Hostname: page-component-745bb68f8f-mzp66 Total loading time: 0 Render date: 2025-01-09T13:42:33.520Z Has data issue: false hasContentIssue false
  • English
  • Français

Effects of maternal liver abnormality on in vitro maturation of bovine oocytes

Published online by Cambridge University Press:  06 January 2025

Shiori Ashibe Open the ORCID record for Shiori Ashibe [Opens in a new window] ,
Yui Kobayashi ,
Shusuke Toishikawa  and
Yoshikazu Nagao Open the ORCID record for Yoshikazu Nagao [Opens in a new window]
Shiori Ashibe
Affiliation:
University Farm, Faculty of Agriculture, Utsunomiya University, Utsunomiya, Tochigi 321-4415, Japan
Yui Kobayashi
Affiliation:
University Farm, Faculty of Agriculture, Utsunomiya University, Utsunomiya, Tochigi 321-4415, Japan
Shusuke Toishikawa
Affiliation:
University Farm, Faculty of Agriculture, Utsunomiya University, Utsunomiya, Tochigi 321-4415, Japan
Yoshikazu Nagao*
Affiliation:
University Farm, Faculty of Agriculture, Utsunomiya University, Utsunomiya, Tochigi 321-4415, Japan
*
Corresponding author: Yoshikazu Nagao; Email: [email protected]
Rights & Permissions [Opens in a new window]

Summary

In cattle, maternal metabolic health has been suggested to influence oocyte and embryo quality. Here, we examined whether maternal liver abnormalities affected in vitro oocyte maturation by screening meiotic maturation, spindle morphology, actin filaments, and lysosomes. In oocytes from the abnormal liver group, the maturation rate (80.2%) was significantly lower compared to a control group with healthy livers (90.8%; P < 0.05). Mean spindle area in oocytes of the abnormal group (50.4 ± 3.4 μm2) was significantly larger than in the control (40.8 ± 1.6 μm2; P < 0.05). Likewise, mean spindle width in the abnormal group (8.8 ± 0.3 μm) was significantly larger than in the control group (7.8 ± 0.2 μm; P < 0.05). The proportion of cells with correctly aligned chromosomes in the abnormal group (48.0%) was significantly lower than in the control (78.3%; P < 0.05). The number of cortical actin filaments in mature oocytes of the abnormal group (299.3 ± 3.7) was significantly lower than in the control (314.7 ± 3.2; P < 0.05). The number of lysosomes in mature oocytes of the abnormal group (1363.6 ± 39.0) was significantly higher than in the control (1123.4 ± 26.3; P < 0.05). In conclusion, our findings indicate that the quality of in vitro matured oocytes is lower in cattle with liver abnormalities than in healthy cattle.

Keywords

bovinein vitro maturationmaternal liver abnormalityoocyteSpindle
Type
Research Article
Information
Zygote , First View , pp. 1 - 6
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press

Introduction

Advances in in vitro embryo production (IVP) have enabled this technology to be applied to livestock production. However, in cattle, only about 30% of oocytes used in IVP develop to the blastocyst stage (Lonergan and Fair, Reference Lonergan and Fair2016; Hansen, Reference Hansen2020). It is known that a range of factors can influence embryo development in vitro. For example, the use of supplements such as growth factors and antioxidants during in vitro maturation (IVM) can increase the rate of success in IVP (de Matos and Furnus, Reference de Matos and Furnus2000; Wasielak and Bogacki, Reference Wasielak and Bogacki2007; Wang et al., Reference Wang, Tian, Zhang, He, Ji, Li, Tan and Liu2014). In recent years, maternal metabolic health has also been implicated in oocyte and embryo quality, the so-called “Origins of Health and Disease (DOHaD)” hypothesis (Fleming et al., Reference Fleming, Velazquez and Eckert2015; Leroy et al., Reference Leroy, Valckx, Jordaens, De Bie, Desmet, Van Hoeck, Britt, Marei and Bols2015; Sauer, Reference Sauer2015). In the abattoir where we regularly collect bovine ovaries, the livers of approximately 81.6% of dairy cattle are discarded because of abnormalities such as hepatitis and liver degeneration (Table 1). High energy demand for milk production following parturition causes a negative energy balance that can trigger metabolic disorders and liver damage (Valour et al., Reference Valour, Hue, Degrelle, Déjean, Marot, Dubois, Germain, Humblot, Ponter, Charpigny and Grimard2013). In most instances, this liver damage is subclinical and is not the principal reason for slaughter (Lucy, Reference Lucy2001; González et al, Reference González, Muiño, Pereira, Campos and Benedito2011). The liver is an important organ in insulin-mediated metabolic regulation. In addition to its important role in systemic, glucose, and lipid homeostasis, it is also the primary site of synthesis of factors such as plasma proteins and insulin-like growth factors I and II (IGF-I and IGF-II) and their binding proteins, thereby affecting systemic metabolism and growth (Postic et al., Reference Postic, Dentin and Girard2004). IGF-I is involved in many processes during follicular development, oocyte maturation (Demeestere et al., Reference Demeestere, Gervy, Centner, Devreker, Englert and Delbaere2004), and subsequent embryonic development in many animals including bovine (Palma et al., Reference Palma, Müller and Brem1997) and porcine species (Xia et al., Reference Xia, Tekpetey and Armstrong1994), mice (O’Neill, Reference O’Neill1997), and humans (Lighten et al., Reference Lighten, Moore, Winston and Hardy1998). Therefore, liver disease may have a negative impact on reproduction. We previously reported that developmental potential is lower in oocytes derived from cattle with abnormal livers compared to those from cattle with healthy livers (Sarentonglaga et al., Reference Sarentonglaga, Ogata, Taguchi, Kato and Nagao2013; Sarentonglaga et al., Reference Sarentonglaga, Ashibe, Kato, Atchalalt, Fukumori and Nagao2021). Additionally, γ-glutamyl transpeptidase (γ-GTP) levels in follicular fluid (FF) are higher in cattle with an abnormal liver (Sarentonglaga et al., Reference Sarentonglaga, Ogata, Taguchi, Kato and Nagao2013; Sarentonglaga et al., Reference Sarentonglaga, Ashibe, Kato, Atchalalt, Fukumori and Nagao2021). To date, however, the influence of an abnormal liver on in vitro oocyte maturation in cattle has not been investigated.

