Poul Hyttel

Oocyte growth, capacitation and final maturation in cattle

Abstract The oocyte growth phase includes a series of modulations of organelles and inclusions, as well as a period of oocyte transcription, which are necessary for the oocyte to achieve meiotic and developmental competence. Oocyte transcription including nucleolar function (rRNA-synthesis) is activated in the secondary follicle and is maintained up to an oocyte diameter of about 110 μm in the 3 mm tertiary follicle. At a diameter of 100 to 110 μm, the oocyte gradually achieves the competence to undergo meiotic maturation and sustain embryonic development. In the dominant follicle the oocyte undergoes further ultrastructural modifications and attains full developmental competence through a process that may be termed “capacitation”. The final oocyte maturation up to metaphase II after LH stimulation of the ovulatory follicle is the culmination of the previous processes and equips the oocyte with a haploid chromosomal compartment and the cell biological apparatus specialized for fertilization and initial embryonic development.

Effects of in vivo prematuration and in vivo final maturation on developmental capacity and quality of pre-implantation embryos

In current in vitro production (IVP) systems, oocytes lack in vivo dominant and preovulatory follicular development, which may compromise pregnancy and viability of calves born. When an oocyte sets off in vivo on the road toward fertilization, it contains numerous transcripts and proteins necessary to survive the first few cell cycles of embryonic development. It is not yet known during which period of development the oocyte builds up the store, possibly primarily during the major growth phase of the oocyte, which is completed at the time a follicle reaches the size of 3 mm. Here, we investigated to what extent the later phases of follicular development, such as prematuration in the dominant follicle before the LH surge and ensuing final maturation in the preovulatory follicle, contribute to oocyte competence and development into viable biastocysts. Recent studies on in vivo vs in vitro oocyte maturation employed oocytes from an identical preovulatory development by applying ovum pick-up (OPU) twice (before and 24 h after the LH surge) in each cow treated for superovulation with a controlled LH surge. The embryo recovery rates at Day 7 of IVC after IVF were similar: 44% (97/219) for in vivo- vs 41% (87/213) for in vitro-matured oocytes, which shows that the natural environment during final maturation is not essential for the mere in vitro development of the prematured oocyte beyond the 8- to 16-cell stage. However, in vivo maturation appeared to contribute to the oocytes quality in a more subtle way, as indicated by a significant increase in the proportion of expanded blastocysts and a more physiological degree of chromosome aberrations of the embryos. In blastocysts derived from in vivo-matured oocytes, 21% of the embryos were mixoploid vs 50% from in vitro-matured oocytes, concomitant with a higher number of cells (96 vs 54 per normal blastocyst). The expression pattern of a set of six developmentally important genes was, however, not significantly altered in blastocysts derived from in vivo-matured oocytes. Certain deviations were observed compared with the levels of entirely in vivo-developed control blastocysts, which suggests that the beneficial effects of in vivo maturation are possibly exerted at initial stages of embryonic development. Prematuration in vivo, occurring in a dominant follicle developing from about 8 mm into the preovulatory follicle, is accompanied by changes in protein synthesis of the cumulus oocyte complex (COC). Presumably, the differentially expressed proteins are involved in equipping the oocyte with further developmental competence. Although we have unraveled some important biochemical and cellular biological features of the oocyte, further research on in vivo processes is essential to improve in vitro embryo production in practice.

The influence of time of insemination relative to time of ovulation on farrowing frequency and litter size in sows, as investigated by ultrasonography

The objective of this experiment was to identify the optimal time of insemination relative to the time of ovulation, based on ultrasonographic detection of embryonic survival at 10 days after ovulation, number of sows farrowing, and litter size. Furthermore, the possible value of the interval from weaning to onset of estrus for prediction of the time of ovulation was examined. Crossbred sows (n = 143) that had farrowed 2 to 9 litters were weaned (Day 0) and observed for estrus every 8 h from Day 3 until end of estrus. Ultrasonography was performed every 6 h, from 12 h after onset of estrus until ovulation had been observed. The sows were inseminated once at various time intervals from ovulation. At Day 16, 25 of the sows were slaughtered and their uteri were flushed for embryos. In the remaining sows, the number of viable and dead piglets and mummified fetuses per sow was recorded at farrowing, with the sum of the 3 constituting the total number of piglets born per sow. The highest number of embryos recovered per sow was found after insemination during the interval from 24 h before to 4 h after ovulation. The lowest frequency of non-pregnant sows and the highest total number of piglets born per sow were found after insemination from 28 h before to 4 h after ovulation. Consequently, the optimal time for insemination was found to be in the interval 28 h before to 4 h after ovulation. The interval from weaning to onset of estrus and from onset of estrus to ovulation were negatively correlated, allowing a rough prediction of the time of ovulation from the interval from weaning to onset of estrus.

Somatic cell cloning without micromanipulators.

