Time within reproductive season, but not age or inbreeding coefficient, affects seminal and sperm quality in the whooping crane (Grus americana).

All living whooping cranes (Grus americana) are descended from 16 or fewer birds that remained alive in the early 1940s, a bottleneck that puts the species at potential risk for inbreeding depression. Although AI is commonly used in the management of the captive population of this species, little is known about seminal traits or factors affecting sperm quality in the whooping crane. In the present study, semen samples were collected from 29 adult males (age 3-27 years) during the early (March), mid (April) and late (May) breeding season over 2 consecutive years. The effects of donor age, time within reproductive season and level of inbreeding on seminal characteristics were analysed using regression and information-theoretic model selection. Only time within reproductive season significantly affected seminal traits, with total numbers of spermatozoa and proportions of pleiomorphisms increasing across the season. We conclude that, even with a highly restricted number of founders, there is no discernible influence of inbreeding (at the levels described) on sperm output or quality. Furthermore, although there is variance in seminal quality, the whooping crane produces significant numbers of motile spermatozoa throughout the breeding season, similar to values reported for the greater sandhill crane (Grus canadensis tabida).

Molecular markers of spermatogonial stem cells in the domestic cat.

Spermatogonial stem cells (SSCs) represent an exciting new avenue for assisted reproduction in endangered and genetically valuable species. Before this technology can be applied to wildlife, species-specific markers are required to evaluate SSC enrichment strategies and monitor subsequent in vitro culture. This study was designed to evaluate six conserved SSC markers (THY1, GPR125, GFRalpha1, PLZF, UCHL1 and OCT4) in the cat. Testes from three juveniles and three adults were obtained following routine castrations and processed for mRNA extraction. RT-PCR of whole testis and cell suspensions enriched for SSCs by differential plating confirmed that all six SSC markers are expressed in both the whole testis and SSC-enriched cell fractions. The expression of all six putative SSC marker genes in the cat testis suggests conservation of SSC markers, and perhaps self-renewal mechanisms, in felids.

Lessons learned from nuclear transfer (cloning).

Somatic cell nuclear transfer (SCNT) has been accomplished in an ever-growing list of species. In each case, an enucleated oocyte has successfully reset the nucleus of a somatic cell such that the embryonic program could progress to the production of a live offspring. The overall efficiency of the process remains low due to a combination of biological and technical challenges, some of which are known and others remain to be elucidated. Comparative studies between livestock and laboratory species may help improve not only nuclear transfer efficiencies but also uncover basic underlying developmental principles.

Challenges and prospects for the establishment of embryonic stem cell lines of domesticated ungulates.

Embryonic stem (ES) cell lines provide an invaluable research tool for genetic engineering, developmental biology and disease models. These cells can be maintained indefinitely in culture and yet maintain competence to produce all the cells within a fetus. While mouse ES cell lines were first established over two decades ago and primate ES cells in the 1990 s, validated ES cell lines have yet to be established in ungulates. Why competent, pluripotent ES cells can be established from certain strains of mice and from primates, and not from cows, sheep, goats or pigs is an on-going topic of interest to animal reproduction scientists. The identification of appropriate stem cell markers, functional cytokine pathways, and key pluripotency-maintaining factors along with the release of more comprehensive bovine and porcine genomes, provide encouragement for establishment of ungulate ES cell lines in the near future.

State of the art in the production of transgenic goats.

This review summarises recent advances in the field of transgenic goats for the purpose of producing recombinant proteins in their milk. Production of transgenic goats via pronuclear microinjection of DNA expression vectors has been the traditional method, but this results in low efficiencies. Somatic cell nuclear transfer has dramatically improved efficiencies in rates of transgenesis. Characterisation of transfected cells in vitro before use in nuclear transfer guarantees that kids born are transgenic and of predetermined gender. Using these platform technologies, several recombinant proteins of commercial interest have been produced, although none of them has yet gained marketing approval. Before these technologies are implemented in goat improvement programmes, efficiencies must be improved, costs reduced, and regulatory approval obtained for the marketing of food products derived from such animals.

