Animals

C57bl/6 (wild-type) and B6.C-Uchl1^gad-J/J [29] were obtained from the Jackson Laboratory (strain # 024355). B6.C-Uchl1 J/J (“wild-type”), B6.C-Uchl1^gad-J/J (“heterozygous”), or B6.C-Uchl1^gad-J/_gad-J (“knockout”) mice were generated by mating UCHL1 heterozygous male and female mice. Offspring were genotyped by PCR analysis of ear-snip genomic DNA amplifying the region targeted by homologous recombination using genotyping protocols established by the Jackson Laboratory. All animal protocols were reviewed and approved by Brown University Institutional Animal Care and Use Committee and were performed in accordance with the National Institutes of Health Guide for the Care and Use of Laboratory Animals (# 19-07-0001). All animal protocols were all reviewed and acknowledged by the Lifespan University Institutional Animal Care and Use Committee (# 1668974-1).

Fertility trials

To assess female fertility in all genotypes of B6.C-Uchl1^gad-J/J mice, controlled fertility trials were performed. B6.C-Uchl1 J/J, B6.C-Uchl1^gad-J/J, or B6.C-Uchl1^gad-J/_gad-J females were housed with wild-type C57BL/6 J males, both at 6 weeks of age (n = 3 for both wild-type and knockout, n = 4 for heterozygotes). All animals were housed in single breeding pairs with love huts, and monitored for signs of copulation, pregnancy, and birth of pups. Number and sizes of litters were recorded. As Uchl1-null mice develop severe motor dysfunction by 6–7 months of age, all breedings were discontinued at 20 weeks of age, and compared between genotypes.

Vaginal cytology and estrous cycle monitoring

Daily vaginal smear cytology was performed over the course of two weeks to determine estrous cyclicity, beginning at 6 weeks of age on virgin females (n = 4 for wild-type, n = 6 for heterozygotes, and n = 5 for knockouts). Brief ly, the vagina of each mouse was f lushed with a small volume of sterile saline solution and then mixed on a glass slide with toluidine blue O dye [30]. Slides were visualized on an EVOS M5000 Fluorescence Imaging System and were classified as in proestrus, estrus, or metestrus/diestrus based on the majority cell type present in the vaginal sample [30]. The percentage of time spent in each sub-stage was quantified per mouse and averaged per genotype. Following estrous cycling, mice were allowed to age to 5 months, at which point mice were sacrificed in proestrus, whole blood was collected for serum analysis, and ovaries collected for analysis of ovary weights versus body weights (n = 3 wild-type, 5 heterozygous, 5 knockout animals).

Ovarian histology

Ovaries were removed at 1 month of age (n = 8 wild-type, 6 heterozygous, 6 knockout animals), or 5 months of age (n = 4 wild-type, 2 heterozygous, 4 knockout animals) cleaned of excess fat and bursal sac, and fixed in 1:10 formalin solution overnight. Standard paraffin embedding, 5 µM serial sectioning, and hematoxylin-and-eosin staining were performed [31]. Slides were visualized on an EVOS M5000 Fluorescence Imaging System and images of all fields of a single section were captured. Ovarian follicle counts were quantified using two sections on every fourth slide of sectioned ovary to capture all follicle stages without over-counting of larger follicles (given eight sections per slide, at 5-µm per section, every fourth slide represents 160 µm of distance). Follicle counts were normalized to section area to account for size differences between different ovaries. Follicles were classified by standard protocols [32]. In brief, primordial follicles were defined by one layer of flattened granulosa cells surrounding the oocyte; primary follicles were defined by a single later of cuboidal granulosa cells surrounding the oocyte; secondary follicles were defined by two or more layers of cuboidal granulosa cells surrounding the oocyte; pre-antral follicles were classified as follicles in which antral space had begun to form among the granulosa cells; and antral follicles were classified as follicles in which a complete semi-circular antral space had formed and cumulus-surrounded oocytes were observable.

