# JUNO-coated beads as a functional assay to capture and characterize fertilization-competent human sperm

**Authors:** Paula Cots-Rodríguez, Xinyin Wang, Mirian Sanchez-Tudela, Karen K Siu, Patrick Yip, Emilio Gómez, Jeffrey E Lee, Julieta G Hamze, Maria Jiménez-Movilla

PMC · DOI: 10.1093/hropen/hoag010 · 2026-02-13

## TL;DR

A new assay using JUNO-coated beads captures sperm that can fertilize eggs, showing vitrification preserves sperm quality better than slow freezing.

## Contribution

Develops a functional JUNO-bead assay to capture and characterize fertilization-competent sperm with DNA integrity.

## Key findings

- JUNO-beads selectively bind acrosome-reacted sperm with intact DNA.
- Vitrified sperm show higher JUNO-bead binding and DNA integrity than slow-frozen sperm.
- The assay classifies sperm into low- and high-binding capacity groups validated by the hamster test.

## Abstract

Can human fertilization-competent spermatozoa be captured through their ability to bind the oocyte receptor JUNO?

JUNO-coated beads, which mimic the oocyte geometry, selectively bound acrosome-reacted spermatozoa with intact DNA, revealing that vitrification preserves functional sperm binding while slow cryopreservation increases non-specific interactions.

It is well established that sperm must undergo the acrosome reaction and expose the receptor IZUMO1 on the sperm head to bind specifically to JUNO on the oolemma. Studying the spermatozoa that reaches and engages with the oolemma, however, remains highly challenging due to the technical difficulty of recovering these sperm at the site of the molecular interaction. Bead-based models that contain oocyte receptors have therefore emerged as a powerful approach to functionally assess sperm–oocyte interactions, with promising applications for evaluating sperm quality.

This was a cross-sectional experimental study including 21 semen donors of reproductive age recruited between January 2023 and June 2025. The JUNO-bead-based model was first validated using fresh human semen samples to establish the optimal sperm concentration and co-incubation time. Subsequently, two semen preservation methods, slow freezing and rapid freezing, were compared with respect to sperm-binding capacity to JUNO-coated beads, acrosomal status and DNA integrity. Finally, donors were classified according to sperm-binding capacity and validated by the hamster test.

Recombinant JUNO protein was secreted and purified from Drosophila melanogaster S2 cultures. Digital SPR was used to confirm JUNO–IZUMO1 binding kinetics and imaging flow cytometry was performed to assess the biological activity of recombinant JUNO. Protein–bead conjugation and activity were verified by immunochemistry and western blot. Human semen samples were obtained from donors aged 19–42 years, including both fresh ejaculates and cryopreserved samples. Sperm-binding capacity, acrosome reaction, and DNA fragmentation were analysed using widefield fluorescence microscopy and flow cytometry, and the specificity of sperm–bead interaction was evaluated with anti-IZUMO1 monoclonal antibodies.

Recombinant JUNO bind human IZUMO1 ectodomain with a KD = 38 nM and specifically recognizes acrosome-reacted sperm and not acrosome-intact sperm. Human JUNO recombinant protein was successfully conjugated to oocyte-sized beads to generate a sperm-binding assay mimicking the geometry of the oocyte and experimental conditions of IVF. Human sperm bound specifically to JUNO-beads in a dose- and time-dependent manner, with highly significant differences compared to control beads (P ≤ 0.0001). Vitrified-based cryopreserved sperm displayed higher binding to JUNO-beads than conventionally cryopreserved samples (P ≤ 0.0001). Binding was significantly inhibited by an anti-IZUMO1 (2.5 µg/mL) antibody that blocks specifically the IZUMO1–JUNO interaction in vitrified samples (P ≤ 0.01), but not in conventionally cryopreserved sperm. Sperm bound to JUNO-beads were predominantly acrosome-reacted in both preservation methods; however, vitrified samples retained higher DNA integrity compared with conventionally cryopreserved samples. The assay proved robust across multiple donors and ejaculates, allowing classification into low- and high-binding capacity (LBC and HBC) groups, and data were validated using the hamster test. Pearson correlation analyses revealed only weak associations between total sperm motility and bead-binding parameters (|r| < 0.27), indicating negligible or absent linear relationships.

N/A

This study was performed in vitro, and the number of semen donors was limited. As all participants were healthy donors, the population represents a selected fertile subpopulation. Further studies using samples from diverse patient populations are required to validate the assay’s potential as a predictor of male fertility. While sperm–egg binding is an essential prerequisite for fertilization, the JUNO-bead–based assay focuses on this initial interaction and does not capture downstream fertilization events.

This study positions the JUNO-bead binding assay as a powerful functional model to investigate the biology of fertilization-competent sperm. By selectively capturing spermatozoa that have undergone the acrosome reaction and maintain DNA integrity, the model provides a unique experimental platform to study the molecular determinants of fertilization, to refine the selection of sperm for assisted reproduction, and to identify potential targets for novel contraceptive strategies. Beyond preservation protocols, these findings provide new functional evidence that sperm preservation method directly influences the molecular integrity required for fertilization, supporting vitrification as a superior approach over slow freezing. Moreover, the JUNO-bead assay emerges as a sensitive tool to reveal differences in sperm quality that are not captured by standard semen analysis, with potential applications in the optimization of assisted reproduction and fundamental research on the mechanisms that define the fertilizing spermatozoon.

