Ovulation and early embryogenesis in swine

Thirty gilts were used to examine if the sequence in which oocytes were released at ovulation contributed to differences in embryonic development and uterine secretions by Day 12 (Day 0 = onset of estrus). Oocytes of follicles destined to ovulate last were recovered 42 h after injecting proestrous gilts with hCG, incubated with a fluorescent stain, and returned to the donor's oviduct. These later-maturing oocytes subsequently became the lesser-developed (p less than 0.01) embryos on Day 4. In a second experiment, lesser- vs. more-developed Day 4 embryos from additional gilts were transferred to ligated uterine horns of nonpregnant gilts. Subsequently, the lesser-developed Day 4 embryos became the smaller (p less than 0.01) blastocysts within a litter on Day 12. Uterine flushings associated with lesser-developed embryos on Day 12 contained less estradiol (p less than 0.01), less total protein (p less than 0.10), and less acid phosphatase activity (p less than 0.05), but total content of calcium was not different compared to flushings that contained more-developed embryos. Analysis of uterine flushings with two-dimensional PAGE procedures indicated advanced uteroferrin-associated glycoprotein secretion from the horn that contained more-developed embryos. Results of these experiments suggested that oocytes of later-ovulating follicles were progenitors of smaller embryos, which probably stimulated uterine secretion later than more advanced littermates on Day 12.     

The effects of follicular fluid on in vitro maturation, oocyte fertilization and the development of bovine embryos

We determined the effects of follicular fluid in the maturation medium on bovine oocyte maturation, fertilization and subsequent development, as well as on the number of cells in blastocysts following culture. Fluid and oocytes from bovine follicles less than 5 mm in diameter were collected from the ovaries of slaughtered cows. For the maturation medium, follicular fluid at concentrations of 10, 30 or 60% (v/v) was added to Medium 199 with Earle's salts supplemented with 0.1 microg/ml estradiol-17 beta (E(2), Experiment 1) or 0.1 microg/ml E2 and 100 IU/ml hCG (Experiment 2). The control medium contained polyvinylpyrrolidone (PVP; 3 mg/ml) instead of follicular fluid. After maturation for 24 h, oocytes were fertilized in vitro with bull frozen-thawed spermatozoa and cultured on a monolayer of granulosa cells for 9 d. There were no differences in maturation or fertilization rates of oocytes. In Experiment 1, maturation medium containing 10% follicular fluid did not affect the developmental rate of the oocytes to > 2-cell, 8 to 16-cell, blastocyst and hatched blastocyst stage embryos, respectively; whereas 60% decreased embryonic development (P < 0.05) compared with the control. Blastocysts and hatched blastocysts developed from fertilized oocytes which had been matured in medium containing 10 and 30% follicular fluid/E(2) had more cells than the controls (P < 0.01). In Experiment 2, maturation medium containing 10 or 30% follicular fluid did not affect the development fertilized oocytes to the blastocyst stage compared with the control, but decreased at 60% (P < 0.01). There were no differences in the number of cells from Day 9 blastocysts and hatched blastocysts from fertilized oocytes matured in maturation medium containing follicular fluid and E(2) + hCG. The results of these experiments suggest that the addition of bovine follicular fluid to the maturation medium enhances the cell numbers in blastocysts from bovine follicular oocytes matured in vitro.     

Decreased embryonic survival of in-vitro fertilized oocytes in rats is due to retardation of preimplantation development

Immature female rats (60-65 g) were injected with 4 i.u. PMSG on Day -2 and allocated to 3 groups. On the evening of Day 0, rats in Groups I and II were allowed to mate. Embryos were collected on Day 4 (Group I, control morulae) or Day 5 (Group II, control blastocysts) and were transferred into the oviduct or uterine horn of Day-4 pregnant recipient rats. On the transfer side of the recipients, the bursa had been peeled from around the ovary to prevent endogenous oocytes from entering the oviduct. For Group III, unmated donors were killed 65-67 h after PMSG injection. Ovulated oocytes recovered from the oviducts were fertilized in vitro and transferred 16-18 h later. Embryos developing from in-vitro fertilized (IVF) oocytes were recovered on Day 5, separated into morulae (Group IIIm) and blastocysts (Group IIIb) and transferred into Day-4 pregnant recipients similar to control embryos. Some embryos from each group were used to determine the mean number of cells/embryo. Embryo recipients were killed on Day 20. After transfer, the development of IVF oocytes was retarded compared to control embryos. IVF morulae contained significantly fewer cells/embryo than did control morulae but were able to implant and grow to fetuses, in proportions similar to controls, if transferred into the oviduct of the recipients. These results suggest that the developmental potential of rat oocytes fertilized in vitro is limited due to asynchrony between the embryo and the uterine environment at the time of implantation, rather than possible defects incurred by the oocyte during the fertilization procedure.     

