1 Maria Infertility Hospital and 2 Department of Animal Science, Korea University, Seoul, South Korea
3 To whom correspondence should be addressed at: McGill Reproductive Center, Department of Obstetrics and Gynecology, Royal Victoria Hospital, McGill University, Montreal, Quebec H3A 1A1. Email: weon-young.son{at}muhc.mcgill.ca
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Abstract |
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Key words: cumulus cell pattern/HCG/human/immature oocytes/IVM
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Introduction |
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A typical polycystic ovary (PCO) has several antral follicles up to 10 mm in diameter around the periphery of the ovary. Although these follicles are not actively growing, they contain immature oocytes, which may be capable of further development (Polson et al., 1988
; Clayton et al., 1992
; Trounson et al., 1994
; Barnes et al., 1996
). However, the rates of maturation, fertilization and cleavage of immature oocytes obtained from PCOS patients are lower than those obtained from non-PCOS patients (Barnes et al., 1996
; Trounson et al., 1998
), which is thought to be related to a low pregnancy rate.
To compensate for these problems, several attempts have been made to improve the viability of IVM oocytes by gonadotrophin stimulation prior to oocyte collection (Wynn et al., 1998; Jaroudi et al., 1999
). Recently, Chian et al. (2000)
reported that higher rates of oocyte maturation and pregnancies were achieved in patients with PCOS by HCG priming. It was reported previously that oocytes with various cumulus cell (CC) patterns were collected at the time of oocyte retrieval in HCG-primed IVM cycles (Son et al., 2001
). However, no studies on the maturation of oocytes obtained from HCG-primed IVM cycles of PCOS women based on CC patterns have been reported.
The maturation of oocytes depends on the communication between follicular cells and on the presence of gonadotrophin receptors. CCs respond to gonadotrophin and secrete various substances that play a role in nuclear and cytoplasmic maturation (Chian et al., 1999). FSH is important for the development of pre-ovulatory follicles in vivo (Macklon and Fauser, 2000
) and for induction of LH receptors (LH-Rs) (Gougeon, 1996
). Furthermore, in vitro studies have shown that meiotic resumption in cumulusoocyte complexes (COCs) was induced by epidermal growth factor (EGF) (Gomez et al., 1993
; Kobayashi et al., 1994
; Lorenzo et al., 1994
). It was also reported that EGF alone or associated with gonadotrophin induces cumulus expansion and promotes maturation of bovine and mouse oocytes during in vitro culture (Lonergan et al., 1996
; De La Fuente et al., 1999
). Based on these studies, it is hypothesized that FSH receptor (FSH-R), LH-R and EGF-receptor (EGF-R) in CCs account for the high maturation rate of oocytes obtained from PCOS patients in IVM cycles with HCG priming prior to oocyte collection. Therefore, the aims of this study were to compare IVM and blastocyst development of the immature oocytes obtained from HCG-primed IVM cycles of PCOS women with respect to CC patterns and to investigate mRNA expression of FSH-R, LH-R and EGF-R in each CC pattern.
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Materials and methods |
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Retrieval of immature oocytes
After 36 h, oocytes were aspirated with a 19-gauge aspiration needle (Cook, Eight Mile Plains, Queensland, Australia) under the guidance of transvaginal ultrasound. A portable aspiration pump was used with a pressure of between 80 and 100 mmHg. The aspirates were collected in tubes containing pre-warmed heparinized Ham's F-10 medium that contained bicarbonate and HEPES supplemented with 0.3% human serum albumin. Follicular aspirates were placed into a 70 µm pore size filter (Becton Dickinson, NJ) which had been pre-rinsed with the medium. The filtrate was washed several times with medium by vigorous pipetting using a 10 ml serological pipette (Becton Dickinson) to remove erythrocytes and small cellular debris. The retained cells were resuspended in the medium. The COCs were then isolated under a stereomicroscope and washed twice in the same medium. All COC handling procedures were conducted in a mini-chamber under a 5% CO2 atmosphere at 37°C.
