The effect of glutamine on the development of sheep embryos in vitro

The effects of glutamine (Gln) on the in vitro development of sheep embryos cocultured with sheep oviduct epithelial cells (SOEC) or cultured in medium alone were investigated. The in vitro development was evaluated after culture in synthetic oviduct fluid (SOF) medium to Day 6, and then the viability of some of the morula/blastocyst stage embryos was assessed by transfer into recipient ewes. In Experiment 1, sheep embryos were cultured from Day 2 to Day 6 in SOF containing 0 or 1 mM Gln with or without (SOEC) support in a 2 x 2 factorial design. An interaction was found between the effects of Gln and SOEC (P<0.001). The addition of Gln increased blastocyst formation (6%, 2 36 vs 35%, 11 31 ) and the rate of pregnancy (50%, 4 8 vs 100%, 5 5 ) when the embryos were cultured in medium alone, but had no beneficial effect in the presence of SOEC. In Experiments 2 and 3, sheep embryos were cultured from Day 1 to Day 6 in SOF supplemented with 1 mM Gln, with 1 mM alpha-ketoglutarate or without supplementation (control). In Experiment 2, no other amino acids were added, but in Experiment 3 SOF was supplemented with 19 other amino acids. In Experiment 2, when Gln was the only amino acid, the rate of blastocyst formation was increased by the addition of Gln (24%, 8 35 ), but alpha-ketoglutarate caused no increase in blastocyst formation (3%, 1 34 ) compared to the control group (6%, 2 34 ). In Experiment 3, when 19 other amino acids were added, neither Gln nor alpha-ketoglutarate affected the rate of blastocyst formation or the subsequent development of embryos in recipient ewes. These results showed that Gln, when used as a single amino acid, has a beneficial effect on the development of sheep embryos in serum free culture without somatic cells. The data suggest that Gln is used as a source of amino groups rather than as a source of energy since no beneficial effects were found when its deaminated carbon skeleton (alpha-ketoglutarate) was used or when other amino acids were present.     

Effects of in vitro production on horse embryo morphology,cytoskeletal characteristics,and blastocyst capsule formation

Blastocyst formation rates during horse embryo in vitro production (IVP) are disappointing, and embryos that blastulate in culture fail to produce the characteristic and vital glycoprotein capsule. The aim of this study was to evaluate the impact of IVP on horse embryo development and capsule formation. IVP embryos were produced by intracytoplasmic sperm injection of in vitro matured oocytes and either culture in synthetic oviduct fluid (SOF) or temporary transfer to the oviduct of a ewe. Control embryos were flushed from the uterus of mares 6-9 days after ovulation. Embryo morphology was evaluated with light microscopy, and multiphoton scanning confocal microscopy was used to examine the distribution of microfilaments (AlexaFluor-Phalloidin stained) and the rate of apoptosis (cells with fragmented or terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling-positive nuclei). To examine the influence of culture on capsule formation, conceptuses were stained with a monoclonal antibody specific for capsular glycoproteins (OC-1). The blastocyst rate was higher for zygotes transferred to a sheep's oviduct (16%) than for those cultured in SOF (6.3%). Day 7 IVP embryos were small and compact with relatively few cells, little or no blastocoele, and an indistinct inner cell mass. IVP embryos had high percentages of apoptotic cells (10% versus 0.3% for in vivo embryos) and irregularly distributed microfilaments. Although they secreted capsular glycoproteins, the latter did not form a normal capsule but instead permeated into the zona pellucida or remained in patches on the trophectodermal surface. These results demonstrate that the initial layer of capsule is composed of OC-1-reactive glycoproteins and that embryo development ex vivo is retarded and aberrant, with capsule formation failing as a result of failed glycoprotein aggregation.     

Amino acids in oviduct and uterine fluid and blood plasma during the estrous cycle in the bovine

