DNA probe sexing of young in vitro fertilized bovine embryos

Sex-dependent insulin like growth factor-1 expression in preattachment equine embryos

An adjustment of sex ratio of offspring to the conditions present at conception is seen in many mammals including horses. This depends on preferential survival of male embryos under conditions of high energy intake. In several species, growth factors including insulin like growth factor (IGF)-1 have been shown to promote embryonic development by decreasing apoptosis and increasing cell proliferation. We hypothesized that sex-related differences in IGF-1 expression in equine embryos during the phase of maternal recognition of pregnancy might exist and thus contribute to preferential survival of embryos from either of both sexes under specific environmental conditions. Insulin like growth factor-1 mRNA expression of in vivo-produced equine embryos on different days of pregnancy (Day 8, N = 6; Day 10, N = 8; Day 12, N = 14) was analyzed. Insulin like growth factor-1 mRNA expression was evaluated by reverse transcription quantitative polymerase chain reaction. The sex of the embryo was determined by detection of X-inactivation specific transcript (Xist) RNA and equine sex determining region of the Y chromosome DNA. Embryos positive for Xist expression were classified as female, and Xist negative and equine sex determining region of the Y chromosome positive embryos were classified as male. From 28 embryos tested, 15 (54%) showed positive Xist expression and were thus classified as female. Insulin like growth factor-1 mRNA expression was influenced by sex (P = 0.01) but not by day of pregnancy (relative expression of IGF-1 in relation to β-actin, Day 8: male 5.1 ± 2.1, female 11.4; Day 10: male 5.2 ± 1.6, female 17.4 ± 6.7; Day 12: male 2.6 ± 0.3, female 11.6 ± 2.4). Results demonstrate an increased expression of IGF-1 in female equine embryos. Sex-related influences on expression of the IGF system are probably related to a gradual X chromosome inactivation.

Periconceptional influences on offspring sex ratio and placental responses

Maternal diet and secondary factors can strikingly influence fetal outcomes, including biasing offspring sex ratio and altering the molecular biological responses of the conceptus, namely within the placenta. Alterations in the in utero environment might also lead to profound developmental origin of health and disease (DOHaD) outcomes into adulthood, including increased risk for cardiovascular disease, obesity and cancer, with males in general being at greater risk for these diseases. Female mice maintained on a very high fat (VHF) diet birth more sons than those on a chow-based and low fat (LF), high carbohydrate diet, with the latter group producing more daughters. However, neither the underlying mechanisms that contribute to this shift in offspring sex ratio nor when they occur during pregnancy have been resolved. In this review, we consider the evidence that maternal diet and other factors influence secondary sex ratio in a variety of species, including humans, and discuss when this skewing might occur. Additionally, we examine how fetal sex and maternal diet influences gene expression patterns in the mouse placenta, which serves as the primary nutrient acquisition and communication organ between the mother and her developing pups. These adaptations to diet observed as changes in gene expression are likely to provide insight into how the placenta buffers the fetus proper from environmental shifts in nutrient availability during pregnancy and whether male and female conceptuses respond differently to such challenges.

Effect of energy source during culture on in vitro embryo development, resistance to cryopreservation and sex ratio

