The UL4 protein of equine herpesvirus 1 is not essential for replication or pathogenesis and inhibits gene expression controlled by viral and heterologous promoters.

Defective interfering particles (DIP) of equine herpesvirus 1 (EHV-1) inhibit standard virus replication and mediate persistent infection. The DIP genome is comprised of only three genes: UL3, UL4, and a hybrid gene composed of portions of the IR4 (EICP22) and UL5 (EICP27) genes. The hybrid gene is important for DIP interference, but the function(s) of the UL3 and UL4 genes are unknown. Here, we show that UL4 is an early gene activated solely by the immediate early protein. The UL4 protein (UL4P) was detected at 4hours post-infection, was localized throughout the nucleus and cytoplasm, and was not present in purified virions. EHV-1 lacking UL4P expression was infectious and displayed cell tropism and pathogenic properties in the mouse model similar to those of parental and revertant viruses. Reporter assays demonstrated that the UL4P has a broad inhibitory function, suggesting a potential role in establishing and/or maintaining DIP-mediated persistent infection.

Properties of an equine herpesvirus 1 mutant devoid of the internal inverted repeat sequence of the genomic short region.

The 150 kbp genome of equine herpesvirus-1 (EHV-1) is composed of a unique long (UL) region and a unique short (Us) segment, which is flanked by identical internal and terminal repeat (IR and TR) sequences of 12.7 kbp. We constructed an EHV-1 lacking the entire IR (vL11ΔIR) and showed that the IR is dispensable for EHV-1 replication but that the vL11ΔIR exhibits a smaller plaque size and delayed growth kinetics. Western blot analyses of cells infected with vL11ΔIR showed that the synthesis of viral proteins encoded by the immediate-early, early, and late genes was reduced at immediate-early and early times, but by late stages of replication reached wild type levels. Intranasal infection of CBA mice revealed that the vL11ΔIR was significantly attenuated as mice infected with the vL11ΔIR showed a reduced lung viral titer and greater ability to survive infection compared to mice infected with parental or revertant virus.

Robust production of infectious hepatitis C virus (HCV) from stably HCV cDNA-transfected human hepatoma cells.

Hepatitis C virus (HCV) chronically infects approximately 170 million people worldwide, with an increased risk of developing cirrhosis and hepatocellular carcinoma. The study of HCV replication and pathogenesis has been hampered by the lack of an efficient stable cell culture system and small-animal models of HCV infection and propagation. In an effort to develop a robust HCV infection system, we constructed stable human hepatoma cell lines that contain a chromosomally integrated genotype 2a HCV cDNA and constitutively produce infectious virus. Transcriptional expression of the full-length HCV RNA genome is under the control of a cellular Pol II polymerase promoter at the 5' end and a hepatitis delta virus ribozyme at the 3' end. The resulting HCV RNA was expressed and replicated efficiently, as shown by the presence of high levels of HCV proteins as well as both positive- and negative-strand RNAs in the stable Huh7 cell lines. Stable cell lines robustly produce HCV virions with up to 10(8) copies of HCV viral RNA per milliliter (ml) of the culture medium. Subsequent infection of naïve Huh7.5 cells with HCV released from the stable cell lines resulted in high levels of HCV proteins and RNAs. Additionally, HCV infection was inhibited by monoclonal antibodies specific to CD81 and the HCV envelope glycoproteins E1 and E2, and HCV replication was suppressed by alpha interferon. Collectively, these results demonstrate the establishment of a stable HCV culture system that robustly produces infectious virus, which will allow the study of each aspect of the entire HCV life cycle.

High-level scu-PA production by butyrate-treated serum-free culture of recombinant CHO cell line.

The MGpUK-5 cell line, transformed with a single-chain urokinase-type plasminogen activator (scu-PA) minigene, generated mRNA transcripts and scu-PA titers corresponding to 65% or 86% of the amount generated before serum-free adaptation, despite significant loss of scu-PA gene copies during adaptation to serum-free culture. To further augment scu-PA production, a culture strategy employing sodium butyrate was explored. In 60-mL spinner flask cultures, sodium butyrate in the concentration range 1-10 mM allowed scu-PA production 2- to 3-fold higher than that in the negative control culture. Its productivity-enhancing activity was dependent on cell density in a range of 1-5 x 10(6) cells/mL, generating 72,200 +/- 8,100 IU/mL (480 +/- 50 mg/L) in 60-mL spinner flask cultures. To confirm this result, cells were grown to 4.4 x 10(6) cells/mL and treated with 5 mM sodium butyrate in a 2.5-L perfusion culture. The scu-PA titer increased more than 2-fold, and specific production rate of scu-PA increased 3-fold by this treatment. Overall, this perfusion culture gave rise to 1.7 x 10(8) IU scu-PA (1.1 g), comparable to total scu-PA production in a batch butyrate-treated culture performed at a 25-L bioreactor scale (1.3-3.5 g). Our results suggest that sodium butyrate treatment on high-density culture enables scu-PA production in gram quantities.