Production of bioproducts through the use of transgenic animal models.

Transgenic livestock that produce recombinant proteins in their milk can provide an economic and safe system for production of valuable proteins, such as pharmaceutical proteins for treatment or prevention of human disease or biomaterials for medical use. This method of production is frequently referred to as biopharming. The promise of biopharming, that is the actual commercial production of pharmaceuticals and other bioproducts, is nearing fulfillment. Improvements in molecular and reproductive techniques and strong economic incentives have continued to drive the implementation of transgenic technology to domestic animals. Nuclear transfer using transgenic donor cells is rapidly becoming the predominant technique used in the production of transgenic livestock, replacing the direct injection of DNA into the zygotic pronuclei. Production of transgenic founder animals by nuclear transfer in combination with traditional reproductive technologies can result in the propagation of transgenic herds of sufficient size to meet market demands for commercially important proteins. While some of the companies that have established transgenic programs have run into setbacks owing to a combination of economic, scientific and regulatory difficulties, other companies are continuing to make significant advances. While further improvements are needed to increase efficiencies of production, economically viable production of recombinant proteins using livestock species is not only possible but should be a commercial reality in the very near future.

Prepubertal propagation of transgenic cloned goats by laparoscopic ovum pick-up and in vitro embryo production.

The use of laparoscopic ovum pick-up (LOPU) followed by in vitro embryo production was evaluated in the early propagation of cloned goats. Ten kinder goats produced by somatic cell nuclear transfer technology were used as oocyte donors. Half of the donor animals were subjected to LOPU at 2-3 months of age (prior to induction of lactation), whereas the other five goats were subjected to LOPU at 6-7 months of age (following induction to lactation). They were stimulated with 80 mg NIH-FSH-P1 (Folltropin, Vetrepharm, Canada) together with 300 IU eCG (Novormon, Vetrepharm, Canada) administered intramuscularly 36 h prior to LOPU. The number of follicles aspirated and oocytes recovered was higher in the younger group of donors (57 +/- 7 and 41 +/- 4 vs. 28 +/- 2 and 25.8 +/- 2, p < 0.05), however, oocytes from animals in the late prepubertal age showed higher developmental capacity resulting in higher transferable embryo yield (81.4% vs. 67.8%, p < 0.01), pregnancy rate (80% vs. 40%, p < 0.05) and total kids born (27 vs. 15, p < 0.01). In conclusion, LOPU in combination with in vitro embryo production techniques is an efficient method for the early propagation of valuable goats produced by somatic cell nuclear transfer.

Production of cloned goats after nuclear transfer using adult somatic cells.

The developmental potential of adult somatic nuclei after nuclear transfer (NT) into enucleated, in vitro-matured oocytes was evaluated in a dwarf breed of goat (BELE: Breed Early Lactate Early). Somatic donor cells were obtained from two different sources: 1) adult granulosa cells (GCs) and 2) fetal fibroblasts. Primary GCs were obtained from follicular aspirants after laparoscopic oocyte pick-up (LOPU) and were cryopreserved immediately. Frozen aliquots of cells were thawed and cultured until confluent and were then cultured in low serum for 4 days before use in NT. Immature oocytes were obtained by LOPU and matured before enucleation and NT. Ninety-one adult GC-derived NT embryos were transferred into eight recipients, four of which were confirmed pregnant (50%) at Day 30 by ultrasound. Fifty-four male fetal fibroblast-derived NT embryos were transferred into six recipients, one of which was confirmed pregnant (17%). All pregnancies were maintained through term. Four recipients delivered seven female kids (three sets of twins) derived from the GC cultures (7.7% of embryos transferred). The other recipient delivered two male kids (3.7% of embryos transferred). Birth weights were within the normal range for dwarf goats. One female twin and one male twin died at birth; the remaining kids appeared healthy and normal. DNA analysis confirmed that the kids were genetically identical to their respective donors. These results demonstrated that adult caprine somatic cells could direct normal development after NT.

Seasonal variation in preovulatory events associated with synchronization of estrus in dwarf goats.