Up to 40% of cattle embryos die within 3 weeks of fertilization while they are nutritionally dependent on the maternal environment provided by the oviduct and uterine fluids for their development and survival. Despite this dependence there is limited information on the composition of these fluids in cattle. Amino acids are essential for the normal growth and development of the early embryo, acting as precursors of proteins and nucleic acids and as energy sources, osmolytes and signaling molecules. The objective of this study was to measure and compare the amino acid concentrations of oviduct and uterine fluid and blood plasma on different days of the estrous cycle. Oviduct fluid was collected in situ from anaesthetised heifers on Days 0, 2, 3, 4 and 6 and uterine fluid on Days 6, 8 and 14 of the estrous cycle and the concentrations of 19 amino acids determined. Glycine was the most abundant amino acid in both oviduct and uterine fluid. However, the concentrations of many amino acids differed between oviduct and uterus and many were present at higher concentrations in oviduct and uterine fluid than in blood plasma. Oviduct fluid concentrations of amino acids were not affected by day of cycle in contrast to uterine fluid for which there was a day of cycle effect on most of the amino acids. These results provide novel information on the amino acid concentrations in the maternal environment of the early cattle embryo and could form the basis for devising improved media for the production of embryos in vitro.     

Modifications made to culture medium by bovine oviduct epithelial cells: Changes to carbohydrates stimulate bovine embryo development

Co-culture remains a common method to support the development of bovine embryos, derived from IVM/IVF procedures. However, the mechanism by which somatic cells confer their benefit to the developing embryo remains undetermined. This study therefore analysed the changes made to the culture medium TCM-199, used in bovine embryo co-culture systems, by somatic cells and determined the effects of specific changes in medium composition on bovine embryo development in culture. Bovine oviduct epithelial (BOE), Buffalo rat liver (BRL) and fibroblast (3T3) cells were compared. The concentrations of glucose, L-lactate, pyruvate, amino acids, NH₄⁺, H⁺ and the gas tensions of O₂ and CO₂ were measured in TCM-199 supplemented with 10% fetal calf serum (FCS) prior to and directly following 48 h incubation periods with each cell type. All three somatic cell types modified the carbohydrate composition of the media in a similar manner with the greatest changes made by the BOE cells. Notable alterations were an increase in the levels of L-lactate and pyruvate and a reduction in glucose concentration, which in the case of the BOE cells, fell from 5.55 mM to 2.67 mM. In order to determine the relevance of such changes in carbohydrate concentrations on bovine embryo development, modifications were made to carbohydrate levels in synthetic oviduct fluid (SOF) medium and their effect on blastocyst development in vitro assessed. In SOF medium supplemented with amino acids and BSA (SOFaa), significantly more zygotes developed to the blastocyst stage (64%; P < 0.01) than in SOFaa medium with the concentrations of glucose, D/L-lactate and pyruvate equivalent to those in TCM-199 (11%). Interestingly, when the levels of carbohydrates in SOFaa mimicked those present in TCM-199 following a 48 h incubation with BOE cells, 57% of zygotes reached the blastocyst stage. This improvement was ascribed to the reduction in glucose and increases in D/L-lactate and pyruvate concentrations in the culture system. Results from this study demonstrate that BOE cells create an environment favourable to embryonic development. The analysis of media samples by enzymatic methods meant that only the biologically active L-isomer of lactate was quantified. However, in SOFaa, both the L-isomer and inactive D-isomer are present in equimolar amounts. As such, culture media in which D/L-lactate syrup is used actually contain only 50% biologically active lactate meaning that all D/L-lactate concentrations are reported at twice the effective concentration. Therefore the effect of D/L-lactate concentration on blastocyst development was subsequently determined in this study. Blastocyst development was poor (24–36%) until the total D/L-lactate was present in the culture system at concentrations equal to or greater than 0.82 mM. However, blastocyst cell numbers remained low (60.1 ± 6.9 – 78.5 ± 6.6) until a total D/L-lactate concentration of 3.3 mM. This data reinforces that embryo morphological appearance is not sensitive enough to be used as the sole criterion for assessing embryo development. Mol Reprod Dev 46:146–154, 1997. © 1997 Wiley-Liss, Inc.     

In vitro-matured/in vitro-fertilized bovine oocytes can develop into morulae/blastocysts in chemically defined, protein-free culture media.

