A Surrogate Animal Model for Screening of Ebola and Marburg Glycoprotein-Targeting Drugs Using Pseudotyped Vesicular Stomatitis Viruses.

Filoviruses, including Ebola virus (EBOV) and Marburg virus (MARV), cause severe hemorrhagic fever in humans and nonhuman primates with high mortality rates. There is no approved therapy against these deadly viruses. Antiviral drug development has been hampered by the requirement of a biosafety level (BSL)-4 facility to handle infectious EBOV and MARV because of their high pathogenicity to humans. In this study, we aimed to establish a surrogate animal model that can be used for anti-EBOV and -MARV drug screening under BSL-2 conditions by focusing on the replication-competent recombinant vesicular stomatitis virus (rVSV) pseudotyped with the envelope glycoprotein (GP) of EBOV (rVSV/EBOV) and MARV (rVSV/MARV), which has been investigated as vaccine candidates and thus widely used in BSL-2 laboratories. We first inoculated mice, rats, and hamsters intraperitoneally with rVSV/EBOV and found that only hamsters showed disease signs and succumbed within 4 days post-infection. Infection with rVSV/MARV also caused lethal infection in hamsters. Both rVSV/EBOV and rVSV/MARV were detected at high titers in multiple organs including the liver, spleen, kidney, and lungs of infected hamsters, indicating acute and systemic infection resulting in fatal outcomes. Therapeutic effects of passive immunization with an anti-EBOV neutralizing antibody were specifically observed in rVSV/EBOV-infected hamsters. Thus, this animal model is expected to be a useful tool to facilitate in vivo screening of anti-filovirus drugs targeting the GP molecule.

A null mutation of ROS1a for DNA demethylation in rice is not transmittable to progeny.

Genes that promote DNA methylation and demethylation in plants have been characterized mainly in Arabidopsis. Arabidopsis DNA demethylation is mediated by bi-functional DNA enzymes with glycosylase activity that removes 5-methylcytosine and lyase activity that nicks double-stranded DNA at an abasic site. Homologous recombination-promoted knock-in targeting of the ROS1a gene, the longest of six putative DNA demethylase genes in the rice genome, by fusing its endogenous promoter to the GUS reporter gene, led to reproducibly disrupted ROS1a in primary (T(0)) transgenic plants in the heterozygous condition. These T(0) plants exhibited no overt morphological phenotypes during the vegetative phase, and GUS staining showed ROS1a expression in pollen, unfertilized ovules and meristematic cells. Interestingly, neither the maternal nor paternal knock-in null allele, ros1a-GUS1, was virtually detected in the progeny; such an intransmittable null mutation is difficult to isolate by conventional mutagenesis techniques that are usually used to identify and isolate mutants in the progeny population. Even in the presence of the wild-type paternal ROS1a allele, the maternal ros1a-GUS1 allele caused failure of early-stage endosperm development, resulting in incomplete embryo development, with embryogenesis producing irregular but viable embryos that failed to complete seed dormancy, implying non-equivalent maternal and paternal contribution of ROS1a in endosperm development. The paternal ros1a-GUS1 allele was not transmitted to progeny, presumably because of a male gametophytic defect(s) prior to fertilization. Thus, ROS1a is indispensable in both male and female gametophytes, and DNA demethylation must plays important roles in both gametophytes.

Characterization of a novel Na+/H+ antiporter gene InNHX2 and comparison of InNHX2 with InNHX1, which is responsible for blue flower coloration by increasing the vacuolar pH in the Japanese morning glory.

The reddish-purple buds of the wild-type Japanese morning glory (Ipomoea nil) change into blue open flowers, and the shift in the flower coloration correlates with an increase in the vacuolar pH of the flower epidermal cell. In the mutant deficient in the InNHX1 gene for the vacuolar Na(+)/H(+) antiporter, the vacuolar alkalization occurs only partially, and reddish-purple buds become purple open flowers. While most of the plant NHX genes characterized are generally expressed in leaves, stems and roots and induced by NaCl treatment, the InNHX1 gene is expressed predominantly in the flower limbs at around 12 h before flower opening. It is expressed very sparsly in leaves, stems and roots, and no induction occurs in response to NaCl treatment. Here, we identified a novel vacuolar Na(+)/H(+) antiporter gene InNHX2, which is expressed in leaves, stems and roots and is induced in response to NaCl treatment. In addition, relatively higher expression of InNHX2 was observed in the flower limbs shortly before flower opening. We also discovered that both the InNHX1 and InNHX2 proteins can catalyze both Na(+) and K(+) transport into vacuoles. These results suggest that InNHX2 performs dual functions: to confer salt tolerance on the plant and to promote partial vacuolar alkalization in the petals. The implication is that the InNHX2 protein is probably one of the components responsible for converting reddish-purple buds into purple open flowers by partially increasing the vacuolar pH in the absence of major InNHX1 activity.