Table 1. Number (%) of animals with liver disease among cattle sent for slaughter

Data from an annual report of the Meat Inspection Office, Yamanashi Prefecture, 2020. *Percentage of cattle inspected. #Percentage of the total number of cattle with liver disease.

The quality of the oocytes after in vitro maturation (IVM) is an important factor that determines subsequent developmental competence (Lonergan and Fair, Reference Lonergan and Fair2016). Oocyte maturation includes both nuclear and cytoplasmic modifications. During oocyte maturation, dynamic morphological changes are observed, such as cumulus expansion, formation of a spindle, and chromosome alignment on the spindle (Duan and Sun, Reference Duan and Sun2019). At meiosis, the morphology of the spindle and the rate of chromosome alignment can be adversely affected by temperature (Tamura et al., Reference Tamura, Huang and Marikawa2013), reactive oxygen species (Sasaki et al., Reference Sasaki, Hamatani, Kamijo, Iwai, Kobanawa, Ogawa, Miyado and Tanaka2019), and chemicals (Machtinger et al., Reference Machtinger, Combelles, Missmer, Correia, Williams, Hauser and Racowsky2013). Abnormalities in spindle morphology and chromosome alignment at meiosis are associated with impaired embryonic development after fertilization. It has also been reported that the cytoskeleton and organelles play an important role in oocyte maturation (Reader et al., Reference Reader, Stanton and Juengel2017). Spindle migration and positioning in the oocyte cortex are precisely controlled by actin filaments and are essential for polar body release; these critical functions ensure the asymmetric cytoplasmic division of the oocyte during meiotic maturation (Sun and Kim, Reference Sun and Kim2013; Almonacid et al., Reference Almonacid, Terret and Verlhac2014). Lysosomes also have an important role in oocyte meiosis, particularly in protein hydrolysis and signalling transduction (Perera and Zoncu, Reference Perera and Zoncu2016). Impairment of lysosomal storage and lysosome degradation are associated with several diseases and affect oocyte meiosis (Darios and Stevanin, Reference Darios and Stevanin2020).

The present study was initiated to examine the possible influence of maternal liver abnormality in cattle on in vitro oocyte maturation. Various aspects of maturing oocytes were screened, namely, meiotic maturation, spindle morphology, actin filaments, and lysosomes.

Materials and methods

Ovary collection and classification

Donor cow selection and diagnosis of liver abnormality were performed as described in our previous reports (Sarentonglaga et al., Reference Sarentonglaga, Ogata, Taguchi, Kato and Nagao2013; Sarentonglaga et al., Reference Sarentonglaga, Ashibe, Kato, Atchalalt, Fukumori and Nagao2021). In brief, ovaries were obtained from Holstein dairy cows from a slaughter house; any ovaries with abnormalities, such as follicular cysts and atrophy, were not included in the experiments. The livers of the cows were assessed by an experienced veterinarian and two groups of cows were established: a control group with normal livers; and a group with structural abnormality of the liver, such as fatty liver, hepatitis, or liver degeneration. The ovaries from the two groups were maintained at 15–20°C and transported to the laboratory in saline solution supplemented with 0.1% antibiotics and antimycotics (AB; Invitrogen, Carlsbad, CA, USA); the transport time was approximately 1 h from the slaughter house to the laboratory.

Oocyte collection and in vitro maturation (IVM)

Oocyte collection and IVM were carried out as previously described (Nagao et al., Reference Nagao, Saeki, Hoshi and Kainuma1994). In short, cumulus oocyte-complexes (COCs) were aspirated from 2–6 mm diameter follicles using a 20-gauge needle attached to a 5 ml syringe. Oocytes with three or more layers of compact cumulus cells and evenly granulated cytoplasm were selected as good quality and used for experiments. A pool of COCs were collected from cattle with healthy livers and low concentration of γ-GTP that were lower than 50 IU/L in the FF (Control group, mean: 29.7 ± 1.5 IU/L) and a pool of COCs were collected from cattle with liver disorders and high concentration of γ-GTP that were over 50 IU/L in the FF (Abnormal group, mean: 103.6 ± 13.8 IU/L) (Sarentonglaga et al., Reference Sarentonglaga, Ogata, Taguchi, Kato and Nagao2013). Selected oocytes were washed, placed in 50 µl drops of modified TCM-199 (m-TCM199) in culture dishes (Falcon351007, Becton, Dickinson and Company, Franklin Lakes, NJ, USA), covered with mineral oil (M8410, Sigma-Aldrich), and cultured for 24 h at 39°C under 5% CO2 in humidified air. The m-TCM199 consisted of HEPES-buffered medium 199 (No.12340, Invitrogen) supplemented with 0.1% (w/v) polyvinyl alcohol (PVA; P8136, Sigma-Aldrich), 0.5 mM sodium pyruvate (Nacalai Tesque, Tokyo, Japan), 1% AB, 0.02 AU/ml FSH (Antrin, Kyoritsu Seiyaku, Tokyo, Japan) and 1 µg/ml oestradiol-17 β (E2758, Sigma-Aldrich). Following maturation, oocytes were individually placed on microscope slides and fixed with 3:1 ethanol: acetic acid; the cells were stained with 1% orcein. Oocytes undergoing germinal vesicle breakdown and maturing to metaphase II (MII) were selected for detailed analysis.

