Department of Reproductive Science and Medicine, Institute of Reproductive and Developmental Biology, The Wolfson and Weston Research Centre for Family Health, Imperial College, Hammersmith Hospital, Du Cane Road, London W12 0NN, UK
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Abstract |
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Key words: IVF/IVM/lactate/medium/pyruvate
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Introduction |
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A suboptimal environment for maturation in vitro is one of many factors that could account for the low pregnancy rates. Studies in cows and mice have shown that a variety of commercially available culture media have widely differing effects on spontaneous nuclear maturation and subsequent preimplantation development following IVF (van de Sandt et al., 1990; Rose and Bavister, 1992
). Indeed, in domestic species, the exposure of oocytes and early embryos to certain culture conditions can have profoundly deleterious effects on preimplantation, fetal and post-natal development, resulting in a spectrum of abnormalities collectively referred to as large offspring syndrome (Young et al., 1998
; McEvoy et al., 2001
). It has been proposed that genesis of these abnormalities may involve cellular stress responses to culture conditions and, consequently, disturbances in metabolism and gene expression which result in abnormal development (Leese et al., 1998
). In preimplantation embryos, gene expression and genomic imprinting is altered under different culture conditions (Ho et al., 1995
; Doherty et al., 2000
; Niemann and Wrenzycki, 2000
; Khosla et al., 2001
). A wide variety of culture media, which may be supplemented with any of a number of gonadotrophins, steroids and growth factors, have been used for the maturation of human oocytes in vitro before fertilization and embryo transfer (Trounson et al., 2001
). The animal studies described above highlight the need for a greater understanding of both human oocyte maturation and the effects of the maturation environment on subsequent embryo and fetal development.
In vivo, oocytes resume meiosis and undergo nuclear maturation following the LH surge, although fully grown oocytes from many species can mature spontaneously, resuming meiosis following release from the follicle (Pincus and Enzmann, 1935; Edwards, 1965
). A critical part of the maturation process may involve the development and activation of appropriate metabolic pathways as metabolism shifts from involving both granulosa cells and the oocyte within the cumulusoocyte complex to being oocyte-centred. This shift is important in ensuring the metabolic independence of the oocyte following ovulation and loss of gap junctional communication with surrounding cumulus cells.
Despite increased clinical interest in human IVM over the past decade, little is known about the metabolism of the maturing oocyte, particularly in the absence of surrounding cumulus cells. Pyruvate is produced by cumulus cells (Leese and Barton, 1985), and is the major energy source for maturing mouse, cow and cat oocytes (Biggers et al., 1967
; Steeves and Gardner, 1999a
; Khurana and Niemann, 2000
), with minimal metabolism of glucose (Rieger and Loskutoff, 1994
; Spindler et al., 2000
). Energy substrates have also been shown to play an important role in modulating oocyte maturation by interacting with meiotic inhibitors such as hypoxanthine (Fagbohun and Downs, 1992
; Downs and Mastropolo, 1994
).
Superovulation techniques aim to maximize oocyte maturation in vivo; however, 515% of aspirated oocytes remain at the germinal vesicle (GV) stage at the time of oocyte collection (Janssenswillen et al., 1995; Farhi et al., 1997
). Why these oocytes fail to complete nuclear maturation remains unknown; the follicles may be resistant, or less responsive, to hormonal stimulation (Farhi et al., 1997
), a proportion may be atretic (Goud et al., 1998
) or they may simply be at an earlier developmental stage (Kim et al., 2000
). The latter is the most likely scenario as, with further culture, a cohort will complete nuclear maturation, and can be successfully fertilized and will initiate embryonic development (Janssenswillen et al., 1995
; Farhi et al., 1997
; Goud et al., 1998
; Haberle et al., 1999
; Kim et al., 2000
). Pregnancies and live births have been achieved using such in-vitro matured oocytes (Nagy et al., 1996
; Edirisinghe et al., 1997
; Tucker et al., 1998
). Oocytes that remain immature at the time of oocyte collection are not suitable for ICSI. The exposure of these oocytes to hCG before oocyte retrieval, followed by the removal of cumulus cells to confirm maturity prior to ICSI, will promote resumption of meiosis. These denuded oocytes can be used to study the effect of culture media on the completion of oocyte maturation and the accompanying changes in metabolic requirements.
