In a study led by Flinders University, researchers warn that the release of just 1% of pathogens trapped in melting ice poses a significant risk to Earth’s ecosystems and human health. The long-frozen time-traveling pathogens unleashed by climate change could evolve and become dominant in the environment, leading to substantial losses or changes in living species, the study stated.
Dangers lying in wait
In 2003, bacteria were revived from samples taken from the bottom of an ice core drilled into an ice cap on the Qinghai-Tibetan plateau. The ice at that depth was more than 750,000 years old. In 2014, a giant “zombie” Pithovirus sibericum virus was revived from 30,000-year-old Siberian permafrost, and in 2016, an outbreak of anthrax (a disease caused by the bacterium Bacillus anthracis) in western Siberia was attributed to the rapid thawing of B. anthracis spores in permafrost. It killed thousands of reindeer and affected dozens of people.
More recently, scientists found remarkable genetic compatibility between viruses isolated from lake sediments in the high Arctic and potential living hosts. Earth’s climate is warming at a spectacular rate, and up to four times faster in colder regions such as the Arctic. Estimates suggest we can expect four sextillion (4,000,000,000,000,000,000,000) microorganisms to be released from ice melt each year. This is about the same as the estimated number of stars in the universe.
However, despite the unfathomably large number of microorganisms being released from melting ice (including pathogens that can potentially infect modern species), no one has been able to estimate the risk this poses to modern ecosystems.
In a new study published today in the journal PLOS Computational Biology, we calculated the ecological risks posed by the release of unpredictable ancient viruses. Our simulations show that 1% of simulated releases of just one dormant pathogen could cause major environmental damage and the widespread loss of host organisms around the world.
We used a software called Avida to run experiments that simulated the release of one type of ancient pathogen into modern biological communities. We then measured the impacts of this invading pathogen on the diversity of modern host bacteria in thousands of simulations, and compared these to simulations where no invasion occurred.
The invading pathogens often survived and evolved in the simulated modern world. About 3% of the time the pathogen became dominant in the new environment, in which case they were very likely to cause losses to modern host diversity. In the worst- (but still entirely plausible) case scenario, the invasion reduced the size of its host community by 30% when compared to controls. The risk from this small fraction of pathogens might seem small, but keep in mind these are the results of releasing just one particular pathogen in simulated environments. With the sheer number of ancient microbes being released in the real world, such outbreaks represent a substantial danger.
Extinction and disease
Our findings suggest this unpredictable threat which has so far been confined to science fiction could become a powerful driver of ecological change. While we didn’t model the potential risk to humans, the fact that “time-traveling” pathogens could become established and severely degrade a host community is already worrisome.
We highlight yet another source of potential species extinction in the modern era – one which even our worst-case extinction models do not include. As a society, we need to understand the potential risks so we can prepare for them. Notable viruses such as SARS-CoV-2, Ebola and HIV were likely transmitted to humans via contact with other animal hosts. So it is plausible that a once ice-bound virus could enter the human population via a zoonotic pathway. While the likelihood of a pathogen emerging from melting ice and causing catastrophic extinctions is low, our results show this is no longer a fantasy for which we shouldn’t prepare.
Source: The conversation.