Collection and analysis of follicular fluid (FF)

After aspiration of COCs, residual FF from each cow was centrifuged at 1000 × g at 4°C for 10 min. The concentration of γ-glutamyl transpeptidase (γ-GTP) in each FF sample was measured using the SPOTCHEMTM II assay (Glutamyl Transpeptidase Kit, ARKRAY, Kyoto, Japan) (Sarentonglaga et al., Reference Sarentonglaga, Ogata, Taguchi, Kato and Nagao2013).

Assessment of spindle morphology and chromosome alignment

MII oocytes were washed in PBS + PVA (1 mg/ml) at 37°C and fixed in 2% paraformaldehyde containing 0.1% Triton X-100 for 30 min. Fixed oocytes were then washed in PBS + PVA. For spindle and chromatin staining, oocytes were first blocked in PBS supplemented with 4% bovine serum albumin (BSA) for 30 min at room temperature and then incubated overnight at 37°C in mouse monoclonal anti-α-tubulin (diluted 1:500 in PBS + 1.5% BSA, Invitrogen, USA). After two washes in PBS + 1.5% BSA (15 min each), oocytes were incubated in Alexa Fluor 488-labelled goat anti-mouse secondary antibody (diluted 1:100, abcam) at 37°C for 1 h. Oocytes were then mounted on a glass slide with 4’,6-diamidino-2-phenylidole (DAPI; VECTASHIELD, VECTORLABS, USA) and analyzed using a FV10i FLUOVIEW (OLYMPUS, Japan). Spindles were analyzed as previously described (Ueno et al., Reference Ueno, Kurome, Ueda, Tomii, Hiruma and Nagashima2005) with regard to area, width, and length using the scale tool on the FL10-ASW3.1 (OLYMPUS, Japan) (Figure 2A). The meiotic stages of the oocytes were determined from the organization of the microfilaments, microtubules, and chromatin according to previously described criteria (Campen et al., Reference Campen, Kucharczyk, Bogin, Ehrlich and Combelles2018). Spindles with two defined and focused poles were classified as bipolar (Figure 3A). Spindles with two poles but with structural abnormalities (e.g. splayed or disorganized microtubule fibres, broad or unfocused poles, protrusions of the spindle) were classified as abnormal bipolar. Spindles that had no apparent organization, that were monopolar or tripolar were considered undeterminable. Chromosome alignment was determined in all MII oocytes regardless of spindle morphology. Chromosomes that were located at the equatorial metaphase plate were classified as aligned. Where one to six chromosomes were slightly displaced from the metaphase plate, the chromosomes were classified as mostly aligned. Where more than six chromosomes were displaced from the metaphase plate, the chromosomes were considered undeterminable.

Figure 1. Effect of liver abnormality on maturation rate of the bovine oocytes. Different letters indicate significant differences (P < 0.05). Data were obtained from 9 cows from the control group and 7 cows from the abnormal group. Number of oocytes cultured: control group, 109; abnormal group, 96.

Figure 2. (A) Immunofluorescence images of spindles in metaphase II oocytes. The dashed line shows (a) the area measured; the arrows indicate (b) width and (c) length of the spindle. (B) Comparison of spindle morphology in oocytes from the control and abnormal liver groups. Different letters indicate significant differences (P < 0.05). Error bars represent the standard error of the mean. Data were obtained from 5 cows from the control group and 4 cows from the abnormal group. Measurements were obtained from 27 oocytes from the control group and 13 oocytes from the abnormal group.

Figure 3. (A) Representative images of spindle and chromosome classifications in metaphase II oocytes. Chromosomes are shown in blue (left panels), microtubules are shown in green (centre panels), and merged images are shown in the right panels. (a) Bipolar spindle with aligned chromosomes. (b) Bipolar spindle with unfocused poles and a single misaligned chromosome. (c) Flattened bipolar spindle with extremely broad poles and aligned chromosomes. (d) Non-bipolar spindle with dispersed chromosomes. Bar (for all figures) = 5 μm. (B) Effect of liver abnormality on the frequencies of different spindle and chromosome types. Different letters indicate significant differences (P < 0.05). Data were obtained from 5 cows. We analyzed 46 oocytes from the control group and 25 oocytes from the abnormal group.

Assessment of cortical actin microfilaments

MII oocytes were washed in PBS + PVA (1 mg/ml) at 37°C and fixed in 2% paraformaldehyde containing 0.1% Triton X-100 for 30 min at 4°C. The fixed oocytes were then washed in PBS + PVA and then incubated in 1μg/ml Phalloidin (diluted 1:80 in PBS + PVA, Sigma, USA) at 37°C for 1 h. After two washes in PBS + PVA, oocytes were mounted on a glass slide DAPI and examined using an FV10i FLUOVIEW. Cortical actin filaments were evaluated as previously described (Feitosa et al., Reference Feitosa, Lopes, Visintin and Assumpção2020). Briefly, digital images of oocytes were analyzed using FL10-ASW3.1. The circular draw function was used to quantify the total actin pixel intensity (TAPI) of each oocyte and the medullar actin pixel intensity (MAPI; 70% of TAPI in the centre of the oocyte). TAPI and MAPI were used to calculate cortical actin pixel intensity (CAPI) where CAPI = [(TAPI - 0.7 × MAPI)/0.3]. Cortical actin pixel intensity was normalized by the ratio cortex:medullar pixel intensity (Figure 4A).

