It has long been known that fungi and viruses live in the gut microbiome (the bacteria, fungi, viruses living in the gut), but generally the focus has only been on the bacteria living there. The viruses tend to be bacteriophages - viruses that go after bacteria by infecting them and killing them.
Bacteriophages have a large influence on what lives in the gut, as well as having an effect on the immune system. They start living in the human gut (the GI or gastrointestinal tract) shortly after birth. Scientists are now studying phages to see if they can be used against harmful bacteria and as a treatment for chronic diseases that involve the gastrointestinal system. They think that they could be used in place of antibiotics for antibiotic resistant bacteria.
Fungi are considered immune stimulating. They can have beneficial effects (cause immune responses that promote metabolic health and protect against infection). Others (sometimes even the same species!) can have harmful effects, such as promoting inflammation, for example, in intestinal bowel diseases (IBD). Candida albicans is one such fungi - it is found in the gut of most people, and can cause problems or not.
From Medscape: The Extra-Bacterial Gut Ecosystem: The Influence of Phages and Fungi in the Microbiome
Research on the gut microbiome — and clinical attention to it — has focused mainly on bacteria, but bacteriophages and fungi play critical roles as well, with significant influences on health and disease, experts said at the Gut Microbiota for Health (GMFH) World Summit 2025.
Fungi account for < 1% of the total genetic material in the microbiome but 1%-2% of its total biomass. “Despite their relative rarity, they have an important and outsized influence on gut health” — an impact that results from their unique interface with the immune system, said Kyla Ost, PhD, of the Anschutz Medical Campus, University of Colorado, in Denver, whose research focuses on this interface.
And bacteriophages — viruses that infect and kill bacteria — are highly abundant in the gut. “Bacteriophages begin to colonize our GI [gastrointestinal] tract at the same time we develop our own microbiome shortly after birth, and from that time on, they interact with the bacteria in our GI tract, shaping [and being shaped by] the bacterial species we carry with us,” said Robert (Chip) Schooley, MD, distinguished professor of medicine at the University of California San Diego School of Medicine.
“We’ve been talking about things that affect the gut microbiome — diet, genetics, immune response — but probably the biggest influence on what grows in the GI tract are bacteriophages,” said Schooley, co-director of the Center for Innovative Phage Applications and Therapeutics, in a session on the extra-bacterial gut ecosystem.
‘New life’ for Phage Therapy
Bacteriophages represent a promising approach for the treatment of multidrug resistant bacterial pathogens in an era of increasing resistance and a dried-up antibiotic discovery pipeline, Schooley said. (In 2019, an estimated 4.95 million deaths around the world were associated with bacterial antimicrobial resistance, and by 2050, it has been forecast that this number will rise to an estimated 8.22 million deaths.)
But in addition to suppressing bacterial pathogens causing direct morbidity, phage therapy has the potential to suppress bacteria believed to contribute to chronic diseases, he said. “We have proof-of-concept studies about the ability of phage to modulate bacteria in the digestive tract,” and an increasing number of clinical trials of the use of phages in GI and other diseases are underway, he said.
Phages were discovered just over a century ago, but phage therapy was widely abandoned once antibiotics were developed, except for in Russia and the former Eastern Bloc countries, where phage therapy continued to be used.
Phage therapy “got new life” in the West, Schooley said, about 10-15 years ago with an increasing number of detailed and high-profile case reports, including one in which a UC San Diego colleague, Tom Patterson, PhD, contracted a deadly multidrug resistant bacterial infection in Egypt and was eventually saved with bacteriophage therapy. (The case was the subject of the book The Perfect Predator).
Since then, as described in case reports and studies in the literature, “hundreds of people have been treated with bacteriophages here and in Europe,” most commonly for pulmonary infections and infections in implanted vascular and orthopedic devices, said Schooley, who coauthored a review in Cell in 2023 that describes phage biology and advances and future directions in phage therapy.
Research is also exploring the potential of phage therapy to selectively target adherent invasive E coli in Crohn’s disease, and Klebsiella pneumoniae in the gut microbiome as an exacerbator of inflammatory bowel disease (IBD), he said.
A Window Into the Mycobiome
The human gut mycobiome is primarily composed of fungi in the Saccharomyces, Candida, and Malassezia genera, with Candida species dominating. Fungal cells harbor distinct immune-stimulatory molecules and activate distinct immune pathways compared with bacteria and other members of the microbiome, said Ost, assistant professor in the immunology and microbiology department of CU Anschutz.
Some fungi, including those in the Candida genus, activate adaptive and innate immune responses that promote metabolic health and protect against infection. A recently published study in Science, for instance, demonstrated that colonization with C dubliniensis in very young mice who had been exposed to broad-spectrum antibiotics promoted “the expansion and development of beta cells in the pancreas” in a macrophage dependent manner, improving metabolic health and reducing diabetes incidence, she shared.
On the one hand, fungi can “exacerbate and perpetuate the pathogenic inflammation that’s found in a growing list of inflammatory diseases” such as IBD. And “in fact, a lot of the benefits and detriments are driven by the exact same species of fungi,” said Ost. “This is particularly true of Candida,” which is a “lifelong colonizer of intestinal microbiota that rarely causes disease but can be quite pathogenic when it does.”
A 2023 review in Nature Reviews Gastroenterology & Hepatology coauthored by Ost describes the role of commensal fungi in intestinal diseases, including IBD, colorectal cancer, and pancreatic cancer.
The pathogenic potential of commensal fungi is largely dependent on its strain, its morphology and its expression of virulence factors, researchers are learning. Ost has studied C albicans, which has been associated with intestinal inflammation and IBD. Like some other Candida species, C albicans are “fascinating shape shifters,” she said, transitioning between a less pathogenic “yeast” morphology and an elongated, adhesive “hyphae” shape that is more pathogenic.