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28 July 2020 | Story Andre Damons | Photo Supplied
Prof Aliza le Roux; Dr Martin Nyaga, and Prof Robert Bragg.

There will be more pandemics in the future and some scientists feel that the current COVID-19 pandemic, which has already infected more than 16 million people and killed more than 600 000 people worldwide, is only a dress rehearsal for an even bigger pandemic. 

Prof Robert Bragg, researcher in the Department of Microbial, Biochemical and Food Biotechnology, and Prof Aliza le Roux, Assistant Dean: Natural and Agricultural Sciences and Associate Professor: Zoology and Entomology at the University of the Free State (UFS), warn about future pandemics, saying that humans’ interaction with animals and lack of learning from the past are the reasons for this. 

 Another researcher, Dr Martin Nyaga, Senior Lecturer/ Researcher: Next Generation Sequencing (NGS), agrees with Profs Bragg and Le Roux about new viruses and says viruses will keep emerging due to the general nature of viruses.

More pandemics might be on the cards

 “There will be more pandemics, and there is a feeling among some scientists that this could just be a dress rehearsal for the real big pandemic. Many virologists, including me, have been predicting an influenza pandemic for many years. Mankind has been warned about the coming pandemics for many years, but people seem to want to listen only when they are in the midst of a pandemic.”

“The bird-flu virus, Influenza H5N1, has a mortality rate of around 60-65%, but it has not yet developed human-to-human transmission. If this virus does develop human-to-human transmission, we could be in for a really serious pandemic! We need to prepare for the next major pandemic,” says Prof Bragg. 

Prof Le Roux says humans’ need for affordable meat on a regular basis is creating the perfect breeding ground for more diseases like this. “This means our demand for meat is driving cheaper and less controlled agricultural practices, cramming more animals into smaller spaces, feeding them less and less natural fodder. 

“Remember mad cow disease? Have you seen chicken batteries? We should not blame ‘exotic’ eating practices, but look at our own. If we could see eating meat as a ‘treat’ and not a daily ‘right’, we can reduce pressure on the environment and reduce the speed at which another zoonotic virus can evolve,” according to Prof Le Roux.

Dr Nyaga says that more viruses are possible in other organisms as well. 
“In as much as research on viral particles continues, more outbreaks are possible within not only the coronavirus domain, but also any other class of organisms. The ever-changing nature of viruses, mainly due to mutations and other mechanisms of genetic diversity, could occur through chain of transmission, including via the intermediate hosts. This kind of antigenic mutations could make the general population vulnerable due to lack of immunity against the new strains of emerging strains or completely novel viruses,” says Dr Nyaga.

Origin of SARS-CoV-2 and other diseases

According to Prof Bragg, the previous coronavirus that led to SARS and caused major concerns, also started in a wet food market in China – just like COVID-19. That virus was traced to a civet cat used for meat in such a wet food market. This virus had a very high mortality rate but could only be transmitted when a person showed clinical signs. Therefore, measuring the temperature of people was useful and beneficial. 

“There are many other examples of serious human pandemics which was spread from animals to humans. Another good example is the Ebola virus, which has also been traced to people eating bats in Africa. Yet another example is HIV, which is believed to have spread to man as a result of the consumption of chimpanzee meat.” 

“The most serious has been the 1918 Spanish flu, which started off in pigs and spread to man. All of these have to do with the mistreatment of animals by man,” says Prof Bragg.

Learning from past pandemics

Prof Le Roux says past pandemics can teach us how to respond from a public health perspective. “If we found treatments that worked before, we can use that as a starting point for current treatments. But if we can’t even control human behaviour (learning from past mistakes), think of how much more challenging it is to develop a vaccine against a virus that is so adaptable.”

Prof Bragg adds: “Mankind should also have learned lessons from the 1918 pandemic, but man is notoriously slow at learning lessons from the past. Each generation wants to make their own mistakes. One can only draw parallels from the people who defined lockdown regulations in 1918 to celebrate the end of the First World War and the demonstrations currently underway in the USA.” 

“The celebrations in 1918 caused more deaths than have occurred during the four years of the First World War! I predict that within a week or two, the number of cases and mortalities in the USA (and around the world) are going to skyrocket,” says Prof Bragg.

