A groundbreaking study of the virosphere of the most populous animals - those without backbones such as insects, spiders and worms and that live around our houses - has uncovered 1445 viruses, revealing people have only scratched the surface of the world of viruses - but it is likely that only a few cause disease.
The meta-genomics research, a collaboration between the University of Sydney and the Chinese Centre for Disease Control and Prevention in Beijing, was made possible by new technology that also provides a powerful new way to determine what pathogens cause human diseases.
Professor Edward Holmes, from the Marie Bashir Institute for Infectious Diseases & Biosecurity and the School of Life and Environmental Sciences, who led the Sydney component of the project said although the research revealed humans are surrounded by viruses in our daily lives, these did not transfer easily to humans.
"This groundbreaking study re-writes the virology text book by showing that invertebrates carry an extraordinary number of viruses - far more than we ever thought," Professor Holmes said.
"We have discovered that most groups of viruses that infect vertebrates - including humans, such as those that cause well-known diseases like influenza - are in fact derived from those present in invertebrates," said Professor Holmes, who is also based at the University's multidisciplinary Charles Perkins Centre.
The study suggests these viruses have been associated with invertebrates for potentially billions of years, rather than millions of years as had been believed - and that invertebrates are the true hosts for many types of virus.
The paper, "Redefining the invertebrate RNA virosphere," is published tonight in Nature.
"Viruses are the most common source of DNA and RNA on earth. It is all literally right under our feet," Professor Holmes said.
The findings suggest viruses from ribonucleic acid, known as RNA - whose principal role is generally to carry instructions from DNA - are likely to exist in every species of cellular life.
"It's remarkable that invertebrates like insects carry so very many viruses - no one had thought to look before because most of them had not been associated with human-borne illnesses."
Although insects such mosquitoes are well-known for their potential to transmit viruses like zika and dengue, Professor Holmes stressed that insects should not generally be feared because most viruses were not transferable to humans and invertebrates played an important role in the ecosystem.
Importantly, the same techniques used to discover these invertebrate viruses could also be used to determine the cause of novel human diseases, such as the controversial 'Lyme-like disease' that is claimed to occur following tick bites.
"Our study utilised new techniques in meta-genomics, which we are also using to provide insights into the causes of human-borne diseases," said Professor Holmes, who is also a National Health and Medical Research Council Australia Fellow.
"The new, expensive technologies available to researchers which have allowed us to do this landmark project, provide the ultimate diagnostic tool."
Professor Holmes and his collaborators are conducting human studies using these new techniques to analyse Lyme-like disease and other clinical syndromes.
NOTES TO EDITORS:
This paper describes a landmark 'meta-transcriptomics' analysis of ~220 species of invertebrates from nine diverse animal phyla that have not previously been studied with respect to viral diversity and evolution. What we discovered is a picture of phylogenetic and genomic diversity that fundamentally changes our understanding of RNA virus evolution and re-writes the virology text book.
The meta-sequencing study profiled more than 220 invertebrate species across nine animal phyla and discovered more viruses than have been documented in any one study. The research fills major gaps in the understanding of RNA and reveals viruses evolve in a far more complex way than was previously thought. For example, the study has found that viruses can capture genes (including from the animals they infect), lose genes and transfer genes among themselves.
Together, the data from this new research present a view of the RNA virosphere that is more phylogenetically and genomically diverse than that depicted in current classification schemes and provide a more solid foundation for studies in virus ecology and evolution.
It enables us to re-examine and re-define the invertebrate virosphere, providing a new perspective on the fundamental patterns and processes of viral evolution.