Cheaper anti-cancer drugs for humans might ultimately stem from a new study. Scientists have developed a kind of microbial 'bandage' that protects yew trees from disease-causing fungi. The researchers found that naturally occurring fungi in the yew's vascular system act like an immune system to swarm a wound site and protect against invading pathogens.

Study was conducted by the University of Guelph in Canada. A new paper published in Current Biology is the first to show how beneficial fungi living naturally in yew trees serve as a combination bandage-immune system for the plant.

Taxol is harvested from yew bark for use as an important cancer-fighting drug, but efforts to make synthetic taxol in the lab have been unsuccessful. The research team's findings might point drug makers to a less expensive synthetic process for making more of the substance.

Drug companies might one day harness beneficial fungi to pump out more taxol cheaply and easily to meet demand – this would be a "holy grail" for cancer drug makers.

Researchers have wondered why yew trees and non-pathogenic fungi living in them both produce taxol, a redundant process that uses a lot of energy and nutrients.

The answer lies in the unusual way that yews and their relatives make new branches.  Yews branch from buds under the bark. Branching causes cracks to open deep into the tree's vascular system, an open wound that invites disease-causing fungi. Taxol normally helps protect against pathogenic fungi. But the substance is toxic to the tree's own young buds.

The researchers found that naturally occurring fungi in the yew's vascular system act like an immune system to swarm a wound site and protect against invading pathogens. The taxol fungicide is contained in "fatty bodies" that direct it only against pathogens and not the tree's sensitive tissues.

The fatty bodies come together to form a wall and seal the wound site.

Yews are ancient trees related to ginkgo and Wallemi pine, old species that have similar branch cracking and contain similar fungal species. The researchers now hope to learn more about the genes and chemical pathways involved in making taxol in both trees and fungi.