Development of bovine embryos derived from in vitro-matured/in vitro-fertilized (IVM/IVF) oocytes was examined in two culture media: hamster embryo culture medium (HECM), a relatively simple, chemically defined, protein-free medium containing 20 amino acids; and tissue culture medium (TCM)-199, a more complex medium designed for culture of somatic cells. The first experiment studied (1) effects of glucose and/or phosphate (Pi) using HECM and (2) the development of bovine IVM/IVF embryos in four different conditions: HECM, TCM-199, TCM-199 + 10% unheated bovine calf serum (BCS), and oviduct cell-conditioned TCM-199 + 10% BCS. After IVF, 45% of the inseminated oocytes developed to the morula/blastocyst stages (M&B) when cultured in HECM; blastocyst development was depressed in the presence of glucose and Pi when compared to Pi alone. When the four culture conditions were compared, there was no significant difference in M&B development (42-51% of inseminated oocytes). However, blastocyst development in TCM-199 supplemented with 10% BCS (29.7%) or with BCS + oviduct cell-conditioned medium (21.6%) was significantly greater than in nonsupplemented HECM (9.7%) or TCM-199 (13.8%). In the second experiment, the effects of serum supplementation and/or oviduct cell conditioning on HECM and TCM-199 were examined in a 2 x 2 x 2 factorial experiment. Oviduct cell conditioning of either HECM or TCM-199 without serum supplementation did not enhance bovine embryo development. Serum supplementation exhibited a biphasic effect, with inhibition at the first cleavage and stimulation of morula compaction and blastocyst formation.(ABSTRACT TRUNCATED AT 250 WORDS)     

胚胎体外共培养：影响因素及作用机理

综述了近年来关于哺乳动物早期胚胎与体细胞共培养的研究进展。重点讨论了早期胚胎与不同类型体细胞共培养,血清、发情周期和体细胞传代次数对胚胎共培养效果的影响,以及胚胎体外共培养的作用机理。体细胞共培养体系可以改善早期胚胎体外培养的条件,促进胚胎发育,提高着床率和妊娠率,在发育生殖研究领域有着广泛的应用前景。然而,对其影响因素和作用机理尚欠系统深入研究,许多问题还亟待解决。     

Stimulation of early embryonic development in the sheep by co-culture with oviduct epithelial cells

To examine the effects of somatic cell support on the cleavage and viability of fertilized sheep eggs, 434 pronucleate eggs were co-cultured for 3 or 6 days on oviduct cells or fibroblasts and 77 eggs were cultured in medium alone. During the first 3 days in culture 95% of the single-celled eggs cleaved regularly to non-compacted morulae on either of the feeder-layers but only 13% underwent similar regular cleavage in medium alone. Despite the identical cleavage rates in the co-culture groups, only 33% of embryos grown on fibroblasts as compared with 80% of embryos grown on oviduct cells were fully viable as judged by their ability to develop normally after transfer to recipient animals. The viability of embryos in the oviduct group was equal to that obtained after the direct transfer of morulae from donor to recipient sheep. After 6 days in culture 42% of embryos co-cultured with oviduct cells developed into expanded blastocysts as compared with only 4.5% cultured on fibroblasts. In both co-culture groups virtually all the remaining embryos blocked during the 4th cleavage. When transferred, 30% of blastocysts grown from the pronucleate stage on oviduct cells were viable. We conclude that: (1) during the first 3 days after fertilization cleavage will progress at a normal rate on different feeder-layers but oviduct cells appear to be required for the acquisition of full embryonic viability.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro development up to hatching of bovine in vitro-matured and fertilized oocytes with or without support from somatic cells

To verify the importance of somatic cells upon in vitro embryo development, in vitro-matured (IVM) and -fertilized (IVF) bovine oocytes were cultured in TCM 199 supplemented with estrous cow serum (10% v/v) and 0.25 mM sodium pyruvate (ECSTCM) under the following treatments: 1) ECSTCM alone; 2) together with bovine oviduct epithelial cells (BOEC); 3) with cumulus cells (CC); 4) in fresh BOEC conditioned ECSTCM; or 5) in frozen-thawed BOEC conditioned ECSTCM. Culturing zygotes encased in cumulus cells significantly reduced the cleavage rate (P<0.05). There was no difference between culture systems in the proportions of embryo development through the 8-cell stage (P=0.42) up to the morula/blastocyst stages (P=0.50) at Day 7 post insemination. However, co-culture with BOEC yielded the highest percentage (21.2% of zygotes; P<0.05) of quality Grade-1 and Grade-2 embryos with the number of blastomeres per embryo (114.4) comparable to that of 7-day-old in vivo-developed embryos of similar grades (102.5), and higher (P<0.05) than those of the other treatments. The ratio of blastocysts to total morulae/blastocysts obtained from frozen-thawed conditioned medium was lower (P<0.05) than that from ECSTCM or after co-culture with BOEC at Day 7 post insemination. On average, 7.5 to 17.5% of the zygotes developed to blastocyst, expanded blastocyst and hatched blastocyst stages by Day 10 post insemination, depending upon the culture system. The difference between treatments, however, was not significant (P=0.68). The results indicate that chronological development up to hatching of bovine IVM-IVF embryos is not favored by somatic cells; however, the presence of viable oviduct epithelial cells in culture significantly improves the quality of 7-day-old embryos.     

