By Christine Cuénod
At a significant annual international meeting of more than 10 000 physicists in Chicago in the United States in March, research from the University of KwaZulu-Natal’s (UKZN) Quantum Research Group was presented to the American Physical Society (APS) concerning the role played by the phenomenon of quantum tunnelling in infection with SARS-CoV-2.
This important study reveals what happens on the minutest scale when viruses infect their hosts - and could inform research into new therapies to treat disease and post-viral syndromes, and relieve the burden they impose on health systems.
Researchers in quantum biology have had some success in describing biological processes including photosynthesis, enzyme catalysis, magnetoreception and olfaction (the sense of smell). At the heart of many of these processes is the phenomenon of electron transfer, which is facilitated by the biological environment.
Professor Francesco Petruccione, Professor Ilya Sinayskiy and PhD candidate Betony Adams from UKZN, and Professor Rienk van Grondelle from Vrije Universiteit Amsterdam in The Netherlands authored the study. They were intrigued by the parallels between research in quantum biology and some mechanisms of SARS-CoV-2 infection, specifically the involvement of enzymes, the disruption of olfaction and the use of drugs that target specific receptors.
In the context of the urgent drive to generate more knowledge about exactly how viruses find purchase in their hosts with the SARS-CoV-2 pandemic raging, this research examines how electron transfer might activate cellular receptors.
Quantum tunnelling describes the movement of particles through barriers that appear impenetrable. It is thought to play a role in many biological processes, and possibly in the transfer of particles in the cells responsible for our sense of smell and even in cells in the body’s nervous system.
As the SARS-CoV-2 virus enters the body, it is understood to use enzymes to invade cells. Enzymes make use of the lock-and-key mechanism to bind to a substrate. However, it has also been suggested that quantum tunnelling is involved in the action of enzymes.
Taking this knowledge into account, in combination with observations that the Covid disease disrupts olfactory receptors leading to a loss of sense of smell, the researchers investigated how quantum tunnelling might play a significant role in enabling infection with SARS-CoV-2.
They developed a simple model to illustrate the mode of a viral spike protein’s vibrational and electronic (vibronic) interactions, and the likelihood that there would be a transfer of charge between it and a receptor cell in the body in the first step of virus-host invasion. This suggests that the vibronic mode of the spike protein, such as those found on the SARS-CoV-2 and other viruses, enhances electron transfer. The research could lead to new therapies to treat viruses that can be identified based on their unique vibrational spectra.
Prof Petruccione, the South African Research Chair for Quantum Information Processing and Communication (QIPC), founder of UKZN’s Centre for Quantum Technology, and interim Director of the National Institute for Theoretical and Computational Science (NITheCS) presented the research.