Figure 4. (A) Measurement of cortical actin filament levels in metaphase II oocytes. TAPI = Total actin pixel intensity (orange dashed line), MAPI = Medullar actin pixel intensity (white dashed line), CAPI = Cortical actin pixel intensity. (B) Representative images of cortical actin filament staining of oocytes. Bar = 50μm. (C) Comparison of cortical actin filament levels in oocytes of the control and abnormal liver groups. Different letters indicate significant differences (P < 0.05). Mean fluorescence intensity (MFI) indicates cortical actin levels. Error bars indicate the standard error of the mean. Data were obtained from 3 cows. Measurements were made in 41 oocytes from the control group and 19 oocytes from the abnormal group.

Assessment of lysosomes

MII oocytes were incubated in modified synthetic oviduct fluid supplemented with 0.1% (w/v) PVA (SOF-PVA) and 1 μM Lyso Tracker (Invitrogen, USA) for 30 min at 37°C. The oocytes were then washed twice in PBS + PVA, transferred to a glass-bottomed dish (Matsunami Glass, Osaka, Japan) and immediately viewed under a laser confocal fluorescence microscope (FV10i FLUOVIEW). Digital images were analyzed using FL10-ASW3.1 to determine the intensity of fluorescence and provide a measure of lysosome levels in each oocyte.

Statistical analysis

Differences in maturation rates, spindle morphology, and chromosome alignment were compared between the two groups of cattle using X 2 tests. Spindle size, cortical actin microfilament and lysosome data were analyzed using analyses of variance with F-tests and t-tests. In all experiments, values were considered to be significantly different when P < 0.05.

Results

The rates of oocyte maturation in the two groups of cattle are shown in Figure 1. A significantly lower rate of maturation was found in the abnormal group compared to the control group (80.2% vs 90.8%, respectively; P < 0.05).

The mean area of the spindle in oocytes from the abnormal group was larger than in the control group (50.4 ± 3.4 μm2 vs 40.8 ± 1.6 μm2, respectively; P < 0.05; Figure 2B). Furthermore, the mean width of the spindle in oocytes from the abnormal group was larger than in the control group (8.8 ± 0.3 μm vs 7.8 ± 0.2 μm, respectively; P < 0.05). However, oocytes from the two groups showed no significant differences in spindle length (5.7 ± 0.2 μm in the abnormal group vs 6.1 ± 0.3 μm in the normal group, respectively).

There were no significant differences in the frequencies of oocytes with normal bipolar spindles or abnormal bipolar spindles in the two cattle groups (Figure 3B). However, oocytes from the abnormal liver group had had a lower rate of aligned chromosomes than in the control group (40.8% vs 78.3%, respectively; P < 0.05).

The levels of cortical actin filaments in oocytes of the two groups were assessed using mean fluorescence intensity (MFI; Figure 4C). Oocytes from the abnormal group showed a significantly lower MFI than the control group (299.3 ± 3.7 vs 314.7 ± 3.2, respectively; P < 0.05). Oocytes from the abnormal group had a higher lysosomal MFI than the control group (1363.6 ± 39.0 vs 1123.4 ± 26.3; P < 0.05; Figure 5B).

Figure 5. (A) Representative images of lysosome staining of oocytes. Bar = 50μm. (B) Mean fluorescence intensity (MFI) of lysosomes in metaphase II oocytes from control and abnormal liver groups. Different letters indicate significant differences (P < 0.05). Error bars show the standard error of the mean. Data were obtained from 4 cows. Measurements were made in 52 oocytes from the control group and 49 oocytes from the abnormal group.

Discussion

We previously reported that γ-GTP concentration in FF from cattle with abnormal livers was higher than in cattle with healthy livers. Moreover, the developmental potential of oocytes from cattle with abnormal livers was lower than for oocytes derived from healthy cattle (Sarentonglaga et al., Reference Sarentonglaga, Ogata, Taguchi, Kato and Nagao2013; Sarentonglaga et al., Reference Sarentonglaga, Ashibe, Kato, Atchalalt, Fukumori and Nagao2021). These results indicated that liver abnormalities may impair IVM and reduce the rate of production of blastocysts. Thus, in the present study, we focused on maturation of oocytes from dairy cattle with a liver disorder, which was confirmed by the elevated γ-GTP level in FFs (Supplementary 1). Various factors influence oocyte quality and thereby affect the success of IVP (Lonergan and Fair, Reference Lonergan and Fair2016). For example, delayed progression of nuclear maturation in oocytes derived from cattle with abnormal livers has been reported (Iwata et al., Reference Iwata, Tanaka, Kanke, Sakaguchi, Shibano, Kuwayama and Monji2010). Tanaka et al. (Reference Tanaka, Takeo, Monji, Kuwayama and Iwata2014) also reported similar results to (Iwata et al., Reference Iwata, Tanaka, Kanke, Sakaguchi, Shibano, Kuwayama and Monji2010); however, nuclear maturation rates did not differ significantly after 21 h IVM. In this study, we used dairy cattle with liver disease and high γ-GTP levels in FFs and found that maturation rates were significantly lower compared to cows with healthy livers. The liver plays an important role as the primary site of IGF-I synthesis by stimulation of growth hormone (Matsumoto et al., Reference Matsumoto, Koga, Kasayama, Fukuoka, Iguchi, Odake, Yoshida, Bando, Suda, Nishizawa, Takahashi, Ogawa and Takahashi2018). IGF-I is involved in many metabolic pathways during follicular development, oocyte maturation, and embryonic development (Xia et al., Reference Xia, Tekpetey and Armstrong1994; O’Neill, Reference O’Neill1997; Palma et al., Reference Palma, Müller and Brem1997; Lighten et al., Reference Lighten, Moore, Winston and Hardy1998; Demeestere et al., Reference Demeestere, Gervy, Centner, Devreker, Englert and Delbaere2004). Supplementation of IGF-I during IVM promotes steroid synthesis in granulosa cells (Mani et al., Reference Mani, Fenwick, Cheng, Sharma, Singh and Wathes2010) and decreases the rate of apoptosis in oocytes (Wasielak and Bogacki, Reference Wasielak and Bogacki2007). Furthermore, it has been shown that γ-GTP levels in the blood are negatively correlated with IGF-I levels in cows with liver disorders (Matsumoto et al., Reference Matsumoto, Koga, Kasayama, Fukuoka, Iguchi, Odake, Yoshida, Bando, Suda, Nishizawa, Takahashi, Ogawa and Takahashi2018). These findings suggest that a high concentration of γ-GTP in FF causes a reduction in the levels of IGF-I and consequently may decrease maturation rates.

