Abstract
Mouse oocytes undergo drastic changes in organellar composition and their activities during maturation from the germinal vesicle (GV) to meiosis II (MII) stage. After fertilization, the embryo degrades parts of the maternal components via lysosomal degradation systems, including autophagy and endocytosis, as zygotic gene expression begins during embryogenesis. Here, we demonstrate that endosomal-lysosomal organelles form large spherical assembly structures, termed ELYSAs, in mouse oocytes. ELYSAs are observed in GV oocytes, attaining sizes up to 7–8 μm in diameter in MII oocytes. ELYSAs comprise tubular-vesicular structures containing endosomes, lysosomes, autophagosome-like membranes in the outer layer, with cytosolic components contained within. The V1-subunit of vacuolar ATPase tends to localize to the periphery of ELYSAs in MII oocytes. After fertilization, the V1-subunit is recruited to immature endosomes and lysosomes as ELYSAs are gradually disassembled at the 2-cell stage, which leads to further acidification of endosomal-lysosomal organelles. These findings suggest that the ELYSAs maintain endosomal-lysosomal activity in a static state in oocytes for timely activation during early development.
Summary blurb
This study describes endosomal-lysosomal organellar assembly structures in mammalian oocytes, elucidating statistical alterations in their size, distribution, and correlation with lysosomal maturation.
Introduction
Fertilization triggers the dynamic remodeling of cellular components via zygotic gene expression following the degradation of the cellular components of each maternal and paternal gamete. After fertilization, maternal cytosolic proteins and RNAs are selectively degraded by the ubiquitin-proteasome system (UPS)1 and specific RNA degradation systems2, 3, respectively. Treatment with a proteasome inhibitor or knockdown of the zygote-specific proteasome assembly chaperone gene inhibits cytokinesis in zygotes, suggesting an essential role for the UPS in early development4, 5. Membrane components derived from each gamete are degraded by the lysosomal degradation system via autophagy and endocytosis6, 7. In mice, autophagic activity is relatively low in meiosis II (MII) oocytes, whereas it is rapidly upregulated approximately 4 h after fertilization, and LC3-positive structures appear throughout the cytoplasm. Autophagic activity decreases slightly before and after the 2-cell stage but remains high from the 4- to 8-cell stage8. Loss of Atg5 causes embryonic lethality at the 4- to 8-cell stages, suggesting that autophagy is essential for early mouse development. In contrast, some maternal plasma membrane (PM) proteins are internalized from the PM at the late 2-cell stage and are selectively degraded by lysosomes9. Endocytosis inhibitors prevent cell division in 2-cell embryos, suggesting that endocytosis plays a pivotal role in early development9, 10. Although lysosomal degradation systems are drastically upregulated after fertilization, their regulation remains unknown.
In Caenorhabditis elegans, lysosomal activity in oocytes is upregulated by sperm-derived factors as the oocytes grow and mature. In this process, translational arrest of mRNA coding the V1-subunits of vacuolar ATPase in oocytes is released by the stimulation of sperm-derived factors. Consequently, the V1-subunits are recruited to the V0-subunits in the lysosomal membrane, enhancing lysosomal acidification. This process is known as lysosomal switching11. In mouse embryos, LysoTracker staining analysis suggests that lysosomal acidification is prominent at the 2-cell stage but not in MII oocytes and zygotes12, raising the possibility that lysosomal switching takes place during mouse embryogenesis.
In this study, we aimed to investigate the dynamics of the endolysosomal system during mouse oocyte maturation and embryogenesis. We found that endosomes and lysosomes assembled to form spherical structures in germinal vesicle (GV)-stage oocytes, which became larger as they matured into MII oocytes. Ultrastructural analysis showed that these structures were large spherical membrane assemblies, including endosomes, lysosomes, and tubulo-vesicular structures located in the periphery of the PM. We refer to this structure as the Endosomal-LYSosomal organellar Assembly (ELYSA). The ELYSA contains several cytosolic constituents. While ELYSAs are disassembled in late-stage zygotes, immature endosomes and lysosomes gradually appear in the cytoplasm of early 2-cell stage embryos. Live imaging analysis showed that the V1-subunit of V-ATPase is targeted to the endolysosomal membrane, resulting in further acidification of lysosomal compartments during embryogenesis. These findings suggest that the ELYSA maintains low endosomal and lysosomal activities and acts as a waiting place for endolysosomal organelles to undergo fertilization-triggered activation toward embryogenesis.
Results
Endosomes and lysosomes coordinately form giant structures in MII oocytes
To examine the localization of endosomes and lysosomes in mouse MII oocytes, early or late endosomes were stained with anti-RAB5 or RAB7 antibody, respectively, and their localization was compared with that of lysosomes stained with anti-LAMP1 antibody. Giant structures harboring lysosomes with early and late endosomes were detected (Fig. 1A, Supplementary Fig. 1, Video 1). Each giant structure in the MII oocytes was spherical, ellipsoidal, or concatenated with small spheres. These structures were located in the peripheral region just beneath the PM, excluding the metaphase plate region in proximity to the metaphase chromosomes. These structures were observed from the GV stage to the pronuclear-zygote (PN-zygote) stage but were mostly disassembled at the 2-cell stage. Dispersion and separation of RAB5 and LAMP1 signals after the first division indicated that these giant structures were transiently formed (Fig. 1 B).