Hormonal stimulation and super-ovulation

For hormonal stimulation experiments followed by histology, 1-month-old mice were injected intraperitoneally with 5-IU pregnant mare goat serum (PMSG; Prospec Bio) (n = 2 wild-type and 2 = knockout animals). Forty-eight hours later, one mouse from each genotype was intraperitoneally injected with 5-IU human chorionic gonadotropin (HCG; Prospec Bio), while the other two mice (one of each genotype) were euthanized and ovaries collected for histology. Twelve hours later, HCG-injected mice were euthanized and ovaries collected for histology. For super-ovulation experiments, mice at 4 weeks of age were super-ovulated by standard protocols [33] (n = 13 wild-type, 14 heterozygous, 3 knockout animals). Brief ly, mice were injected intraperitoneally with 5-IU pregnant mare goat serum. Forty-eight hours later, the same mice were intraperitoneally injected with 5-IU human chorionic gonadotropin. Twelve hours later, mice were euthanized and ovaries and oviducts collected. Ovulated cumulus-oocyte complexes were released from the ampulla of the oviduct and counted per mouse. Number of oocytes per mouse were averaged between genotypes and compared.

Serum hormone analysis

For AMH analysis, whole blood was collected from mice at 80 days of age by cardiac puncture (n = 3 wild-type, 7 heterozygous, 6 knockout animals). Blood was collected into serum separator tubes, allowed to clot for 30 min, then spun at 3000 g for 15 min at 4°C. The supernatant was collected as serum for analysis. Serum was sent to the University of Virginia Ligand Assay & Analysis Core of the Center for Research in Reproduction for analysis of anti-Mullerian hormone serum concentrations. For LH and FSH analyses, blood was collected from 5-month-old animals (n = 2 per genotype) and serum purified as described. Serum was analyzed as described at the University of Virginia.

Generation of ovarian single cell libraries

C57bl/6 ovaries were collected from mice at embryonic day 18.5 (E18.5), and postnatal days (PND) 1, 3, and 5 and pooled to generate pools of 1 million cells per time-point (E18.5 n = 47 ovaries, PND1 n = 29 ovaries, PND3 n = 25 ovaries, PND5 n = 8 ovaries). Ovaries were dissociated by incubation in 750 µL 0.25% Trypsin–EDTA for 30 min at 37°C with rotation. Cells were then spun at 500 g for 5 min, and resuspended in 150 µL 7 mg/mL DNase I and gently pipetted to disperse cells. Cells were incubated for 5 min at room temperature, and then DNase I activity was quenched by addition of 1 mL PBS + 10% knockout serum replacement. Cells were filtered through a 40-µM filter and spun again at 500 g for 5 min. The resulting cell pellets were counted and resuspended in freezing media (70% DMEM, 20% knockout serum replacement, 10% DMSO) and stored at –80°C in cryotubes.

Cell preparations were then submitted to Genewiz for 10X Genomics scSEQ on the 10X Genomics Chromium System. Library preparation was performed by Genewiz, per the manufacturer's instructions and as previously described [34]. Libraries were sequenced to an average depth of 394 M reads (range 372–423 M); on average, 93% of reads (range 88–95%) mapped to the reference genome (/gwngsfs/gwngs/data/ ref/cellranger/refdata-cellranger-mm10–3.0.0). Initial quality control ( Supplementary Figures 2 (supplemental_figure_2_4_5_22_ioac086.pdf)– 6 (supplemental_figure_6_4_5_ioac086.pdf)) and bioinformatics analyses were conducted at GENEWIZ, LLC. Loupe Cell Browser 2.0.0 was used for downstream analysis of ovarian somatic cells and oocytes at all time points and visualization with t-distributed stochastic neighbor embedding (tSNE) plots.

Data availability: The single-cell RNAseq data have been deposited in the NCBI Gene Expression Omnibus (GEO) and are accessible through accession number GSE186843.