IVM and embryo culture
The isolated COCs were divided into three groups according to the CC patterns: oocytes with dispersed CCs (group A), with compacted CCs (group B) and with sparse CCs (group C). Dispersed CCs were enclosed by an expanded CC and one or two layers of corona cells around germinal vesicle (GV) oocytes. Compacted CCs possessed 45 layers of corona cells and CCs completely covering the GV oocytes. Sparse CCs had very few coronal cells covering the zona pellucida of GV oocytes (Figure 1). The atretic and denuded COCs were discarded. The mature eggs collected at the time of egg collection were not included in this study. The COCs of each group at the GV stage were cultured separately in 1 ml of IVM medium in a 4-well culture dish. The IVM medium consisted of YS medium (Yoon et al., 2001) supplemented with 30% heat-inactivated human follicular fluid, 1 IU/ml FSH, 10 IU/ml HCG and 10 ng/ml recombinant human (rh)EGF (Daewoong Pharmaceutical Co., Korea) (Son et al., 2002
). The human follicular fluid was prepared using the method described by Chi et al. (1998)
. The COC oocytes were cultured in IVM medium at 37°C in 5% CO2, 5% O2 and 90% N2. After 24 h culture, the oocytes were denuded of CCs with 0.03% hyaluronidase (Sigma Chemical Co., St Louis, MO) and mechanical pipetting. Oocyte nuclear maturation was assessed from the presence of the first polar body under the dissecting microscope. Following examination, immature oocytes remaining at GV or metaphase I (MI) stage were cultured in the same medium and the meiotic status re-examined at 48 h and finally at 72 h of culture. ICSI was used to fertilize the mature oocytes recovered from each group. Fertilization was assessed 1719 h after insemination for the appearance of two distinct pronuclei (2PN) and two polar bodies. The zygotes were co-cultured with CCs in 10 µl YS medium supplemented with 10% human follicular fluid (Yoon et al., 2001
). The CCs for co-culture were prepared using the method reported by Yoon et al. (2001)
. Embryos were cultured on day 4 or day 6 after oocyte retrieval. Blastocyst culture was performed in each group which had
3 good-quality embryos on day 2 after insemination. Of 40 IVM cycles, six cycles were transferred at blastocyst stage on day 6. In the cycles, blastocyst development was examined among embryos derived from three groups.
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RNA isolation and reverse transcription
Total RNA from CCs of each group was isolated using an RNeasy RNA isolation kit (Quiagen, USA). Prior to each reverse transcription reaction, 1 µg of total RNA was dissolved in 10 µl of water and treated with RNase-free DNase (Gibco-BRL, USA) to remove contaminating genomic DNA for 15 min at room temperature. After the incubation, DNase was heat inactivated at 65°C for 15 min. Total RNA (1 µg) was reverse transcribed at 40°C for 1 h in a 20 µl reaction mixture using 100 ng of random hexanucleotide primers and 6 IU of AMV reverse transcriptase (Gibco-BRL) in the presence of cDNA synthesis buffer (Gibco-BRL), 125 mmol/l dNTPs mixtures (Gibco-BRL), 5 mmol/l dithiotheritol (Gibco-BRL) and 40 U of RNase inhibitor (RNasin; Gibco-BRL). The reaction was initiated by adding 1 µl (200 U) of Superscript II reverse transcriptase to each tube, mixed and incubated at 25°C for 10 min. The tubes were then transferred to 40°C and incubated for 60 min. The resultant cDNA mixtures were heated at 95°C for 5 min before storage at 20°C. Negative controls were performed by omission of reverse transcriptase.
Semi-quantitative PCR
Semi-quantitative PCR to compare the expression of FSH-R, LH-R and EGF-R mRNA was performed using a GeneAmp PCR System 2400 (Perkin Elmer, USA). Equal loading was monitored by glyceraldehyde-3-phosphate dehydrogenase (GAPDH) expression (Wong et al., 1994). The PCR amplification was carried out by adding 25 µl of PCR mixture containing 20 mmol/l TrisHCl (pH 8.4), 1.5 mmol/l MgCl2, 50 mmol/l KCl, 0.2 mmol/l dNTP and 2.5 U of Taq polymerase. The PCR conditions were 95°C denaturation, annealing specific for primers (as Table I), 72°C extension, each step 1 min with a final extension of 5 min. For nested PCR, 1 µl of primary product was added to 49 µl of freshly prepared mix as above. Annealing temperatures and cycle numbers were optimized for each phase (Table I). PCR products were analysed by electrophoresis on a 3% agarose gel and stained with ethidum bromide. The density of PCR products was measured by Gel Doc 2000 (Bio-Rad Laboratories, USA). RTPCR experiments for the FSH-R, LH-R and EGF-R genes and for the control GAPDH gene were repeated 10 times.
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Results |
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Discussion |
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Recent studies of the treatment of PCOS patients with HCG before oocyte recovery showed an increased rate of oocyte maturation (Chian et al., 2000). Similar clinical results were obtained with a similar approach in the IVM programme for patients with PCOS (Son et al., 2002
). The current results showed that the COC patterns at the time of oocyte retrieval in HCG-primed IVM cycles of PCO(S) patients were different in oocytes with dispersed, compacted and sparse CC patterns. A similar observation has been reported by Son et al. (2001)
, which determined the COC pattern in HCG-primed IVM cycles for patients with a high risk of OHSS. Moreover, the maturation speed and rate of oocytes with dispersed CCs after culture in this study were significantly higher than those with compacted and sparse CCs. About 72% of oocytes with dispersed CCs reached the MII stage by 24 h of culture, which was similar to maturation and morphology of GV-stage oocytes obtained from superovulated IVF cycles. Cha and Chian (1998)
reported the different time course of germinal vesicle breakdown (GVBD) for GV-stage oocytes recovered from superovulated IVF patients and from unstimulated IVF patients, which was contributed to by different patterns of CCs in GV-stage oocytes. In the study, up to 12 h of culture, 80% of GV oocytes recovered from superovulated IVF patients underwent GVBD, whereas all the oocytes recovered from untreated patients still had intact GVs (Cha and Chian, 1998
). It was also found that the oocytes with dispersed CC patterns only appeared in HCG-primed IVM cycles compared with oocytes in non-primed and low dose HMG-primed IVM cycles (Son et al., 2001
). Therefore, it is considered that differences in the maturation speed and rates of oocytes with different CC patterns might be due to the difference in priming of follicles by HCG before oocyte recovery and the activity of the CCs with the follicles.