Analyses of the number, size, and distribution of LAMP1-positive organelles were carried out by reconstituting three-dimensional objects using LAMP1-positive signals in immunocytochemically stained oocytes and embryos (Supplementary Fig. 2). Although the LAMP1 signals on the PM increased in the 2-cell stages, reconstitution of the objects was carried out only for the cytoplasmic fraction. The total number of the LAMP1-positive objects was highest at the GV stage, and it decreased toward the late 2-cell stage, with a significant difference compared to that in MII oocytes (Fig. 2A). Sorting of the objects based on their sizes (indicated with the diameters when converting the volume of each object to the corresponding sphere) revealed that the LAMP1-positive structures with diameters of 0.2–0.8 μm, which were prominent in GV oocytes, significantly decreased toward the MII stage, while the number of giant LAMP1-positive structures with diameters of 3–7 μm decreased during the post-fertilization changes at the early and late 2-cell stage relative to that in MII (Fig. 2B). The transiently increased LAMP1-positive structures with 9–10 μm diameter at the early 2-cell stage were observed as concatenated spheres that gathered upon cellular division; concurrently, prominent signals on the PM appeared, especially at the cleavage furrow (Fig. 2C, D). The total volume of LAMP1-positive objects was highest in MII, and it decreased over the early and late 2-cell stages (Fig. 2E). LAMP1-positive structures with diameters of >3 μm were also observed in GV oocytes, but those larger than 5 μm in diameter were rarely detected, and the total volume of LAMP1-positive structures larger than 3 μm in diameter in MII oocytes accounted for 51.3% of the total volume. (Fig. 2F). The large population of the LAMP1-positive structures with diameters larger than 3 μm in MII transitioned to structures with diameters of 1–3 μm during the 2-cell stages, as indicated by the percentage of the volume of each object size relative to the total volume (Fig. 2G).
Furthermore, the analysis of object distribution for GV and MII oocytes indicated that MII oocytes had a greater number of LAMP1-positive structures with >4 μm diameter in the cellular periphery, whereas GV oocytes had a greater number of these structures in the cellular medial regions (Fig. 2H, I). These results suggest that the giant LAMP1-positive structures are enlarged and migrate to the cellular periphery during oocyte maturation.
Endosomes, lysosomes, and tubulo-vesicular structures form an ELYSA
To clarify the internal structure of this giant structure containing lysosomes and endosomes in the MII oocytes, we observed these in MII oocytes with in-resin correlative light and electron microscopy (CLEM) using immunological reaction (immune in-resin CLEM) with anti-RAB7 and -LAMP1 antibodies13, 14. RAB7- and LAMP1-signals were well detected even in the ultrathin section (100 nm thickness) of the Epon-embedded MII oocyte, fixed with the mixture of 4% paraformaldehyde and 0.025% glutaraldehyde (GA), which showed similar distribution as that shown in Fig. 1 and Supplementary Fig. 3. Toluidine blue staining in adjacent ultrathin sections revealed that the RAB7/LAMP1-double positive structures in the fluorescence observation were also positive for toluidine blue, with interspaces were often found in the center of spheres (Fig. 3A). Confocal fluorescent images of the ultrathin sections clarified that RAB7-positive signals were frequently observed on the periphery of these LAMP1-positive signals. Electron microscopic analysis of the RAB7/LAMP1-double positive region in the ultrathin sections revealed that the RAB7/LAMP1-double positive structures are assemblies of tubulo-vesicular structures, with either vacuolated or filled interiors (Fig. 3B). The toluidine blue stain-positive structures were confirmed to match in size and peripheral distribution with those identified via RAB7/LAMP1 immunostaining, except for the metaphase plate, even under 2.5% GA conditions for precise ultrastructural observation (Fig. 3C, Supplementary Fig. 4, Video 2). Therefore, we examined the ultrastructural morphology of toluidine blue-positive giant structures in MII oocytes fixed with 2.5% GA. The results showed that tubular membrane vesicles with a short diameter of approximately 60.5 ± 15.9 nm assembled in the structure, with gaps in the cytoplasm of approximately 24.0 ± 6.7 nm. Some of the vesicles also harbored lysosome-like electron-dense contents, while others displayed multilamellar or multivesicular body-like structures, and mitochondria appeared to be absent (Fig. 3D). Based on these observations, we termed this membrane assembly the Endosomal-LYSosomal organellar Assembly (ELYSA).
An autophagosome marker, LC3, also accumulated in ELYSA
Decreased autophagic activity in MII oocytes is suggested by the fact that puncta formation of transgenically expressed GFP-LC3, an autophagosome marker, disappeared at the MII stage8. Since GFP fluorescence may be quenched under acidic conditions, we examined the localization of LC3 in GV and MII oocytes by immunostaining with an anti-LC3 antibody. We found that LC3 hardly formed puncta in the cytoplasm, but part of the LC3 signal overlapped with the ELYSA in both GV and MII oocytes (Fig. 4A, B), suggesting that LC3-positive membrane structures were also present in the ELYSA.
ELYSA enlargement and migration proceed actin dependently
The migration from the perinuclear (medial region) to the peripheral region during oocyte maturation (Fig. 2H, I) is similar to the redistribution of the endoplasmic reticulum (ER) and the formation of cortical ER clusters. Fitzharris et al. showed that the inhibition of actin cytoskeleton polymerization disturbs ER migration and cortical ER cluster formation15. Therefore, we added latrunculin A (LatA) or cytochalasin B (CCB) as inhibitors of actin polymerization, and nocodazole (Noco) as an inhibitor of microtubule formation, to examine whether these affect ELYSA formation after in vitro maturation (IVM). While all the drugs inhibited polar body extrusion and metaphase plate formation as reported previously15, co-immunostaining of LC3- or RAB5-antibody with LAMP1-antibody revealed their persistent colocalization in ELYSAs (Fig. 5A, Supplementary Fig. 5).
Analysis of LAMP1-positive organelles via three-dimensional object analysis indicated that the actin polymerization inhibitors increased the organelle number, particularly those with diameters in the range of 0.8–2 μm, but the tubulin inhibitor Noco did not have the same effect (Fig. 5B, C). The total volume of the objects was largely unchanged by the inhibitors. However, treatment with an actin polymerization inhibitor increased the percentage of total volume occupied by the structures with diameters of 1–2 μm, while conversely decreasing that of the structures with diameters of 4–7 μm that correspond to the enlarged ELYSAs (Fig. 5D, E). Further examination of the distribution of the LAMP1-positive structures in IVM oocytes indicated that only actin polymerization inhibitors reduced the number of objects larger than 4 μm in diameter at the cell periphery but not that in the cellular medial region (Fig. 5F, G).