Single-cell RNA seq (scSEQ) data analysis [35]

The PND0 sample SRX6451401 from GEO Series GSE134339 was downloaded from NCBI SRA onto Brown University's high-performance computing cluster at the Center for Computation and Visualization. In this published dataset, isolated PND0 ovaries from C57BL/6 J mice were cut into pieces and transferred into 0.25% trypsin/EDTA and collagenase for 6–8 minutes at 37°C. Following the termination of digestion, the single cell suspension was filtered with a 40-µm mesh strainer and washed twice with PBS containing 0.04% BSA. Single-cell RNA-seq libraries were prepared using Single Cell 3' Library and Gel Bead Kit V2 (10x Genomics Inc., 120,237, Pleasanton, CA, USA) following the manufacturer's instructions. This cell preparation is highly analogous to the cell preparation for our single-cell sequencing presented in this study, allowing reasonable analysis of the relationship between Uchl1 expression and that of other oocyte-specific genes, and for those findings to be applicable to our own. The downloaded fastq files were aligned using Cell Ranger (v 5.0.0, 10× Genomics Inc.) count to the mm10 genome. The resulting “filtered feature bc matrix” was used as input for Seurat (v 3.9.9, a software package designed for quality control and analysis of scSEQ data). in RStudio (R v 4.0.2). Seurat [35] was used to select for Ddx4-positive (Ddx4 > 0), high-quality (nFeature_RNA > 100, nFeature_RNA < 7000, nCount <40,000, percent mitochondrial genes <15%) oocytes. To obtain gene counts, the Seurat function “GetAssayData” under the slot “counts” was used. These gene expression counts for Uchl1 compared to Sohlh1, Figla, and Lhx8 were plotted in Graphpad Prism and a linear regression applied ( Supplementary Figure 9 (supplemental_figure_9_4_5_ioac086.pdf)).

Immunofluorescence

Wild-type ovaries were collected at E18.5, PND0, PND1, PND3, 3 weeks, 1 month, 5 months, and 8 months of age (n = 2 per time point), cleaned of excess fat, and fixed in 1:10 formalin solution overnight before dehydration and embedding in paraffin by the Brown University Molecular Pathology Core. Fixed ovaries were sectioned at 5 µm onto glass slides by the Brown University Molecular Pathology Core. To stain, sections were de-paraffinized by standard protocols [36] with minor modifications: 3×, 5 minute washes in Safeclear followed by rehydration in 100% ethanol (2×, 5 min), 95% ethanol (2×, 5 min), 70% ethanol (1×, 5 min), water (1×, 5 min). Staining was carried out by standard protocols [37]: sections were then incubated in boiling antigen retrieval buffer (10 mM sodium citrate, 0.05% Tween-20, pH 6.0) for 20 minutes and left to cool. Sections were washed 3×, 5 minutes in 1X PBS + 0.1% Triton-X (PBST). Tissue sections were then incubated in blocking buffer [3% goat serum (Sigma), 1% bovine serum albumin (Sigma), and 0.5% Triton-X (Fisher Scientific) in 1X PBS] and stained by incubation with primary antibodies against UCHL1 (Proteintech #14730–1-AP, 1:100) and TRA98 (Abcam #ab82527; 1:100) overnight at 4°C. The following day, slides were washed 3×, 5 min in PBST and then incubated with secondary antibodies raised in goat against rat (594 nm) and rabbit (488 nm) at 1:500 for 1 h at 37°C. A secondary antibody-only control was included to assess background staining ( Supplementary Figure 10B (supplemental_figure_10_4_5_ioac086.pdf)). Sections were further stained with DAPI to visualize nuclei, mounted and analyzed on a Nikon TE2000e inverted epifluorescence microscope. For a given set of antibodies, images were exposed equivalently for all samples from different time points to generate images for relative comparison of intensity over time.

Timeline of experimental procedures and cohorts

Statistical analysis

All statistical analyses were performed in GraphPad Prism, and all data assessed for normal distribution. Simple linear regression analyses of single-cell sequencing gene expression were carried out with Pearson correlation co-efficient and Pvalues calculated. Fecundity analyses were performed using two-way ANOVA with Šídák's multiple comparisons tests applied. Follicle count and estrous cyclicity analyses were performed using two-way ANOVA with Tukey's multiple comparisons tests applied. Analysis of ovary weights were performed using one-way ANOVA with Tukey's multiple comparisons test applied. Serum AMH and LH analyses were also performed using one-way ANOVA with Tukey's multiple comparisons test applied.