The aim of this work was to evaluate whether minimizing the glucose concentration during culture or replacing the hexose with other energy substrates and/or embryotrophic compounds would affect the in vitro development, the resistance to cryopreservation and the sex ratio of bovine embryos. In vitro matured and fertilized oocytes were randomly assigned to 4 groups for in vitro culture, that differed in the energy substrates included: group A) 1.5 mM glucose, as in standard SOF; group B) 0.15 mM glucose; group C) 0.125 mM G3P, in the presence of 0.15 mM glucose and group D) 0.34 mM citrate, in combination with 2.77 mM myo-inositol. Blastocysts were evaluated on day 7, then vitrified by cryotop in 16.5% DMSO, 16.5% EG and 0.5 M sucrose and warmed in decreasing concentration of sucrose (0.25 to 0.15 M sucrose). The survival rates were assessed after 24 h in vitro culture. Finally, the blastocysts produced were sexed by PCR. An increased blastocyst rate was recorded in groups B, C and D, i.e., when glucose concentration was reduced, compared to group A (28.2, 41.0, 35.7 and 35.8, respectively in groups A, B, C and D; P < 0.01). However, the embryos cultured in group D showed the slowest developmental speed, indicated by the lowest percentage of advanced stage-embryos (expanded and hatched blastocysts) out of the total blastocysts (56.1, 45.8, 56.9 and 31.8 %, respectively in groups A, B, C and D; P < 0.01). Furthermore, survival rates after 24 h culture of vitrified-warmed blastocysts also decreased in group D (73.3, 73.1, 71.4 and 58.4%, respectively in groups A, B, C and D; P < 0.01). Interestingly, in group D a higher percentage of female embryos was obtained compared to group A, with intermediate values in groups B and C (45.6, 53.4, 50.0 and 61.5%, respectively in groups A, B, C and D; P < 0.05). In conclusion, it was demonstrated that the energy substrate during in vitro culture affects both the production and the viability of blastocysts. Furthermore, manipulating the metabolic profile of embryos during in vitro culture may have an impact on sex ratio.

The influence of gamete co-incubation length on the in vitro fertility and sex ratio of bovine bulls with different penetration speed

The objectives of this work were to evaluate whether the sperm penetration speed is correlated to the in vitro fertility and whether adapting the gamete co-incubation length to the kinetics of the bull improves in vitro fertility and affects the sex ratio. In vitro matured oocytes were co-incubated with spermatozoa from four different bulls (A-D). At various post-insemination (p.i.) times (4, 8, 12, 16 and 20 h), samples of oocytes were fixed and stained with DAPI for nuclei examination, while the remaining ones were transferred into culture to evaluate embryo development. The blastocysts produced were sexed by PCR. Two bulls (A and B) had faster kinetics than the others (C and D), as shown by the higher penetration rates recorded at 4 h p.i. (43%, 30%, 11% and 6%, respectively for bulls A, B, C and D; p<0.01). The differences in the kinetics among bulls did not reflect their in vitro fertility. The incidence of polyspermy was higher for faster penetrating bulls (36%, 24%, 16% and 4%, respectively for bulls A, B, C and D; p<0.01) and at longer co-incubation times (0%, 16%, 19%, 30% and 34%, respectively at 4, 8, 12, 16 and 20 h p.i.; p<0.01). The fertilizing ability of individual bulls may be improved by adapting the co-incubation length to their penetration speed. A sperm-oocyte co-incubation length of 8 h ensured the greatest blastocyst yields for the two faster penetrating bulls. On the contrary, 16 h co-incubation was required to increase (p<0.01) cleavage rate of the two slower bulls. Bulls with a faster kinetics did not alter the embryo sex ratio towards males. The female/male (F/M) ratios recorded were 2.1, 1.4, 1.2, 1.3 and 1.6, respectively at 4, 8, 12, 16 and 20 h p.i.

Maternal diet and other factors affecting offspring sex ratio: a review

Mammals usually produce approximately equal numbers of sons and daughters, but there are exceptions to this general rule, as has been observed in ruminant ungulate species, where the sex-allocation hypothesis of Trivers and Willard has provided a rational evolutionary underpinning to adaptive changes in sex ratio. Here, we review circumstances whereby ruminants and other mammalian species, especially rodents and primates, appear able to skew the sex ratio of their offspring. We also discuss some of the factors, both nutritional and nonnutritional, that potentially promote such skewing. Work from our laboratory, performed on mice, suggests that age of the mother and maternal diet, rather than the maternal body condition per se, play directive roles in controlling sex ratio. In particular, a diet high in saturated fats but low in carbohydrate leads to the birth of significantly more male than female offspring in mature laboratory mice, whereas when calories are supplied mainly in the form of carbohydrate rather than fat, daughters predominate. As the diets fed to the mice in these experiments were nutritionally complete and because litter sizes did not differ between treatments, dietary inadequacy seems not to be the cause for sex-ratio distortion. A number of mechanisms, all of which are testable, are discussed to provide an explanation for the phenomenon. We conclude the review by discussing potential implications of these observations to human medicine and agriculture.