V1 component of V-ATPase partially localizes to the periphery of ELISAs in oocytes
We studied the relationship between ELYSA formation and endosomal/lysosomal acidification in oocytes. V1A is a component of the V1 subunit of V-ATPase, which is associated with the outer lysosomal membrane and drives endosomal/lysosomal acidification. We used LAMP1-EGFP mRNA to observe ELYSA behaviors during oocyte maturation, with ATP6V1A-mCherry mRNA (V1A-mCherry: a core component of V-ATPase fused with the mCherry marker) to further examine whether the V1 subunit is targeted to ELYSAs. The mRNAs were injected into GV oocytes, and the oocytes were applied to IVM.
Live-cell imaging of LAMP1-EGFP fluorescence captured the dynamics of LAMP1-positive organelles during oocyte maturation, notably demonstrating its stable expression after germinal vesicle breakdown (GVBD, 2–3 h after initiation of IVM), and revealed that the enlargement of ELYSAs larger than 5 μm in diameter occurred through the sequential assembly of smaller ELYSAs that constantly migrated and contacted each other (Fig. 6A, Video 3).
We then analyzed the localization of V1A-mCherry in the oocytes after IVM. Although V1A-mCherry signals were detected adjacent to LAMP1-positive organelles in deconvolved confocal images, they were largely distributed on the ELYSA surface and rarely observed within ELYSAs (Fig. 6B, Video 4).
Acidification of lysosomes is facilitated as ELYSA disassembly proceeds in embryos
We examined the relationship between ELYSA disappearance and the emergence of acidic membrane compartments during early development. LysoSensor probes exhibit increased fluorescence in a pH-dependent manner upon acidification and enable the semi-quantitative analysis of cellular acidic compartments, whereas LysoTracker probes exhibit non-pH-dependent fluorescence. We first co-stained oocytes and embryos at various stages with LysoTracker Red and LysoSensor Green (in the same medium drop). LysoTracker showed a pronounced puncta-like signal after the 2-cell stage, as previously reported12. In contrast, the ELYSAs in GV and MII oocytes were clearly identified by LysoSensor, whereas LysoTracker only produced a very dim signal. Thus, the ratio of LysoTracker/LysoSensor fluorescent intensities in the cytoplasm of each stage embryo indicated that ELYSAs were present at a low ratio, while embryos at the 4-cell stage and beyond displayed small punctate signals with a higher ratio (Fig. 7). A comparison between LysoTracker and V1A-mCherry signals showed that these fluorescent signals colocalized well on small bright vesicles but not on the ELYSA, and both LysoTracker and V1A-mCherry puncta were reduced in embryos cultured in the presence of bafilomycin A1, which inhibits the H⁺ translocation of V-ATPase (Supplementary Fig. 6). This suggests that LysoTracker detects membrane compartment acidification, but it may not sufficiently capture this process within the ELYSA. In contrast, the results using LysoSensor suggest that lysosomes within the ELYSA were not completely neutralized and remained acidic at a lower level, even though V1A was difficult to localize.
To examine the spatiotemporal relationship between V1A localization and lysosomal acidification during embryogenesis, we injected V1A-mCherry mRNA to PN zygotes and cultured them in the presence of LysoSensor. It should be noted that stable detection of LysoSensor and V1A-mCherry fluorescence required 4–8 h. In this process, targeting of V1A to lysosomes was rarely observed until ELYSA disappearance or disassembly throughout the PN-zygote stage, but the targeting was rapidly enhanced in the early 2-cell embryo stage. LysoSensor-positive punctate structures, where V1A-mCherry accumulated, increased in number during the transition from early to late 2-cell stage, indicating that lysosomal acidification is promoted after ELYSA disappearance (Fig. 8, Video 5).
Low-level cathepsin-dependent proteolytic activity was maintained in ELYSA
Cathepsins are mainly responsible for the proteolytic activity in lysosomes. We visualized the proteolytic activity of cathepsin B, the expression of which has been confirmed in mouse embryos12. Mouse oocytes and embryos at various stages were simultaneously collected and stained with Magic Red cathepsin B staining solution to examine their relationship with the ELYSA. Magic Red staining showed that proteolytic activity was detected not only in the small, isolated membrane structures (mature lysosomes) but also in the ELYSA in the GV and MII oocytes, whereas small punctate structures were predominantly stained in other stages (Supplementary Fig. 7, Fig. 9A). The intensity plots of LysoSensor and Magic Red fluorescence revealed that the proteolytic activity indicated by the Magic Red signal in the ELYSA was not as strong as that in isolated punctate structures (lysosomes) in the GV and MII oocytes (Fig. 9B).
Discussion
In this study, we identified a large spherical structure, the ELYSA, consisting of endosomes, lysosomes, LC3-positive vesicles, and various vesicular-tubular structures in mouse oocytes. Small ELYSAs are formed in GV oocytes and become larger (3 to 7 μm in diameter) through assembly, migrating to the cellular periphery, in an actin-dependent manner during oocyte maturation and occupy more than half the volume of the LAMP1-positive fraction in MII oocytes. After fertilization, as ELYSAs gradually disassemble in zygotes, punctate structures positive for either RAB5- or LAMP1-signal alone appear in the cytoplasm of embryos at the early 2-cell stage. The V1-subunit of V-ATPase is targeted to these structures, leading to further acidification of the endosomal/lysosomal compartments. These results suggest that the ELYSA functions as a reservoir that accumulates endosomal and lysosomal compartments in the periphery of the cell cortex and maintains their activities in a static state until embryogenesis following fertilization.
