Uirusu最新文献

Viruses achieve their efficient reproduction by utilizing their limited components (nucleic acids, lipids, and proteins) and host cell machineries. A detailed understanding of virus-virus and virus-host interactions will lead to the elucidation of mechanisms underlying viral pathogenesis and the development of novel medical countermeasures. We elucidated the details of several such interactions and their roles in the multiplication of negative-strand RNA viruses, measles virus, and Lassa virus. These discoveries were harnessed to develop a novel genetic approach for the generation of live-attenuated vaccine candidates with a well-defined molecular mechanism of attenuation. This article describes our findings.

Recently, outbreaks of highly pathogenic viruses, such as those of Ebola and Lassa viruses, have become a global public health issue. Such viruses must be handled in biosafety level 4 (BSL-4) laboratories. Currently, 62 BSL-4 laboratories are in operation, under construction, or planned in 24 counties. In this review, I provide an overview of the current status and characteristics of BSL-4 facilities in abroad and introduce my research on the wild-type Ebola virus at the BSL-4 facility in the USA.

Biosafety Level 4 (BSL-4) laboratories are required for research on microorganisms that are highly pathogenic to humans and for which there are no prevention or treatment methods. Currently, the majority of BSL-4 laboratories in more than 60 around the world are suit-type laboratories using positive pressure protective suits. In 2021, the first suit-type BSL-4 laboratory in Japan was constructed at Nagasaki University. Positive pressure protective suits are important as primary barriers to protect workers from pathogens, but the selection process has been largely unexplored. Here, I describe the selection process for the positive pressure protective suits to be used at the BSL-4 laboratory of Nagasaki University, and introduce a novel positive pressure protective suit (PS-790BSL4-AL), which was originally designed and produced in Japan.

Crimean-Congo hemorrhagic fever (CCHF) is an acute febrile illness with a high case fatality rate caused by the infection with Crimean-Congo hemorrhagic fever virus (CCHFV). The disease is endemic to a wide regions from the African continent to Asia through Europe. CCHFV is maintained in nature between Hyalomma species ticks and some species of animals. Humans are infected with CCHFV from CCHFV-positive tick bite or through a close contact with viremic animals in clucling hum am patients with CCHF. The CCHF-endemic regions depend on the distribution of the species of ticks such as Hyalomma species ticks, main vectors for CCHFV. There have been no confirmed cases of CCHF patients in Japan so far. CCHF is one of the zoonotic virus infections. Main clinical signs of the disease in humans are fever with nonspecific symptoms, and hemorrhage and deterioration in consciousness appear in severe cases. CCHF is classified in the disease category of viral hemorrhagic fevers, which include ebolavirus disease. Viral tick-borne diseases including tick-borne encephalitis, severe fever with thrombocytopenia syndrome, and Yezo virus infection, which has recently been discovered as a novel bunyavirus infection in Hokkaido, Japan, are becoming major concerns for public health in Japan. Trends of CCHF in terms of epidemiology should closely be monitored.

COVID-19 vaccination commenced globally in December 2020. Japan launched its vaccination rollout on February 17, 2021 and commenced booster vaccination campaign on December 1, 2021. It has been crucial to grasp the immune landscape in the country in order to aid in decision-making and evaluation of vaccination campaigns as well as understating the transmission dynamics of various variants of SARS-CoV-2. The present article shows a framework that enables us to predict the immune landscape, specifically, the proportion of immune population, using a mathematical modeling approach. This involved: prediction of vaccine coverage; estimation of vaccine effectiveness against the dominant SARS-CoV-2 variant in circulation; the quantification of increasing vaccine effectiveness (immune-build up) since receiving the first dose; the estimation of waning rate of vaccine effectiveness since receiving the second and third doses; and the consideration on the infection-induced immunity.

Viral diseases are responsible for substantial morbidity and mortality and continue to be of great concern. To ensure better control of viral infections, I have been tackling the issue as a medical doctor, an academic researcher, and a public health officer. Especially, I have studied respiratory viruses, such as the influenza virus, from the perspectives of molecular virology, theoretical modeling, and field epidemiology. RNA biology and its involvement with viral life-cycle and pathogenicity are central topics of molecular study, while mathematical models of transmission dynamics and phylogenetics are major components of theoretical research. As a field epidemiologist, I work with public health authorities during viral disease outbreaks. I was deployed to West Africa for viral hemorrhagic fever outbreak responses as a WHO consultant, and I have served the Japanese Government as an advisor for COVID-19 countermeasures. I would like to integrate various approaches from clinical medicine to epidemiology, theoretical modeling, evolutionary biology, genetics, and molecular biology in my research. In that way, we could gain a more comprehensive understanding of viral diseases. I hope these findings will help ease the disease burden of viral infections around the world.

In recent years, numerous emerging and reemerging infectious diseases have occurred worldwide and have seriously threatened our society. As a countermeasure against the pathogens responsible for serious diseases (classified as class 4 pathogens), we are preparing for full operation of the first suit-type biosafety level 4 (BSL-4) facility available for basic and applied research at Nagasaki University. For the safe operation of these facilities, experienced and qualified personnel with appropriate skills and knowledge of biorisk management must be certified. Developing an appropriate training system is a prerequisite for ensuring the safety of users involved in research in a BSL-4 laboratory. Here, we introduce an overview of the content of the training program that we are currently establishing for the BSL-4 facility at Nagasaki University. We are designing this program to follow national and international guidelines and regulations in part by referring to experiences and materials derived from multiple BSL-4 facilities in other countries. The established training program system, including the formulation processes, will serve as a reference and will provide practical materials for other research organizations to develop their own high-containment laboratory training programs.