Influence of the duration of gamete interaction on cleavage, growth rate and sex distribution of in vitro produced bovine embryos

Various factors including the length of gamete interaction and embryo culture conditions are known to influence the rate of development and sex ratio of mammalian embryos produced in vitro. While the duration of gamete interaction deemed optimum would vary depending upon the species involved and the preferred sex in the outcome of in vitro procedures, the mechanisms favoring the selection of embryos of one sex over the other, or the exact time of post-fertilization stage at which a sex-related difference in growth rate is manifested, are not fully understood. In order to determine the optimum length of gamete co-incubation and the impact of male gamete 'aging' on the growth rate and sex ratio of bovine embryos, a series of experiments was carried out using in vitro matured (IVM) oocytes. In experiment 1, IVM oocytes were co-incubated with sperm from two different bulls for 6, 9, 12 and 18 h and the presumptive zygotes were cultured for approximately 7.5 days (178-180 h post-insemination (hpi)) prior to assessing the cleavage rate, blastocyst yield and the sex ratio of blastocysts in each co-incubation group. In experiment 2, the blastocysts obtained from different co-incubation groups were subjected to differential staining to determine the total cell number (TCN) and the proportion of cells allocated to the inner cell mass (ICM) in male and female embryos to test for sex-related differences in cell proliferation or in differentiation of the two embryonic cell lineages in the blastocysts. In experiment 3, IVM oocytes co-incubated for 6, 9, 12 and 18 h with sperm from a single bull, were cultured for 3 days (72 hpi) and the pre-morulae, categorized according to the specific stage of early development, were sexed to determine if a sex-dependent difference is detectable before the blastocyst stage. In experiment 4, IVM oocytes exposed to prolonged co-incubation (18 and 24 h) were compared with those co-incubated with "aged" (pre-incubated) sperm to determine if "aging sperm" is a factor affecting the growth rate and sex ratio of the out come. Our experiments showed that (1) the shortest period (6 h) allowed the highest proportion of cleaved oocytes to reach the blastocyst stage regardless of the semen donor, (2) males out number females (over 2 to 1) among blastocysts when co-incubation of gametes is reduced to 6 h, (3) the male blastocysts display higher total cell count, and (4) the faster growth rate of the male embryos does not affect the early differentiation and allocation of cells to the ICM. Furthermore, our results indicate that the disruption of the expected 1:1 ratio for male and female embryos in the short term co-incubation group is evident as early as the 4-cell stage and peaks at the 8-cell stage and that prolonged gamete interaction tends to reduce the blastocyst yield to even out the sex ratio. Absence of a significant effect on the yield and sex ratio of blastocysts in the prolonged co-incubation groups irrespective of the type of sperm (aged versus non-aged) used suggest that the preponderance of male embryos in short term gamete interaction group may be dependent upon the in vitro advantage of the Y-chromosome bearing sperm. This advantage, manifested in the precocious development during the pre-morulae stage is confined to a short duration that is neutralized when gamete interaction is allowed to proceed beyond 6h.