We have studied the dynamics and activity of endosomes and lysosomes in mouse oocytes and embryo and have found that some oocyte PM proteins are internalized from the PM at the late 2-cell stage and are selectively degraded in lysosomes9. In this process, we noted that lysosomes were not well stained by LysoTracker until the early 2-cell stage, but their signals became stronger from the late 2-cell stage, suggesting the existence of a mechanism underlying developmentally regulated endosomal/lysosomal activation during embryogenesis9, 12. Notably, ELYSAs were stained with toluidine blue and LysoSensor, suggesting that these structures were acidified to some extent (Fig. 3, 7). In addition, Magic Red, which reflects cathepsin B activity, weakly stained ELYSAs (Fig. 9). These observations indicate that lysosomes in ELYSAs have some activity, albeit at low levels. Mouse oocytes accumulate several maternal constituents, including proteins, lipids, and mRNA, and grow to approximately 75 μm in diameter. In addition, oocytes must remain at the GV and MII stages for an extended period to maintain their quality until fertilization. In such situations, lysosomal degradation activity may be suppressed to a relatively low level by the ELYSA, whereas nutrient uptake, storage, and protein synthesis are predominantly upregulated in growing oocytes. Furthermore, we found that the V1-subunits were largely detected on the periphery of ELYSAs but not in their interior in oocytes (Fig. 6). Thus, it is possible that ELYSA formation prevents V1-subunits from targeting the lysosomal membrane inside the ELYSA.
Ultrastructural analysis revealed that the ELYSA consists of outer and inner membrane assembly layers that contain several endosomes and lysosomes, respectively (Fig. 1, 3). Upon disassembly of the ELYSA, endosomes in the outer layer and lysosomes in the inner layer are expected to be released from the ELISA earlier and later, respectively. This may explain the time lag between fertilization and lysosomal acidification beginning at the early-2-cell stage. Since the ELYSA appears to contain cytosolic constituents, it may accommodate some cytosolic constituents as a capsule to provide nutrition or signaling factors for development.
ELYSAs were gradually distributed from the perinuclear region to the periphery of the oocyte cell cortex, except in the MII cell plate, from the GV to the MII stage (Fig. 1, 2). This movement is reminiscent of that of the ER and cortical ER clusters, whose distribution is regulated by the actomyosin system15. In fact, the treatment of actin cytoskeleton polymerization inhibitors, but not a tubulin polymerization inhibitor, prevented the redistribution of ELYSAs from the cell cortex to the cytoplasm in oocytes (Fig. 5). The former treatment increased the number of small LAMP1-positive organelles but reduced the size of ELYSAs in oocytes (Fig. 5). These results suggest that actin cytoskeleton is involved in the assembly of smaller (<2 μm in diameter) LAMP1-positive organelles for the enlargement of ELYSAs and also in the redistribution of ELYSAs to the cell periphery.
Our detailed imaging analysis showed that lysosomal acidification is promoted by the accumulation of the V1-subunits on lysosomes during ELYSA disassembly in late zygotes and is further facilitated from the 2- to 4-cell stage and is enhanced after the morula stage (Fig. 8, Supplementary Fig. 6). These findings suggest that lysosomal acidification and maturation are linked to the ELYSA disassembly. Notably, minor and major zygotic gene activation in mouse embryos occur at the 1- and 2-cell stages, respectively, implying that lysosomal degradation of maternal components is coupled with zygotic gene expression to promote embryogenesis16. Fertilization appears to trigger ELYSA disassembly, but the downstream signaling pathways remain to be identified and warrant further research.
Very recently, after sharing this ELYSA paper as a preprint in 202317, Zaffagnini et al. reported the endolysosomal vesicular assemblies (ELVAs), which resemble with ELYSAs, in mouse oocytes18. Consistencies between the ELVA and ELYSA in their contents and actin-dependent dynamics during oocyte maturation/embryogenesis strongly suggests that ELYSAs and ELVAs are identical structures18, assuring the solidity of these findings in this paper. Zaffagnini et al. also observed the accumulation of proteasomes and ubiquitinated proteins in ELVAs and demonstrated that the depletion of a RUN and FYVE domain-containing protein 1 (RUFY1) protein from oocytes by the Trim-Away method causes disappearance of ELVAs, suggesting that RUFY1 is involved in the ELVA assembly. Analysis of Rufy1-knockout ELVA/ELYSA free oocytes is awaited to elucidate the physiological role of ELVAs or probably ELYSAs. They also suggested that ELVAs sequester and degrade specific proteins that is known to be aggregate and cause diseases, including proto-oncogene receptor tyrosine kinase KIT, upon oocyte maturation18. Complementally to their findings, our study revealed that the recruitment of the V1-subunit is limited on ELYSAs in oocytes but enhanced on the isolated LAMP1-positive vesicles after late 2-cell stage. These findings support a hypothesis that ELYSA has a multimodal function, keeping endosomal and lysosomal compartments at a relatively static state and supplying these membrane compartments as a reservoir for embryogenesis.
Inhibition of lysosomal acidification by bafilomycin A1 treatment arrests embryogenesis at the 4–8-cell stage, while inhibition of cathepsin activity using a mixture of E64d and pepstatin A blocks embryogenesis at the 8-cell or morula stage12. In contrast, the inhibition of endocytosis by Pitstop2 treatment causes arrest at the 2-cell stage9. These differences may imply that at the 2-cell stage, the endocytic activity is more important than the lysosomal degradation activity, which is essential at later stages. However, insights from this study shed light on the correlation between increased endocytic/autophagic activity and lysosomal maturation through ELYSA disassembly and the potential significance of minor lysosomal maturation in the early phase of embryogenesis.