We found that oocytes from the abnormal group had a significantly larger mean spindle area. Additionally, mean width of the spindle was significantly larger in oocytes of the abnormal group. Ueno et al. (Reference Ueno, Kurome, Ueda, Tomii, Hiruma and Nagashima2005) reported that maturation conditions influenced the morphogenesis of MII spindles in porcine oocytes. Machtinger et al. (Reference Machtinger, Combelles, Missmer, Correia, Williams, Hauser and Racowsky2013) further reported that exposure to 200 ng/ml of Bisphenol-A increased the width of spindles in human oocytes; bisphenol-A treatment also significantly increased the frequencies of oocytes with spindle abnormalities and dispersed chromosomes (Campen et al., Reference Campen, Kucharczyk, Bogin, Ehrlich and Combelles2018). Here, we found that frequency of oocytes with correctly aligned chromosomes was significantly lower in the abnormal group. In the mouse, a change in spindle integrity and chromosome alignment was found in oocytes exposed to reactive oxygen species (ROS) (Zhang et al., Reference Zhang, Wu, Lu, Guo and Ma2006). Wang et al. (Reference Wang, Dong, Bai, Yuan, Xu, Cao and Liu2017) reported that exogenous or endogenous sources of ROS could induce significant mitotic delays due to abnormal mitotic spindle assembly in HeLa cells. Moreover, the frequencies of misaligned chromosomes and multipolar spindles at metaphase are substantially increased in the presence of H2O2 (Wang et al., Reference Wang, Dong, Bai, Yuan, Xu, Cao and Liu2017). In our previous study, we found that the levels of ROS in oocytes were significantly higher in the abnormal group (Sarentonglaga et al., Reference Sarentonglaga, Ashibe, Kato, Atchalalt, Fukumori and Nagao2021). The present study might have occurred in oocytes from the abnormal group due to high levels of ROS, resulting in the occurrence of abnormal spindle morphology. Moreover, in our pre-experiment, the rates of development to the blastocyst stage in in vitro fertilization were significantly lower (P < 0.05) in the abnormal group (10.8%) than that in the control group (24.6%). Since abnormal spindle morphology may result in incorrect chromosome segregation and subsequent aneuploidy, spindle morphology is an important contributor to oocyte quality and subsequent embryonic developmental potential. Our findings support the view that liver abnormalities causing high γ-GTP concentration in FF have a negative influence on spindle architecture and chromosome organization during oocyte maturation.

Actin filaments that are located near the plasma membrane are important for progression of nuclear and cytoplasmic maturation in mammalian oocytes (Sun and Schatten, Reference Sun and Schatten2006). We found here that oocytes from the abnormal group had a significantly lower mean intensity of fluorescence; this indicates a lower level of cortical actin filaments in these oocytes. A previous study reported that a lower fluorescence intensity of cortical actin filaments in oocytes exposed to 2 or 4 h of heat shock (Ju and Tseng, Reference Ju and Tseng2004). In rabbits, it has been reported that hyperthermal stimulation during embryonic development destabilizes F-actin, resulting in failure of embryonic morphogenesis and apoptosis (Makarevich et al., Reference Makarevich, Olexiková, Chrenek, Kubovicová, Fréharová and Pivko2007). The present study indicates that healthy livers and low γ-GTP levels in the FF play critical roles in determining the F-actin structures in oocytes. Egerszegi et al. (Reference Egerszegi, Somfai, Nakai, Tanihara, Noguchi, Kaneko, Nagai, Rátky and Kikuchi2013) found that a higher frequency of spindle and actin filament damage was associated with a lower frequency of 2nd polar body formation in frozen-thawed oocytes. We found here that oocytes from cows with liver abnormalities and high γ-GTP concentrations in the FF had reduced actin filament formation, suggesting that actin abnormalities could lead to abnormal spindle formation and blockage of meiosis in bovine oocytes. We also examined lysosome levels in oocytes using fluorescence intensities and found that oocytes of the abnormal group had significantly higher levels of lysosomes. Wang et al. (Reference Wang, Xu, Ju, Liu and Sun2021) reported that lysosome fluorescence intensity was higher in mouse oocytes after Fumonisin B1 treatment. Lysosomes have been suggested to sequester macromolecules from the endocytosis and autophagy pathways for degradation and recycling and to play important roles in regulating oocyte maturation and development (Miao et al., Reference Miao, Liu, Liu, Liu, Wang, Du and Yang2019). Lysosomes can increase in number to fulfil different cellular demands, such as autophagy due to starvation and the distribution of lysosomes to daughter cells during cell division (Yang and Wang, Reference Yang and Wang2021). In the present study, it is possible that oocytes from the abnormal liver group were starving and that the autophagy pathway increased the amount of nutrition needed for embryonic development. As described above, we also found oocytes from the abnormal liver group had altered lysosomal function, which might be related to autophagy pathways.

