Russia creates its own humanised mice to test COVID-19 vaccines and drugs

Following the recent Coronavirus outbreak, almost three million people have been infected worldwide, whereas the death toll has already passed the 200,000 mark, according to official reports. Meanwhile, a vaccine remains to be found, and classic medications show low efficacy. Under these conditions, it is up to pharmacologists to do their best in the search of novel treatments. However, laboratory studies are limited by the absence of COVID-19 animal models.

Russian scientists from the Institute of Gene Biology of the Russian Academy of Sciences, the State Virology and Biotechnology Research Center “Vector” and Belgorod University are already working on the development of SARS-CoV-2-sensitive mice to be used as a murine model in tests of potential COVID-19 vaccines and drugs, reports the Office of the Chief State Sanitary Inspector.

To create such a line of mice, researchers have formulated a two-step concept, recently described in the open-access, peer-reviewed scholarly journal Research Results and Pharmacology. Firstly, the mice are to be made biologically safe for routine laboratory practice. Secondly, in order for the mice to be efficient for non-clinical trials, they will need to experience symptoms and pathogenesis as human-like as possible. The scientists believe that they have everything necessary to implement this conception and expect the first results as early as June 2020.

“SARS-CoV-2-inoculated mice will have a human-like pathogenesis and symptoms of the COVID-19. The key difference between a new model and the existing ones will be its biological safety – animals will become sensitive to SARS-CoV-2 only after activation in conditions of a virological laboratory. It makes it possible to nullify the contagion risk for the staff working in nurseries and non-specialised laboratories during a pandemic,”

the team explains.

Already available data shows that there are two key proteins in the human cells, which are involved in the virus entry. First of all, it is the angiotensin-converting enzyme 2 (ACE2), which is the direct and main target of the coronavirus’ “corona”. Three lines of transgenic mice with the human ACE2 variant have been found to be susceptible to the SARS-CoV, a causative agent of the SARS outbreak in 2003. However, it was shown that, in addition to ACE2, a molecular pathway of coronavirus invasion contains another important link: the enzyme transmembrane protease serine 2 (TMPRSS2). The blocking of TMPRSS2 prevents SARS-CoV-2 entry on the cell culture in vitro.

To obtain mice with human-like COVID-19 symptoms and pathology, the researchers will introduce human ACE2 and TMPRSS2 genes into the murine genome under the mice’s own Tmprss2 promoter. Another key decision on the way of creating the new model is to ensure that SARS-CoV-2 sensitivity is inducible only after the introduction of LoxP sites in front of the human ACE2 and TMPRSS2 genes. As a result, human genes in a murine genome will turn on once a crossbreeding with mice expressing Cre-recombinase occurs. 

“The main trick here is that this crossbreed will only happen in specialised virological laboratories, which will prevent the novel line of mice from becoming an infection ‘reservoir’ in ordinary laboratories,”

say the researchers.

Original source:

Soldatov VO, Kubekina MV, Silaeva YuYu, Bruter AV, Deykin AV (2020) On the way from SARS-CoV-sensitive mice to murine COVID-19 model. Research Results in Pharmacology 6(2): 1-7. https://doi.org/10.3897/rrpharmacology.6.53633

Novel research on African bats pilots new ways in sharing and linking published data

A colony of what is apparently a new species of the genus Hipposideros found in an abandoned gold mine in Western Kenya
Photo by B. D. Patterson / Field Museum

Newly published findings about the phylogenetics and systematics of some previously known, but also other yet to be identified species of Old World Leaf-nosed bats, provide the first contribution to a recently launched collection of research articles, whose task is to help scientists from across disciplines to better understand potential hosts and vectors of zoonotic diseases, such as the Coronavirus. Bats and pangolins are among the animals already identified to be particularly potent vehicles of life-threatening viruses, including the infamous SARS-CoV-2.

The article, publicly available in the peer-reviewed scholarly journal ZooKeys, also pilots a new generation of Linked Open Data (LOD) publishing practices, invented and implemented to facilitate ongoing scientific collaborations in times of urgency like those we experience today with the COVID-19 pandemic currently ravaging across over 230 countries around the globe.

In their study, an international team of scientists, led by Dr Bruce PattersonField Museum‘s MacArthur curator of mammals, point to the existence of numerous, yet to be described species of leaf-nosed bats inhabiting the biodiversity hotspots of East Africa and Southeast Asia. In order to expedite future discoveries about the identity, biology and ecology of those bats, they provide key insights into the genetics and relations within their higher groupings, as well as further information about their geographic distribution.

“Leaf-nosed bats carry coronaviruses–not the strain that’s affecting humans right now, but this is certainly not the last time a virus will be transmitted from a wild mammal to humans. If we have better knowledge of what these bats are, we’ll be better prepared if that happens,”

says Dr Terrence Demos, a post-doctoral researcher in Patterson’s lab and a principal author of the paper.
One of the possibly three new to science bat species, previously referred to as Hipposideros caffer or Sundevall’s leaf-nosed bat
Photo by B. D. Patterson / Field Museum

“With COVID-19, we have a virus that’s running amok in the human population. It originated in a horseshoe bat in China. There are 25 or 30 species of horseshoe bats in China, and no one can determine which one was involved. We owe it to ourselves to learn more about them and their relatives,”

comments Patterson.

In order to ensure that scientists from across disciplines, including biologists, but also virologists and epidemiologists, in addition to health and policy officials and decision-makers have the scientific data and evidence at hand, Patterson and his team supplemented their research publication with a particularly valuable appendix table. There, in a conveniently organized table format, everyone can access fundamental raw genetic data about each studied specimen, as well as its precise identification, origin and the natural history collection it is preserved. However, what makes those data particularly useful for researchers looking to make ground-breaking and potentially life-saving discoveries is that all that information is linked to other types of data stored at various databases and repositories contributed by scientists from anywhere in the world.

Furthermore, in this case, those linked and publicly available data or Linked Open Data (LOD) are published in specific code languages, so that they are “understandable” for computers. Thus, when a researcher seeks to access data associated with a particular specimen he/she finds in the table, he/she can immediately access additional data stored at external data repositories by means of a single algorithm. Alternatively, another researcher might want to retrieve all pathogens extracted from tissues from specimens of a specific animal species or from particular populations inhabiting a certain geographical range and so on.

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The data publication and dissemination approach piloted in this new study was elaborated by the science publisher and technology provider Pensoft and the digitisation company Plazi for the purposes of a special collection of research papers reporting on novel findings concerning the biology of bats and pangolins in the scholarly journal ZooKeys. By targeting the two most likely ‘culprits’ at the roots of the Coronavirus outbreak in 2020: bats and pangolins, the article collection aligns with the agenda of the COVID-19 Joint Task Force, a recent call for contributions made by the Consortium of European Taxonomic Facilities (CETAF), the Distributed System for Scientific Collections (DiSSCo) and the Integrated Digitized Biocollections (iDigBio).

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Original source:

Patterson BD, Webala PW, Lavery TH, Agwanda BR, Goodman SM, Kerbis Peterhans JC, Demos TC (2020) Evolutionary relationships and population genetics of the Afrotropical leaf-nosed bats (Chiroptera, Hipposideridae). ZooKeys 929: 117-161. https://doi.org/10.3897/zookeys.929.50240