Sperm: The secrets of success
In mammals, sperm cannot fertilize eggs unless they spend time in the female reproductive tract, where they undergo a series of processes that are collectively called ‘capacitation’. During these processes, sperm change their swimming pattern, their cytosol becomes more basic, and the lipids that make up their plasma membrane change substantially (Florman and Fissore, 2015). The final stage of capacitation is the acrosome reaction, which involves the release of enzymes from a compartment in the head of the sperm called the acrosome. It is thought that these enzymes break down the ‘coating’ surrounding the egg so that fertilization can take place (Florman and Storey, 1982). It is also known that sperm from mice that do not produce a sperm-specific ion channel called CatSper do not undergo capacitation, so they are infertile (Lishko and Mannowetz, 2018; Ren et al., 2001).
CatSper ion channels allow Ca2+ to cross the cell membrane. The channels line up in a stripe pattern that begins in the midpiece of the sperm and extends down sperm tail (Figure 1; Chung et al., 2017). The opening and closing of CatSper channels is controlled by diverse cellular signals including membrane voltage, pH and the level of free Ca2+ inside the cell (Lishko and Mannowetz, 2018). The channel is comprised of at least ten subunits, including four proteins that form the central pore through which Ca2+ travels. Nearly all of these subunits are required for the channel to localize in the membrane and for male fertility (Hwang et al., 2019). For the most part, capacitation and CatSper channels have been studied by performing in vitro experiments in which mouse sperm are exposed to conditions that simulate the female reproductive tract. Now, in eLife, Jean-Ju Chung and colleagues at Yale University, the Czech Academy of Sciences and Boston Children’s Hospital – including Lukas Ded as first author – report on the differences between in vitro and in vivo capacitation (Ded et al., 2020).
To better understand how CatSper is regulated, Ded et al. checked whether proteins forming the channel were modified with either phosphoryl groups (phosphorylation) or carbohydrates (glycosylation). They found that the molecular weight of one of the CatSper pore-forming subunits, called CatSper1, increased as sperm matured in the epididymis (the highly convoluted tubes on top of the testes that lead to the duct through which sperm is expelled). When the protein was treated with deglycosylating enzymes, which remove carbohydrate modifications, the increase in molecular weight was reversed. This revealed that CatSper undergoes glycosylation (Figure 1A), which is thought to promote the migration and survival of sperm in the female reproductive tract (Ma et al., 2016).
Next, Ded et al. imaged mouse sperm that had been treated in vitro to induce capacitation and found that these sperm exhibited degradation of CatSper channels over time. This was unexpected because CatSper channels are required at the end of capacitation, close to fertilization. In sperm where CatSper was degraded, enzymes inside the sperm called serine/threonine proteases were cleaving the intracellular N-terminal domain of the CatSper1 subunit. This cleavage required high levels of Ca2+ inside the sperm cell which, in vivo, occur during capacitation.
Interestingly, this CatSper degradation was associated with the phosphorylation of tyrosine residues in proteins in the sperm tail: over 30 years ago it was proposed that tyrosine phosphorylation was an indicator of successful in vitro capacitation (reviewed in Florman and Fissore, 2015). By imaging sperm in vivo within the female reproductive tract, Ded et al. showed that the tails of sperm that had successfully traveled to the ampulla, the site of fertilization, were not tyrosine phosphorylated (Figure 1B). By contrast, sperm stuck in the uterus and unable to make the journey to the egg exhibited high levels of tyrosine phosphorylation. This supports recent evidence that tyrosine phosphorylation may not be required for capacitation (Alvau et al., 2016; Luño et al., 2013). Together these findings suggest that the tyrosine phosphorylation cascade that leads to CatSper degradation is a signature of sperm unable to fertilize.
Additional experiments imaging sperm within the female reproductive tract revealed other surprising findings. For example, sperm at the ampulla had already lost their acrosome, suggesting that sperm undergo the acrosome reaction prior to meeting the egg. By adapting the method they used to detect sperm (which involved making changes to a neural network that processed output from their imaging experiments) Ded et al. were able to assess the integrity of sperm as they navigated through the female reproductive tract. Sperm that successfully completed the journey to the egg in the ampulla had intact lines of CatSper extending over the length of their tail, whereas sperm undergoing CatSper degradation did not reach the site of fertilization.
Together these data show that CatSper degradation, the timing of the acrosome reaction, and tyrosine phosphorylation of proteins in the sperm tail differ substantially between in vitro and in vivo capacitation. This demonstrates that the conditions in the female reproductive tract are not well mimicked by current methods used to induce capacitation in vitro. Finding conditions that better mimic the natural environment of the sperm as it travels to the egg can improve in vitro capacitation. This can be used in the clinic to achieve greater success for people trying to get pregnant using assisted reproductive technologies.
References
-
BookFertilization in MammalsIn: Plant T. M, Zeleznik A. J, editors. Knobil and Neill's Physiology of Reproduction. Academic Press. pp. 149–196.https://doi.org/10.1007/3-540-29623-9_3270
-
CatSper: a unique calcium channel of the sperm flagellumCurrent Opinion in Physiology 2:109–113.https://doi.org/10.1016/j.cophys.2018.02.004
Article and author information
Author details
Publication history
- Version of Record published: December 2, 2020 (version 1)
Copyright
© 2020, Komondor and Carlson
This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.
Metrics
-
- 1,984
- views
-
- 148
- downloads
-
- 1
- citations
Views, downloads and citations are aggregated across all versions of this paper published by eLife.
Download links
Downloads (link to download the article as PDF)
Open citations (links to open the citations from this article in various online reference manager services)
Cite this article (links to download the citations from this article in formats compatible with various reference manager tools)
Further reading
-
- Cell Biology
Quiescence (G0) maintenance and exit are crucial for tissue homeostasis and regeneration in mammals. Here, we show that methyl-CpG binding protein 2 (Mecp2) expression is cell cycle-dependent and negatively regulates quiescence exit in cultured cells and in an injury-induced liver regeneration mouse model. Specifically, acute reduction of Mecp2 is required for efficient quiescence exit as deletion of Mecp2 accelerates, while overexpression of Mecp2 delays quiescence exit, and forced expression of Mecp2 after Mecp2 conditional knockout rescues cell cycle reentry. The E3 ligase Nedd4 mediates the ubiquitination and degradation of Mecp2, and thus facilitates quiescence exit. A genome-wide study uncovered the dual role of Mecp2 in preventing quiescence exit by transcriptionally activating metabolic genes while repressing proliferation-associated genes. Particularly disruption of two nuclear receptors, Rara or Nr1h3, accelerates quiescence exit, mimicking the Mecp2 depletion phenotype. Our studies unravel a previously unrecognized role for Mecp2 as an essential regulator of quiescence exit and tissue regeneration.
-
- Cancer Biology
- Cell Biology
Mutations in the gene for β-catenin cause liver cancer cells to release fewer exosomes, which reduces the number of immune cells infiltrating the tumor.