The aims of this study were to: (i) evaluate whether the basic culture medium alone, in the absence of hormones and growth factors, could influence rates of human oocyte maturation; (ii) assess non-invasively, for the first time, pyruvate uptake and lactate production by oocytes as they complete nuclear maturation in vitro; and (iii) ascertain whether the composition of the culture medium affects oocyte metabolism. To achieve these aims, we matured individual GV stage oocytes in one of two commercial culture media commonly used for oocyte maturation: tissue culture medium (TCM) 199 and modified Eagle medium with Earles modified salts (MEME). During maturation we non-invasively measured the depletion of pyruvate and the accumulation of lactate in the culture medium.
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Materials and methods |
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IVM
Two commercially available media were used for further culture of the immature oocytes, TCM 199 (Gibco BRL, Paisley, UK) and MEME (Gibco) (Table I). Both media contain inorganic salts, glucose and essential amino acids and are supplemented with 0.4% (v/v) human serum albumin (Zenalb 20; Bio Products Laboratory, Elstree, Herts, UK), 0.47 mmol/l sodium pyruvate (Sigma), 83.2 IU/ml penicillin (Sigma) and 0.075 mg/ml streptomycin. TCM 199 is more complex than MEME, containing, in addition, DNA and RNA precursors and a wider range of non-essential amino acids and vitamins.
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Measurement of pyruvate uptake and lactate production
Fifty-nine immature ICSI oocytes (which had been completely denuded of cumulus cells) were cultured singly in 5 µl drops of either TCM 199 (n = 26) or MEME (n = 33) overnight from day 0 to day 1 (17 h), and for a further 24 h in fresh 5 µl drops of the same medium. Similar 5 µl drops of medium alone were incubated alongside the oocyte-containing drops and served as controls. At the end of each culture period, individual 3 µl aliquots of the spent and control drops from the recently terminated culture dishes were diluted with 597 µl of a 5 µmol/l lactate solution (lactate standard; Sigma). Pyruvate uptake and lactate production were measured by analysing the difference between nutrient concentrations in the control and incubation drops as described previously (Hardy et al., 1995
). The high concentration of glucose in these commercial media precluded the accurate measurement of glucose uptake by single oocytes.
Ethical approval
The study was granted ethical approval by the Research Ethics Committee for Hammersmith, Queen Charlottes and Chelsea and Acton Hospitals, and written consent was obtained from all participating patients.
Statistical analysis
2 and MannWhitney U-tests were used for statistical analyses as appropriate. Significance was accepted when P < 0.05.
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Results |
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IVM
All oocytes were at the GV stage at the time of oocyte retrieval. Those donated to research were available for study on the afternoon of oocyte retrieval, by which time a proportion had already initiated GV breakdown (GVBD). Denuded oocytes were randomly allocated to the two culture media before scoring and retrospective analysis showed that there was no significant difference between the two groups in terms of developmental stage at 6 h. At 24 h post-aspiration, significantly more oocytes had progressed to metaphase II in MEME (55%) than in TCM 199 (28%) (P = 0.03; Figure 1). At 48 h post-aspiration, the majority of oocytes had completed nuclear maturation with 74% metaphase II oocytes in MEME compared with 69% in TCM 199 (not significant; Figure 1
).
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Lactate production by individual oocytes was lower than pyruvate uptake (Figure 2). In MEME, lactate production during the first incubation was significantly lower for fast maturers than for slow maturers, i.e. oocytes which had only reached metaphase I (P = 0.02). During the second incubation period, lactate production was significantly lower for slow than for fast maturers (P = 0.04). In TCM 199, lactate production was similar in the first and second maturation period, irrespective of whether oocytes were maturing quickly or slowly.