Effect of the in vitro culture system on the kinetics of blastocyst development and sex ratio of bovine embryos

Bovine blastocysts were produced using 6 different systems: 5 commonly used in vitro culture systems (synthetic oviduct fluid medium - SOF- without fetal calf serum, SOF supplemented with 10% serum for the entire culture period, SOF supplemented with 10% serum from Day 4 of culture, M199 coculture with bovine oviduct epithelial cells, M199 coculture with granulosa cell monolayer) and 1 in vivo culture system involving collection of blastocysts from superovulated bovine donors at Day 7. Zygotes obtained from IVM/IVF were assigned randomly to 1 of the 5 systems tested and were cultured for 9 d (Day 0= day of insemination). Cleavage, development to the blastocyst stage and blastocyst sex ratio were assessed in all treatments. In addition, the effect of the IVC system on the kinetics of blastocyst development and sex ratio was assessed on Days 6, 7, 8, and 9. The presence of fetal calf serum in SOF not only resulted in faster development (19.1% of blastocysts in SOF supplemented with serum vs 7.1% in absence of serum at Day 6; P < 0.05) and increased blastocyst production (47.5% of blastocysts in SOF supplemented with serum vs 34.4% in absence of serum; P < 0.05) but it also enhanced overall male survival. The coculture systems produced fewer blastocysts than culture in SOF (27.6 to 28.3% in coculture vs 47.5% in SOF supplemented with serum; P < 0.05), but similar to SOF without fetal calf serum, they had no effect on blastocyst sex ratio.

Comparison of sex ratio and cell number of IVM-IVF bovine blastocysts co-cultured with bovine oviduct epithelial cells or with Vero cells

The influence of 2 co-culture systems (BOEC and Vero cells) on the development rates, quality grades and sex ratios of IVM-IVF bovine embryos were studied. Zygotes obtained after IVF were co-cultured in each co-culture system for 7 and 8 d (Day 0 = day of insemination) in B2 medium. No effect of the co-culture system was observed on development rates measured on Days 7 and 8. However, Vero cell co-culture had a positive influence on embryo quality. Irrespective of their sex, embryos produced on Vero cells showed higher cells number than those co-cultured on BOEC (103.4 +/- 3.8 and 97 +/- 8.12 for BOEC vs 113.7 +/- 3.5 and 114 +/- 5.9 for Vero cells at Days 7 and 8, respectively; P < 0.05). The percentage of male embryos was increased in the two co-culture systems (60.7% males for BOEC; P < 0.05 vs 63% males for Vero cells; P < 0.01) on Day 7. In both co-culture systems the increase in the percentage of males was more obvious for embryos reaching the most advanced stage (expanded blastocysts). The results show that Vero cells improved the quality grade of bovine embryos produced in vitro, and thus are recommended for use as a safe co-culture system that does not contain pathogens.

Transcription of Y- and X-linked genes in preimplantation ovine embryos

Because male ovine embryos develop faster than female embryos, the transcription of SRY and ZFY, two genes located on the Y chromosome, was examined in preimplantation stages using the reverse transcriptase polymerase chain reaction (RT-PCR). RNA was extracted from pools of ovine embryos matured and fertilized in vitro then cultured in synthetic oviduct fluid medium and recovered from 24 to 207 hr post-insemination (two-cell up to hatched blastocyst stage). Since primers used to amplify ZFY also amplify the homologue ZFX, located on the X chromosome, transcripts were differentiated by digestion with restriction enzymes. ZFY and ZFX transcripts were present in all stages examined following RT-PCR, whereas transcripts for SRY were undetectable in all investigated stages following either RT nested PCR or Southern analysis. The presence of ZFY transcripts suggests that Y chromosome is transcriptionally active during early ovine preimplantation development. The possible relationship between a faster growth of male embryos and the transcription of Y-linked genes at early stages of development is discussed.

Relationship between stage of development and sex of bovine IVM-IVF embryos cultured in vitro versus in the sheep oviduct

We have confirmed more rapid development of male compared with female in vitro-cultured bovine embryos during the first 7 d after in vitro fertilization. The male-to-female sex ratio of expanded blastocysts after 10 d of in vitro culture was 1.37:1.00, which was significantly different from the expected 1:1 ratio, but no deviation from a 1:1 ratio was observed for male and female expanded blastocysts derived from culture of bovine embryos in the sheep oviduct (1.11:1.00). When embryos that developed only to the morula stage were analyzed for sex, a greater number of female than male bovine embryos was observed from in vitro culture but not after culture in the sheep oviduct. Possible causes of these sex-related differences in development of cultured bovine embryos are discussed.