In conclusion, the present study showed that oocyte maturation potential was lower in dairy cattle with liver abnormalities than in healthy cattle and highlighted the possible influence of spindle morphology, actin filaments and lysosomes as factors that influence the success of in vitro maturation.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0967199424000352

Acknowledgements

We thank Dr B. Sarentonglaga of Utsunomiya University Farm and Dr T. Kobayashi of The Institute of Medical Science of Tokyo University for their invaluable advice. The authors would like to thank Chikusei Meat Center and Nakao Chikusan Co. Ltd. for providing the ovaries used in this study.

Funding

This research received no specific grant from any funding agency, commercial, or not-for-profit sectors.

Competing interests

None.

Footnotes

*

Current address: Sendai ART Clinic, Sendai, Miyagi 983-0864, Japan

References

Almonacid, M., Terret, M.É., Verlhac, M.H. (2014) Actin-based spindle positioning: new insights from female gametes. Journal of Cell Science 127(Pt 3), 477483.Google ScholarPubMed
Campen, K.A., Kucharczyk, K.M., Bogin, B., Ehrlich, J.M., Combelles, C.M.H. (2018) Spindle abnormalities and chromosome misalignment in bovine oocytes after exposure to low doses of bisphenol A or bisphenol S. Human Reproduction (Oxford, England) 33(5), 895904.CrossRefGoogle ScholarPubMed
de Matos, D.G., Furnus, C.C. (2000) The importance of having high glutathione (GSH) level after bovine in vitro. maturation on embryo development effect of beta-mercaptoethanol, cysteine and cystine. Theriogenology 53(3), 761771.CrossRefGoogle ScholarPubMed
Demeestere, I., Gervy, C., Centner, J., Devreker, F., Englert, Y., Delbaere, A. (2004) Effect of insulin-like growth factor-I during preantral follicular culture on steroidogenesis, in vitro oocyte maturation, and embryo development in mice. Biology of Reproduction 70(6), 16641669.CrossRefGoogle ScholarPubMed
Duan, X., Sun, S.C. (2019) Actin cytoskeleton dynamics in mammalian oocyte meiosis. Biology of Reproduction 100(1), 1524.CrossRefGoogle ScholarPubMed
Darios, F., Stevanin, G. (2020) Impairment of lysosome function and autophagy in rare neurodegenerative diseases. Journal of Molecular Biology 432(8), 27142734.CrossRefGoogle ScholarPubMed
Egerszegi, I., Somfai, T., Nakai, M., Tanihara, F., Noguchi, J., Kaneko, H., Nagai, T., Rátky, J., Kikuchi, K. (2013) Comparison of cytoskeletal integrity, fertilization and developmental competence of oocytes vitrified before or after in vitro maturation in a porcine model. Cryobiology 67(3), 287292.CrossRefGoogle ScholarPubMed
Fleming, T.P., Velazquez, M.A., Eckert, J.J. (2015) Embryos, DOHaD and David Barker. Journal of Developmental Origins of Health and Diseases 6(5), 377383.CrossRefGoogle ScholarPubMed
Feitosa, W.B., Lopes, E., Visintin, J.A., Assumpção, M.E.O.D. (2020) Endoplasmic reticulum distribution during. bovine oocyte activation is regulated by protein kinase C via actin filaments. Journal of Cellular Physiology 235(7-8), 58235834.CrossRefGoogle ScholarPubMed
González, F.D., Muiño, R., Pereira, V., Campos, R., Benedito, J.L. (2011) Relationship among blood indicators of lipomobilization and hepatic function during early lactation in high-yielding dairy cows. Journal of Veterinary Science 12(3), 251255.CrossRefGoogle ScholarPubMed
Hansen, P.J. (2020) The incompletely fulfilled promise of embryo transfer in cattle-why aren’t pregnancy rates. greater and what can we do about it? Journal of Animal Science 98(11), skaa288.CrossRefGoogle Scholar
Iwata, H., Tanaka, H., Kanke, T., Sakaguchi, Y., Shibano, K., Kuwayama, T., Monji, Y. (2010) Follicle. growth and oocyte developmental competence in cows with liver damage. Reproduction in Domestic Animals 45(5), 888895.Google ScholarPubMed
Ju, J.C., Tseng, J.K. (2004) Nuclear and cytoskeletal alterations of in vitro matured porcine oocytes under. hyperthermia. Molecular Reproduction and Development 68(1), 125133.CrossRefGoogle ScholarPubMed
Lighten, A.D., Moore, G.E., Winston, R.M., Hardy, K. (1998) Routine addition of human insulin-like growth factor-I ligand could benefit clinical in-vitro fertilization culture. Human Reproduction (Oxford, England) 13(11), 31443150.CrossRefGoogle ScholarPubMed
Lucy, M.C. (2001) Reproductive loss in high-producing dairy cattle: where will it end? Journal of Dairy Science 84(6), 12771293.CrossRefGoogle ScholarPubMed
Leroy, J.L., Valckx, S.D., Jordaens, L., De Bie, J., Desmet, K.L., Van Hoeck, V., Britt, J.H., Marei, W.F., Bols, P.E. (2015) Nutrition and maternal metabolic health in relation to oocyte and embryo quality: critical views on what we learned from the dairy cow model. Reproduction Fertility and Development 27(4), 693703.CrossRefGoogle ScholarPubMed
Lonergan, P., Fair, T. (2016) Maturation of oocytes in vitro. Annual Review of Animal Biosciences 4, 255268.CrossRefGoogle ScholarPubMed
Makarevich, A.V., Olexiková, L., Chrenek, P., Kubovicová, E., Fréharová, K., Pivko, J. (2007) The effect of hyperthermia in vitro on vitality of rabbit preimplantation embryos. Physiological Research 56(6), 789796.CrossRefGoogle ScholarPubMed
Mani, A.M., Fenwick, M.A., Cheng, Z., Sharma, M.K., Singh, D., Wathes, D.C. (2010) IGF1 induces up-regulation of steroidogenic and apoptotic regulatory genes via activation of phosphatidylinositol-dependent kinase/AKT in bovine granulosa cells. Reproduction 139(1), 139151.CrossRefGoogle ScholarPubMed
Machtinger, R., Combelles, C.M., Missmer, S.A., Correia, K.F., Williams, P., Hauser, R., Racowsky, C. (2013) Bisphenol-A and human oocyte maturation in vitro. Human Reproduction (Oxford, England) 28(10), 27352745.CrossRefGoogle ScholarPubMed