By assessing the maturational stage of the oocyte at the beginning and end of each incubation period, it was possible to correlate substrate uptake/production with a particular cellular event occurring during maturation. Pyruvate uptake was less during polar body extrusion than GVBD in both media, significantly so in MEME (P < 0.05, Figure 3). There was no significant difference in pyruvate uptake between the two media during GVBD or polar body extrusion (Figure 3
). However, when oocytes that had already completed maturation and extruded their first polar body during the first culture period were cultured for a further 24 h, pyruvate uptake was significantly greater for those in TCM 199 than in MEME (P < 0.01, Figure 3
). In TCM 199 there was no significant difference in the amount of lactate produced during GVBD, polar body extrusion or for oocytes remaining at metaphase II. However, when oocytes were matured in MEME, significantly less lactate was produced during polar body extrusion than during GVBD (P < 0.01, Figure 3
).
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Discussion |
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The maturation rates seen over a 48 h period are comparable with those achieved by others working with denuded, immature oocytes retrieved from women following superovulation (Janssenswillen et al., 1995; Farhi et al., 1997
; Goud et al., 1998
; Haberle et al., 1999
). Significantly more oocytes reached metaphase II within 24 h in MEME than in TCM 199 (Figure 1
). This could be important clinically, as earlier first polar body extrusion by mouse oocytes has been associated with improved developmental competence (van de Sandt et al., 1990
). In general terms, MEME is a less complex medium than TCM 199. Both contain a similar range of inorganic salts, but MEME has a higher glucose concentration, fewer non-essential amino acids and a relatively small number of vitamins (Table I
). TCM 199 has a lower glucose concentration, both essential and non-essential amino acids, a larger range of vitamins, purines and pyrimidines, and several other components such as cholesterol, glutathione and ribose (Table I
). Amino acids are known to be beneficial for embryo development (Gardner and Lane, 1993
; Steeves and Gardner, 1999b
; Devreker et al., 2001
) and oocyte maturation (Rose-Hellekant et al., 1998
; Watson et al., 2000
) in several species. However, certain amino acids are known to have a detrimental effect on hamster embryo development (Bavister and McKiernan, 1993
). The different amino acid content between the two culture media may account for the difference in maturation rates seen in this study.
Other candidate factors for the relative inhibitory effect of TCM 199 on maturation of denuded immature ICSI oocytes are purines and purine precursors, both of which are present in this medium (Table I). Extensive studies on the maturation of cumulus-enclosed and denuded mouse oocytes have established the existence of a wide range of meiosis-inhibiting factors, including purines such as hypoxanthine (Downs et al., 1985
), nucleosides such as adenosine (Eppig et al., 1985
), and purine precursors such as glutamine, glycine and aspartic acid (Downs, 1998
). The maturation-arresting action of these factors involve complex interactions between components in the media (for example glucose and pyruvate) and the oocyte and its companion cumulus cells. In the present study, several meiosis-arresting substrates, or their precursors, are present in TCM 199 that are not included in MEME, namely hypoxanthine, AMP, aspartic acid and glycine, which may explain the slower rate of maturation. However, levels of hypoxanthine in TCM 199 (2.2 µmol/l) are significantly lower those used to maintain meiotic arrest of denuded mouse oocytes (4 mmol/l) (Downs and Mastropolo, 1994
), and such hypoxanthine-induced arrest can be completely reversed in the presence of 0.5 mmol/l pyruvate (which is also present in TCM 199). It is therefore unlikely that hypoxanthine per se is inhibiting maturation, although this does not preclude the possibility that the purines and purine precursors present in combination in TCM 199 may slow the rate of maturation.
Studies examining the metabolism of radiolabelled energy substrates during maturation of cumulus-free cow and cat oocytes (Rieger and Loskutoff, 1994; Steeves and Gardner, 1999a
; Spindler et al., 2000
) have shown that pyruvate is the predominant energy source. We have shown here that pyruvate uptake by maturing human oocytes is also high (Figures 2 and 3
). Furthermore, levels of pyruvate uptake and lactate production by human oocytes maturing in vitro are consistent with previous studies in human embryos. The amount of pyruvate taken up throughout maturation is of a similar order of magnitude to that taken up by human oocytes (Leese et al., 1986
) and embryos during their first cleavage divisions (Hardy et al., 1989
; Gott et al., 1990
; Conaghan et al., 1993
; Turner et al., 1994
; Devreker et al., 1998
, 1999
), but is higher than that of fertilized human zygotes following ICSI (Devreker et al., 2000
).