Extracellular proteins in plant embryogenesis.

In many plant species nonzygotic embryos can develop from diploid somatic cells grown in tissue culture. Extracellular glycoproteins have been identified that can rescue arrested somatic embryos. One of these glycoproteins may be part of a mechanism that controls the expansion of plant cells.     

Influence of ovine oviducal amino acid concentrations and an ovine oestrus-associated glycoprotein on development and viability of bovine embryos

This study examined the effects of incorporating an ovine oviducal oestrus-associated glycoprotein (oEGP) and amino acids, at the concentrations present in the ovine oviduct around the time of oestrus, on in vitro production and subsequent viability of bovine embryos. The first experiment compared the influence of ovine oviducal concentrations of amino acids with MEM and BME amino acids. There was no treatment effect on cleavage rate (74.9% vs. 75.5%), but there was a higher (P < 0.05) blastocyst yield (30.4 vs. 25.2) and a shorter time (P < 0.05) to blastocyst formation (7.16 ± 0.64 vs. 7.27 ± 0.56 days) following use of oviducal concentrations of amino acids. Experiment 2 examined the influence of oEGP in combination with each of the amino acid treatments. oEGP had no effect on cleavage or blastocyst yield within amino acid treatments. Day of blastocyst formation significantly influenced nuclei numbers (P < 0.001) with higher numbers being obtained on day 7 than on either day 6 or day 8. There was also a significant (P < 0.01) interaction between day of blastocyst formation and amino acid treatment on blastocyst nuclei numbers. The third experiment studied the effects of the amino acid treatments on embryo viability. There was no effect of amino acid treatment of embryos on pregnancy rates (34.5 vs. 44.4%) following transfer of days 6 and 7 blastocysts to synchronized recipients. oEGP did not influence any of the parameters of bovine embryo development that were measured, suggesting that effects of this protein observed on ovine embryos are species specific. It is concluded that ovine oviducal amino acid concentrations are beneficial to blastocyst development in vitro but do not have any further beneficial effect following transfer of blastocysts to recipients. Mol. Reprod. Dev. 47:164–169, 1997. © 1997 Wiley-Liss, Inc.     

Nutrient concentrations in murine follicular fluid and the female reproductive tract

The culture of murine oocytes and preimplantation embryos in vitro has been used successfully for many years. However, this practice can result in cellular stress and reduced viability. Since this phenomenon is partly attributable to differences in nutrient composition between culture media and maternal tract fluids, we determined the concentrations of glucose, pyruvate, lactate and 19 amino acids in murine preovulatory follicles and oestrous oviductal and uterine fluids. Follicular fluids were aspirated from hyperstimulated ovaries, whereas oviductal fluids (with/without oocyte-cumulus complexes) and uterine fluids were collected from naturally cycling animals. Glucose, pyruvate and lactate concentrations were analysed using ultramicrofluorometric methods, whilst amino acid profiles were determined by reverse-phase high performance liquid chromatography. Mean glucose concentrations in follicular, oviduct (with/without cumulus cells) and uterine fluids were 0.46, 1.09/1.65 and 0.61 mmol l(-1), respectively. Pyruvate concentrations were 0.38, 0.37/0.17 and 0.25 mmol l(-1), respectively, and lactate concentrations were 17.34, 10.92/11.68 and 9.41 mmol l(-1), respectively. Oviductal pyruvate concentration was significantly higher, and glucose significantly lower, in the presence of cumulus cells. Taurine, glycine, alanine, glutamine and glutamate were the major amino acids detected. Concentrations of amino acids differed among fluids, with highest levels being found in the oviduct. The follicular fluid and tract nutrient profiles differed from those of murine maturation, fertilisation and embryo culture media. These data extend our understanding of cellular metabolism and of nutritional environments of the oocyte and early embryo as they progress along the reproductive tract in vivo. These results may also contribute to the formulation of nutritionally more physiological media for mouse oocyte maturation and embryo culture.     

