Introduction
Bighorn sheep is one of 14 species of Mexican fauna considered a priority under special protection status by NOM-059-ECOL-2010,1,2 and only the bighorn sheep of México is still in Appendix II of the Convention on International Trade of Wild Fauna and Flora Endangered Species.3 In 1994, Mexican subspecies of the “desert bighorn sheep” were classified by the Red List of Threatened Species of International Union for the Conservation of Nature (IUCN) as “vulnerable” (O. c. mexicana), “endangered” (O. c. cremnobates), and “critically endangered” (O. c. weemsi).4 Since 2010, the IUCN reclassified bighorn sheep as of “least concern”5 because their populations in North America are stable, even though they have increased, mainly in the United States of America, with at least 31,000 desert bighorn sheep in the wild;6 and 3000 to 4500 with private landowners, mostly in México. However, their distribution is only 4% of the historical range.6-9
Assisted reproduction techniques in wild animal practice as a tool for conservation have been widely discussed by several authors,10-11 but there has been little progress in terms of the possible value of interspecies gestations. This is because there are important knowledge voids on the phylogenetic closeness, differences in oestrous cycle and gestation length, differences in placenta formation, and in the immunological gestation that have sparked conflicts.12
Interspecies gestations have been achieved in the Ovis genus with the birth of fertile, pure or hybrid lambs, when species have similar chromosome number (mostly 2n = 54), and when the oestrus cycle and gestations are of similar lengths.13-14 There are hybrids between Mouflon sheep (O. musimon) and domestic sheep (O. aries),15 and between Mouflon and argali sheep (O. argali).16-17 Mouflon embryos have been successfully transferred into domestic sheep,18 and Armenian red sheep (O. orientalis) lambs have been produced by in vitro fertilization and embryo transfer into domestic females.19 These mentioned species have oestrus cycles of 16 days and gestations of 150 days, on average. It has also been possible to produce hybrids between Dall sheep (O. dalli) and bighorn sheep (O. canadensis),20 because they share oestrus cycles of approximately 28 days and a gestation period between 175 and 179 days.21-22
A recent work on gestations between bighorn and domestic sheep has uncovered that, in these interspecies gestations, there was placental insufficiency, characterized by a significant decrease in the plasma concentration of progesterone and endothelial dysfunction characterized by an increase in plasma levels of vascular endothelial growth factor and placental insulin-like growth factor-1, as well as an overexpression of hypoxia-inducible factor-1α.23
This work sought to confirm if the production of hybrids is viable, despite the phylogenetic distance between bighorn and domestic sheep, and if the adminis tering of progesterone throughout these gestations could favour placental develop ment and promote foetal growth.
Materials and methods
Experiment I
Procedures
To produce hybrids between O. canadensis and O. aries, a total of 40 domestic Suffolk sheep between three and four years old, with at least two previous deliveries and a live weight of about 90 kg, were used in the first experiment. To cover the daily requirements during early pregnancy (first two-thirds), sheep were given 1.75 kg of dry matter, 3.35 MCal of metabolizable energy and 96 g of metabolizable protein. During late gestation (last third), sheep were given 2.15 kg of dry matter, 4.10 MCal of metabolizable energy and 124 g of metabolizable protein. These requirements were provided by oat hay, alfalfa and commercial feed. Water was available ad libitum throughout the experiment.24
Twenty sheep were inseminated with frozen bighorn semen obtained by electroejaculation from two males, one located in the Chapultepec Zoo of México City and the other in the Centro Ecológico de Sonora (Sonora State, México), after fasting and anaesthesia using xylacine (1 mg/kg live weight) and ketamine (4 mg/kg) and reversed after the process with yohimbine (0.25 mg/kg).25 An additional 20 domestic sheep were inseminated with frozen semen collected from two domestic males using an artificial vagina. Previously, the semen of both species was evaluated, diluted with Triladyl (Minitübe) at 37 °C, cooled at 5 °C for at least two hours, packaged in 0.25-mL straws at a concentration of 70 × 106 and frozen in liquid nitrogen (-196 °C) in 10 minutes.26