Uchl1 is highly expressed in oocytes within the mouse ovary, with protein localization in oocytes of all stages

In an effort to identify and profile the dynamic gene expression changes that take place during murine ovarian reserve formation, we collected mouse ovaries at several time points to span the establishment of the ovarian reserve (embryonic day 18.5, E18.5, and postnatal days (PND) 1, 3, and 5). By choosing these time points, we expected to capture oocytes still within ovarian cysts, as well as oocytes undergoing cyst breakdown, and oocytes which are later comprising primordial follicles. For each time point, 4–5000 cells per mouse were processed through the 10X Genomics Chromium System using standard protocols for single cell RNA sequencing (scSEQ). Libraries were sequenced to an average depth of 1.3 billion reads; on average, 93.1% of reads mapped to the reference genome. After standard data processing, we obtained gene expression profiles for approximately 1100 cells per library ( Supplementary Figure 1A (supplemental_figure_1_4_5_22_ioac086.pdf),  Supplementary Figures 2 (supplemental_figure_2_4_5_22_ioac086.pdf)– 6 (supplemental_figure_6_4_5_ioac086.pdf)), of which a total of only 70, or about 2%, were germ cells, identified by Dazl and Ddx4 expression ( Supplementary Figure 7 (supplemental_figure_7_4_5_ioac086.pdf)). While most of the cells in our data set were ovarian somatic cells, this germ cell retention limitation is not unique to this study, with other recent studies also demonstrating comparatively reduced germ cell representation compared to somatic cell representation [38].

We were able to identify globally distinguishing genes in the oocyte population, or genes, which are highly and specifically expressed in the germ cells of the developing ovarian reserve. Oocytes selected by expression of the germ cell markers Dazl and Ddx4 ( Supplementary Figure 7 (supplemental_figure_7_4_5_ioac086.pdf)) were further analyzed to identify novel gene expression dynamics. Our analysis revealed a list of the top 20 oocyte-enriched factors ( Supplementary Figure 1A (supplemental_figure_1_4_5_22_ioac086.pdf)), the vast majority of which are already well characterized for expression and function, including Dazl, meiosis regulators Sycp1, Sycp3, Syce3, Hormad1, and Smc1b [39]; transcriptional regulators Figla 40–42] and Taf7l [43]; and retrotransposon regulators Mov10l1 [44] and Mael [45, 46]. While these serve as excellent positive controls for the fidelity of our study, our aims to identify novel regulators resulted in further analysis of the twentieth most highly-expressed oocyte-expressed gene identified in our study, Uchl1 ( Supplementary Figure 1B (supplemental_figure_1_4_5_22_ioac086.pdf)). We also observe lower levels of Uchl1 expression in three specific sub-populations of somatic cells ( Supplementary Figure 8 (supplemental_figure_8_4_5_ioac086.pdf)), specifically pre-granulosa cells, which are Lgr5-expression, Foxl2-expressing, and Nr2f2-expressing [47].

Due to low oocyte yield in our dataset, we also mined existing data sets to independently verify our Uchl1 oocyte expression data. In the PND0 murine ovarian dataset from Wang et al. [48], the authors retained nearly 3000 oocytes for their analysis, allowing us to correlate Uchl1 expression with other known regulators of oocyte development. Correlation analysis of Uchl1 with oocyte-specific transcriptional regulators Factor in the Germline Alpha (Figla), spermatogenesis and oogenesis-specific basic helix–loop–helix 1 (Sohlh1), and LIM Homeobox Protein 8 (Lhx8) revealed significant correlations between the expression of both genes (r = 0.7895, r = 0.7700, and r = 0.7074, respectively;  Supplementary Figure 9 (supplemental_figure_9_4_5_ioac086.pdf)), further suggesting that Uchl1 may be playing a key role in oocyte development at the same time as these known master regulators.

