Feline aminopeptidase N is not a functional receptor for avian infectious bronchitis virus.

BACKGROUND: Coronaviruses are an important cause of infectious diseases in humans, including severe acute respiratory syndrome (SARS), and have the continued potential for emergence from animal species. A major factor in the host range of a coronavirus is its receptor utilization on host cells. In many cases, coronavirus-receptor interactions are well understood. However, a notable exception is the receptor utilization by group 3 coronaviruses, including avian infectious bronchitis virus (IBV). Feline aminopeptidase N (fAPN) serves as a functional receptor for most group 1 coronaviruses including feline infectious peritonitis virus (FIPV), canine coronavirus, transmissible gastroenteritis virus (TGEV), and human coronavirus 229E (HCoV-229E). A recent report has also suggested a role for fAPN during IBV entry (Miguel B, Pharr GT, Wang C: The role of feline aminopeptidase N as a receptor for infectious bronchitis virus. Brief review. Arch Virol 2002, 147:2047-2056. RESULTS: Here we show that, whereas both transient transfection and constitutive expression of fAPN on BHK-21 cells can rescue FIPV and TGEV infection in non-permissive BHK cells, fAPN expression does not rescue infection by the prototype IBV strain Mass41. To account for the previous suggestion that fAPN could serve as an IBV receptor, we show that feline cells can be infected with the prototype strain of IBV (Mass 41), but with low susceptibility compared to primary chick kidney cells. We also show that BHK-21 cells are slightly susceptible to certain IBV strains, including Ark99, Ark_DPI, CA99, and Iowa97 (<0.01% efficiency), but this level of infection is not increased by fAPN expression. CONCLUSION: We conclude that fAPN is not a functional receptor for IBV, the identity of which is currently under investigation.

The avian coronavirus infectious bronchitis virus undergoes direct low-pH-dependent fusion activation during entry into host cells.

Coronaviruses are the causative agents of respiratory disease in humans and animals, including severe acute respiratory syndrome. Fusion of coronaviruses is generally thought to occur at neutral pH, although there is also evidence for a role of acidic endosomes during entry of a variety of coronaviruses. Therefore, the molecular basis of coronavirus fusion during entry into host cells remains incompletely defined. Here, we examined coronavirus-cell fusion and entry employing the avian coronavirus infectious bronchitis virus (IBV). Virus entry into cells was inhibited by acidotropic bases and by other inhibitors of pH-dependent endocytosis. We carried out fluorescence-dequenching fusion assays of R18-labeled virions and show that for IBV, coronavirus-cell fusion occurs in a low-pH-dependent manner, with a half-maximal rate of fusion occurring at pH 5.5. Fusion was reduced, but still occurred, at lower temperatures (20 degrees C). We observed no effect of inhibitors of endosomal proteases on the fusion event. These data are the first direct measure of virus-cell fusion for any coronavirus and demonstrate that the coronavirus IBV employs a direct, low-pH-dependent virus-cell fusion activation reaction. We further show that IBV was not inactivated, and fusion was unaffected, by prior exposure to pH 5.0 buffer. Virions also showed evidence of reversible conformational changes in their surface proteins, indicating that aspects of the fusion reaction may be reversible in nature.

The ubiquitin-vacuolar protein sorting system is selectively required during entry of influenza virus into host cells.

Influenza virus enters cells by endocytosis, and requires the low pH of the late endosome for successful infection. Here, we investigated the requirements for sorting into the multivesicular body pathway of endocytosis. We show that treatment of host cells with the proteasome inhibitors MG132 and lactacystin directly affects the early stages of virus replication. Unlike other viruses, such as retroviruses, influenza virus budding was not affected. The requirement for proteasome function was not shared by two other pH-dependent viruses: Semliki Forest virus and vesicular stomatitis virus. With MG132 treatment, incoming influenza viruses were retained in endosomes that partially colocalized with mannose 6-phosphate receptor, but not with classical markers of early or late endosomes. Colocalization was also observed with Rme-1, which is part of the recycling pathway of endocytosis. In addition, influenza virus entry was dependent on the vacuolar protein sorting pathway, as over-expression of dominant-negative hVPS4 caused arrest of viruses in endosome-like populations that partially colocalized with the hVPS4 protein. Overall, we conclude that influenza virus selectively requires the ubiquitin/vacuolar protein sorting pathway for entry into host cells, and that it must communicate with a specific cellular machinery for intracellular sorting during the initial phase of virus infection.