By the end of every spring semester, students in my introductory biology course at Vanderbilt University have become quite familiar with natural variation in human sex chromosomes. They know, for example, that most females have two X chromosomes and most males have one X and one Y chromosome. But in every thousand humans, there are typically a few whose biological sex doesn’t match their sex chromosomes, such as XX males and XY females, or whose sex chromosome combinations are not even XX or XY, such as XXX females and XYY males.
Above: The split gill mushroom Schizophyllum commune, a fungal species that includes more than 20,000 sexes. Bernard Spragg
The relationship between the sex chromosomes we inherited from our parents and gender, and how people identify, has been in the news quite a lot recently, not least because the Trump administration is considering revising the definition of human genders.
As an evolutionary biologist who studies fungi, I often like to view such complex issues through the lens of life’s diversity. I believe that studying the reproductive strategies of fungi, and how the sex of these organisms is determined, offers a bewildering, but also fresh and surprising perspective of the sheer diversity with which, well, these organisms do it.
Unlike humans, sex in fungi is controlled by a specific and relatively small region – locus is the technical term – of DNA on a chromosome. For example, the sex locus of the baker’s yeast contains two different gene variants, which means that this organism has two sexes (or mating types) and individuals of one sex can only mate with individuals of the other.
In contrast, several mushroom-forming species have two genetic regions that determine sex – let’s call them A and B; and instead of two variants, the A and B regions can each contain multiple variants – let’s number them A1, A2, and so on and B1, B2 and so on. As the sex of each individual is determined by the specific combination of gene variants in the two regions, the number of possible sexes within these species grows: A1B1, A1B2, A2B1, A2B2 and so on. Still with me?
Given that some species of mushroom-forming fungi harbor dozens to hundreds of A and B region variants, it is estimated that these organisms contain thousands of sexes. And did I mention that in some species there are more than two sex determining regions? Sex in some fungi is heady stuff. No wonder then that professor Lisa Vaillancourt at the University of Kentucky was inspired to use standard card decks to create “fungal mating games” to help her students navigate and appreciate the mating lives of fungi.
Switching and Selfing
But the surprises offered by peeking into fungal sex don’t end here. One key aspect of the sex life of the baker’s yeast worth mentioning is that they are capable of switching their sex, a strategy thought to have evolved to promote mating with siblings of the opposite sex. Several other fungi, such as the mold Aspergillus fumigatus, which is one of the major fungal pathogens affecting humans, have the same two-sex system as the baker’s yeast, albeit without the ability for switching. However, individuals of the penicillin-producing mold Aspergillus nidulans, a close relative of A. fumigatus, contain both variants of the sex locus in their own genomes. What’s the advantage? The ability, and choice, to either self-reproduce or to mate with another individual.
Now why this organism is also able to undergo a process called parasexuality, which confers all the genetic benefits of sex but without (you guessed it) sex, is a story for another time. In recent years, however, parasexuality is receiving lots of attention as it is also employed by the human commensal yeast Candida albicans, another major human pathogen responsible for vaginal yeast infections but also deadly systemic ones.
What is then the meaning of all this diversity? Detailed evolutionary analyses indicate that some of these reproductive lifestyles, such as the ability to self-reproduce, have evolved repeatedly and frequently throughout fungi from the same building block, the mating locus. And variation in reproductive systems among closely related species is quite common, suggesting that these transitions can take place – on an evolutionary timescale – relatively quickly and easily.