The ewes were synchronized using vaginal sponges with 20 mg of fluorogestone acetate (FGA) (Chronogest, Intervet) for 12 days and 100 IU of equine chorionic gonadotropin (eCG) (Folligon, Intervet) at the day of removal. Intrauterine insemination was carried out 56 hours later through laparoscopy27 after fasting and anesthesia using xylacine (0.22 mg/kg live weight) and ketamine (1 mg/kg live weight). The diagnosis of gestation was carried out by transrectal ultrasonography with a linear 7.5 MHz transducer at day 30 post-insemination and confirmed by transabdominal ultrasonography with a linear 5 MHz transducer at day 40.28-29 Progesterone levels were measured once a week from only six females with single gestations from each group from weeks 6 to 22 of gestation. Blood samples were obtained by venipuncture from the jugular using vacutainer tubes and needles. Samples were centrifuged at 1200 g for 10 min to obtain serum, which was kept at -20 °C until processing. Progesterone was quantified by a solid-phase radioimmunoassay, which was done in duplicate and in a single assay, using a commercial kit ensuring an intra-assay coefficient of variation <10% and an inter-assay coefficient of variation <15% (Coat-A -Count Progesterone, Siemens Medical Solutions) and according to the method described by the supplier. The minimum sensitivity of the assay was 0.094 ng/mL, and the intra-assay coefficient of variation was 3.6%. The assay kit has been validated for the ewe.30
At parturition, the condition of single gestations was confirmed, the duration was determined, offspring were weighed, and placentas were recovered in order to measure their length and width. Placentas were divided into four quadrants. All of the cotyledons present were counted, and three cotyledons from each quadrant were weighed.31
Experiment II
Procedures
To evaluate if the administration of exogen progesterone promotes placental development and foetal growth, the second experiment was composed of 30 domestic sheep (with the same characteristics and conditions as Experiment I), from which six were embryo donors. Donors were synchronized using vaginal sponges containing 20 mg of FGA during 12 days, and superovulation was induced by intramuscular injection of 180 mg of follicle stimulating hormone (Folltropin, Vetoquinol). The total dosage was divided into two daily administrations for four days, with a decreasing dose pattern (from 40 mg to 10 mg) across days. The first administration was two days before the removal of the sponge. These sheep were intrauterine inseminated by laparoscopy using two doses of frozen bighorn semen with 70(106) in each one, 48 hours later. Embryo retrieval was carried out by mid-ventral laparotomy at day seven after insemination. After their evaluation, excellent and good quality morulae and blastocysts32 were transferred fresh and individually to 24 recipients, in order to assure that each ewe only gestated a single offspring. Recipients were previously synchronized using vaginal sponges with 20 mg of FGA during 12 days and a 300 IU dose of equine chorionic gonadotropin at the time of their removal. Embryo transfer was done at day seven with the help of an endoscope, in order to expose the uterine horn ipsilateral to the ovary that had the best quality corpus luteum. A small puncture was made on the selected uterine horn, and the embryo previously loaded into a catheter was introduced.33 Gestation diagnosis was carried out 40 days after embryo transfer using real-time ultrasonography with a linear 5 MHz transducer, and pregnant ewes were randomly placed into two groups: treated (n = 5, hybrid embryo + P4), which received a daily intramuscular dose of 25 mg (0.5 mL) of a natural progesterone (Progesvit A-E, Dechra-Brovel) from weeks 7 to 20 of gestation, and non treated control (n = 6, hybrid embryo), which received 0.5 mL of saline solution in the same schedule as the treated group.
Similar to the first experiment, the progesterone levels were determined each week from weeks 7 to 22 of gestation using a radioimmunoassay, and the duration of gestation was noted. Offspring were weighed at birth, and placentas were recovered to determine their morphometry.
Statistical analyses
In both experiments, a chi-square test was used to compare the fertility in inseminated or embryo recipient sheep, while a t-test was used for comparing gestation duration, placental morphometry and birth weight. A mixed-model for repeated measures analysis of variance was used to compare the effect of type of gestation and the week of gestation on progesterone concentration: domestic or hybrid and weeks 6 to 22 in Experiment I, and hybrid embryo with progesterone or hybrid embryo without progesterone and weeks 7 to 22 in Experiment II. For the test, the type of gestation and week of gestation were considered as fixed effects, while sheep were considered as a random effect.34
Ethical standards
The authors declare that the experimental protocol was approved by the Internal Committee for Care and Use of the Animals (CICUA, FMVZ-UNAM) and according to Mexican legislation.
Results and discussion
Experiment I
Domestic sheep inseminated with frozen bighorn semen had reduced fertility, 40% (8/20), when compared to those inseminated with domestic semen, 65% (13/20), (x2(1) = 2.50, p = 0.11). The duration of gestation in domestic sheep inseminated with bighorn semen was greater, 152.13 ±0.22 days, than in domestic sheep inseminated with domestic semen, 146.54 ±0.21 days (t(19) = -17.04, p < 0.001). Hybrid offspring (O. c. mexicana × O. aries) weighed less at birth, 2.46 ±0.09 kg, than domestic offspring, 5.10 ±0.22 kg, (t(10) = 10.83, p < 0.001). Table 1 shows the morphometry of the placentas that were recovered at birth grouped by the type of gestation.
