X vs. Y: The Hidden Genetic War That Decides Sex
Scientists have discovered how genes on X and Y chromosomes fight for control over sperm, influencing whether more male or female offspring are born—and they’re studying this battle by recreating it in yeast. Deep within the cells of mice, a genetic arms race is unfolding between X and Y chromosome genes, battling for dominance in sperm.
Researchers have now discovered how these gene families compete by hijacking key proteins to boost the odds of producing male or female offspring. Using an ingenious yeast-based model, scientists are unraveling the molecular chess game that helps maintain the evolutionary balance of the sexes.
What Is Evolutionary Fitness?
In evolutionary terms, fitness is defined as an organism’s ability to survive and reproduce its genes into the next generation. Genes influence fitness, sometimes competing against each other within an organism. This competition, or arms race, is typically hard to observe–except when the genes in question live on the X and Y chromosomes, which determine the sex of offspring in mammals. In mice, this arms race can result in broods that have more males or females.
Cracking the Code of Sperm Competition
A study from University of Michigan researchers has uncovered the mechanism behind the arms race for mouse X and Y bearing sperm to fertilize an egg, analogous to space races to reach the moon.
“The X-carrying or Y-carrying sperm that gets there first is the one that successfully fertilizes the egg,” said Martin Arlt, Ph.D., associate research scientist in the Department of Human Genetics.
“If there were genes conferring benefits to X-bearing sperm, you would start to see more female offspring and vice versa. Yet we see a close to 50-50 split,” said Arlt, also the first author on the study.
“Over evolutionary time, the 50-50 split is the optimal ratio for a species with minor shifts potentially leading to loss of the species.”
Co-Adaptation on the X and Y Chromosomes
The sex-ratio balance is maintained as genes on the X and Y chromosomes co-adapt to keep each other in check. How this happens has been a mystery, as sperm cannot be grown in a lab. The U-M team found a unique solution, moving the X-linked Slxl1/Slx and Y-linked Sly gene families from mouse and putting them into yeast.
“We introduced each player in the competition into yeast to better understand how they work. Then we combined them to see how they interact and compete with one another.”
Competing for Control: The Role of Spindlins
In doing so, they discovered that the proteins encoded by Slxl1/Slx and Sly that affect sperm fitness appeared to compete for proteins called Spindlins, which influence gene expression. These proteins compete against each other for binding; the more of the X-linked gene family proteins that bind, the more X-carrying sperm that result and vice versa.
A Recent Evolutionary Innovation
“These proteins are relatively new innovations in evolutionary time, only a few million years old, well after humans diverged from chimps,” said Jacob Mueller, Ph.D., associate professor of human genetics and senior author on the paper.
“Spermatogenesis can and does occur fine without Slxl1/Slx and Sly, yet these genes have persisted in mice by integrating themselves into a system that is very important for the species. We have evidence that these arms races are happening over and over again in different species at different times.”
What’s Next in Gene Competition Research
In the future, the team plans to use the yeast model system to explore the evolution of the X/Y arms race and other competitive genes.
genetic war, sex determination, SRY gene, X chromosome, Y chromosome, transcription factors, sexual differentiation, gonadal development, gene expression, epigenetics, hormonal signaling, intersex, androgen insensitivity, turner syndrome, genomic imprinting, developmental biology, CRISPR, genome sequencing, comparative genomics, molecular biology
#GeneticWar, #SexDetermination, #SRYgene, #Xchromosome, #Ychromosome, #TranscriptionFactors, #SexualDifferentiation, #GonadalDevelopment, #GeneExpression, #Epigenetics, #HormonalSignaling, #Intersex, #AndrogenInsensitivity, #TurnerSyndrome, #GenomicImprinting, #DevelopmentalBiology, #CRISPR, #GenomeSequencing, #ComparativeGenomics, #MolecularBiology
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