Development, freezability and amino acid consumption of bovine embryos cultured in synthetic oviductal fluid (SOF) medium containing amino acids at oviductal or uterine-fluid concentrations

In this study, we examined the development, freezability and amino acid consumption of in vitro produced bovine embryos cultured in a chemically defined medium (SOF+polyvinyl alcohol), supplemented with 24 amino acids at concentrations measured in bovine oviductal or uterine fluid. Amino acids at concentrations in oviductal fluid tested by Elhanssan (EOAA) significantly improved development to the hatched blastocyst stage, compared to Sigma amino acid solutions BME and MEM (SAA). Amino acids at concentrations in uterine fluid tested by Li (LUAA) were not compared to SAA, and development in LUAA was not significantly different from development in EOAA. Amino acids at concentrations in uterine fluid tested by Elhanssan (EUAA) significantly reduced cleavage rate and blocked further embryo development. When the IVF embryos were cultured in EOAA for 48, 72, 96, or 120 h and then transferred to LUAA, blastocyst and hatched blastocyst rates were not significantly affected. The freezability of blastocysts cultured in EOAA for the first 72 h and then moved to LUAA was improved compared to that in SAA. During the 1-8-cell stages, embryos secreted all 23 amino acids (total, 6,368 pmol/embryo). During the 8-cell to morula stages, embryos continued to secrete 21 amino acids (total, 2,495 pmol/embryo), meanwhile embryos began to absorb Arg (70 pmol/embryo) and Gln (18 pmol/embryo). After the morula stage, embryos began to absorb 15 amino acids including Glu, Gly, Arg, and Gln (total, 2,742 pmol/embryo) and secreted eight amino acids (total, 1,616 pmol/embryo). Embryos absorbed only Arg (183 pmol/embryo) and secreted the other 22 amino acids (total, 3,697 pmol/embryo) when the culture medium was not changed during the entire culture period (zygote to blastocyst).     

Regeneration of somatic embryos in Theobroma cacao L. in temporary immersion bioreactor and analyses of free amino acids in different tissues

The present study aimed at developing temporary immersion bioreactor techniques for multiplication of cacao somatic embryos. Temporary Immersion System (TIS), i.e. flooding of plant tissue at regular time intervals provides an efficient way to propagate plants. Somatic embryos were regenerated in twin flask bioreactors. The TIS proved to be suitable for mass regeneration of somatic embryos and for their subsequent direct sowing. The number of embryos after 3 months of culture was significantly higher in TIS cultures than in the solid medium variant. TIS also improved embryo development regarding the conversion to torpedo shaped forms. Matured embryos derived from TIS and pre-treated with 6% sucrose were converted into plants after direct sowing. Additionally to the influence of culture conditions on the development of somatic embryogenesis the content and composition of free amino acids were analysed. The content of free amino acids in somatic embryos rose as immersion frequency increased. The endogenous free GABA content in embryogenic callus was significantly higher than in non-embryogenic callus.     

Modulation of gamete and embryonic microenvironments by oviduct glycoproteins

Studies on protein molecules in oviduct luminal fluid are viewed historically, and then in terms of more recent studies on a possible involvement of unique glycoproteins in embryonic development. As a caution, however, it is noted that incorporation of such molecules into the vitellus may be nonspecific. The question is raised as to whether oviduct glycoproteins could be acting primarily in a physical sense to stabilize differing chemical environments along the oviduct. Equally or more importantly, glycoproteins might be acting as carrier molecules to present cations and metabolic substrates at appropriate concentrations to the vitelline membrane. This latter possibility is examined in some detail and could be tested by manipulating the composition of the perivitelline fluid. Glycoproteins may also be critically involved in regulating the physiological competence of spermatozoa in the pre- and peri-ovulatory oviduct, in maintaining a coordinated pattern of cilial beat, and in immunosuppressive functions within the oviduct, not least in those associated with the masking of paternal antigens on both spermatozoa and embryos. © 1994 Wiley-Liss, Inc.     