Gamete recovery and follicular transfer (graft) using transvaginal ultrasonography in cattle

Current in vitro culture systems may not be adequate to support maturation, fertilization and embryo development of calf oocytes. Thus, we initiated a study to investigate an alternative method of assessing oocyte competence in vivo, initially using oocytes from adults. Experiment 1 was done to determine if follicle puncture would alter subsequent follicle development, ovulation and CL formation. In control (no follicle puncture, n = 3) and treated (follicle puncture, n = 3) heifers, ultrasound-guided transvaginal follicle aspiration was used to ablate all follicles > or = 5 mm at random stages of the estrous cycle to induce synchronous follicular wave emergence among heifers; PGF2 alpha was given 4 d later. Three days after PGF2 alpha, the preovulatory follicle in treated heifers was punctured with a 25-g needle between the exposed and nonexposed portions of the follicular wall, and 200 microL of PBS were infused into the antrum. There was no significant difference between control and treated heifers for mean diameter of the dominant follicle prior to ovulation, the interval to ovulation following PGF2 alpha, or first detection and diameter of the CL. Experiment 2 was designed to assess multiple embryo production following interfollicular transfer of oocytes (i.e., transfer of multiple oocytes from donor follicles to a single recipient preovulatory follicle). Follicular wave emergence was synchronized among control (no follicle puncture, n = 5), oocyte recipient (n = 7) and oocyte donor (n = 5) heifers as in Experiment 1. In control and oocyte recipient heifers, a norgestomet ear implant was placed at the time of ablation and removed 4 d later, at the second PGF2 alpha treatment. In oocyte donor heifers, FSH was given the day after ablation, and, 4 d later, oocytes were collected by transvaginal follicle aspiration, pooled and placed in holding medium. Five or 6 oocytes were loaded into the 25-g needle of the follicle infusion apparatus with < or = 200 microL of transfer medium. Puncture of the preovulatory follicle of recipient heifers was done as in Experiment 1. Immediately thereafter, LH was given to control and oocyte recipient heifers, but only the recipients were inseminated. Ovarian function was assessed by transrectal ultrasonography and control and oocyte recipient heifers were sent to the abattoir 2 or 3 d after ovulation, where excised oviducts were flushed. The interval between LH administration and ovulation (33 to 36 h) was highly synchronous within and among control and oocyte recipient heifers. Four of 5 (80%) ova were collected from controls and 16 of a potential 43 (37%) ova/embryos were recovered from oocyte recipients; 8 embryos from 3 heifers. Thus, the gamete recovery and follicular transfer procedure (GRAFT) did not alter ovulation or subsequent CL formation, and resulted in the recovery of multiple ova/embryos in which a total of 19 oocytes yielded as many as 8 early embryos, a 42% embryo production rate.     

Developmental competence of bovine oocytes: effects of follicle size and the phase of follicular wave on in vitro embryo production