This work is part of the projects PID 2020-114109GB-I00 and PID2024-159920OB-I00 funded by MICIU/AEI/10.13039/501100011033 and by ERDF, EU and 23046/GERM/25 funded by FSRM/10.13039/100007801 to M.J.-M. This work was also supported, in part, by the Gates Foundation [INV-055841]. The conclusions and opinions expressed in this work are those of the author(s) alone and shall not be attributed to the Foundation. Under the grant conditions of the Foundation, a Creative Commons Attribution 4.0 License has already been assigned to the Author Accepted Manuscript version that might arise from this submission. Protein production and characterization and biophysics infrastructure is supported by funding from a Canadian Institutes of Health Research Project Grant (PJT-203841) and Canada Foundation for Innovation John R Evans Leaders Fund (CFI-JELF) to J.E.L. The authors declare no conflicts of interest.

## Linked entities

- **Genes:** IZUMO1R (IZUMO1 receptor, JUNO) [NCBI Gene 390243], IZUMO1 (izumo sperm-oocyte fusion 1) [NCBI Gene 284359]
- **Proteins:** IZUMO1R (IZUMO1 receptor, JUNO), IZUMO1 (izumo sperm-oocyte fusion 1)
- **Species:** Drosophila melanogaster (taxon 7227), Mus musculus (taxon 10090)

## Full-text entities

- **Genes:** TMEM81 (transmembrane protein 81) [NCBI Gene 388730] {aka HC3107, KVLA2788, UNQ2788}, HEPHL1 (hephaestin like 1) [NCBI Gene 341208] {aka HJDD, ZP}, DCST1 (DC-STAMP domain containing 1) [NCBI Gene 149095] {aka SNKY, SPE49}, IZUMO1R (IZUMO1 receptor, JUNO) [NCBI Gene 390243] {aka FOLR4, FR-delta, Folbp3, JUNO}, DNTT (DNA nucleotidylexotransferase) [NCBI Gene 1791] {aka TDT}, SPACA6 (sperm acrosome associated 6) [NCBI Gene 147650] {aka LET7EH, LINC00085, NCRNA00085, SPACA6P}, DCST2 (DC-STAMP domain containing 2) [NCBI Gene 127579] {aka SPE42}, CD9 (CD9 molecule) [NCBI Gene 928] {aka BTCC-1, DRAP-27, MIC3, MRP-1, TSPAN-29, TSPAN29}, IZUMO1 (izumo sperm-oocyte fusion 1) [NCBI Gene 284359] {aka IZUMO, OBF}, TMEM95 (transmembrane protein 95) [NCBI Gene 339168] {aka UNQ9390}, Izumo1r (IZUMO1 receptor, JUNO) [NCBI Gene 64931] {aka 0910001L11Rik, Folbp3, Folr4, Juno}, F2 (coagulation factor II, thrombin) [NCBI Gene 2147] {aka PT, RPRGL2, THPH1}, CD46 (CD46 molecule) [NCBI Gene 4179] {aka AHUS2, MCP, MIC10, TLX, TRA2.10}, Izumo1 (izumo sperm-egg fusion 1) [NCBI Gene 73456] {aka 1700058F15Rik, Izumo}, ALB (albumin) [NCBI Gene 213] {aka FDAHT, HSA, PRO0883, PRO0903, PRO1341}
- **Diseases:** male infertility (MESH:D007248), LARGE (MESH:D018287), IVF (MESH:C537182), LARGE-SCALE (MESH:C538175)
- **Chemicals:** progesterone (MESH:D011374), Alexa Fluor 555 (MESH:C000608607), SDS (MESH:D012967), CaCl2 (MESH:D002122), NaOH (MESH:D012972), water (MESH:D014867), imidazole (MESH:C029899), tetramethylrhodamine (MESH:C005358), nitrogen (MESH:D009584), His (MESH:D006639), FITC (MESH:D016650), Triton X-100 (MESH:D017830), NaCl (MESH:D012965), PBS (MESH:D007854), Tween-20 (MESH:D011136), calcium (MESH:D002118), magnesium (MESH:D008274), DAPI (MESH:C007293), CO2 (MESH:D002245), Sepharose (MESH:D012685), Effectene (MESH:C498175), paraformaldehyde (MESH:C003043), Hoechst 33342 (MESH:C017807), Alexa Fluor 488 (MESH:C000711379), 4E04 (-), NaHCO3 (MESH:D017693), sodium phosphate (MESH:C018279), Alexa Fluor 647 (MESH:C569686), CuSO4 (MESH:D019327), puromycin (MESH:D011691)
- **Species:** Mus musculus (house mouse, species) [taxon 10090], Cricetus cricetus (black-bellied hamster, species) [taxon 10034], Drosophila melanogaster (fruit fly, species) [taxon 7227], Bos taurus (bovine, species) [taxon 9913], Homo sapiens (human, species) [taxon 9606]
- **Cell lines:** S2 — Drosophila melanogaster (Fruit fly), Spontaneously immortalized cell line (CVCL_Z232), HBC — Trichoplusia ni (Cabbage looper), Spontaneously immortalized cell line (CVCL_C190)

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12961186/full.md

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Source: https://tomesphere.com/paper/PMC12961186