Lactate was produced by maturing human oocytes in vitro at rates similar to those described previously for early human preimplantation embryos (Hardy et al., 1995; Devreker et al., 1998
) but lower than that seen by Gott et al. (Gott et al., 1990
). It has previously been proposed that lactate produced by preimplantation mouse and human embryos is derived from exogenous glucose (Gott et al., 1990
). Levels of glucose in the two commercial media used here were high (Table I
) compared with levels measured in fluid from the human Fallopian tube and uterus (Gardner et al., 1996
), and glucose uptake by oocytes is negligible (Devreker et al., 2000
). Studies using radiolabelled pyruvate as the sole energy source for 2-cell mouse embryos in vitro have demonstrated that lactate can be produced from pyruvate (Wales and Whittingham, 1970
). Culture of early human embryos in medium containing pyruvate alone (Butcher et al., 1998
) resulted in lactate production of a similar magnitude (
12 pmol/embryo/h) to that observed here (
10 pmol/oocyte/h, Figure 3
). These data, in conjunction with high levels of lactate dehydrogenase in human embryos (Martin et al., 1993
), suggest that the lactate produced could be derived from pyruvate.
During the first incubation, pyruvate uptake was similar in the two media (Figure 2). However, during the second incubation, pyruvate uptake was 30% lower in MEME than in TCM 199. Levels of glutamine are >4-fold higher in MEME compared with TCM 199 (Table I
). Glutamine is metabolized by both maturing cow and cat oocytes (Rieger and Loskutoff, 1994
; Steeves and Gardner, 1999a
; Spindler et al., 2000
). As both pyruvate and glutamine are tricarboxylic acid (TCA) cycle precursors, it can be hypothesized that the high levels of glutamine found in MEME may compete with pyruvate for entry into the TCA cycle, resulting in lower pyruvate uptake under these conditions. Alternatively, the presence of Tween 80 in TCM 199 could result in the oocyte membrane becoming more permeable with time, leading to higher pyruvate uptake during the second incubation.
The significant differences in pyruvate uptake between oocytes undergoing GVBD and those extruding their polar body when cultured in MEME are intriguing. Cyclic AMP (cAMP) is involved in the maintenance of meiosis in a number of species (Downs, 1995a; review) and arises from ATP by the action of adenylate cyclase. During spontaneous maturation in vitro, cAMP levels decrease in oocytes (Downs, 1995a
), and this is associated with a decrease in ATP levels (Downs, 1995b
). It is possible that once the oocyte is irreversibly committed to mature, cAMP is no longer required to maintain meiotic arrest, ATP requirements fall and pyruvate uptake decreases. Interestingly, pyruvate uptake by oocytes which failed to mature remained high throughout the 24 h period.
Maturation of human oocytes in vitro is accompanied by changes in the aggregation patterns of mitochondria (Sathananthan and Trounson, 2000; Wilding et al., 2001
), which may reflect changing metabolic needs of the oocyte in preparation for fertilization. These changes in mitochondrial distribution may also account for the lower pyruvate uptake that was observed during later stages of nuclear maturation.
This work has shown for the first time that it is possible to measure pyruvate uptake and lactate production by individual, maturing human oocytes non-invasively. It also demonstrates that the metabolism of human oocytes can be significantly influenced by both the composition of the in-vitro culture medium and the cellular event taking place within the oocyte nucleus. The fact that the culture environment affects metabolism during human oocyte maturation suggests that the choice of culture medium for clinical IVM could be critical for embryonic and possibly fetal health. Further work is needed to investigate how substrate utilisation by maturing oocytes relates to subsequent development.