Developmental competence of bovine oocytes collected from follicles of different size categories (in either the growth or the dominant phase of the first follicular wave) was studied, with the aim of improving in vitro embryo production. Estrus and ovulation of 39 cyclic Holstein dairy cows were synchronized by two prostaglandin F2alpha treatments at 11-day intervals and one hCG treatment on the day of onset of estrus (Day 0). Cows with follicles in either the growth (Day 3, n=25) or the dominant phase (Day 7, n=14) were slaughtered, and follicles >5 mm were counted. Three oocyte populations were recovered separately from large (11-15 mm), medium (6-10 mm) and small (2-5 mm) follicles in both follicular phases. All collected cumulus-oocyte complexes (COC), except for markedly atretic oocytes without cumulus cells, were used in experiments. Oocytes were matured, fertilized and cultured by standard methods. There were no significant differences between the growth and the dominant phases for mean numbers of large follicles, usable oocytes and embryos per donor. Generally, those numbers were low, but the development rates of oocytes into blastocysts were high, particularly in the growth phase (60.0%). Mean (+/- S.E.M.) numbers of medium follicles, oocytes and embryos per donor were higher in the growth as compared with the dominant phase; in the usable oocytes and embryos, this difference was significant (9.6 +/- 1.4 and 3.5 +/- 0.6 versus 3.9 +/- 0.6 and 1.1 +/- 0.3; P<0.01). The development rates of oocytes into blastocysts, however, did not differ significantly between the growth and the dominant phases (36.7% versus 27.8%). Mean numbers of usable oocytes and embryos per donor recovered from small follicles in both follicular wave phases were similar. The development rate of oocytes into blastocysts was generally low, but higher (P<0.01) in the growth than in the dominant phase (24.5% versus 11.7%). Comparison between the two phases showed that mean number of all counted follicles and all usable oocytes collected per donor were similar, but the mean number of embryos per donor and the development rate of oocytes into blastocysts were higher in the growth phase than in the dominant phase (8.0 +/- 1.2 versus 3.8 +/- 2.4; P=0.012 and 30.3% versus 14.9%; P<0.01). The interaction between follicle size and the phase of follicular wave affected the efficiency of embryo production. The yield of embryos was primarily influenced by the number of oocytes collected from medium follicles and the developmental competence of oocytes from small follicles. The growth phase was more effective for oocyte collection; the number of oocytes from medium follicles and the developmental competence of oocytes from small follicles decreased in the dominant phase.     

Blastocyst formation by pig embryos resulting from in-vitro fertilization of oocytes matured in vitro

Follicular oocytes collected from prepubertal gilts at a local slaughter house were matured (36 h), fertilized and developed in vitro. Of 785 embryos, 190 (24%) embryos cleaved to the 2-4 cell stages with blastomeres of regular size by 33 h after insemination. These cleaved embryos were surgically transferred into the oviducts of 4 synchronized recipient gilts and recovered from the uterine horns 4 or 7 days later: 13 morulae, 2 blastocysts and 1 expanded blastocyst were recovered after 4 days and 3 hatched blastocysts were recovered 7 days after transfer. Re-culture in vitro sustained further development of morulae recovered 4 days after transfer: 11 of 13 morulae had developed to the blastocyst/hatched blastocyst stages. Overall, 17 of 190 (9%) embryos developed to the blastocyst stage. The results indicate that pig oocytes can be matured and fertilized in vitro, and subsequently develop to the blastocyst stage.     

Aspects of follicle and oocyte stage that affect in vitro maturation and development of bovine oocytes

Success of in vitro maturation (IVM) and production of bovine embryos as related to aspects of follicle source and oocyte size were evaluated. First, it was determined that bovine oocytes continue growing in all follicular sizes studied, including >1- to 15-mm follicles. Populations of oocytes were collected from surface visible (peripheral) and cortical follicles from the same ovaries. When the number of oocytes from both peripheral and cortical follicles was combined, the yield of oocytes was approximately double that collected from 1 ovarian site alone. Oocytes from cortical follicles were smaller than those from the surface population, and the smaller cortical oocytes had a lower potential for both meiotic maturation and embryo development Only cortical oocytes with the largest diameters underwent IVM and subsequently developed to blastocysts at rates comparable to oocytes from peripheral follicles. As the diameter of the oocytes recovered from peripheral follicles increased, so did their developmental potential. When the stage of the estrous cycle was observed, it was found to have no effect on developmental potential. Finally, oocytes which extruded polar bodies at an earlier time during maturation were, on average, larger than those which extruded polar bodies later. The results serve a practical purpose in assisting selection of oocytes capable of developing into blastocysts and they give useful correlates of oocyte competencies based on knowledge of follicle source and oocyte stage.     

Pregnancies after co-culture of cumulus cells with bovine embryos derived from in-vitro fertilization of in-vitro matured follicular oocytes

Bovine follicular oocytes surrounded by cumulus cells for more than one-third of their surface were matured, fertilized and developed in vitro utilizing a co-culture system with bovine cumulus cells. Embryos developed into blastocysts were non-surgically transferred to the uteri of cows at Day 6, 7 or 8 (Day 0 = oestrus). Out of 6 recipient cows (19 blastocysts transferred), 3 became pregnant. One of the 3 pregnant cows carried twins. The results of this study demonstrated the viability of embryos obtained from in-vitro maturation of bovine oocytes followed by in-vitro fertilization and culture to the blastocyst stage in vitro.     

