Microscopy images showing normal seminiferous
tubules in control testes with mature sperm (black arrow: left) but smaller
empty seminiferous tubules in testes harboring a synaptonemal complex protein
point mutation (black asterisk: right). Credit: Stowers Institute for Medical
Research
Millions of
couples worldwide experience infertility with half of the cases originating in
men. For 10% of infertile males, little or no sperm are produced. Now, new
research from the Stowers Institute for Medical Research, in collaboration with
the Wellcome Center for Cell Biology at the University of Edinburgh, is
shedding light on what may be going wrong in the process of sperm formation,
leading to potential theories on possible treatments.
"A significant cause of infertility in males is
that they just cannot make sperm," said Stowers Investigator Scott Hawley,
Ph.D. "If you know exactly what is wrong, there are technologies emerging
right now that might give you a way to fix it."
The study published on October 20, 2023, in Science Advances from the Hawley Lab
and Wellcome Center Investigator Owen Davies, Ph.D., may help explain why some
men do not make enough sperm to fertilize an egg.
In most sexually-reproducing species, including humans, a critical protein structure resembling a lattice-like bridge needs to be built properly to produce sperm and egg cells. The team led by former Postdoctoral Research Associate Katherine Billmyre, Ph.D., discovered that in mice, changing a single and very specific point in this bridge caused it to collapse, leading to infertility and thus providing insight into human infertility in males due to similar problems with meiosis.
Stowers scientists collaborate to uncover one
underlying reason for male infertility. The study published on October 20,
2023, in Science Advances from the Hawley Lab and Wellcome
Centre Investigator Owen Davies, Ph.D., may help explain why some men do not
make enough sperm to fertilize an egg. Credit: Stowers Institute for Medical
Research
Meiosis, the cell division process giving rise to sperm and eggs, involves
several steps, one of which is the formation of a large protein structure
called the synaptonemal complex. Like a bridge, the complex holds chromosome
pairs in place enabling necessary genetic exchanges to occur that are essential
for the chromosomes to then correctly separate into sperm and eggs.
"A significant contributor to infertility is defects in meiosis,"
said Billmyre. "To understand how chromosomes separate into reproductive
cells correctly, we are really interested in what happens right before that
when the synaptonemal complex forms between them."
Previous studies have examined many proteins comprising the synaptonemal complex, how they interact with each other, and have identified various mutations linked to male infertility. The protein the researchers investigated in this study forms the lattices of the proverbial bridge, which has a section found in humans, mice, and most other vertebrates suggesting it is critical for assembly. Modeling different mutations in a potentially crucial region in the human protein enabled the team to predict which of these might disrupt protein function.
Model of the synaptonemal complex in control and
mutant mice. The protein the team investigated (SYCP1) forms normally, and all
additional necessary proteins are recruited. In the mutant, SYCP1 localizes to
the chromosome axes but does not successfully form the bridge-like structure
(head-to-head interactions), and the additional proteins that help keep the
bridge intact are either missing or not properly organized. Credit: Stowers
Institute for Medical Research
The authors
used a precise gene editing technique to make mutations in one key synaptonemal complex protein in mice, which allowed the researchers, for the first
time, to test the function of key regions of the protein in live animals. Just
a single mutation, predicted from the modeling experiments, was verified as the
culprit of infertility in mice.
"We're talking about pinpoint surgery here," said Hawley. "We focused on a tiny little region of one protein in this gigantic structure that we were pretty sure could be a significant cause of infertility."
Representative testes from nine-week-old control
mice (left) and mice with a point mutation in one synaptonemal complex protein
(right). Credit: Stowers Institute for Medical Research
Mice have long
been used as models for human diseases. From the modeling experiments using
human protein sequences, along with the high conservation of this protein
structure across species, the precise molecule that caused infertility in mice
likely functions the same way in humans.
"What is really exciting to me is that our
research can help us understand this really basic process that is necessary for
life," said Billmyre.
For Hawley, this research is a true representation of
the versatility of the Institute. Hawley's lab typically conducts research in fruit flies, yet the protein discovered in this study was not present in fruit
flies and demanded a different research organism to continue. Because of the
resources and Technology Centers at the Institute, it was possible to quickly
pivot and test the new infertility hypothesis in mice.
Additional authors include Emily A. Kesler, Dai Tsuchiya, Ph.D., Timothy J. Corbin, Kyle Weaver, Andrea Moran, Zulin Yu, Ph.D., Lane Adams, Kym Delventhal, Michael Durnin, Ph.D., and Owen Richard Davies, Ph.D.
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