Gestation type | Placenta length (cm) (mean ±SE) | Placenta width (cm) (mean ±SE) | Number of cotyledons (mean ±SE) | Cotyledon weight (g) (mean ±SE) |
---|---|---|---|---|
Intraspecies or domestic (n = 6) | 72.17 ±1.35a | 23.83 ±1.07a | 54.67 ±2.02a | 3.20 ±0.27a |
Interspecies or hybrid (n=6) | 48.67 ±2.48b | 17.83 ±0.47b | 53.50 ±2.23a | 1.50 ±0.13b |
(t(10) = 8.30, p < 0.001 | (t(10) = 5.09, p < 0.001 | (t(10) = 0.38, p = 0.70 | (t(10) = 5.46, p < 0.001 |
a,b Within variables, values with different letters are statistically differents.
Figure 1 shows the serum progesterone levels determined between weeks 6 and 22 of gestation. In general, progesterone levels were lower during the final third of interspecies gestations (O. c. mexicana × O. aries) when compared to the levels determined from domestic sheep gestations (O. aries × O. aries), (F(33, 170) = 9.35, p < 0.001, partial η2= 0.64).
Experiment II
The duration of gestation in domestic sheep that received one hybrid embryo (O. c. mexicana × O. aries) and progesterone treatment reached 152.60 ±0.51 days, which is similar to the 153.33 ±0.88 days (t(9) = -0.68, p = 0.51) in the non treated group. Offspring of the group treated with progesterone had higher birth weights, 3.41 ±0.20 kg, than the control, 2.21 ±0.10 kg, (t(9) = 5.46, p < 0.001). Table 2 shows the morphometry of the placentas recovered at birth by group.
Group | Placenta length (cm) (mean ±SE) | Placenta width (cm) (mean ±SE) | Number of cotyledons (mean ±SE) | Cotyledon weight (g) (mean ±SE) |
---|---|---|---|---|
Hybrid embryo + P4 (n = 5) | 71.20 ±3.03a | 19.44 ±1.13a | 54.60 ±2.61a | 1.70 ±0.27a |
Hybrid embryo (n = 6) | 50.83 ±3.33b | 18.66 ±0.76a | 56.83 ±6.68a | 1.33 ±0.24a |
(t(9) = 4.43, p = 0.002 | (t(9) = 0.58, P = 0.57 | (t(9) = -0.28, p = 0.78 | (t(9) = 0.98, P = 0.35 |
a,b Within variables, values with different letters are statistically different.
Figure 2 shows the serum progesterone levels determined between weeks 7 and 22 of gestation. Progesterone levels were significantly higher during all gestation (F(31, 144) = 14.26, p < 0.001, partial η2= 0.75) in females with an interspecies gestation (O. c. mexicana × O. aries) and treated with exogenous progesterone.
The establishment and development of assisted reproduction techniques in bighorn sheep in México have been considered. In a previous work, bighorn sheep embryos (O. c. mexicana) were transferred into two domestic sheep ewes (O. aries) and two F1 hybrids (O. c. mexicana × O. aries), from which none of the domestic ewes became pregnant, and one of the hybrid recipients lost its pregnancy of two bighorn offspring at day 156.35
The value of hybrids in ex situ conservation was demonstrated with the rescue project for wild ibex goats (Capra pyrenaica pyrenaica), which recently became extinct in Spain. In these studies, the transfer of 53 ibex embryos into domestic goats (C. hircus) produced only two offspring. The authors attributed the loss of the majority of the gestations to placental incompatibility or immunological rejection.36-37 Later, ibex embryos were transferred into hybrid first (F1) and second (F2) filial generations (C. p. pyrenaica × C. hircus), from which three Ibex offspring were born, one from an F1 hybrid and two from F2 hybrids.38 Finally, after several attempts with an important number of cloned embryos transferred into domestic and hybrid goats, the gestation of an ibex in a hybrid recipient and the birth of a live ibex offspring was achieved, although it died due to respiratory problems minutes after being born.39
Despite the differences in the length of the oestrous cycle and gestation, and the lower fertility of the domestic sheep inseminated with frozen semen of bighorn, it is possible to produce embryos, gestations and viable hybrids between these not very closely related species.23,40 The duration of gestation can be modified by different factors, and the foetal genotype has a very significant effect on the gestation period, because within this genome, the paternal component is the most important.41 In hybrids between donkey and horse (mules), the gestation period is closer to the father’s species than to that of the mother.42 Similarly, regarding the gestations of hybrids between bighorn and domestic sheep, the paternal component of the bighorn sheep that has a gestation period of approximately 175 days21 significantly increases the normal gestation period of domestic sheep, from 146 days to 152 days (on average), like the results obtained in these two experiments and in a previous work.23