The relationship between such endocytic/autophagic activities in early-stage embryos and the embryonic developmental potential have been recently studied. Using GFP-LC3 as an indicator of autophagic activity, Tsukamoto et al. found that aged oocytes from 14- to 15-month-old mice had lower autophagic activity than those from younger mice, probably due to decreased lysosomal activity. Females transplanted with embryos with high autophagic activity at the 4-cell stage have a significantly higher litter size ratio than that of control females19. Analysis of ELYSA formation and disassembly in aged oocytes and embryos may be a useful tool for determining oocyte quality by examining appropriate regulation of endosomal/lysosomal activities.
Methods
Animal experiments and strains
Neither randomization nor blinding was used for animal selection (8–16-week-old). All experimental protocols involving animals were approved and performed in accordance with the guidelines of the Animal Care and Experimentation Committee of Gunma University (Approval No. 22-076). Hybrid B6D2F1 mice were purchased from the Japan SLC (Hamamatsu, Japan)
Antibodies and inhibitors
The following primary antibodies were used: rabbit monoclonal anti-RAB5 (C8B1; 3547; Cell Signaling Technology, Danvers, MA, USA), rabbit monoclonal anti-RAB7 (D95F2; 9367; Cell Signaling Technology), rat monoclonal anti-mouse LAMP1 (1D4B; sc-19992; Santa Cruz Biotechnology, Dallas, TX, USA), and mouse monoclonal anti-rat LC3 (Clones 4E12; M152-3; Medical and Biological Laboratories, Tokyo, Japan). The following secondary antibodies were used: goat anti-rabbit IgG (H+L) conjugated with Alexa Fluor 555 (A-21428; Thermo Fisher Scientific, Waltham, MA, USA), goat anti-rat IgG (H+L) cross-adsorbed secondary antibody conjugated with Alexa Fluor 488 and 647 (A-11006 and A-21247, respectively; Thermo Fisher Scientific), and goat anti-mouse IgG (H+L) cross-adsorbed secondary antibody conjugated with Alexa Fluor 546 (A-11030; Thermo Fisher Scientific). The following inhibitors or solutions were used for IVM or embryonic culture assays: dimethyl sulfoxide (DMSO) (13406-55; Nacalai Tesque, Kyoto, Japan); latrunculin A actin polymerization inhibitor that binds to monomer actin (428021; Sigma-Aldrich, St. Louis, MO, USA); cytochalasin B, an actin polymerization inhibitor that binds to the plus-end of polymerized actin (C6762; Sigma-Aldrich); and nocodazole, a tubulin polymerization inhibitor that binds to β-tubulin (M1404; Sigma-Aldrich). Stock solutions of latrunculin A, cytochalasin B, or nocodazole were prepared by solubilizing each in DMSO at 200× concentration for the assays. Bafilomycin A1 was dissolved in DMSO (L266; Dojindo, Kumamoto, Japan) at a final concentration of 25 nM.
Oocyte preparation
GV oocytes were collected from the ovaries of female mice 46 h after injection with pregnant mare serum gonadotropin or an anti-inhibin antibody (CARD HyperOva; Kyudo, Kumamoto, Japan). Antral follicles were suspended in 30 μL of FHM medium drops (Sigma-Aldrich) covered with liquid paraffin (Nacalai Tesque), punctured using 26G needles (Terumo, Tokyo, Japan), and the GV oocytes were collected using a glass needle with a mouth pipette. MII oocytes were collected from the oviducts of female mice 13 h after injection with CARD HyperOva and 7.5 IU human chorionic gonadotropin (hCG; ASKA Pharmaceutical, Tokyo, Japan) 48 h apart. The oviductal wall was punctured using a 26G needle to collect cumulus-oocyte complexes in 20 μL potassium simplex optimization medium (KSOM; Kyudo) drops covered with liquid paraffin.
DNA vector construction and mRNA synthesis
Complementary DNA for mouse Lamp1 (accession number NM_001317353) or Atp6v1a (accession number NM_001358204) was amplified using PCR with High-fidelity Taq Polymerase, KOD FX Neo (Toyobo, Osaka, Japan), and a mouse ovary cDNA library as a template (Genostaff, Tokyo, Japan). The amplicon was then subcloned into the entry vector pDONR221, and transferred into the destination vectors pDEST-CMV-C-EGFP (#122844; for Lamp1; Addgene, Watertown, MA, USA) or pDest-mCherry-N1 (#31907; for Atp6v1a; Addgene) using Gateway recombination cloning technology. The following primer combinations were used for cloning: 5′-GCGCACAAGTTTGTACAAAAAAGCAGGCTGCCACCATGGCGGCCCCCGGCG-3′ and 5′-GCGCACCACTTTGTACAAGAAAGCTGGGTTGTCTTCAAGGCTACGGAATG-3′ (for Lamp1), or 5′-GCGCACCACTTTGTACAAGAAAGCTGGGTTGATGGTCTGATAGCCGGCGTGA CT-3′ and 5′-GCGCACCACTTTGTACAAGAAAGCTGGGTTGTCTTCAAGGCTACGGAATG-3′ (for Atp6v1a). The cDNA encoding Lamp1-EGFP or Atp6v1a-mCherry were amplified using the following primer combinations: 5′-CGCAAATGGGCGGTAGGCGTG-3′ and 5′-TCCAGCAGGACCATGTGATCGC-3′ (for Lamp1-EGFP), or 5′-CGCAAATGGGCGGTAGGCGTG-3′ and 5′-TTGGTCACCTTCAGCTTGG-3′ (for Atp6v1a-mCherry). RNA synthesis using each PCR amplicon as a template, poly-A tail addition, and mRNA purification were performed, using an mMESSAGE mMACHINE T7 Ultra kit (Thermo Fisher Scientific) and MEGAclear transcription clean-up kit (Thermo Fisher Scientific), according to the manufacturer’s protocols. Synthesized mRNAs were dissolved in RNase-free demineralized water at a concentration of 400 ng/μL and frozen in aliquots until use.
