Malassezia yeasts, everywhere and sometimes dangerous

This image shows pityriasis versicolor (left) and folliculitis (right); two skin diseases caused by Malassezia yeasts.
Credit: Aristea Velegraki, National and Kapodistrian University of Athens, Greece. CC-BY

Malassezia yeasts have been found in human dandruff, deep-sea vents, and pretty much everywhere in between. The skin of most if not all warm-blooded animals is covered with these microbes, and while they mostly live in peaceful co-existence with their hosts, they can cause serious diseases in humans and other animals. A Pearl (a short review) published on January 8th in PLOS Pathogens discusses the diseases caused by Malassezia, their detection, and treatment.

The article by Teun Boekhout, from the CBS-KNAW Fungal Biodiversity Center in Utrecht, The Netherlands, and colleagues from Greece and Italy, is the fifth and final one in a series on Malassezia, and focuses on its role as a pathogen. Most of the problems caused by Malassezia yeasts are skin diseases. Some of them, like dandruff and atopic eczema in humans or external ear infections in dogs, are very common.

While treatments exist for most of these, the researchers point out that when treating Malassezia skin diseases, “one should always bear in mind that Malassezia yeasts are integral components of the skin microbiota, and therefore the therapeutic target should be controlling the Malassezia population rather than eradicating it.”

Malassezia bloodstream infections are less common, but premature infants and immunocompromised patients with extended stays in intensive care are at risk. Such infections are often linked to catheterization that facilitates internalization of the yeasts, either from the patient’s own skin or from someone else’s. Because routine tests in patients with blood infections of un-known origin often do not detect Malassezia right away, diagnosis might be delayed, which can be dangerous. However, once Malassezia is identified as the culprit, therapy with antifungal drugs is usually successful in eliminating the pathogen from the bloodstream.

As humans, we are covered head-to-toe with Malassezia–but that is not all. As Keisha Findley and Elisabeth Grice describe in their contribution to the series, healthy skin is actually cultivated by a well-balanced mix of bacteria and fungi (yeasts and molds), and this “skin flora” does not appear to elicit defense reactions by our immune system. How Malassezia interacts with other skin microbes is not yet known, but researchers think that both changes in the flora and changes in the immune system can disturb this peaceful equilibrium and lead to a range of skin diseases.

One of the reasons why, despite our intimate association, we do not know more about Malassezia, is that the yeasts cannot easily be isolated and grown in a laboratory environment. Malassezia are lipophilic, meaning they like fat. Human skin contains sebaceous glands that produce fats to lubricate and waterproof the skin, and Malassezia brakes down these fats and uses them as its main energy source.

As the yeasts metabolize the skin surface fat, they form break-down products that can potentially trigger harmful reactions by the skin. For example, Boekhout and colleagues discuss the intriguing possibility that Malassezia is involved in the development of skin cancer, because some of its fat breakdown products can activate known tumor-promoting pathways in the skin that are similar to those triggered by sun light.

How Malassezia strains that live in radically different environments (including the marine forms discussed by Anthony Amend in his Pearl) interact with their surroundings and obtain energy is still a mystery. However, Malassezia yeasts have been found pretty much any place scientists have looked for them–often in very large numbers–and are likely to play important roles in the both the healthy and diseased states of these environments.

Story Source:

The above story is based on materials provided by PLOS. Note: Materials may be edited for content and length.

Journal Reference:

  1. Aristea Velegraki, Claudia Cafarchia, Georgios Gaitanis, Roberta Iatta, Teun Boekhout. Malassezia Infections in Humans and Animals: Pathophysiology, Detection, and Treatment. PLoS Pathogens, 2015; 11 (1): e1004523 DOI: 10.1371/journal.ppat.1004523