From a physiological perspective, an inadequate placental vascularization and size throughout pregnancy causes reduced intrauterine foetal growth and the birth of small offspring.43 This condition is known as intrauterine growth restriction (IUGR), and it has been extensively studied in women with pre-eclampsia and new-born infants with an evident delay in their growth.44 Animal models that cause IUGR decrease blood flow between the placenta and foetus by ligature of one of the foetal umbilical arteries45 or by limiting the implant sites between the endometrium and the placenta by partial removal of endometrial caruncles.46 Placentas and offspring that showed restricted vascularization and reduced intrauterine growth, such as in those coming from numerous litters, have also been studied.47-48 Other models restrict feed or over feed pregnant females in order to evaluate the effects on placental, cotyledon and foetal development, as well as the concentrations of various hormones, amino acids and essential metabolites.49-51
The proper development of the placenta is critical for determining the availability of nutrients in the development of the foetus and regulation of gas exchange or removal of waste products. The placental exchange efficiency is also affected by morphology, since it has great plasticity and adaptation to situations that cause stress.31,43 Since the maintenance of gestation depends greatly on the intense growth and formation of new blood vessels (angiogenesis) in the placenta, which in turn has a direct association with uterine and umbilical blood flow, the foetal weight and placental size are a consequence of these interactions.52-53 Several studies have demonstrated the existence of a positive direct relationship between the amount of uterine and umbilical blood flow and the growth and weight of placentomes. The greater the blood flow, the heavier is the weight; therefore, the importance of placental circulation resides in its close relationship with foetal and placental weights. An increase in uterine vascular resistance has been clinically shown to have an effect on placental vascular and placentome development, decreasing the nutrient exchange capacity, which in turn has a negative effect on foetal growth and birth weight.54-55 This is similar to the results obtained with the interspecies gestations between bighorn and domestic sheep that are not treated with exogenous progesterone.
Progesterone is a hormone that is directly related to gestation, due to its multiple effects on the differentiation of the endometrial stroma, the control of the secretion of molecules that provide nutrition to the embryo at early stages, and the uterine secretion of local immunomodulating molecules, among others, that determine the gestation success or failure.56-57 With regard to domestic sheep, progesterone is produced at the beginning of gestation only by the corpus luteum, but starting from day 50 of gestation, the placenta produces higher levels.58-59 There is evidence in different species, including sheep, where both embryo survival and development rhythm depend on the concentration of progesterone present during the first weeks of life.60-64 In addition, the lamb birth weight has been positively correlated with the progesterone concentrations from weeks 9 to 19 of gestation.65 Higher levels of progesterone during all of gestation allow the mobilization of larger quantities of fatty acids and glucose from reserves into the maternal circulation, and similarly, greater development of the placenta produces greater placental lactogen and other hormones with mitogenic activity favouring the intrauterine growth of the foetus.51,66
When comparing placental development in the second experiment of this work, it becomes noticeable that placentas from O. c. mexicana × O. aries interspecies gestations treated with progesterone have greater lengths, similar to that of intraspecies O. aries × O. aries gestations from the first experiment. This result could explain why the birth weight of hybrid offspring from the group treated with progesterone was also higher in relation to the hybrid offspring weight of the non treated control group. These results also suggest that progesterone could have a major effect on foetal growth in restricted gestations.
Conclusions
Although the insemination of domestic sheep with bighorn sheep semen causes reduced fertility and lighter offspring birth weight, the production of hybrids is possible. Since foetal genotype has an effect on the duration of gestation, the use of hybrid females could be proposed as bighorn sheep embryo recipients. This type of interspecies gestations, O. canadensis × O. aries, could be considered as a restricted intrauterine growth model that could provide information regarding both domestic and wild animals. Similarly, the evaluation of simple treatments, such as the administration of progesterone to promote placental development and higher weights at birth, which are events related to placental vascularization and in turn with intrauterine foetal growth, could contribute to the development of assisted reproduction techniques for the conservation of wild species that are threatened, as well as to the study of an issue relevant to animal health and wellbeing.