In vitro maturation, fertilization, and embryonic culture
IVM for the GV oocytes was conducted by washing the oocytes twice and culturing in alpha-modified Eagle’s minimum essential medium (Thermo Fisher Scientific) containing 5% (vol/vol) fetal bovine serum (FBS), 0.1 of IU/mL follicle-stimulating hormone (MSD, Tokyo, Japan), 1.2 IU/mL of hCG (ASKA Pharmaceutical), and 4 ng/mL of epidermal growth factor (Thermo Fisher Scientific) for 17 h at 37 °C under a 5% CO2 atmosphere20. For in vitro fertilization, spermatozoa from a B6D2F1 epididymis were pre-incubated in a 100-μL modified human tubal fluid medium (Kyudo) drop covered with liquid paraffin and inseminated at a sperm concentration of 1.5 × 105 per mL for 1.5 h. Excess spermatozoa were washed out, and the oocytes were incubated in a 20-μL KSOM drop (Kyudo) for further development. IVM assays using latrunculin A and cytochalasin B were performed by transferring oocytes to medium drops containing each inhibitor or DMSO 4 h after the start of IVM (waiting for the completion of GVBD), as previously reported15. IVM media containing DMSO, latrunculin A, or cytochalasin B was prepared by diluting the stock solution (1:400), and the final concentration of the inhibitors was 10 μM. The embryonic culture assay using bafilomycin A1 was conducted by transferring the PN-zygote into a 20-μL drop of KSOM containing 25 nM bafilomycin A1 covered with liquid paraffin at 6 h post-fertilization (hpf). Embryos were transferred at 24, 48, and 72 hpf to freshly prepared KSOM containing bafilomycin A1.
Immunostaining
Immunostaining of oocytes or embryos was performed as previously described9. Oocytes or embryos were cultured to the indicated stages and fixed in 4% paraformaldehyde (PFA; Nacalai Tesque) in phosphate-buffered saline (PBS) containing 0.1 mg/mL polyvinyl alcohol (PVA; Sigma-Aldrich) (PVA/PBS) for 15 min at 25–27 °C. After fixation, the cells were permeabilized with PVA/PBS containing 0.1% Triton X-100 (Sigma-Aldrich) for 30 min at 25–27 °C and washed three times with PVA/PBS. After blocking with 10% FBS (Thermo Fisher Scientific) in PBS for 1 h at room temperature, the cells were incubated with the aforementioned primary antibodies (1:100 for all) overnight at 4 °C. Next, the cells were washed three times in PVA/PBS, and incubated with anti-mouse, rat, or rabbit IgG secondary antibodies coupled with Alexa Fluor 488, 555, or 564 (1:200 for all; Thermo Fisher Scientific) at 25–27 °C for 2–4 h. Thereafter, the cells were incubated with PVA/PBS containing 10 μg/mL Hoechst 33342 (Dojindo) for 10 min and washed with fresh PVA/PBS a few times. Subsequently, control and nonspecific staining were performed by processing oocytes and embryos in the absence of primary antibodies. The oocytes and embryos were imaged in PVA/PBS microdrops in 35-mm glass-bottomed dishes (MatTek Corporation, Ashland, MA, USA). For each position, confocal images at 81 z-axis planes with 1-μm increments were acquired on an IX-71 inverted microscope (Olympus Corporation, Tokyo, Japan) equipped with a CSU W-1 confocal scanner unit (Yokogawa Electric Corporation) using a 60× silicone immersion lens UPLSAPO60XS (Olympus Corporation).
LysoTracker/LysoSensor staining of oocytes and generation of ratio images
Acidic organelles in the oocytes were visualized using LysoTracker Red DND-99 and LysoSensor Green DND-189 (Thermo Fisher Scientific) according to the manufacturer’s instructions. Briefly, the oocytes or embryos at target stages for one experimental round were obtained simultaneously and incubated in a large drop of reaction mixture (KSOM containing 1/10,000 Magic Red stock solution dissolved in DMSO and 1/1,000 LysoSensor Green DND-189 stock solution dissolved in DMSO) for 30 min at 37 °C under 5% CO2 in a humidified atmosphere in liquid paraffin in a 35-mm glass-bottom dish (MatTek Corporation). Subsequently, confocal images at 41 z-axis planes with 2-μm increments were obtained using a CSU W-1 spinning disk confocal microscope with a 30× silicone immersion lens UPLSAPO30XS (Olympus Corporation). Acquisition conditions for fluorescence excited by 470-nm (LysoSensor) and 555-nm (LysoTracker) lasers were determined in preliminary experiments to be almost 1:1 intensities between the two wavelengths for cytosolic punctate structures in the 2-cell embryo. Further generation of ratio images for LysoTracker/LysoSensor fluorescence were carried out using Fiji software21. Averaged intensity projection was carried out, determining background intensity of each field by subtracting the averaged intensities of four cellular blank regions from the whole image. Then, 32-bit ratio images for LysoTracker/LysoSensor fluorescence of cytosolic regions were generated by processing images with “Math/Divide” function in Fiji, and “fire” look up table images were converted to RGB images.
Magic Red/LysoSensor staining
Intracellular cathepsin activity was assayed in oocytes or embryos using Magic Red Cathepsin B or Cathepsin L detection kits (ImmunoChemistry Technologies LLC, Davies, CA, USA) according to the manufacturer’s instructions. Briefly, the oocytes or embryos at target stages for one experimental round were obtained simultaneously and incubated in a large drop of reaction mixture (KSOM containing 1/250 Magic Red stock solution dissolved in DMSO and 1/1,000 LysoSensor Green DND-189 stock solution dissolved in DMSO) for 25 min at 37 °C under 5% CO2 in a humidified atmosphere in liquid paraffin in a 35-mm glass-bottom dish (MatTek Corporation). Thereafter, Hoechst 33342 (10 μg/mL) was added to the drop to a final concentration of 10 μg/mL, and incubated for 5 min. Subsequently, oocytes or embryos at the same stage were collected, and confocal images at 41 z-axis planes with 2-μm increments for both 470-nm (LysoSensor) and 555-nm (Magic Red) lasers were obtained on a CSU W-1 spinning disk confocal microscopy using a 30× silicone immersion lens UPLSAPO30XS (Olympus Corporation).