Regulation of starch and protein accumulation in alfalfa (Medicago sativa L.) somatic embryos

Compared to seeds, somatic embryos accumulated relatively low levels and different types of storage carbohydrates. The regulation of starch accumulation was studied to determine its effects on desiccation tolerance and vigor of dry somatic embryos. Somatic embryos of Medicago sativa are routinely matured through three phases: 7 days of development; 10 days of phase I maturation, a rapid growth phase; and 10 days of phase II maturation, a phase leading to the acquisition of desiccation tolerance. The control of starch deposition was investigated in alfalfa somatic embryos by manipulating the composition of the phase I maturation medium with different levels of sucrose, abscisic acid, glutamine and different types of carbohydrates and amino acids. After phase II maturation, mature somatic embryos were collected for desiccation and subsequent conversion, or for biochemical analyses. Starch deposition occurred primarily during phase I maturation, and variations in the composition of this medium influenced embryo quality, storage protein and starch accumulation. A factorial experiment with two levels of glutamine × three levels of sucrose showed that increasing the sucrose concentration from 30 to 80 g/l increased embryo size and starch content, but had minimal effect on accumulation of storage proteins; glutamine also increased embryo size, but decreased starch content and increased accumulation of the high salt soluble S-2 (medicagin) storage proteins. ABA did not influence any of the parameters tested when included in phase I maturation at concentration up to 10 μM. Replicating sucrose with maltose, glucose, or glucose and fructose did not alter embryo size or starch accumulation (mg/g fresh weight), but replacement with fructose alone reduced embryo size, and replacement with glucose alone reduced germination. Suplementation with the amino acids, asparagine, aspartic acid and glutamine increased seedling vigor, but decreased the starch content of embryos. The data indicate that starch accumulation in somatic embryos is regulated by the relative availability of carbon versus nitrogen nutrients in the maturation medium. The quality of mature somatic embryos, determined by the rate of seedling development (conversion and vigor), correlated with embryo size, storage protein and free amino acid but not with starch. Therefore, further improvements in the quality of somatic embryo may be achieved through manipulation of the maturation medium in order to increase storage protein, but not starch deposition.     

Developmental competence and metabolism of bovine embryos cultured in semi-defined and defined culture media.

Development of in vitro-produced bovine embryos was studied in 3 two-step culture media: synthetic oviduct fluid (SOF), Gardner's G1/G2, and control (hamster embryo culture medium with 11 amino acids [HECM-6] followed by tissue culture medium 199 + 10% bovine calf serum). Modifications were made to reduce or eliminate protein. Glycolysis and Krebs cycle activity of morulae and blastocysts developed from selected immature oocytes were measured. There were no differences in development to the morula and blastocyst stages between SOF, G1/G2, or control (41%, 36%, and 46%, respectively), although more blastocysts developed in control medium than in G1/G2 (46%, 30%, respectively). Reducing or removing BSA during the initial culture period did not significantly reduce development to blastocyst (31%, 33%, respectively), although development was reduced in SOF with BSA removed from the final culture period (19%). There were no differences in development to the blastocyst stage between SOF, SOF with BSA removed during the initial culture period, and control (44%, 32%, 49%, respectively), but development was reduced in chemically defined protein-free medium throughout the culture period (21%). Krebs cycle activity did not differ between treatments; however, glycolysis was highest in the control embryos and lowest in embryos cultured in protein-free medium. Embryos that developed in the presence of serum appeared dark and granular and had elevated glycolytic rates compared to embryos developed in completely defined medium. This study shows that both metabolism and blastocyst development of embryos are altered by different culture media, implying a functional linkage between these two indicators of successful embryogenesis.     

Development of rat embryos in culture media containing different concentrations of normal and diabetic rat serum.

In vitro culture of rodent embryos has been extensively used in the search for teratologic agents, with possible relevance to diabetic pregnancy. However, the high concentrations of rat serum added to the culture medium (approximately 75%) have raised concern that the teratogenic effects of some compounds may be attenuated or masked in this culture system and thereby forced the addition of pharmacological concentrations of the compounds (e.g., D-glucose and beta-hydroxybutyrate) to the medium. This issue has been examined in the present study where the effects of different concentrations of rat serum on growth and differentiation of rat embryos were recorded in cultures supplemented with increased concentrations of D-glucose and beta-hydroxybutyrate. The embryonic development was also evaluated after culture in medium supplied with serum from diabetic rats. Compared with normal rat serum, the diabetic serum had an elevated glucose concentration as well as markedly increased levels of triglycerides and branched amino acids, indicating a potentially rich supply of major nutrients for the cultured embryos. Lowering the serum concentration in the culture medium from 80% to 50% yielded progressively retarded embryonic growth but no increased rate of other morphological malformations. At 40% serum concentration, however, there was a sharp rise in the incidence of somatic malformations, in addition to the prevailing growth retardation. When the embryonic growth and development were compared at 50% and 80% serum concentrations, increased D-glucose or beta-hydroxybutyrate concentrations caused similar degrees of embryonic dysmorphogenesis. Also, the uptake of each compound by the embryos exposed to elevated levels of the two agents were similar in 50% and 80% serum cultures. There was, therefore, no protection against the teratogenic and growth-retarding effects of increased D-glucose or beta-hydroxybutyrate offered by high serum concentrations in the culture medium (i.e., 80% vs. 50%). Embryos cultured in 50% or 80% diabetic rat serum at 30 mmol/L or 50 mmol/L D-glucose concentration showed similar rates of somatic malformations as did embryos exposed to the same proportion of normal rat serum at similar glucose concentrations. By contrast, the diabetic rat serum amplified the general retarding effects of high D-glucose levels, yielding lower protein levels and somite numbers in embryos from diabetic serum culture than in embryos cultured in normal rat serum.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nuclear transfer procedures in the ovine can induce early embryo fragmentation and compromise cloned embryo development