Morphological changes in the oocyte and its surrounding vestments during in vivo fertilization in the dasyurid marsupial Sminthopsis crassicaudata

This light and transmission electron microscopical study shows that the first polar body is given off before ovulation and that part of its cell membrane and that of the surrounding oocyte have long microvilli at the time of its ejection. Several layers of cumulus cells initially surround the secondary oocyte and first polar body, but the ovulated oocytes in the oviducts in the process of being fertilized do not have cumulus cells around them. Partly expelled second polar bodies occur in the oviduct; they are elongated structures that lack organelles and have electron-dense nuclei. A small fertilization cone appears to form around the sperm tail at the time of sperm entry into the egg and an incorporation cone develops around the sperm head in the egg cytoplasm. In three fertilized eggs a small hole was seen in the zona, which was presumably formed by the spermatozoon during penetration. Cortical granules, present in ovarian oocytes, are not seen in fertilized tubal or uterine eggs; release of their contents probably reduces the chances of polyspermy, although at least one polyspermic fertilized egg was seen and several other fertilized eggs had spermatozoa within the zona pellucida. In the zygote the pronuclei come to lie close together, but there was no evidence of fusion. A "yolk mass," which becomes eccentric before ovulation, is extruded by the time the two-cell embryos are formed, but many vacuoles remain in the non-yolky pole of the egg. A shell membrane of variable thickness is present around all uterine eggs but its origin remains undetermined.     

Overcoming MIII arrest from spontaneous activation in cultured rat oocytes

The rat oocyte spontaneously activates under a wide variety of conditions. This process progresses to MIII arrest that is not responsive to parthenogenetic activation and development. Insofar as activation involves extrusion of the second polar body (PBII), we set out to determine if preventing this step by inhibiting microfilaments would change the course of spontaneous activation (SA). In particular, how long does the effect of SA persist while retaining reversibility of PBII extrusion once inhibitors are removed? We wanted to determine if the eggs would be responsive to parthenogenetic activation and capable of resuming development once a permanent inhibition is achieved. We set out to determine whether SA would depend on the ovular age of oocytes. Inhibiting of PBII extrusion was achieved by affecting microtubules with demecolcine or nocodazole or actin filaments with cytochalasin B (CB) and cytochalasin D (CD). We found that all oocytes undergo SA and progression to MIII; however, the rapidity of spontaneous activation is a function of the ovular age of the oocyte. The resumption of the meiosis period changes dramatically from 20 to 180 min with decreasing ovular age. We established that suppression of PB formation can be effectively achieved in oocytes of younger ovular age, and that inhibition of PB extrusion became irreversible after 3.5 h of treatment. We established that drug-treated oocytes could undergo subsequent reactivation and in vitro development to blastocysts. The rate of in vitro development of cytochalasin-treated group was comparable to parthenogenetic controls, while nocodazole and demecolcine produced oocytes that developed at lower frequencies. Thus, the application of the microfilament inhibiting drugs helps to overcome the negative effect of SA that results in MIII arrest. Here we also show optimized parthenogenetic stimulation that resulted in development to the blastocyst stage at frequency comparable to development of fertilized embryos.     

The localization of LAP2beta in bovine oocytes after in vitro activation and fertilization

The present study was designed to clarify the localization of LAP2beta and to compare it with those of lamins A/C and B in bovine oocytes after activation and in vitro fertilization (IVF). After fertilization, LAP2beta was not found until telophase II, and was observed around condensed chromatin after the extrusion of the second polar body, but not in activated oocytes. Although the reaction of LAP2beta was temporally negative or weak on the membrane of the growing small pronuclei, it became strong on the fully grown pronuclei of both activated and fertilized oocytes. Examination of the timing of DNA synthesis using bromodeoxyuridine revealed that the expression of LAP2beta on the pronuclear membrane became strong around the end of the DNA synthesis in both activated and fertilized oocytes. Both male and female pronuclei exhibited the same reactivity to all nuclear proteins examined. It was also shown that LAP2beta first assembled around condensed chromatin, followed by the integration of lamins B and A/C as in somatic cells. LAP2beta staining was maintained on the nuclear membrane of the embryonic cells at interphase until the later stage of preimplantational development. There were no differences between parthenogenetic and fertilized embryos in the expression and localization of LAP2beta from the PN-stage oocyte to the blastocyst. The assembly of LAP2beta was observed around the telophase chromatin of both blastocyst and cumulus cells. Thus, it was shown that the timing of the aggregation of LAP2beta at the second meiosis was different from that in the mitosis of blastocyst and somatic cells. LAP2beta was constantly expressed in the nuclear membrane in in vitro fertilized and parthenogenetic embryos as was lamin B, and lamin A/C was expressed stage-dependently in both types of embryos. Lamin A/C was positive in some inner cell mass cells of parthenogenetic blastocysts, but not those of in vitro fertilized embryos.     

