reproductive and respiratory syndrome virus (PRRSV). The full-length genome of 15395 nucleotides was assembled as a single cDNA clone and placed under either the prokaryotic T7 or eukaryotic CMV promoter. Transfection of cells with the RNA transcripts or the DNA clone induced cytopathic effects and produced infectious progeny. The reconstituted virus was stable and grew to the titer of the parental virus in cells. Upon infection, pigs produced clinical signs and lung pathology typical for PRRSV and induced viremia and specific antibodies. Previously, we showed that the PRRSV nucleocapsid (N) protein forms homodimers via both noncovalent and covalent interactions and that cysteine at position 23 is responsible for the covalent interaction. The functional significance of cysteines of N for PRRSV infectivity was assessed using the infectious cDNA clone. Each cysteine of N at positions 23, 75, and 90 was replaced with serine and the individual mutation was incorporated into the cDNA clone such that three independent cysteine mutants were constructed. When transfected, the wild type and C75S clones induced cytopathic effects and produced infectious virus with indistinguishable plaque morphology. In contrast, the C23S mutation completely abolished infectivity of the clone, indicating that C23-mediated N protein homodimerization plays a critical role in PRRSV infectivity. Unexpectedly, the C90S mutation also appeared to be lethal for virus infectivity. Genome replication and mRNA transcription were both positive for the replication-defective C23S and C90S mutants. The data suggest that, in addition to homodimerization, the PRRSV N protein may also undergo heterodimerization with another structural protein using cysteine 90 and that the N protein heterodimerization is essential for PRRSV infectivity.
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