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Acknowledgements |
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Notes |
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References |
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Biggers, J.D., Whittingham, D.G. and Donahue, R.P. (1967) The pattern of energy metabolism in the mouse oocyte and zygote. Proc. Natl Acad. Sci. USA, 58, 560567.[ISI][Medline]
Butcher, L., Coates, A., Martin, K.L., Rutherford, A.J. and Leese, H.J. (1998) Metabolism of pyruvate by the early human embryo. Biol. Reprod., 58, 10541056.[Abstract]
Conaghan, J., Hardy, K., Handyside, A.H., Winston, R.M. and Leese, H.J. (1993) Selection criteria for human embryo transfer: a comparison of pyruvate uptake and morphology. J. Assist. Reprod. Genet., 10, 2130.[ISI][Medline]
Dawson, K.J., Conaghan, J., Ostera, G.R., Winston, R.M. and Hardy, K. (1995) Delaying transfer to the third day post-insemination, to select non-arrested embryos, increases development to the fetal heart stage. Hum. Reprod., 10, 177182.[Abstract]
Devreker, F., Winston, R.M. and Hardy, K. (1998) Glutamine improves human preimplantation development in vitro. Fertil. Steril., 69, 293299.[ISI][Medline]
Devreker, F., Van den Bergh, M., Biramane, J., Winston, R.L., Englert, Y. and Hardy, K. (1999) Effects of taurine on human embryo development in vitro. Hum. Reprod., 14, 23502356.
Devreker, F., Hardy, K., Van den Bergh, M., Winston, J., Biramane, J. and Englert, Y. (2000) Noninvasive assessment of glucose and pyruvate uptake by human embryos after intracytoplasmic sperm injection and during the formation of pronuclei. Fertil. Steril., 73, 947954.[ISI][Medline]
Devreker, F., Hardy, K., Van den Bergh, M., Vannin, A.S., Emiliani, S. and Englert, Y. (2001) Amino acids promote human blastocyst development in vitro. Hum. Reprod., 16, 749756.
Doherty, A.S., Mann, M.R., Tremblay, K.D., Bartolomei, M.S. and Schultz, R.M. (2000) Differential effects of culture on imprinted H19 expression in the preimplantation mouse embryo. Biol. Reprod., 62, 15261535.
Downs S.M. (1995a) Ovulation 2: Control of the resumption of meiotic maturation in mammalian oocytes. In Grudzinskas, J.G. and Yovich, J.L. (eds) GametesThe Oocyte. Cambridge University Press, Cambridge, UK, pp. 150192.
Downs, S.M. (1995b) The influence of glucose, cumulus cells, and metabolic coupling on ATP levels and meiotic control in the isolated mouse oocyte. Dev. Biol., 167, 502512.[ISI][Medline]
Downs, S.M. (1998) Precursors of the purine backbone augment the inhibitory action of hypoxanthine and dibutyryl cAMP on mouse oocyte maturation. J. Exp. Zool., 282, 376384.[ISI][Medline]
Downs, S.M. and Mastropolo, A.M. (1994) The participation of energy substrates in the control of meiotic maturation in murine oocytes. Dev. Biol., 162, 154168.[ISI][Medline]
Downs, S.M., Coleman, D.L., Ward-Bailey, P.F. and Eppig, J.J. (1985) Hypoxanthine is the principal inhibitor of murine oocyte maturation in a low molecular weight fraction of porcine follicular fluid. Proc. Natl Acad. Sci. USA, 82, 454458.[Abstract]
Edirisinghe, W.R., Junk, S.M., Matson, P.L. and Yovich, J.L. (1997) Birth from cryopreserved embryos following in-vitro maturation of oocytes and intracytoplasmic sperm injection. Hum. Reprod., 12, 10561058.[ISI][Medline]
Edwards, R.G. (1965) Maturation in vitro of mouse, sheep, cow, pig, rhesus monkey and human ovarian oocytes. Nature, 208, 349351.[ISI][Medline]
Eppig, J.J., Ward-Bailey, P.F. and Coleman, D.L. (1985) Hypoxanthine and adenosine in murine ovarian follicular fluid: concentrations and activity in maintaining oocyte meiotic arrest. Biol. Reprod., 33, 10411049.[Abstract]