Fertilization and development of quail oocytes after intracytoplasmic sperm injection

The present study was conducted to establish the intracytoplasmic sperm injection (ICSI) method for in vitro fertilization and development in quail. The efficiency of fertilization of oocytes was compared 1) between spontaneous and premature ovulation and 2) among testicular round spermatids, elongated spermatids, and immature and mature spermatozoa. The oocytes were injected with a single spermatozoon or spermatid and cultured for 24 h. Cell division was histologically observed with hematoxylin-eosin (HE) and a nucleus-specific fluorescent dye (DAPI). Five of 30 (16.6%) and 4 of 30 (13.3%) oocytes injected with mature sperm were fertilized in the spontaneous and induced ovulation group, respectively. Those embryos showed development at stages II-VII. Half the number (three of six) of the oocytes injected with testicular spermatozoa were fertilized and developed to stages IV-VII, and two of five oocytes injected with elongated spermatids were fertilized and developed to stage VI. All ooocytes injected with round spermatids were unfertilized. The results demonstrate that intracytoplasmic injection of a single sperm into quail oocyte can activate the oocyte and lead to fertilization. Oocytes prematurely ovulated are capable of fertilizing with mature sperm as are those spontaneously ovulated. In addition, the results suggest that the testicular round spermatids may not possess sufficient oocyte-activating potency but that the elongated spermatids and immature spermatozoa are competent to participate in fertilization and early embryonic development in quail.     

Pregnancy resulting from cattle oocytes matured and fertilized in vitro

Follicular oocytes (n = 81) collected from cattle at a local slaughterhouse were matured and fertilized in vitro. Of 27 ova 19 (70%) were penetrated by spermatozoa and 40/54 (74%) inseminated ova transferred surgically to the oviducts of a synchronized heifer were recovered by non-surgical flushing of the uterine horns 6 days later. Of the 40 ova 15 (38%) were at the morula, early blastocyst or diminutive morula stages. Culture in vitro sustained further development of all embryos and 9 were expanding or expanded blastocysts. One pregnancy resulted from non-surgical transfer of 2 blastocysts. The results demonstrate that immature oocytes from cattle can be matured and fertilized in vitro, subsequently develop to the blastocyst stage, and develop into a normal pregnancy after non-surgical transfer.     

Characterization of embryos derived from calf oocytes: kinetics of cleavage, cell allocation to inner cell mass, and trophectoderm and lipid metabolism

Embryos derived from calf oocytes were compared with adult cow oocyte-derived embryos (1) by studying the kinetics of embryo development using time-lapse cinematography (2) by evaluating the ratio between inner cell mass (ICM) and trophectoderm (TE) cells in blastocysts (3) by measuring the triglyceride content of the blastocysts. The rate of calf oocyte-derived embryos reaching the blastocyst stage was reduced (26 vs. 46% for adult derived embryos). Calf oocyte-derived embryos preferably arrested their development before the 9-cell stage. Those that developed into blastocysts had cleaved earlier to reach the 2-cell or 3-cell stages than embryos that arrested before the 9-cell stage. The 9-cell stage tended to appear later in calf oocyte-derived embryo that reached the blastocyst stage than in adult-derived embryos. This difference became significant at the morula stage. Accordingly, the fourth cell cycle duration was longer for calf oocyte-derived embryos. Day 8 blastocysts from both sources had similar total cell numbers (calf: 89 +/- 20; cow: 100 +/- 30) and cell distribution between TE and ICM. The triglyceride content of day 7 blastocysts was similar for both sources (64 +/- 15 vs. 65 +/- 6 ng/embryo, respectively). In conclusion, calf oocyte-derived embryos are characterized by a higher rate of developmental arrest before the 9-cell stage and by a longer lag phase preceding the major onset of embryonic genome expression. These changes might be related to insufficient "capacitation" of the calf oocyte during follicular growth. Despite these differences, modifications in the quality of the resulting blastocysts were not detected.     