Survival rates and sex ratio of bovine IVE embryos frozen at different developmental stages on day 7

Two experiments were designed to determine the effects of stage of development on Day 7 of in vitro-produced bovine embryos on survival after deep freezing and on sex ratio. Bovine IVF embryos and bovine oviductal epithelial cells (BOEC) were co-cultured in TCM-199 and, on Day 7 after insemination (Day 0), were morphologically evaluated and divided into groups by developmental stage. In Experiment 1, embryos classified as early blastocysts, blastocysts and full-expanding blastocysts were randomly subdivided into 2 groups by replicate: 50% of the embryos were placed immediately in a new BOEC co-culture (fresh group), while the other 50% were frozen, thawed and placed in a new BOEC co-culture (frozen/thawed group). Embryos were frozen in 1.5 M glycerol using a standard slow cooling technique. Fresh and frozen/thawed embryos were compared for survival rate (embryos hatching/hatched) in BOEC co-culture over the following 3 d (i.e., Days 7 to 10). The overall survival of the 425 embryos (early to full-expanding blastocysts) was 33% and was not different between fresh (35%) and frozen/thawed (30%) embryos. Survival of embryos cultured fresh or after freezing/thawing was higher for full-expanding blastocysts than for early blastocysts or for blastocysts, both of which were not different. In Experiment 2, all frozen/thawed embryos used in Experiment 1 plus all morulae and hatched blastocysts collected and frozen on Day 7 without regard to survival were sexed utilizing the polymerase chain reaction (PCR) technique. Sex of the embryos, by stage of development on Day 7, was determined in order to compare the rate of development in BOEC co-culture with the sex ratio (percentage of males). A total of 235 embryos was sex-determined with an overall percentage of males of 51%, which was not different from the expected 1:1 sex ratio. Both full-expanding blastocysts and hatched blastocysts had a significantly higher (P < 0.05) proportion of males (68 and 100%, respectively), while morulae had a significantly lower proportion of males (24%). Early blastocysts and blastocysts did not differ from a 1:1 sex ratio. The results indicate that male embryos develop faster in vitro than female embryos. The higher survival rate of full-expanding blastocysts after freezing/thawing, and the production of a higher number of males than females among embryos of this developmental stage suggest that a greater number of male fetuses may result from the successful freezing and transfer of in vitro-produced bovine embryos.

Differential cleavage and developmental rates and their correlation with cell numbers and sex ratios in buffalo embryos generated in vitro

In vitro matured and fertilized buffalo oocytes were co-cultured with buffalo oviductal epithelial cells (BOEC) in CRlaa medium. Cleaved embryos were separated according to the time of completion of first cleavage (i.e., before 30 h and after 30 h post insemination) and cultured for 5 to 10 d and allowed to develop to the blastocyst stage. Zygotes cleaving before 30 h were termed fast-cleaving while those cleaving after 30 h were termed slow-cleaving. The results indicated that fast-cleaving embryos are more likely to develop into blastocysts (25%) than slow-cleaving embryos (7.8%). The quality and viability of fast-cleaving and fast-developing blastocysts was found to be better than that of slow-cleaving, slow-developing blastocysts as judged by cell numbers (67.7 +/- 3.7 vs 35.2 +/- 2.1). However, the mitotic index was not different between the 2 groups. The sex of fast-developing and slow-developing blastocysts was determined via the polymerase chain reaction (PCR) to correlate the rate of embryonic development with the sex ratio of the embryos. Embryos produced by Bull 293 and Bull M-82, irrespective of their being fast or slow-developing, gave rise to more females and males, respectively. From these results, we suggest that there may be a sire effect on sex ratio of in vitro produced buffalo embryos.