UCHL1 has been studied cursorily in the context of oogenesis, though these studies utilized other model systems [12], knockdowns instead of genetic mutants [11, 27], or obsolete UCHL1-deficient mouse lines, which may not reflect loss of function of the protein [25, 26]. Furthermore, UCHL1 has never been studied in the context of ovarian reserve formation, leading us to explore its expression and localization in this context. Wild-type mouse ovaries were obtained from a variety of perinatal (Figure 1) as well as juvenile and adult (Figure 2) time points and immuno-stained for UCHL1. Perinatal mouse ovaries were also stained with an antibody against TRA98, an early germ cell marker [49], allowing us to observe the initiation of UCHL1 expression in this population. This staining revealed a protein localization pattern that is consistent with the scSEQ mRNA data, with oocyte-enriched expression through all stages of follicle development. While a low level of Uchl1 expression was observed in some somatic cells in our scSEQ dataset, this was not observed widely at the protein level, though some protein expression is apparent in the corpora lutea (CL) of adult ovaries (Figure 2,  Supplementary Figure 10 (supplemental_figure_10_4_5_ioac086.pdf)). From this staining, we also observed UCHL1 co-localization with early oocyte marker TRA98. Interestingly, it is apparent that at E18.5, only a subset of TRA98-positive oocytes are UCHL1-positive, suggesting an intriguing possibility that UCHL1 may represent a part of a survival signature in oocytes, as it is expressed in a subset of oocytes at the peak of perinatal oocyte attrition [3–6], and oocytes, which remain after this wave of attrition are nearly all UCHL1-positive (Figure 1). This ubiquitous, oocyte-enriched UCHL1 expression remains throughout juvenile and adult life, including in reproductive-aged 8 month old mice (Figure 2). Importantly, and as expected, UCHL1 knockout ovaries have no detectable UCHL1 expression ( Supplemental Figure 10A (supplemental_figure_10_4_5_ioac086.pdf)).

UCHL1 knockout mice are severely sub-fertile, with heterozygous mice exhibiting a less severe reduction in fertility

To better understand the role that UCHL1 may be playing in mammalian oocyte development, we obtained a UCHL1-heterozygous mouse line (B6.C-Uchl1^gad-J/J), which we bred to obtain all genotypes: B6.C-Uchl1 ^J /J (“wild-type”), B6.C-Uchl1^gad-J/J (“heterozygous”), or B6.C-Uchl1^gad-J/ ^gad-J (“knockout”). Mice of all genotypes were paired with verified C57BL/6 J male breeders in single-breeding-pair cages at 6 weeks of age. Mice were monitored for the presence of copulation plugs and normal mating behavior, evidence of pregnancy, the birth of pups, and the number of live pups per litter. Knockout mice appear to breed normally with repeated observation of copulation plugs (data not shown). As UCHL1 knockout mice develop severe motor neuron dysfunction between 6 and 7 months of age, breedings were only maintained until 5 months of age, at which time all mice were euthanized. Severe sub-fertility in knockout females was demonstrated with significantly fewer litters than wild-type animals (0.667 litters vs. 4.333 litters, respectively, P = 0.042). Knockout animals also produce significantly fewer pups per litter than wild-type animals (2.500 pups vs 8.769 pups, respectively, P = 0.0002), as well as fewer pups per litter than heterozygous animals (2.500 pups vs 6.625 pups, respectively, P= 0.008). Heterozygous animals also demonstrate a non-significant trend toward reduced litters and litter sizes (Figure 3).

UCHL1 knockout mice demonstrate estrous cyclicity disruption as well as reduced response to ovarian stimulation

The severe subfertility seen in knockout animals could be correlated with disrupted estrous cyclicity, reduced follicle abundance or recruitment, and reduced ovulations in these animals. Consistent with this hypothesis, estrous cyclicity analysis in all genotypes of mice revealed significantly disrupted cycles in both knockout and heterozygous animals. Mice were assessed for vaginal cytology daily for two weeks starting at 40 days of age, and percentage of time spent in each cycle stage was averaged between animals in a genotype. Interestingly, both heterozygotes and knockouts spent significantly less time in the follicular phase of proestrus (P = 0.0145 and P = 0.0085 respectively) and spent significantly more time in the secretory, luteal phase of diestrus (P = 0.0434 and P = 0.0456, respectively) than wild-type animals (Figure 4A). Additionally, knockout animals trended towards increased time spent in estrus, with several animals spending greater than 5 days in uninterrupted estrus, though this average did not reach statistical significance.

Figure 1.

UCHL1 protein expression in perinatal mouse ovaries. Ovaries were collected from mice at E18.5, PND0, PND1, and PND3, paraffin-embedded, sectioned in 5-µm sections, and stained with antibodies against UCHL1 (red) and early oocyte marker TRA98 (green), as well as DAPI (blue).