Culture media for mouse oocyte maturation affect subsequent embryonic development

These experiments were done to determine whether the culture medium used for the spontaneous maturation of mouse oocytes can affect the subsequent capacity of the ova to become fertilized and complete preimplantation development in vitro and development to live young. Oocytes obtained from antral follicles of gonadotropin-primed immature mice underwent spontaneous maturation in control medium, i.e. Eagle's Minimum Essential Medium (MEM) supplemented with 5% fetal bovine serum, or in one of eight different media which were also supplemented with serum. All of the ova were fertilized in Whitten's medium and were assessed for cleavage to the 2-cell stage and for further preimplantation development to blastocysts during culture in Whitten's medium. Three of the eight media used for oocyte maturation improved the capacity of the ova to develop to the blastocyst stage when compared with the control: Waymouth MB 752/1, MEM with non-essential amino acids, and MEM Alpha; Waymouth medium promoted the highest frequency of development of ova to the blastocyst stage. Moreover, the blastocysts derived from oocytes that matured in Waymouth medium contained more cells than blastocysts derived from oocytes that matured in control medium. Although BGJb medium promoted the cleavage of eggs to the 2-cell stage when present during oocyte maturation, it had a detrimental effect on their subsequent preimplantation developmental capacity. Following transfer to foster mothers, more 2-cell stage embryos developed to live young after oocyte maturation in Waymouth medium (21%) than in control medium (13%).(ABSTRACT TRUNCATED AT 250 WORDS)     

Gene expression during mammalian oogenesis and early embryogenesis: quantification of three messenger RNAs abundant in fully grown mouse oocytes

Ribonuclease protection assays have been used to quantitatively assess changes in steady-state levels of specific mRNAs during oogenesis and early embryogenesis in mice. The mRNAs encode ZP3 (a glycoprotein that serves as a sperm receptor), LDH-B (heart-type lactate dehydrogenase), and MOM-1 (a protein of unknown function). MOM-1 and LDH-B are expressed in a variety of adult mouse tissues and midgestation embryos, whereas ZP3 expression is restricted completely to oocytes. All three mRNAs are expressed by growing mouse oocytes and accumulate to unusually high levels in fully grown oocytes as compared to somatic cells; 240,000, 200,000 and 74,000 copies mRNA per fully grown oocyte for ZP3, LDH-B and MOM-1, respectively. Steady-state levels of LDH-B and MOM-1 mRNA undergo a modest decline (approximately 20-40%) during ovulation when fully grown oocytes become unfertilized eggs and, in general, mirror the reported change in poly(A)+RNA levels during this period of development. On the other hand, the level of ZP3 mRNA declines dramatically (approximately 98%) during ovulation, from approximately 240,000 copies per oocyte to approximately 5000 copies per unfertilized egg, and ZP3 mRNA is undetectable in fertilized eggs (less than 1000 copies per fertilized egg). MOM-1 mRNA is expressed at relatively low levels in morulae (approximately 2000 copies per embryo) and blastocysts (approximately 5000 copies per embryo), whereas ZP3 mRNA remains undetectable (less than 1000 copies per embryo) at these stages of preimplantation development. These findings are discussed in the context of overall gene expression during oocyte growth, meiotic maturation and early embryogenesis in mice.     

Relationships between follicular fluid steroid hormone concentrations, oocyte maturity, in vitro fertilization and embryonic development in the rhesus monkey

Oocytes and matched samples of follicular fluid (FF) were obtained from 70 follicles of five rhesus monkeys stimulated with either pregnant mare serum gonadotropin or human menopausal gonadotropin. Follicular aspiration was performed 30-32 h after human chorionic gonadotropin administration. The concentrations of estradiol (E2), progesterone (P), testosterone (T), and dihydrotestosterone (DHT) in FF were measured. Twenty-six percent of oocytes were classified as mature (M), 41% matured in vitro (Miv), 13% were dysmature, and 20% atretic. M oocytes were associated with significantly higher levels of P and a higher P:E2 ratio. There were no differences in hormone levels associated with fertilized and nonfertilized oocytes. Thirty-five embryos developed to the six- to eight-cell stage in vitro, of which 13 exhibited optimal cleavage rates. Significantly lower levels of E2 and higher P:E2 ratios were associated with the more rapidly cleaving embryos. Proportionally more embryos showing optimal cleavage rates developed from M compared to Miv oocytes, and only embryos derived from M oocytes developed to blastocysts in culture. Optimal cleavage rates to the six- to eight-cell stage in vitro, rather than fertilization rates, are a better indicator of (subsequent) developmental capacity, and, in this study, embryonic development was closely associated with the maturity of the oocyte at recovery.