Matsumoto, R., Koga, M., Kasayama, S., Fukuoka, H., Iguchi, G., Odake, Y., Yoshida, K., Bando, H., Suda, K., Nishizawa, H., Takahashi, M., Ogawa, W., Takahashi, Y. (2018) Factors correlated with serum insulin-like growth factor-I levels in health check-up subjects. Growth Hormone & IGF Research 40, 5560.CrossRefGoogle ScholarPubMed
Miao, J.K., Liu, Y.H., Liu, S., Liu, X.M., Wang, P.C., Du, Z.Q., Yang, C.X. (2019) Lysosomal dysfunction disturbs. porcine oocyte maturation and developmental capacity by disorganizing chromosome/cytoskeleton and activating autophagy/apoptosis. Theriogenology 140, 4451.CrossRefGoogle ScholarPubMed
Nagao, Y., Saeki, K., Hoshi, M., Kainuma, H. (1994) Effects of oxygen concentration and oviductal epithelial tissue on the development of in vitro matured and fertilized bovine oocytes cultured in protein-free medium. Theriogenology 41, 681687.CrossRefGoogle ScholarPubMed
O’Neill, C. (1997) Evidence for the requirement of autocrine growth factors for development of mouse. preimplantation embryos in vitro. Biology of Reproduction 56(1), 229237.CrossRefGoogle ScholarPubMed
Palma, G.A., Müller, M., Brem, G. (1997) Effect of insulin-like growth factor I (IGF-I) at high concentrations on blastocyst development of bovine embryos produced in vitro. Journal of Reproduction and Fertility 110(2), 347353.CrossRefGoogle ScholarPubMed
Postic, C., Dentin, R., Girard, J. (2004) Role of the liver in the control of carbohydrate and lipid homeostasis. Diabetes & Metabolism 30(5), 398408.CrossRefGoogle ScholarPubMed
Perera, R.M., Zoncu, R. (2016) The lysosome as a regulatory hub. Annual Review of Cell and Developmental Biology 32, 223253.CrossRefGoogle ScholarPubMed
Reader, K.L., Stanton, J.L., Juengel, J.L. (2017) The role of oocyte organelles in determining developmental competence. Biology 6(3), 35.CrossRefGoogle ScholarPubMed
Sun, Q.Y., Schatten, H. (2006) Regulation of dynamic events by microfilaments during oocyte maturation and fertilization. Reproduction 131(2), 193205.CrossRefGoogle ScholarPubMed
Sarentonglaga, B., Ogata, K., Taguchi, Y., Kato, Y., Nagao, Y. (2013) The developmental potential of oocytes is impaired in cattle with liver abnormalities. The Journal of Reproduction and Development 59, 168e73.CrossRefGoogle ScholarPubMed
Sun, S.C., Kim, N.H. (2013) Molecular mechanisms of asymmetric division in oocytes. Microscopy and Microanalysis 19(4), 883897.CrossRefGoogle ScholarPubMed
Sauer, M.V. (2015) Reproduction at an advanced maternal age and maternal health. Fertility and Sterility 103(5), 11361143.CrossRefGoogle Scholar
Sasaki, H., Hamatani, T., Kamijo, S., Iwai, M., Kobanawa, M., Ogawa, S., Miyado, K., Tanaka, M. (2019) Impact. of oxidative stress on age-associated decline in oocyte developmental competence. Frontiers in Endocrinology 10, 811.CrossRefGoogle ScholarPubMed
Sarentonglaga, B., Ashibe, S., Kato, T., Atchalalt, K., Fukumori, R., Nagao, Y. (2021) The effects of glutathione ethyl ester in in vitro maturation on the developmental ability of oocytes derived from cattle with liver abnormalities. Theriogenology 170, 8590.CrossRefGoogle ScholarPubMed
Tamura, A.N., Huang, T.T., Marikawa, Y. (2013) Impact of vitrification on the meiotic spindle and components of the microtubule-organizing center in mouse mature oocytes. Biology of Reproduction 89(5), 112.CrossRefGoogle ScholarPubMed
Tanaka, H., Takeo, S., Monji, Y., Kuwayama, T., Iwata, H. (2014) Maternal liver damage delays meiotic resumption in bovine oocytes through impairment of signalling cascades originated from low p38MAPK activity in cumulus cells. Reproduction in Domestic Animals 49(1) 101108.CrossRefGoogle ScholarPubMed
Ueno, S., Kurome, M., Ueda, H., Tomii, R., Hiruma, K., Nagashima, H. (2005) Effects of maturation conditions on spindle morphology in porcine MII oocytes. The Journal of Reproduction and Development 51(3), 405410.CrossRefGoogle ScholarPubMed
Valour, D., Hue, I., Degrelle, S.A., Déjean, S., Marot, G., Dubois, O., Germain, G., Humblot, P., Ponter, A.A., Charpigny, G., Grimard, B. (2013) Pre- and post-partum mild underfeeding influences gene expression in the reproductive tract of cyclic dairy cows. Reproduction in Domestic Animals 48(3), 484499.CrossRefGoogle ScholarPubMed
Wasielak, M., Bogacki, M. (2007) Apoptosis inhibition by insulin-like growth factor (IGF)-I during in vitro maturation of bovine oocytes. The Journal of Reproduction and Development 53(2), 419426.CrossRefGoogle ScholarPubMed
Wang, F., Tian, X., Zhang, L., He, C., Ji, P., Li, Y., Tan, D., Liu, G. (2014) Beneficial effect of resveratrol on bovine oocyte maturation and subsequent embryonic development after in vitro fertilization. Fertility and Sterility 101(2), 577586.CrossRefGoogle ScholarPubMed
Wang, G.F., Dong, Q., Bai, Y., Yuan, J., Xu, Q., Cao, C., Liu, X. (2017) Oxidative stress induces mitotic arrest by inhibiting Aurora A-involved mitotic spindle formation. Free Radical Biology and Medicine 103, 177187.CrossRefGoogle ScholarPubMed
Wang, Y., Xu, Y., Ju, J.Q., Liu, J.C., Sun, S.C. (2021) Fumonisin B1 exposure deteriorates oocyte quality by inducing organelle dysfunction and DNA damage in mice. Ecotoxicology and Environment Safety 223, 112598.CrossRefGoogle ScholarPubMed
Xia, P, Tekpetey, FR, Armstrong, D.T. (1994) Effect of IGF-I on pig oocyte maturation, fertilization, and early embryonic development in vitro, and on granulosa and cumulus cell biosynthetic activity. Molecular Reproduction and Development 38(4), 373379.CrossRefGoogle ScholarPubMed
Yang, C., Wang, X. (2021) Lysosome biogenesis: Regulation and functions. The Journal of Cell Biology 220(6), e202102001.CrossRefGoogle ScholarPubMed
Zhang, X, Wu, X.Q., Lu, S., Guo, Y.L., Ma, X. (2006) Deficit of mitochondria-derived ATP during oxidative stress impairs mouse MII oocyte spindles. Cell Research 16(10), 841850.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Number (%) of animals with liver disease among cattle sent for slaughter