This experiment was conducted to define the temporal relationships among estrus, the LH surge and ovulation after estrus synchronization in dwarf goats and to assess the effect of season on these parameters. In November (breeding season), March (transition period) and July (non-breeding season), estrus was synchronized in 12 dwarf goats by means of intravaginal sponges containing 60 mg medroxyprogesterone acetate (MAP) for 10 d, coupled with 125 microg cloprostenol i.m. 48 h before sponge removal and 300 IU eCG i.m. at sponge removal. A different group of animals was used during each time period. Onset of estrus was monitored using two males, and blood samples for the measurement of plasma LH were collected at 2-h intervals from 24 to 60 h after sponge removal. Ovulation was confirmed by laparoscopy at 54 and 72 h after sponge removal. A seasonal shift was detected in the intervals to onset of estrus, LH surge, and ovulation after sponge removal (P<0.05), with sponge removal to onset of estrus being shorter (P<0.05) in November (25.0 +/- 1.56 h) and July (28.9 +/- 2.43 h) than in March (40.9 +/- 3.27 h). The intervals between onset of estrus and the LH surge and between the LH surge and ovulation were found to be constant throughout the different seasons. An optimal time for breeding, artificial insemination, oocyte and embryo recovery, and embryo transfer may be predicted using information gained from these studies.

Generation of dwarf goat (Capra hircus) clones following nuclear transfer with transfected and nontransfected fetal fibroblasts and in vitro-matured oocytes.

The developmental potential of caprine fetal fibroblast nuclei after in vitro transfection and nuclear transfer (NT) into enucleated, in vitro-matured oocytes was evaluated. Fetal fibroblasts were isolated from Day 27 to Day 30 fetuses from a dwarf breed of goat (BELE: breed early lactate early). Cells were transfected with constructs containing the enhanced green fluorescent protein (eGFP) and neomycin resistance genes and were selected with G418. Three eGFP lines and one nontransfected line were used as donor cells in NT. Donor cells were cultured in Dulbecco minimum Eagle medium plus 0.5% fetal calf serum for 4-8 days prior to use in NT. Immature oocytes were recovered by laparoscopic ovum pick-up and matured for 24 h prior to enucleation and NT. Reconstructed embryos were transferred as cleaved embryos into synchronized recipients. A total of 27 embryos derived from transgenic cells and 70 embryos derived from nontransgenic cells were transferred into 13 recipients. Five recipients (38%) were confirmed pregnant at Day 35 by ultrasound. Of these, four recipients delivered five male kids (7.1% of embryos transferred) derived from the nontransfected line. One recipient delivered a female kid derived from an eGFP line (7.7% of embryos transferred for that cell line). Presence of the eGFP transgene was confirmed by polymerase chain reaction, Southern blotting, and fluorescent in situ hybridization analyses. Nuclear transfer derivation from the donor cells was confirmed by single-strand confirmation polymorphism analysis. These results demonstrate that both in vitro-transfected and nontransfected caprine fetal fibroblasts can direct full-term development following NT.

Sexual maturation and fertility of male Nigerian Dwarf goat (Capra hircus) clones produced by somatic cell nuclear transfer.

Three, genetically identical, Nigerian Dwarf bucks produced by somatic cell nuclear transfer (NT) of fetal fibroblasts were monitored for sexual maturation and fertility. Starting at four months of age, these male clones were trained to serve an artificial vagina (AV). Average age of the NT-derived bucks at first semen collection was 20 weeks, which was not different from that of other young bucks of this breed (average age at first collection = 20 weeks). Average sperm production at 5 months of age for the NT-derived bucks was 5.0 x 10(8) spermatozoa, which was comparable to that of dwarf bucks of similar age (3.4 x 10(8) spermatozoa). At seven months of age, semen collected from two NT-derived bucks was used to artificially inseminate six females (three does per buck). Five does were confirmed pregnant by ultrasound at day 42. Nine healthy kids, four males and five females, were born in March and April 2000. Viable spermatozoa were collected from one of the F1 males at 28 weeks of age. These results demonstrated that NT-derived bucks and one of their male offspring developed sexually within the normal timeframe for their breed and that the clones were fertile.

