Drug-resistant fungi thrive in even the most remote regions

A wide shot of a Himalayan valley with a river running through it, taken from a height.

Even in sparsely populated, remote spots like the Three Parallel Rivers region in Yunnan, China, drug-resistant fungal strains are capable of propagating and spreading very quickly, researcher Jianping Xu says. (Photo courtesy Jianping Xu))


A disease-causing fungus — collected from one of the most remote regions in the world — is resistant to a common antifungal medicine used to treat infections, new McMaster research finds.

Seven per cent of Aspergillus fumigatus samples collected from the Three Parallel Rivers region in Yunnan, China were drug resistant, showed the study, published recently in mSphere.

Perched 6,000 metres above sea level and guarded by the staggering glaciated peaks of the Eastern Himalayas, the region is sparsely populated and undeveloped, which makes the presence of antimicrobial-resistant strains of A. fumigatus all the more striking for Jianping Xu, who led the study with colleagues in China.

“Seven per cent may seem like only a small number, but these drug-resistant strains are capable of propagating very quickly and taking over local and regional populations of this species,” explains Xu, a professor of biology at McMaster and a member of the Michael G. DeGroote Institute for Infectious Disease Research.

“There is a need for increased surveillance of drug resistance in the environment across diverse geographic regions.”

This study is the third in a trio of related studies by Xu and colleagues. The first found that approximately 80 per cent of A. fumigatus samples from Yunnan greenhouses were resistant to commonly used antifungal drugs; the second study determined that around 15 per cent of samples from Yunnan agricultural fields, lake sediments, and forests were likewise resistant.

While there is increasing evidence supporting the natural development of resistance in the environment, the outward gradation of resistance from greenhouses indicates that these resistant Himalayan strains of A. fumigatus were likely born from the spores of other fungi that were overexposed to agricultural fungicides in other settings, says Xu.

That these drug-resistant spores could potentially travel to and propagate in such remote areas is concerning for global spread, says Xu, whose research supports the Global Nexus School for Pandemic Prevention & Response.

“This fungus is highly ubiquitous — it’s around us all the time,” he explains.

“It is estimated that we all inhale hundreds of spores of this species every day. While it doesn’t always cause noticeable health problems, three to four million people experience disease symptoms caused by A. fumigatus each year.

“It can be very dangerous — it can lead to lung removal or even death — and now, increasingly, many of these infections will be impacted by drug resistance.”

In his other research, Xu has already examined identical mechanisms of resistance in strains of fungi found in Canada’s Northwest Territories and India — some 10,000 kilometres apart.

“Unlike viruses like COVID-19, fungi don’t need a host to spread,” Xu explains. “They can travel on humans, through trade, and even on strong winds.”

With that in mind, Xu will soon head back to the mountainous regions of China to sample the air for fungal spores, which he hopes will add clarity to how these resistant strains are reaching and growing in such remote regions.

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