Figure 1

Figure 1. Effect of liver abnormality on maturation rate of the bovine oocytes. Different letters indicate significant differences (P < 0.05). Data were obtained from 9 cows from the control group and 7 cows from the abnormal group. Number of oocytes cultured: control group, 109; abnormal group, 96.

Figure 2

Figure 2. (A) Immunofluorescence images of spindles in metaphase II oocytes. The dashed line shows (a) the area measured; the arrows indicate (b) width and (c) length of the spindle. (B) Comparison of spindle morphology in oocytes from the control and abnormal liver groups. Different letters indicate significant differences (P < 0.05). Error bars represent the standard error of the mean. Data were obtained from 5 cows from the control group and 4 cows from the abnormal group. Measurements were obtained from 27 oocytes from the control group and 13 oocytes from the abnormal group.

Figure 3

Figure 3. (A) Representative images of spindle and chromosome classifications in metaphase II oocytes. Chromosomes are shown in blue (left panels), microtubules are shown in green (centre panels), and merged images are shown in the right panels. (a) Bipolar spindle with aligned chromosomes. (b) Bipolar spindle with unfocused poles and a single misaligned chromosome. (c) Flattened bipolar spindle with extremely broad poles and aligned chromosomes. (d) Non-bipolar spindle with dispersed chromosomes. Bar (for all figures) = 5 μm. (B) Effect of liver abnormality on the frequencies of different spindle and chromosome types. Different letters indicate significant differences (P < 0.05). Data were obtained from 5 cows. We analyzed 46 oocytes from the control group and 25 oocytes from the abnormal group.

Figure 4

Figure 4. (A) Measurement of cortical actin filament levels in metaphase II oocytes. TAPI = Total actin pixel intensity (orange dashed line), MAPI = Medullar actin pixel intensity (white dashed line), CAPI = Cortical actin pixel intensity. (B) Representative images of cortical actin filament staining of oocytes. Bar = 50μm. (C) Comparison of cortical actin filament levels in oocytes of the control and abnormal liver groups. Different letters indicate significant differences (P < 0.05). Mean fluorescence intensity (MFI) indicates cortical actin levels. Error bars indicate the standard error of the mean. Data were obtained from 3 cows. Measurements were made in 41 oocytes from the control group and 19 oocytes from the abnormal group.

Figure 5

Figure 5. (A) Representative images of lysosome staining of oocytes. Bar = 50μm. (B) Mean fluorescence intensity (MFI) of lysosomes in metaphase II oocytes from control and abnormal liver groups. Different letters indicate significant differences (P < 0.05). Error bars show the standard error of the mean. Data were obtained from 4 cows. Measurements were made in 52 oocytes from the control group and 49 oocytes from the abnormal group.

Supplementary material: File

Ashibe et al. supplementary material

Ashibe et al. supplementary material
Download Ashibe et al. supplementary material(File)
File 13.1 KB