Until now, micromanipulators have been regarded as indispensable for somatic cell nuclear transfer. This paper describes an improved zona-free nuclear transfer procedure with manual bisection of oocytes, selection of cytoplasts by Hoechst staining, and two-step fusion of somatic cells from primary granulosa cell cultures with two cytoplasts. Blastocyst rates in the three systems tested for zona-free embryo culture were 0%, 18%, and 36% for microdrops, well of the wells (WOW system), and microcapillaries (GO system), respectively. This simple, rapid, and inexpensive procedure may become a useful alternative to the existing techniques for somatic cell nuclear transfer for large-scale application of the technology.

Oocyte ultrastructure in bovine primordial to early tertiary follicles.

Abstract The aim of the present study was to describe in detail the changes occurring in the cytoplasmic ultrastructure of the bovine oocyte from the onset of growth in the primordial follicle until the completion of growth in the tertiary follicle. Bovine oocytes from primordial, primary, secondary and early to mid-antral follicles were processed and analysed by light and transmission electron microscopy. The primordial follicular oocyte was characterized by numerous coated pits on the oolemma and the accumulation of free and organelle-related smooth (SER) and rough (RER) endoplasmic reticulum, round mitochondria and Golgi complexes around the nucleus, which was located slightly off centre. Up to the secondary follicular stage the oocyte displayed an increase in the number of microvilli, elongated mitochondria and Golgi complexes. During the secondary follicular stage, formation of the zona pellucida, development of gap junctions between the oocyte and the granulosa cells, formation of the cortical granules in the oocyte and reduction in the number of coated pits on the oolemma were seen. In the tertiary follicular oocyte up to 100 μm in diameter, the number of Golgi complexes and lipid droplets increased and the organelles were dislocated to the deep cortical region. During the final growth of the oocyte up to >120 μm, the organelles were dislocated further to the peripheral region, the extent of the free SER and RER compartments were reduced, the number of individual cortical granules increased, hooded mitochondria became abundant and the perivitelline space developed. In conclusion, the growth of the bovine oocyte is associated with the relocation and modulation of a number of cytoplasmic organelles as well as the development of oocyte specific structures such as the zona pellucida and cortical granules.

Effect of nutrition and superovulation on oocyte morphology, follicular fluid composition and systemic hormone concentrations in ewes

The objective was to determine the effect of dietary intake on follicle and oocyte morphology in unstimulated and superovulated ewes. Fifty-four ewes were fed grass meal at 0.5, 1.0 or 2.0 times maintenance energy requirements (M) for 32 days. Oestrous cycles were synchronized using progestagen pessaries and either unstimulated or superovulated with 200 mg pig FSH. The ewes were killed and ovaries were collected either 36 or 12 h before the anticipated LH surge. Serum progesterone concentrations in ewes on day 10 after withdrawal of the pessary were lower in ewes fed 2.0M than in ewes fed 0.5M or 1.0M (P < 0.05). LH pulse frequency tended to be higher in ewes fed 2M than 1M (1.0 +/- 0.3 versus 0.3 +/- 0.2 pulses per 8 h) on day 6 after removal of the pessary but the effect was not significant. In unstimulated ewes, more follicles (>/= 3 mm) were observed when the animals were killed in ewes fed 2.0M (3.5 +/- 0.3) than in ewes fed 0.5M (2.4 +/- 0.3) or 1.0M (2.4 +/- 0.5; P < 0. 05). Fewer follicles were observed in superovulated ewes on 0.5M (7. 5 +/- 1.2) than in ewes on 1.0M (12.0 +/- 0.5) or 2.0M (12.3 +/- 1. 4; P < 0.05). Follicular fluid progesterone concentrations were higher in ewes fed 0.5M compared with those fed 1M or 2M (P < 0.05). Insulin-like growth factor (IGF)-I concentrations were higher in follicular fluid from ewes on 1M compared with either those on 0.5M or 2M (P < 0.05), whereas IGF-II concentrations were lower in follicular fluid from ewes on 2M compared with those on 1M or 0.5M (P < 0.05). Superovulation increased follicular fluid progesterone, oestradiol, IGF-I and IGF-II concentrations (P < 0.01). Concentrations of the 34, 22 and 20 kDa IGF binding proteins were lower in follicles from superovulated ewes compared with unstimulated ewes (P < 0.05). Oocytes from superovulated ewes showed abnormalities such as premature activation of cumulus expansion and vacuolation of the nucleolus and increased frequency of detachment of interchromatin-like granules from the nucleolar remnant. Collectively, these results indicate that both high and low dietary intakes can alter systemic and follicular fluid hormone concentrations. Relative to dietary effects, the effects of superovulation were greater and involved substantial increases in follicular fluid hormone concentrations and abnormal oocyte morphology.

Rapid Method to Prepare Mammalian Oocytes and Embryos for Transmission Electron Microscopy

A method for the preparation of mammalian oocytes and embryos for transmission electron microscopy employing agar embedding of oocytes and re-embedding of semithin sections is described. This method offers rapid and safe handling of small specimens, and it allows analyses of even very small structures in the oocytes.

