Type I interferon and interferon-stimulated gene expression in oral epithelial cells.

Oral epithelial cells (OEC) represent the first site of host interaction with viruses that infect the body through the oral route; however, their innate antiviral defense mechanisms yet to be defined. Previous studies have determined that OEC express pathogen-, damage-, or danger-associated molecular patterns (PAMPs or DAMPs), but their expression of key antiviral innate immune mediators, including type I interferons (type I IFN) and interferon-stimulated genes (ISGs) has not been studied extensively. We used the oral keratinocyte cell line, OKF6/TERT1, in the presence and absence of the viral mimics poly(I:C) and unmethylated CpG DNA, to define the expression of type I IFN and ISGs. We identified the basal expression of novel type I IFN genes IFNE and IFNK, while IFNB1 was induced by viral mimics, through the nuclear translocation of IRF3. Numerous ISGs were expressed at basal levels in OEC, with an apparent correlation between high expression and antiviral activity at the earlier stages of viral infection. Stimulation of OECs with poly(I:C) led to selective induction of ISGs, including MX1, BST2, PML, RSAD2, ISG15, and ZC3HAV1. Together, our results demonstrate that OECs exhibit a robust innate antiviral immune defense profile, which is primed to address a wide variety of pathogenic viruses that are transmitted orally.

A novel DNA-binding protein associated with DNA polymerase-alpha in pea stimulates polymerase activity on infrequently primed templates.

A 42 kDa DNA-binding protein is associated with DNA polymerase-alpha-primase in pea (Pisum sativum). In a previous publication it was shown that the protein has strong preference for ds-ss junctions in DNA, including the cohesive termini generated by restriction endonucleases. In this paper it is shown that when the DNA-binding protein is added back to polymerase-primase, the protein stimulates the activity of the polymerase. The stimulation is particularly marked when M13 DNA, primed with a single sequencing primer or primed with oligoribonucleotides by the polymerase's associated primase activity, is used as a template. The stimulation of polymerase activity is not caused by an increase in processivity. These data lead to the suggestion that the 42 kDa DNA-binding protein is a primer-recognition protein.