In addition to impaired hormonal cyclicity, knockout animals are also significantly less responsive to ovulation induction (Figure 4B). At 28 days of age, animals of all genotypes were hormonally stimulated using PMSG and HCG, and cumulus-oocyte complexes were collected from the ampullas of all mice. Significantly fewer oocytes were recovered from knockout animals compared to their heterozygous or wild-type counterparts (an average of 7, 23.2, and 27.8 oocytes per animal, respectively, P = 0.050), despite ovarian follicle counts appearing indistinguishable at this same time point (Figure 5A). To gain a better understanding of where in the ovulatory process a block to ovulation may be experienced, 1 month old wild-type and knockout animals were stimulated with PMSG alone to assess development of follicles to the antral stage, or with PMSG followed by HCG to assess follicle luteinization. As expected, given that knockout animals are able to ovulate a reduced number of oocytes and even produce small numbers of pups, pre-antral and antral follicles are present following PMSG stimulation, though at potentially slightly delayed stages of maturation compared to wild-type littermates. Interestingly, however, we do also observe the presence of luteinized unruptured follicles (LUFs) [50] in knockout ovaries following both PMSG and HCG stimulation, which are not observed in hormonally stimulated wild-type littermates ( Supplementary Figure 11A-D (supplemental_figure_11_4_6_ioac086.pdf)). Interestingly, we also observe significantly elevated LH levels in knockout animals during the follicular phase of proestrus in contrast to wild-type and heterozygous littermates (P = 0.0.266 and 0.0474, respectively,  Supplementary Figure 11E (supplemental_figure_11_4_6_ioac086.pdf)), and non-significant elevations in both FSH and the LH:FSH ratio ( Supplementary Figure 11F,G (supplemental_figure_11_4_6_ioac086.pdf)) again supporting a phenotype of endocrine dysfunction in these animals.

UCHL1-heterozygous and UCHL1-knockout ovaries contain normal follicle densities early in life and produce normal anti-Mullerian hormone, with ovarian function becoming compromised by middle age

To better understand the ovary-intrinsic effects of UCHL1 loss, ovaries from all genotypes of mice were collected at 1 month and 5 months of age and ovarian follicle counts were quantified. Follicle counts were normalized to the section area to account for size differences between different ovaries. Ovarian weights were also obtained from 5-month-old animals and compared to body weight as a readout of ovarian volume.

Figure 2.

UCHL1 protein expression in juvenile and adult mouse ovaries. Ovaries were collected from mice at PND21, 1 month, 5 months, and 8 months, paraffin-embedded, sectioned in 5-µm sections, and stained with antibody against UCHL1 (red) as well as DAPI (blue).

At 1 month of age, all genotypes possess similar densities of all follicle stages, suggesting initially normal development and maturation of ovarian follicles, despite qualitative appreciation of increased degenerating or atretic follicles in knockout ovaries (Figure 5A, C-E). While heterozygotes possessed significantly more primordial follicles than knockout animals per unit area at this age (P = 0.0308), this effect was not observed in wild-type or knockout animals. As an independent assessment of ovarian follicle endowment, additional mice were collected at 2.5 months, with whole blood collected for serum analysis of anti-Mullerian hormone (AMH). AMH is currently the gold standard for measuring oocyte endowment, as it is produced by the granulosa cells of growing follicles [51]. Consistent with our 1-month follicle density data, no differences were observed in AMH serum concentrations between genotypes at 2.5 months of age (Figure 5B).

Interestingly, however, UCHL1 knockout ovaries begin to demonstrate ovarian dysfunction just a few months later, with decreased ovarian volume (Figure 6B and C) as well as altered follicle densities compared to wild-type and knockout animals (Figure 6A, D-F). While primordial follicle densities are the only significantly enriched follicle stage in 5-month-old knockout ovaries (P = 0.0206 vs. wild-type animals, and P = 0.0443 vs. heterozygous animals), densities of all follicle stages trend towards greater enrichment in knockout ovaries. This is surprising, given the reduced ovarian volume at this time, with knockout ovaries being significantly smaller than wild-type ovaries when normalized for body weight (P = 0.050; Figure 6B and C). While this is an unexpected result given the retained follicle density in these animals, these data suggest a potential deficit in oocyte maturation or folliculogenesis.