Topoisomerase 3b is dispensable for replication of a positive-sense RNA virus--murine coronavirus.

A recent study demonstrated that a DNA-RNA dual-activity topoisomerase complex, TOP3B-TDRD3, is required for normal replication of positive-sense RNA viruses, including several human flaviviruses and coronaviruses; and the authors proposed that TOP3B is a target of antiviral drugs. Here we examined this hypothesis by investigating whether inactivation of Top3b can inhibit the replication of a mouse coronavirus, MHV, using cell lines and mice that are inactivated of Top3b or Tdrd3. We found that Top3b-KO or Tdrd3-KO cell lines generated by different CRISPR-CAS9 guide RNAs have variable effects on MHV replication. In addition, we did not find significant changes of MHV replication in brains or lungs in Top3B-KO mice. Moreover, immunostaining showed that Top3b proteins are not co-localized with MHV replication complexes but rather, localized in stress granules in the MHV-infected cells. Our results suggest that Top3b does not have a universal role in promoting replication of positive-sense RNA virus, and cautions should be taken when targeting it to develop anti-viral drugs.

A method for hypothermia-induction and maintenance allows precise body and brain temperature control in mice.

The benefits as well as mechanisms of hypothermia in brain injuries are actively studied at the bench and in the clinic. However, methods used in controlling hypothermia vary among laboratories, and usually brain temperatures are not monitored directly in animals due to the need for an invasive procedure. Here we show a method, water immersion technique, which we developed recently to regulate body temperature in mice during hypothermia process. This method significantly reduced the temperature variation around target temperature. Importantly, this method demonstrated a parallel and consistent relationship between rectal temperature and brain temperature (the brain temperature was consistently 0.5C higher than rectal temperature) throughout hypothermia maintenance. This technique may be well adapted to hypothermia studies in mice and other rodents, especially to the assessment and regulation of brain temperature during studies.

Characterization of immune responses during regression of rabbit oral papillomavirus infections.

Rabbit oral papillomavirus (ROPV) is a mucosatropic papillomavirus that causes small benign discrete papillomas within the oral cavity of domestic rabbits. The goal of this study was to characterize the immune cell infiltrate over the course of regression of oral papillomas. ROPV-infected oral tissues were harvested at various time points after infection and analyzed by immunohistochemistry for papilloma morphology, viral capsid proteins, and associated immune infiltrates. The results of this study indicated that the L1 and L2 viral capsid proteins were lost rapidly at a time that coincided with an inflammatory response from the rabbit. This inflammatory response began with a rapid rise in numbers of CD11c+ cells at early regression. CD11c+ cells continued to increase in frequency through mid-regression and remained the most-represented cell through late regression. The initial rise in CD11c+ cells was followed by an infiltrate containing increased numbers of activated T cells, including CD4+ and CD25+ cells, during mid-regression. Mid-regression coincided spatially with a loss of viral capsid stain, suggesting that immune cells or cytokines or both were playing a key role in clearance of the papillomas. CD8+ cells increased at the lowest rate and were at low levels in the papilloma epidermis even at mid-regression. All cell types decreased by late regression. CD11c+ and major histocompatibility class II+ cells were the last populations of cells to decrease in number.