Son et al. (2002) reported that MII-stage oocytes could be collected at the time of oocyte retrieval in HCG-primed IVM cycles of women with PCOS. We also found 8% of mature eggs at the day of egg retrieval in this study, and these were from oocytes with dispersed CCs. There was no difference in embryo quality morphologically between embryos derived from immature oocytes either with or without MII oocytes at the time of oocyte retrieval. Recently, Chian et al. (2004)
reported that maturational and developmental competence of immature oocytes was not detrimentally affected by the presence of a dominant follicle of 19 mm at the time of egg retrieval. Russell (1998)
reported a marked decrease in the rates of maturation, fertilization and transfer among cycles in which immature oocytes were retrieved when a dominant follicle of
14 mm was present at the time of retrieval. In our study, we only measured follicle diameter just before HCG was given to the patients. The size of the leading follicle was
10 mm. Therefore, the leading follicle size at the time of egg retrieval was probably 1113 mm in diameter after HCG priming. Therefore, we think that the developmental competence of immature oocytes may not be detrimentally affected by the presence of a <14 mm leading follicles at the time of egg retrieval. However, further studies to clarify the correlation of leading follicular size and developmental capacity of sibling immature oocytes in an IVM programme are necessary.
During follicular growth up to the pre-ovulatory stage, numerous genes are activated and inactivated in the developing oocyte and surrounding mural granulosa cells and CCs (Salustri et al., 1989). The induction of LH-R by FSH is mediated by the FSH-induced increase in intracellular cyclic AMP (Erickson et al., 1979
, Erickson et al., 1982
). The LH-induced events induce GVBD. LH also induces CC expansion, which involves the secretion of a hyaluronic acid-rich proteoglycan matrix from CCs (Salustri et al., 1989
). However, in this study, LH-R mRNA was found to be highly expressed on the dispersed CCs in spite of no FSH induction. In addition, the expression of FSH-R and EGF-R mRNA was not different between dispersed CCs and compacted CCs collected from priming HCG in IVM cycles of PCO(S) patients. This was probably due to the difference in the stage of follicle development at the time of oocyte retrieval after HCG administration.
It was reported that FSH-R mRNA in the immature rat ovary could already be localized in granulosa cells of small follicles (Nakamura et al., 1991; Lapolt et al., 1992
). Treatment with pregnant mare's serum gonadotrophin (PMSG) to stimulate follicle growth resulted in a marked increase of FSH-R mRNA expression and FSH-binding sites, whereas subsequent administration of HCG to induce ovulation and luteinization significantly decreased FSH-R expression (Nakamura et al., 1991
; Lapolt et al., 1992
). EGF-R was detected by immunostaining and RTPCR on CCs of all stages of porcine follicle development (Singh et al., 1995
). Immunoreactivities for EGF-R were expressed simultaneously in the human oocytes of primordial, primary, pre-antral and antral follicles (Qu et al., 2000
). In human ovary, LH-R mRNA increased from pre-ovulatory follicles to the corpus luteum of the midluteal phase (Minegishi et al., 1997
). Therefore, based on these reports, it is thought that some follicles at the time of HCG priming in PCOS patients might already have LH-R, resulting in the oocytes retrieved having a dispersed CC pattern. Similarly, compact CCs around oocytes following the administration of large doses of HCG (1000 IU) could be due to the presence of insufficient LH-R in order to induce the CC response in vivo. Meanwhile, the oocytes with sparse CCs might be mixed with oocytes that removed CCs mostly by high pressure on ovum aspiration and that were entering the degenerative process. A well-defined further study is needed to ascertain this possibility.
Barnes et al. (1996) reported that those oocytes first reaching MII were shown to be the most competent to develop into blastocysts. Our results showed that the rate of blastocysts derived from oocytes with dispersed CCs was significantly higher than those of oocytes with compacted and sparse CCs, even though the number of embryos examined was small. Therefore, the results from this study suggest that the presence of dispersed CCs at the time of oocyte retrieval may be positively correlated with oocyte maturation and blastocyst development in HCG-primed IVM cycles. In addition, the results also indicate that the expression of the LH-R in CCs may be correlated with the CC pattern at the time of oocyte retrieval.
In conclusion, the CC pattern at the time of aspiration plays a predictive role in the maturation of oocytes recovered in HCG-stimulated IVM cycles, and may be a relevant parameter in the development of technology with higher rates of successful oocyte maturation and developmental competence of embryos in vitro.
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Acknowledgements |
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References |
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Submitted on December 22, 2004; resubmitted on March 17, 2005; accepted on April 1, 2005.
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