Activation of bovine oocytes following intracytoplasmic sperm injection (ICSI).

In the human and the mouse, intracytoplasmic sperm injection (ICSI) apparently triggers normal fertilization and may result in offspring. In the bovine, injection of spermatozoa must be accompanied by artificial methods of oocyte activation in order to achieve normal fertilization events (e.g., pronuclear formation). In this study, different methods of oocyte activation were tested following ICSI of in vitro-matured bovine oocytes. Bovine oocytes were centrifuged to facilitate sperm injection, and spermatozoa were pretreated with 5 mM dithiothreitol (DTT) to promote decondensation. Sperm-injected or sham-injected oocytes were activated with 5 microM ionomycin (A23187). Three hours after activation, oocytes with second polar bodies were selected and treated with 1.9 mM 6-dimethylaminopurine (DMAP). The cleavage rate of sperm-injected oocytes treated with ionomycin and DMAP was higher than with ionomycin alone (62 vs 27%, P < or = 0.05). Blastocysts (2 of 41 cleaved) were obtained only from the sperm-injected, ionomycin + DMAP-treated oocytes. Upon examination 16 h after ICSI, pronuclear formation was observed in 33 of 47 (70%) DMAP-treated oocytes. Two pronuclei were present in 18 of 33 (55%), while 1 and 3 pronuclei were seen in 8 of 33 (24%) and 7 of 33 (21%) oocytes, respectively. In sham-injected oocytes, pronuclear formation was observed in 15 of 38 (39%) with 9 (60%) having 2 pronuclei. Asa single calcium stimulation was insufficient and DMAP treatment could result in triploidy, activation by multiple calcium stimulations was tested. Three calcium stimulations (5 microM ionomycin) were given at 30-min intervals following ICSI. Two pronuclei were found in 12 of 41 (29%) injected oocytes. Increasing the concentration of ionomycin from 5 to 50 microM resulted in a higher rate of activation (41 vs 26%). The rate of metaphase III arrest was lower while the rate of pronuclear formation and cleavage development was higher in sperm-injected than sham-injected oocytes, suggesting that spermatozoa contribute to the activation process. Further improvements in oocyte activation following ICSI in the bovine are necessary.

Pluripotent bovine embryonic cell lines direct embryonic development following nuclear transfer.

Nuclear transfer (NT) procedures were used to determine the in vivo developmental capacity of bovine embryonic cell lines derived from both morula- and blastocyst-stage embryos. These cell lines differed in morphology from trophoblast and endoderm-like cells. Regardless of initial donor embryo stage, cells in the resulting bovine embryonic cell lines had a small cytoplasmic/nuclear volume ratio and contained cytoplasmic vesicles. Developmental rates to blastocyst stage for NT embryos were improved when smaller cells (15 microns) rather than larger cells (18 microns or 21 microns) were used in the NT procedure and the recipient oocyte was activated after the cell fusion step. NT embryos produced from these embryonic cell lines, both morula- and blastocyst-derived, initiated pregnancies following transfer into recipient females. However, all of these pregnancies were lost prior to 60 days of gestation. These NT embryos were able to direct development through organogenesis, with one NT fetus reaching 55 days before death. When viable NT embryos were recovered during early gestation (38 days), an absence of cotyledons and a hemorrhagic response in the caruncles were observed. A chimera produced by aggregating an NT embryo with two 8-cell-stage blastomeres from in vitro-produced embryos developed through the 85th day of gestation. However, this conceptus was also deficient of cotyledons. DNA markers indicated that 50% of the chimera conceptus tissues were derived from the embryonic cell line. Blastocyst- and morula-derived embryonic cell line nuclei are pluripotent in that they can direct development through organogenesis, with subsequent pregnancy loss due, at least in part, to a deficiency in placentome development.

Bovine nuclear transfer embryos: oocyte activation prior to blastomere fusion.