The effects of exogenous gonadotropins on oocyte and embryo quality in cattle

Abstract It is well documented and unfortunately accepted that approximately 15 to 20% of all donor cattle superstimulated with eCG or FSH yield no transferable embryos. In the present paper, some factors leading to reduced oocyte and embryo quality are discussed. We have focused firstly on certain endocrine and oocyte maturational features which take place during the period of luteal regression, i.e. the period from PGF2α administration until the preovulatory LH surge, and secondly, on the relationship between the superovulatory response and the embryo quality on Day 7. We conclude that: 1) treatment with eCG or FSH causes increased estradiol-17β plasma levels, suppressed episodic LH secretion, earlier occurrence of the LH surge and the nucleoli of oocytes from undergoing the normal vacuolization in a certain proportion of donor cattle, 2) although subtle and hardly measurable, these deviations have a profound effect on the subsequent embryonic developmental capacity, 3) the superovulatory response does not affect the subsequent viability of embryos transferred on Day 7 and 4) optimization of the donors reproductive physiology is the only way to reduce the incidence of non-transferable embryos.

Ultrastructure of bovine blastocysts following cryopreservation: Effect of method of blastocyst production

The objective of this study was to describe the ultrastructure of blastocysts derived by in vivo and in vitro methods and to investigate how the morphology is affected by exposure to cryoprotectant (10% glycerol) or cryopreservation by conventional slow freezing. In vivo derived blastocysts were characterized by a narrow perivitelline space (PvS), a continuous cover of numerous stacked microvilli (MV) on the plasma membrane, a well‐defined system of cell‐to‐cell coupling and a large population of round or elongated mitochondria with numerous transverse cristae. Exposure of these blastocysts to cryoprotectant was manifested by shrinkage of the blastocysts and swelling of the mitochondria. Cryopreservation resulted in further shrinkage, damage to the MV, and accumulation of cellular debris. In comparison, the in vitro matured (IVM)/in vitro fertilized (IVF) in vivo cultured blastocysts displayed a wider PvS; they appeared to possess less MV and all blastocysts displayed some cellular debris in their PvS. There was also a decrease in the number of junctional contacts between the trophoblastic cells. The reaction of these blastocysts to exposure to cryoprotectant was similar to that of the in vivo derived blastocysts. However, they appeared to be more susceptible to cryopreservation. The totally in vitro produced (IVP) blastocysts displayed a wider PvS, no stacking of the MV, increased numbers of lipid droplets and a further reduction in the junctional contacts between trophoblastic cells. The IVP blastocysts sustained breakage of the zona pellucida on exposure to cryoprotectant and were extremely sensitive to cryopreservation, losing all cell structure and organization. The findings of the present study indicate that in vivo derived blastocysts possess certain structural characteristics that confer a greater tolerance on them to exposure to cryoprotectant and cryopreservation. Mol. Reprod. Dev. 58:186–195, 2001.

Transcriptional activity in in vitro produced bovine two- and four-cell embryos

The objectives of this study on in vitro produced bovine two‐ and four‐cell embryos were (1) to investigate the uptake of 3H‐uridine through the plasma membrane, (2) to characterize the pattern of RNA synthesis during the second cell cycle, and (3) to measure the incorporation of 3H‐uridine into de novo synthesized RNA. A total of 200 embryos were incubated with 3H‐uridine for 15, 30, 60 (two‐ and four‐cell embryos), 120 (four‐cell embryos), 180 (two‐cell embryos), and 240 min (two‐ and four‐cell embryos), respectively. 3H‐uridine uptake reached a maximum by 30 min in two‐cell embryos, whereas four‐cell embryos reached a maximum at 120 min. A total of 440 two‐cell embryos were isolated 27–33 hr postinsemination (hpi), and 90 of these were incubated for 10 hr with 3H‐uridine (200 μCi/ml). The remainder were incubated with 3H‐uridine for 3 hr starting at 0–3 (n = 54), 3–6 (n = 75), 6–9 (n = 77), or 9–12 (n = 77) hr after cleavage to the two‐cell stage. Control two‐cell embryos (n = 67) were incubated with 3H‐uridine supplemented with 5 mg/ml of unlabelled uridine for 10 hr (inhibition control), or they were incubated with 3H‐uridine for 10 hr and RNase treated (100 μg/ml post fixation (RNase control). Subsequently, the embryos were processed for autoradiography. The long‐term incubation revealed transcription (autoradiographically labelled nuclei) in a total of 77% of the two‐ and four‐cell embryos. No transcription was observed in any of the 3 hr incubation groups. The RNase control embryos lacked labelling of the nuclei, whereas the inhibition control embryos only showed markedly reduced labelling. Finally, total RNA extraction was performed on a total of 336 two‐cell embryos that were incubated with 3H‐uridine or 3H‐uridine supplemented with unlabelled uridine for 2, 5, or 10 hr. It was possible to detect an increasing amount of labelled RNA after the 2, 5, and 10 hr incubation periods, and it was possible to inhibit this incorporation competitively. Together the data demonstrate a low level of transcription during the second cell cycle without a well‐defined transcriptional peak.