In-resin CLEM and electron microscopy
In-resin CLEM was performed as previously described with some modifications13, 14. Briefly, oocytes were fixed in 4% PFA and 0.025% glutaraldehyde (GA). After permeabilization with 50 μg/mL digitonin (Nacalai Tesque) and 0.02% Triton X-100, oocytes were washed with PVA/PBS three times and incubated with PBS containing 10% (w/v) FBS (Thermo Fisher Scientific) for 1 h at room temperature. Thereafter, oocytes were incubated with PVA/PBS containing primary antibody overnight at 4 °C. After incubation with a secondary antibody in PVA/PBS for 2 h, oocytes were fixed in 4% PFA and 2.5% GA, embedded in 1.5% agarose, stained with osmium tetroxide, dehydrated with graded ethanol solutions (QY1), and embedded in epoxy resin (Oken Shoji, Tokyo, Japan). Ultrathin sections of Epon-embedded oocytes (100-nm thickness) were prepared using a Leica UC6 ultramicrotome (Leica, Nussloch, Germany) and placed on glass coverslips. Subsequently, fluorescence microscopy images of the sections were obtained using a Nikon A1RHD25 confocal laser scanning microscope with a NIS-Elements software (Nikon, Tokyo, Japan). Electron microscopic images were observed using a Helios Nanolab 660 FIB-SEM instrument (FEI Company, Hillsboro, USA).
For conventional electron microscopy, the oocytes were fixed in the presence of 2% PFA and 2.5% GA and stained with osmium tetroxide. After dehydration with ethanol, the oocytes were embedded in epoxy resin, as described above. Sections were cut at a thickness of 100 nm using a UC6 ultramicrotome, mounted on glass coverslips, stained with uranyl acetate and lead citrate, and observed under a Regulus8240 scanning electron microscope (Hitachi High-Tech Corporation, Tokyo, Japan).
Serial semi-thin sections and 3D reconstruction of toluidine blue-positive structures
Serial semi-thin sections were cut at a thickness of 300 nm using a UC6 ultramicrotome and mounted on glass slides. Next, the sections were stained with 1% toluidine blue/0.1 M PB, and images were obtained using a BX50 light microscope (Olympus Corporation). Serial toluidine blue-stained images were aligned using FIJI (National Institutes of Health, MD, USA) with plugin-linear stack alignment using SIFT (LSAS), and 3D reconstruction was performed using Amira software (Thermo Fisher Scientific).
Microinjection into the oocytes
Microinjection of mRNA into GV oocytes was performed as previously described22,23. Briefly, antral follicles were harvested in FHM medium containing 250 μM of dbcAMP using 26G needles (Terumo). After dissociating the cumulus cells by pipetting, the oocytes were transferred to medium supplemented with 250 μM of dbcAMP and 10 μM of cytochalasin B (Sigma-Aldrich). Thereafter, mRNA injection into the oocytes was performed using a piezo-micromanipulator (Primetech, Tokyo, Japan) with a glass capillary needle. The mRNA concentrations were 50 and 100 ng/μL for V1A-mCherry and Lamp1-EGFP, respectively. The oocytes were washed three times and used for IVM. Microinjection of mRNA into zygote stage embryo (at 3–4 hpf) was carried out as previously described9. The concentration of mRNA was the same as that in the GV oocytes.
Time-lapse confocal imaging of oocytes/embryos
Low-invasive confocal fluorescence imaging of oocytes/embryos was performed as previously described24, 25, 26 with slight modifications. Briefly, on an inverted microscope IX-71 (Olympus Corporation) equipped with a CSU W-1 confocal scanner unit (Yokogawa Electric Corporation), an incubation chamber (Tokai Hit, Fujinomiya, Japan) was set at 37 °C on the microscope stage, with a gas mixture of 5% CO2 introduced into the chamber at 150 mL/min. Oocytes/embryos were placed in 8 μL of IVM medium or KSOM drops covered with liquid paraffin (Nacalai Tesque) in 35-mm glass-bottomed dishes (MatTek Corporation). Subsequently, confocal images at 41 z-axis planes with 2-μm increments for excitation lasers of 470- and 555-nm from an LDI-7 Laser Diode Illuminator (89North, Williston, VT, USA) were obtained every 30 or 60 min during IVM or embryonic culture observation, respectively, through optimized band-pass filters using 30× silicone immersion lens UPLSAPO30XS (Olympus Corporation).
Three-dimensional object analysis
Series of confocal images with 81 z-axis planes with 1-μm increments for LAMP1 immunostaining were used for 3D object analysis. Fields to analyze were cropped for each oocyte/embryo, and the upper and lower end of LAMP1 fluorescent signals in the cytosol were examined to determine the center plane (middle height) of the cell. The cellular region in the center plane was used for masking and determination of the geometric center (as a 3D center) of each oocyte. Deletion of the signals from the polar body or zona pellucida was carried out manually. Objects were profiled using the 3D object counter plugin27 of Fiji software21, to measure the number, volume, geometric center of each object, and mean distance from the geometrical center of the object to its surface. Thresholding was carried out after background subtraction using the Fiji software, manually applying intensities of 600–1200 as threshold to recognize objects separately. Signals on PM were eliminated both via size filtering (0–5000 μm3) of the 3D object counter plugin and manual erasing. The distal distance of each object from the 3D center of the oocyte was used for distribution analysis to avoid underestimation of the distance of large ELYSA. This was calculated by adding the distance from the 3D center of the oocyte to the geometric center of each object and the mean distance from the geometrical center of the object to its surface. Distance calculation and generation of bar graphs were carried out using Excel 2016 software (Microsoft, Redmond, WA, USA).