Successful bovine nuclear transfer (NT) embryo production requires proper oocyte activation and transfer of a nucleus into this oocyte. However, the temporal relationship between these two events is unclear. The current study examined whether activation of the oocyte prior to fusion would induce nuclear swelling while also affecting development to morula and blastocyst stage and finally development to offspring. Aged oocytes can be activated by a number of techniques including exposure to room temperature. In this study oocyte activation was induced through three different means: reduced temperature culture alone, reduced temperature culture and calcium ionophore, and naturally, through the fertilization process. Electrofusion was carried out after the activation stimulus. When used in the NT procedure, activation of oocytes prior to fusion resulted in NT embryos that underwent nuclear swelling and had a high developmental rate to morula and blastocyst stages. Also, these NT embryos developed to normal offspring when transferred to recipient animals. The addition of a calcium ionophore treatment to the reduced temperature culture was not beneficial and resulted in less nuclear swelling. The use of enucleated fertilized oocytes as recipient cytoplasm for the new nucleus resulted in NT embryos developing to morula and blastocyst stages at the same rate as room temperature activated NT embryos. Therefore, improved embryo development can be obtained from NT embryos if the aged recipient oocyte is activated prior to the time of fusion. Also, offspring were obtained from these pre-activated NT embryos.

Bovine inner cell mass cells as donor nuclei in the production of nuclear transfer embryos and calves.

Bovine inner cell mass (ICM) cells were used as donor nuclei in nuclear transfer procedures to determine their totipotency. ICMs were isolated by immunosurgery from expanded Day 7-9 blastocysts that had been produced in vitro. Each individual ICM cell was transferred into an enucleated oocyte. Oocytes were checked for enucleation with Hoechst dye to ensure that all DNA was removed, thus eliminating the possibility of parthenogenetic development. ICM cell-oocyte units were fused by a brief electrical pulse (110 V DC, 15 microseconds in a 500-microns chamber), and the resulting zygotes were placed into CR1 bovine embryo culture medium supplemented with amino acids and fetal calf serum. The nuclear transfer embryos were scored for development to the blastocyst stage on Day 7 (day of fusion = 0). A total of 948 nuclear transfers were completed in 25 trials. In 12 of the trials, development to the blastocyst stage (5%, 30 of 629) was observed. This resulted in an overall developmental rate of 3% for all trials. Twenty-six of the ICM-derived blastocysts were transferred. The initial pregnancy rate at 30 days was 23% with six pregnant recipients. Two pregnancies were lost after 60 days, and four calves were born, two of which were stillborn. These results demonstrated that nucleic of ICM cells from expanded bovine blastocysts were pluripotent, if not in fact totipotent, since these nuclei after nuclear transfer to enucleated oocytes could direct embryonic and fetal development resulting in live offspring.

In vitro culture of bovine IVM-IVF embryos: Cooperative interaction among embryos and the role of growth factors.

The objective of this study was to determine whether there is a cooperative interaction among bovine embryos during in vitro culture. Furthermore, culture medium was supplemented with the growth factors, epidermal growth factor (EGF) and transforming growth factor-beta1 (TGF-beta1), to determine if these factors had a stimulatory effect on bovine embryo development similar to that seen in mouse development. In vitro matured - in vitro fertilized bovine embryos (2- to 8-cell) were cultured singly and in groups of five in 25 mul of medium (CR1 + amino acids + fatty acid-free bovine serum albumin) with or without EGF and TGF-beta1. Bovine embryos cultured in groups had a significantly higher rate of development to the blastocyst stage than embryos cultured singly. Neither EGF (10 ng/ml) nor TGF-beta1 (2 ng/ml) affected blastocyst development, hatching or the cell number of the embryos cultured in groups. Epidermal growth factor stimulated hatching of embryos cultured singly from the 8-cell stage, but did not significantly affect blastocyst development.

Effect of follicle-stimulating hormone and luteinizing hormone during bovine in vitro maturation on development following in vitro fertilization and nuclear transfer.