Fagbohun, C.F. and Downs, S.M. (1992) Requirement for glucose in ligand-stimulated meiotic maturation of cumulus cell-enclosed mouse oocytes. J. Reprod. Fertil., 96, 681697.[Abstract]
Farhi, J., Nahum, H., Zakut, H. and Levran, D. (1997) Incubation with sperm enhances in vitro maturation of the oocyte from the germinal vesicle to the M2 stage. Fertil. Steril., 68, 318322.[ISI][Medline]
Gardner, D.K. and Lane, M. (1993) Amino acids and ammonium regulate mouse embryo development in culture. Biol. Reprod., 48, 377385.[Abstract]
Gardner, D.K., Lane, M., Calderon, I. and Leeton, J. (1996) Environment of the preimplantation human embryo in vivo: metabolite analysis of oviduct and uterine fluids and metabolism of cumulus cells. Fertil. Steril., 65, 349353.[ISI][Medline]
Gott, A.L., Hardy, K., Winston, R.M. and Leese, H.J. (1990) Non-invasive measurement of pyruvate and glucose uptake and lactate production by single human preimplantation embryos. Hum. Reprod., 5, 104108.[Abstract]
Goud, P.T., Goud, A.P., Qian, C., Laverge, H., Van der Elst, J., De Sutter, P. and Dhont, M. (1998) In-vitro maturation of human germinal vesicle stage oocytes: role of cumulus cells and epidermal growth factor in the culture medium. Hum. Reprod., 13, 16381644.[Abstract]
Haberle, M., Scheurer, P., Lauerer, K., Fischer, M. and Hohl, M.K. (1999) Are cumulus cells necessary for the spontaneous maturation of germinal vesicle-stage oocytes to metaphase II. J. Assist. Reprod. Genet., 16, 329331.[ISI][Medline]
Hardy, K., Hooper, M.A., Handyside, A.H., Rutherford, A.J., Winston, R.M. and Leese, H.J. (1989) Non-invasive measurement of glucose and pyruvate uptake by individual human oocytes and preimplantation embryos. Hum. Reprod., 4, 188191.[Abstract]
Hardy, K., Robinson, F.M., Paraschos, T., Wicks, R., Franks, S. and Winston, R.M. (1995) Normal development and metabolic activity of preimplantation embryos in vitro from patients with polycystic ovaries. Hum. Reprod., 10, 21252135.[Abstract]
Ho, Y., Wigglesworth, K., Eppig, J.J. and Schultz, R.M. (1995) Preimplantation development of mouse embryos in KSOM: augmentation by amino acids and analysis of gene expression. Mol. Reprod. Dev., 41, 232238.[ISI][Medline]
Janssenswillen, C., Nagy, Z.P. and Van Steirteghem, A. (1995) Maturation of human cumulus-free germinal vesicle-stage oocytes to metaphase II by coculture with monolayer Vero cells. Hum. Reprod., 10, 375378.[Abstract]
Khosla, S., Dean, W., Reik, W. and Feil, R. (2001) Culture of preimplantation embryos and its long-term effects on gene expression and phenotype. Hum. Reprod. Update, 7, 419427.
Khurana, N.K. and Niemann, H. (2000) Energy metabolism in preimplantation bovine embryos derived in vitro or in vivo. Biol. Reprod., 62, 847856.
Kim, B.K., Lee, S.C., Kim, K.J., Han, C.H. and Kim, J.H. (2000) In vitro maturation, fertilization, and development of human germinal vesicle oocytes collected from stimulated cycles. Fertil. Steril., 74, 11531158.[ISI][Medline]
Leese, H.J. and Barton, A.M. (1985) Production of pyruvate by isolated mouse cumulus cells. J. Exp. Zool., 234, 231236.[ISI][Medline]
Leese, H.J., Hooper, M.A., Edwards, R.G. and Ashwood-Smith, M.J. (1986) Uptake of pyruvate by early human embryos determined by a non-invasive technique. Hum. Reprod., 1, 181182.[Abstract]
Leese, H.J., Donnay, I. and Thompson, J.G. (1998) Human assisted conception: a cautionary tale. Lessons from domestic animals. Hum. Reprod., 13 (Suppl. 4), 184202.[Medline]
McEvoy, T.G., Robinson, J.J. and Sinclair, K.D. (2001) Developmental consequences of embryo and cell manipulation in mice and farm animals. Reproduction, 122, 507518.