Knowing the animals involved

Dr Nyaga explains that identification of the source (reservoir hosts) and the intermediate host(s) is crucial in devising strategies, including palliative measures and designing drugs or vaccines against a potential pathogenic agent such as SARS-CoV-2. This will help in understanding the genomic dynamics and likely immunological responses that could be triggered along the chain of transmission to humans, and more importantly, how the compounds in the therapies can terminate the different stages of viral replication.

Prof Le Roux says she is not sure if a vaccine would be developed based on knowledge of a host species, but there is the possibility that (depending on the species) we can use some of the host’s antibodies to develop our own antibody therapies. “But generally, the knowledge can help more long-term planning on how to avoid future host shifts to humans. If we know where the virus originated, we can study that species or group of species better, and understand how the mutations occurred, etc. It would help us with future prevention more than current mitigation, I think.”

Research in the fight against COVID-19

According to the experts, various research efforts are afoot on the control of the disease. These range from the development of a vaccine, development of antiviral drugs, and the development of monoclonal antibodies or antibody fragments. Research is also needed on improved, faster, and cheaper diagnostic tests to test for the presence of the virus as well as for the detection of antibodies against the virus in people. This last test is needed to demonstrate the efficacy of vaccines as well as people in the population who have recovered from the virus. 

Prof Bragg says research on the epidemiology of the virus is also needed. How far it can spread and how long it can survive are critical questions, particularly when talking about social distancing. Much of the current information is based on guesswork.  

“Worldwide, research efforts are gaining an understanding of the virus and how it is causing disease in humans. If you think that this virus was unknown before December 2019, mankind has very quickly learned a lot about this virus and there are many very interesting articles coming out on what receptors the virus binds to and how the virus causes damage to the host and overcomes the host defence mechanisms,” says Prof Bragg.

Dr Nyaga says while the understanding of SARS-CoV-2 and COVID-19 is still in its infancy, results are already emerging on the molecular dynamics and immunological perspectives of the virus. With the characterisation of the genomic sequences of the virus, it has been possible to design several vaccines, including the inactivated virus, viral vectors, nucleic acid-based and protein-based vaccines. A good number of them are currently under clinical trials for possible WHO qualification towards global use. 

“Just recently, a clinical trial on one of these vaccines, called ‘the South African Ox1Cov-19 Vaccine VIDA-trial’, was on schedule locally to be championed by the University of the Witwatersrand, Johannesburg,” says Dr Nyaga. 
According to him, effective prevention essentially requires an in-depth understanding of the clinical severity of COVID-19, the extent of transmission and infection, and the efficacy of treatment options in order to accelerate the development of diagnostics and treatment options.

Prof Bragg says that the socio-economic impact of the virus is very serious at this stage. The final number of human cases and fatalities are still a long way from completion.  This virus is going to be with us for quite some time and the mortality rate in some countries with high levels of HIV and TB could become very high.

UFS-NGS part of COVID-19 research

The UFS-NGS Unit is privileged and well-positioned for high-throughput genomic work, attracting several high-profile projects prior to the COVID-19 outbreak and several funding calls for rapid response to COVID-19 during this pandemic period. Specifically, in this time of COVID-19, the UFS-NGS unit may be involved in proposed consortiums and current partnerships with several national and international organisations undertaking COVID-19 research. These include the Durban University of Technology in South Africa, the College of Medicine in Malawi, the University of Embu in Kenya, the Kenya Medical Research Institute, and the University of Ibadan in Nigeria, among others, working on COVID-19 projects to understand the evolving features of SARS-CoV-2 in Africa, with a view to tendering indigenous solutions to the outbreak.

News Archive

Region workshop on biosafety held at UFS
2009-07-17

 
A workshop for countries in the Southern African region on biosafety was presented at the University of the Free State (UFS) in Bloemfontein by the GMO Testing Facility at the UFS in collaboration with the SANBI, the South African National Biodiversity Institute, and the Norwegian Centre for Biodiversity, GenØk. Seventy participants with fourteen resource people, among them scientists, policy makers and regulators, attended the workshop on holistic foundations and assessment and regulation of GMO organisms. Seen here are, from the left: Prof. Chris Viljoen (Department of Haematology and Cell Biology at the UFS), Dr Theressa Frantz (SANBI) and Dr Jan Husby (Centre for Gene Ecology in Norway).
Photo: Stephen Collett

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