New & Noteworthy
The Dark Yeast Rises
April 04, 2017
Sometimes in life you need to take risks to survive and prosper. Maybe you need to take a leap of faith like Bruce Wayne does to escape that pit in The Dark Knight Rises. Or you need to try a risky business strategy to put your company out in front.
While these are critical things to do at the time, chronic risk-taking is not usually a good idea. Even Bruce Wayne retires to Florence at the end of The Dark Knight Rises, his risky life choices done now that he has saved his beloved Gotham City. He can now settle down with Selina Kyle (Catwoman) and live happily (and safely) ever after.
Something similar can happen in the budding yeast, Saccharomyces cerevisiae. In the right environment, certain yeasts can build up mutations like mad, hoping to hit on one that lets them make it out of that pit.
But then, over time, yeasts with the successful mutation lose that frenetic mutation rate—they take fewer risks with their DNA. One way they can do this is by ending up with a mutation that suppresses the high mutation rate. This is like Bruce Wayne retiring to a nice villa on the Arno.
Another way they can reestablish their old mutation rate is to mate with a nonmutator, a yeast strain that does not risk its DNA with a high mutation rate. Now, the next generations have the beneficial mutation and a lowered mutation rate as well. It is as if Bruce Wayne settled down with an accountant instead of Catwoman and had risk-averse children to carry on the Wayne name.
Bui and coworkers investigate this phenomenon in yeast in a new study out in GENETICS. They show that natural isolates exist that can sporulate into one of these mutator strains. And that at least one strain predicted to have a high mutation rate has a number of suppressor mutations that tamp down that higher rate.
Previous work had shown that a high mutation rate can happen with mutations in two genes in the mismatch repair (MMR) pathway, MLH1 and PMS1. This was discovered when researchers saw that some of the haploid strains from a mating of two laboratory strains, S288C and SK1, showed this mutator phenotype. A closer look revealed that S288C has a mutation in MLH1, and SK1 has a mutation in PMS1.
Bui and coworkers show that these mutator haploid strains outcompete other strains in high salt media. The strain hits upon mutations that allowed for better survival in high salt faster than its slower mutating brethren. But this advantage does not last.
After 120 generations these mutator strains start to lag behind strains with more typical mutation rates. Their DNA becomes as beat up as Bruce Wayne’s body by the third movie.
The researchers next looked at the MLH1 and PMS1 genes of 1,010 natural isolates of S. cerevisiae to see if there were any that might be able to sporulate into a mutator strain. Or that were already mutator strains themselves.
Since the mutations that lead to the mutator phenotype are recessive, strains that are heterozygotes for mutations in both genes should be able to form haploid spores with the higher mutation rate. They found 18 that fit the bill.
They also found one strain, YJM523, that was homozygous for both mutations and so would be predicted to have a high mutation rate. They further investigated this strain.
The first thing they did was to test the YJM523 mutant genes in an S288C background. They found that these two mutant genes did indeed give S288C a mutator phenotype. In fact, it had a higher mutation rate than the original genes from S288C and SK1 did, suggesting there were other mutations in one or both YJM523 genes that further increased the mutation rate.
These researchers next wanted to determine if YJM523 had a higher mutation rate or not, but needed to first develop a new assay that could be used in natural isolates. They came up with a reporter system that is not dependent on the typical markers used in yeast experiments, but instead relies on two antibiotic markers.
The reporter uses the NatMX antibiotic resistance marker for selection and the KanMX marker to identify revertant mutants. By scoring the number of colonies resistant to both antibiotics, they could determine the mutation rate.
When the researchers did this experiment, they found that YJM523 did not have a particularly high mutation rate. Sporulation experiments showed that this was most likely due to multiple suppressor mutations.
So out in the wild, the potential for mutator strains exists. And a close look at the genome of YJM523 showed that if it did have a mutator phenotype, it was for a short time. This yeast at least quickly lost its high mutation rate (assuming it ever had one).
This study helps to explain how yeast can obtain that mutator phenotype that researchers have seen before. And how yeast can escape that mutation pit to get back to the safety of a reasonable DNA repair pathway. To quote the prisoners in The Dark Knight, “Deshi Basara”, or ‘rise up’ yeast!
by Barry Starr, Ph.D., Director of Outreach Activities, Stanford Genetics
Categories: Research Spotlight
Tags: adaptation, DNA mismatch repair, experimental evolution, genetic incompatibility, mutator phenotype, natural yeast isolates