The effects of luteinizing hormone (LH) (0, 100, 10,000 IU/ml) and follicle-stimulating hormone (FSH) (20 micrograms/ml) supplementation during in vitro maturation of slaughterhouse-derived oocytes on polar body formation and embryo development subsequent to in vitro fertilization and nuclear transfer were evaluated. Gonadotropin supplementation of maturation medium in the presence of serum neither enhanced the proportion of oocytes forming a polar body nor significantly affected development following in vitro fertilization or nuclear transfer, except at the highest LH concentration. A very high concentration of LH (10,000 IU/ml) significantly decreased polar body formation, initial cleavage, and blastocyst development (P < 0.05).

Multiple generational bovine embryo cloning.

Repeated cycles (multiple generations) of nuclear transfer procedures have the potential of producing a large number of identical offspring from the micromanipulation of one mammalian embryo. This paper outlines the differences in nuclear transfer procedure efficiencies and developmental rates for the various stages and generations of embryos. We report the production of 54 genetically identical embryos that developed to the morula stage from one parent embryo. When a limited number of nuclear transfer embryos (clones) were transferred to recipient females, first, second, and third generation calves were born. Clones cultured for 5 days in the sheep oviduct had a greater number of cells (28.1 +/- 1.7) than clones cultured for 4 days (17.8 +/- 1.7). However, fusion rates were lower for Day 5 clones (Day 5, 57% vs. Day 4, 68%; p < 0.001) used as donors for the next generation of cloning. Different generations of clones also varied in fusion rates. Fusion rates generally declined with each additional generation and ranged from 66% for the parent-donor embryos to 52% for second generation donors (p < 0.01). Developmental rates were highest for first and third generation donors (20% and 19%) and lowest for second generation donors (10%; p < 0.001). Further understanding of the factors that are conducive to high developmental rates and nuclear reprogramming may make it possible to produce an unlimited number of genetically identical animals.

Blood constituents during the estrous cycle and early pregnancy in dairy cows.

The objective of this study was to determine if maternal platelet count, white blood cell count or other blood constituents undergo sustained alterations in concentration following fertilization. Blood samples from 17 Holstein females were collected over an 18-d period starting at estrus. Blood was analyzed for levels of platelets, white blood cells, red blood cells, hemoglobin and hematocrit. Results were analyzed for differences between nonpregnant and pregnant groups. Analysis of variance revealed a day-by-group interaction in the platelet count (P<0.01). White blood cell count showed both a day-by-group interaction and a difference between days (P<0.01). Red blood cell count, hematocrit and hemoglobin levels resulted in no significant difference between the two groups (P>0.05). While statistically significant differences were observed in platelet and white blood cell count, neither of these were sustained over a period longer than 2 d.

Cleavage development of bovine oocytes fertilized by sperm injection.

Whole in vitro capacitated bovine spermatozoa were microinjected directly into the ooplasm of in vitro matured bovine oocytes in order to determine whether oocytes fertilized by sperm injection could undergo normal pronuclear formation and cleavage development. Immature oocytes recovered from follicles (2-5 mm) of unstimulated ovaries were cultured for 24-25 h in modified TCM 199 medium supplemented with heat-treated day 20 cow serum, luteinizing hormone (LH), and estradiol 17-B. In vitro capacitated, frozen-thawed spermatozoa were injected into the ooplasm, and the injected oocytes were cultured for an additional 24-28 h. Twenty-one percent (21/101) of the sperm-injected oocytes contained a sperm within the ooplasm; however, only 2% (2/101) cleaved. The remaining oocytes either did not contain a sperm or had degenerated. After oocyte activation induced by a 5 min incubation in 1 microM A23187, sperm nuclear decondensation occurred in the A23187-activated, injected oocytes but not in the unactivated, injected controls (37% vs. 0% after 3 h). Those injected, activated oocytes that contained a male pronucleus also exhibited a female pronucleus and second polar body. Furthermore, a significantly higher number (28%, 6/21) of the injected, activated oocytes cleaved to a two- to four-cell stage after 48 h than did the injected, unactivated oocytes (4%). These results indicate that, unlike hamster and rabbit oocytes, bovine oocytes are not sufficiently stimulated by the injection procedure to complete meiosis, but, upon activation by calcium ionophore, they will undergo normal-appearing cleavage development following fertilization by sperm injection.