Martin, K.L., Hardy, K., Winston, R.M. and Leese, H.J. (1993) Activity of enzymes of energy metabolism in single human preimplantation embryos. J. Reprod. Fertil., 99, 259266.[Abstract]
Nagy, Z.P., Cecile, J., Liu, J., Loccufier, A., Devroey, P. and Van Steirteghem, A. (1996) Pregnancy and birth after intracytoplasmic sperm injection of in vitro matured germinal-vesicle stage oocytes: case report. Fertil. Steril., 65, 10471050.[ISI][Medline]
Niemann, H. and Wrenzycki, C. (2000) Alterations of expression of developmentally important genes in preimplantation bovine embryos by in vitro culture conditions: implications for subsequent development. Theriogenology, 53, 2134.[ISI][Medline]
Pincus, G.P. and Enzmann, E.V. (1935) The comparative behaviour of mammalian eggs in vivo and in vitro. I. The activation of ovarian eggs. J. Exp. Med., 62, 665675.
Rieger, D. and Loskutoff, N.M. (1994) Changes in the metabolism of glucose, pyruvate, glutamine and glycine during maturation of cattle oocytes in vitro. J. Reprod. Fertil., 100, 257262.[Abstract]
Rose, T.A. and Bavister, B.D. (1992) Effect of oocyte maturation medium on in vitro development of in vitro fertilized bovine embryos. Mol. Reprod. Dev., 31, 7277.[ISI][Medline]
Rose-Hellekant, T.A., Libersky-Williamson, E.A. and Bavister, B.D. (1998) Energy substrates and amino acids provided during in vitro maturation of bovine oocytes alter acquisition of developmental competence. Zygote, 6, 285294.[ISI][Medline]
Sathananthan, A.H. and Trounson, A.O. (2000) Mitochondrial morphology during preimplantational human embryogenesis. Hum. Reprod., 15 (Suppl. 2), 148159.[Medline]
Spindler, R.E., Pukazhenthi, B.S. and Wildt, D.E. (2000) Oocyte metabolism predicts the development of cat embryos to blastocyst in vitro. Mol. Reprod. Dev., 56, 163171.[ISI][Medline]
Steeves, T.E. and Gardner, D.K. (1999a) Metabolism of glucose, pyruvate, and glutamine during the maturation of oocytes derived from pre-pubertal and adult cows. Mol. Reprod. Dev., 54, 92101.[ISI][Medline]
Steeves, T.E. and Gardner, D.K. (1999b) Temporal and differential effects of amino acids on bovine embryo development in culture. Biol. Reprod., 61, 731740.
Trounson, A., Anderiesz, C. and Jones, G. (2001) Maturation of human oocytes in vitro and their developmental competence. Reproduction, 121, 5175.
Tucker, M.J., Wright, G., Morton, P.C. and Massey, J.B. (1998) Birth after cryopreservation of immature oocytes with subsequent in vitro maturation. Fertil. Steril., 70, 578579.[ISI][Medline]
Turner, K., Martin, K.L., Woodward, B.J., Lenton, E.A. and Leese, H.J. (1994) Comparison of pyruvate uptake by embryos derived from conception and non-conception natural cycles. Hum. Reprod., 9, 23622366.[Abstract]
van de Sandt, J.J., Schroeder, A.C. and Eppig, J.J. (1990) Culture media for mouse oocyte maturation affect subsequent embryonic development. Mol. Reprod. Dev., 25, 164171.[ISI][Medline]
Wales, R.G. and Whittingham, D.G. (1970) Metabolism of specifically labelled pyruvate by mouse embryos during culture from the two-cell stage to the blastocyst. Aust. J. Biol. Sci., 23, 877887.[ISI][Medline]
Watson, A.J., De Sousa, P., Caveney, A., Barcroft, L.C., Natale, D., Urquhart, J. and Westhusin, M.E. (2000) Impact of bovine oocyte maturation media on oocyte transcript levels, blastocyst development, cell number, and apoptosis. Biol. Reprod., 62, 355364.
Wilding, M., Dale, B., Marino, M., di Matteo, L., Alviggi, C., Pisaturo, M.L., Lombardi, L. and De Placido, G. (2001) Mitochondrial aggregation patterns and activity in human oocytes and preimplantation embryos. Hum. Reprod., 16, 909917.
Young, L.E., Sinclair, K.D. and Wilmut, I. (1998) Large offspring syndrome in cattle and sheep. Rev. Reprod., 3, 155163.
Submitted on January 8, 2002; resubmitted on March 19, 2002; accepted on June 12, 2002.