Analysis of microscopic images and movies
Analysis of the acquired images, including the generation of a line plot of intensity, adjustment of intensity, and generation of montage images at a uniform intensity, was performed using Fiji software21. To enhance the images, a Gaussian Blur filter (at a sigma radius of 1) and auto-adjustment of the intensity were applied to the stack of images. To adjust the intensity, auto-adjustment of the intensity was applied to each image. The movies were concatenated using Premiere Pro software (Adobe, San Jose, CA, USA).
Statistics and reproducibility
Sample sizes were estimated based on previous studies using similar experiments, and results from preliminary experiments were examined to ensure statistical power more than 0.8 using statistical power analysis in the G*Power software28. Statistical analyses and generation of dot plot graphs were performed using Graph-Pad Prism 8 (GraphPad Software, Boston, MA, USA). The significance of difference among groups were compared using one-way ANOVA. The experimenters were not blinded because of a limitation in the availability of experienced personnel.
Data availability
The data supporting the findings of this study are available from the corresponding authors upon request.
Materials availability statement
The materials supporting the findings of this manuscript are available from the corresponding authors upon reasonable request.
Acknowledgements
We would like to thank Editage (www.editage.jp) for English language editing.
Funding
This study was supported by the Japan Society for the Promotion of Science KAKENHI (Grant Numbers 19H05711 and 20H00466 to K. Sato, 21H02435, 22H02872, and 22H04652 to I. Tanida, and 20K22744 to J. Yamaguchi), the Mochida Memorial Foundation for Medical and Pharmaceutical Research, Takeda Science Foundation (Grant Number 2022093867), and The Cell Science Research Foundation to Y. Satouh. This work was partly supported by the Project for Elucidating and Controlling Mechanisms of Aging and Longevity from the Japan Agency for Medical Research and Development (AMED 21gm5010003 to Y. Uchiyama., 22gm1710001 s0201 and 23gm1710001s0202 to I. Tanida) and by the MEXT-supported Program for the Strategic Research Foundation at Private Universities (to Y. Uchiyama), and the Center of Genomic and Regeneration Medicine, Juntendo University Graduate School of Medicine (to Y. Uchiyama and I. Tanida).This work was partly supported by the joint research program of the Institute for Molecular and Cellular Regulation, Gunma University (24014 to I. Tanida and K. Sato).
Competing interests
No competing interests declared.
References
- 1.Control of the oocyte-to-embryo transition by the ubiquitin-proteolytic system in mouse and C. elegansCurr Opin Cell Biol 22:758–763
- 2.Five questions toward mRNA degradation in oocytes and preimplantation embryos: when, who, to whom, how, and why?Biol Reprod 107:62–75
- 3.The maternal-zygotic transition: death and birth of RNAsScience 316:406–407
- 4.Mouse zygote-specific proteasome assembly chaperone important for maternal-to-zygotic transitionBiol Open 2:170–182
- 5.Inhibition of the ubiquitin-proteasome system leads to delay of the onset of ZGA gene expressionJ Reprod Dev 56:655–663
- 6.Multiple roles of endocytosis and autophagy in intracellular remodeling during oocyte-to-embryo transitionProc Jpn Acad Ser B Phys Biol Sci 98:207–221
- 7.Autophagy and endocytosis - interconnections and interdependenciesJ Cell Sci 133
- 8.Autophagy is essential for preimplantation development of mouse embryosScience 321:117–120
- 9.Clathrin-mediated endocytosis is essential for the selective degradation of maternal membrane proteins and preimplantation developmentDevelopment 148
- 10.Reorganization, specialization, and degradation of oocyte maternal components for early developmentReprod Med Biol 22
- 11.A lysosomal switch triggers proteostasis renewal in the immortal C. elegans germ lineageNature 551:629–633
- 12.Functional analysis of lysosomes during mouse preimplantation embryo developmentJ Reprod Dev 59:33–39
- 13.Application of immuno- and affinity labeling with fluorescent dyes to in-resin CLEM of Epon-embedded cellsHeliyon 9
- 14.TUNEL-positive structures in activated microglia and SQSTM1/p62-positive structures in activated astrocytes in the neurodegenerative brain of a CLN10 mouse modelGlia 71:2753–2769
- 15.Changes in endoplasmic reticulum structure during mouse oocyte maturation are controlled by the cytoskeleton and cytoplasmic dyneinDev Biol 305:133–144
- 16.Mechanisms regulating zygotic genome activationNat Rev Genet 20:221–234
- 17.Endosomal-lysosomal organellar assembly (ELYSA) structures coordinate lysosomal degradation systems through mammalian oocyte-to-embryo transitionbioRxiv https://doi.org/10.1101/2023.12.29.573616
- 18.Mouse oocytes sequester aggregated proteins in degradative super-organellesCell 187:1109–1126
- 19.Fluorescence-based visualization of autophagic activity predicts mouse embryo viabilitySci Rep 4
- 20.Complete in vitro generation of fertile oocytes from mouse primordial germ cellsProc Natl Acad Sci U S A 113:9021–9026
- 21.Fiji: an open-source platform for biological-image analysisNat Methods 9:676–682
- 22.Structural insights into tetraspanin CD9 functionNat Commun 11
- 23.Structural and functional insights into IZUMO1 recognition by JUNO in mammalian fertilizationNat Commun 7
- 24.Sperm-borne phospholipase C zeta-1 ensures monospermic fertilization in miceSci Rep 8
- 25.Viable offspring after imaging of Ca2+ oscillations and visualization of the cortical reaction in mouse eggsBiol Reprod 96:563–575
- 26.Visualization of the moment of mouse sperm-egg fusion and dynamic localization of IZUMO1J Cell Sci 125:4985–4990
- 27.A guided tour into subcellular colocalization analysis in light microscopyJ Microsc 224:213–232
- 28.G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciencesBehav Res Methods 39:175–191
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