Model Suggests That Mammalian Sperm Cells Have Two Modes of Swimming

This new model predicts that the swimming speed of a mammalian sperm cell does not simply increase as its chemical motors’ activity increases. Instead, as the motor activity of a swimming sperm cell increases, this motor activity passes a threshold level at which point a second, distinct swimming mode emerges. It is this second mode that could potentially be linked to sperm hyperactivation. 

In swimming mode one, the head of the mammalian sperm cell swings back and forth more than it does in swimming mode two. In swimming mode two, the wave-shaped beating of the flagellum is stronger than it is in swimming mode one. (See the related video for a visual side-by-side comparison of swimming modes one and two.)

“While we can’t state for certain that this new model predicts the phenomenon of sperm hyperactivation that often occurs right before fertilization, it is certainly an interesting possibility. I hope further research will clarify whether the motility transition seen in our model is indeed related to sperm hyperactivation,” said UC San Diego Professor David Saintillan, the corresponding author on the new paper and a fluid mechanics researcher in the Department of Mechanical and Aerospace Engineering at the UC San Diego Jacobs School of Engineering. 

“There is so much opportunity for engineers and mathematicians to contribute to our understanding of biology. More and more of the models we are working on in the field of fluid dynamics, for example, are emerging as important tools for understanding the dynamics of biological systems like locomotion. In some cases, models allow us to test mechanisms or hypotheses that you can’t easily address experimentally. In these kinds of situations, models can be extremely useful,” said Saintillan. 

The study of the mechanisms involved in mammalian sperm locomotion is an example of a problem where models have played a key role alongside experiments, Saintillan noted. “You can’t control the activity of the motors in live sperm cells with the turn of a dial, but with a model such as ours you can speed up or slow down the motor activity of sperm and see how the locomotion changes.”

Paper title

“A chemomechanical model of sperm locomotion reveals two modes of swimming,” published in the journal, Physical Review Fluids.

Authors

Chenji Li, Pedro Castilla, Achal Mahajan and David Saintillan from the Department of Mechanical and Aerospace Engineering at the UC San Diego Jacobs School of Engineering. 

Brato Chakrabarti at the Center for Computational Biology, Flatiron Institute

Li is currently at Purdue University.

Mahajan is currently at Altos Labs.