Cytoplasmic fragmentations are frequently observed in early mammalian embryos, and especially in the human. In our research we have observed subtle clues that the occurrence of fragmentation was most likely a result of somatic cell nuclear transfer (NT) protocols, and in particular, the in vitro culture system. In this study we examined various putative factors that might induce early embryo fragmentation in the ovine. The results indicate that nuclear transfer protocols such as the fusion parameter, activation treatment, and especially the choice of culture medium affected embryo cleavage rates and resulted in a higher incidence of fragmented embryos. Upon using the same fusion parameter, activation parameters that were based upon amino acids containing synthetic oviduct fluids (SOFaa) culture system resulted in significantly lower fragmentation rates than when utilizing a Charles Rosenkrans 1 (CR1aa) culture system. Fragmented embryos typically exhibited irregular numbers of blastomeres with the majority of blastomeres devoid of chromatin. Factors such as fusion DC pulse, activation treatment and culture system led to higher fragmentation and also affected in vitro and in vivo embryo development. The SOFaa based culture system produced a higher number of quality NT embryos resulting in higher pregnancy rates and the birth of live lambs as compared to the CR1aa based system (P<0.05). We conclude that early embryo fragmentation in the ovine is caused by suboptimal cloning protocols, and NT embryo development is especially affected by the culture system used.     

Components of oviduct physiology in eutherian mammals

Recalling the evolutionary sequence of development first of gonad and subsequently of oviducts, ovarian endocrine regulation of all known components of oviduct physiology is reviewed. Ovaries not only influence oviducts via the systemic blood circulation, but also locally by counter‐current transfer of relatively high concentrations of steroid hormones and prostaglandins between the ovarian vein and oviduct branch of the ovarian artery. The efficiency and impact of such counter‐current transfer is greatest around the time of ovulation, the transfer process receiving further inputs from hormones present in peritoneal fluid. Classical oviduct physiology is summarised, and the potential molecular consequences of temperature gradients within the duct lumen examined. At ovulation, an oocyte‐cumulus complex is displaced in minutes from the follicular surface to the site of fertilisation at the ampullary‐isthmic junction of the oviduct. This rapid initial phase is contrasted with the subsequent slow progression of embryos to the uterus in days, still encompassed within a zona pellucida. Regarding transport of spermatozoa, the formation of a pre‐ovulatory reservoir in the caudal portion of the oviduct isthmus is noted, with suppression of motility and sperm‐head binding to epithelial organelles acting to maintain fertilising ability. Completion of capacitation is prompted shortly before ovulation, predominantly by Ca²⁺ influx into bound spermatozoa. A controlled release of spermatozoa coupled with their hyperactivation results in initial sperm:egg ratios at the site of fertilisation close to unity, thereby avoiding the pathological condition of polyspermy. Both the oviduct milieu and embryonic development are influenced by paracrine activity of follicular granulosa cells released at ovulation and remaining in suspension in the vicinity of the oocyte or embryo. These cells may amplify early pregnancy signals from a zygote to the endosalpinx. Beneficial effects of the oviduct on domestic animal embryos are contrasted with anomalies arising as a consequence of in vitro culture. Primate embryos do not require exposure to an oviduct for normal development, perhaps due to overlapping compositions of endosalpingeal and endometrial secretions. Additionally, primate endometrial secretions may be modified by viable gametes or an embryo in the presence of a cumulus cell suspension.