Development of a large commercial camel embryo transfer program: 20 years of scientific research.

Embryo transfer in camels was initiated to respond to demand from the camel industry particularly in the United Arab Emirates since 1990. This paper reviews the research performed in critical areas of reproductive physiology and reproductive function evaluation that constitute a pre-requisite for a successful embryo transfer program. A description of donor and recipient management as well as a retrospective evaluation of calf production in the embryo transfer program at Sweihan, UAE is provided. The program utilized two management systems for donors, with and without ovarian superstimulation. Non-stimulated donors are flushed every 14-15 days with a mean embryo production per year per female of 8.5±3.1 (mean±SEM). Response to gonadotropin stimulation is extremely variable. FSH doses and frequency of administration is often adjusted to a specific female. In the period of 1990-2010, 11,477 embryos were transferred to recipients. Transfers from 1990 to 2009 (n=10,600) resulted in 2858 weaned calves, representing an overall efficiency (% weaned calves/transfer) of 27%. Pregnancy rates at 60 days post transfer varied from 19 to 44%. Pregnancy length following transfer is extremely variable. A major challenge in a large embryo transfer program is finding good quality recipients. Causes of pregnancy and neonatal losses are under study.

Selection and characterization of recombinant dromedary antiovalbumin antibody fragments that do not cross-react with ovalbumin-related protein X: use for immunoaffinity.

Ovalbumin-related protein X (OVAX) and ovalbumin are two very close ovalbumin-related serpins. As primary data on OVAX remain recent, information about possible cross-reaction of available antiovalbumin antibodies with OVAX is still missing. Using labeled purified OVAX and dot ligand blotting, we identified 49 recombinant dromedary antiovalbumin single domain antibody (sdAb) fragments that were unable to bind OVAX. Discrimination between OVAX and ovalbumin was confirmed for two of the corresponding sdAb fragments by surface plasmon resonance and Western ligand blotting (WLB) characterizations. Furthermore, they were covalently linked to Sepharose and used as an affinity matrix for ovalbumin depletion. At least 90% of the original ovalbumin was eliminated from the allantoic fluid of 14 day old chicken embryo in one step. These sdAb fragments, which bind ovalbumin with nanomolar affinity, should also contribute to a better characterization of ovalbumin preparations.

A one-step exclusion-binding procedure for the purification of functional heavy-chain and mammalian-type gamma-globulins from camelid sera.

A new approach has recently been proposed for the purification of 'mammalian-type' IgG, consisting of exclusion binding. The technique uses a gel ('Melon gel'; Pierce) that binds to all plasma proteins, but not to IgGs, thus allowing IgGs to be recovered in the FT (flow-through) fraction. Here, the technique was applied to camelid IgGs, which are known to be composed of not only classic mammalian-type IgGs (IgG1) but also HC-IgGs (heavy chain IgGs). Both mammalian type and HC-IgGs can be purified in the FT fraction of dromedary (Camelus dromedarius) plasma samples with less than 8.5% contamination, by making minor improvements to the conditions recommended by the manufacturer. The contaminant proteins, as determined by LC-MS/MS (liquid chromatography-tandem MS), are mainly transferrin and albumin. The recovery rate is elevated for both types of IgGs (95+/-14% and 88+/-25% for IgG1 and HC-IgGs respectively). IgGs thus purified maintain their ability to bind to their antigen, as measured by surface plasmon resonance and Western ligand blotting. Furthermore, IgGs can be purified from plasma samples of all camelid species in a similar manner, although the ratio of HC-IgGs to total IgGs was lower for Lama (llama) and Vicugna (vicuña) than for Camelus species. The 'Melon gel' technique can thus be used to satisfactorily purify IgG1 and HC-IgGs from all camelid species.

A new method to discriminate immunogen-specific heavy-chain homodimer from heterotetramer immunoglobulin G directly in immunized dromedary whole plasma proteins: Western ligand blotting.

The variable domain of heavy-chain camelid antibodies (VHH), exclusively present in the homodimer IgGs (HC IgG), provides valuable ligands for diagnosis, imaging and therapy. These VHHs are efficiently produced from lymphocytes of immunized animals through phage display and recombination biotechnology. For VHH development it is desirable to identify animals with high affinity HC IgG response by monitoring antigen-binding in the course of immunization. The aim of this study was to propose a direct approach on whole plasma samples to distinguish between homodimer IgG and heterotetramer (IgG(1)) responses, and quantify them, using western ligand blotting (WLB). WLB consists here in electrophoretic separation of the target IgG subclasses on the basis of molecular size and binding of (125)I labeled antigen. First, we established the WLB parameters for titration of antigen-binding homodimers in relation to antigen-binding total IgGs in ovalbumin-immunized dromedary plasma samples and demonstrated that the WLB is an alternative to ELISA for IgG subclass titration. As purification of IgG subclasses or availability of IgG subclass-specific antibodies is not necessary, WLB is more direct and practical for screening a large number of samples. Second, WLB was applied to study the pattern of homodimer and heterotetramer responses during the time-course of immunizations against three different types of immunogens. As these patterns can differ between animals and immunogens, the method may be useful for identifying animals displaying the desired antigen-specific homodimer IgG response. Lastly, WLB was also described in its variant form of dot ligand blotting for identifying antigen-binding phages at the final step of a phage display experiment.

The first dromedary (Camelus dromedarius) offspring obtained from in vitro matured, in vitro fertilized and in vitro cultured abattoir-derived oocytes.

Dromedary offspring have never been produced fully in vitro. We have previously demonstrated that embryos obtained by culture in semi-defined medium (mKSOMaa) have better in vitro development ability than those cultured with oviductal epithelial cells. The aim of the present experiment was to study the pregnancy rate after embryo transfer of in vitro-produced (IVP) dromedary embryos cultured in semi-defined modified medium (mKSOMaa). IVM/IVF procedures were conducted on six hundred and sixty four (664) cumulus oocytes complexes (COCs) aspirated from ovaries collected at a local slaughterhouse and cultured in vitro (38.5 degrees C; 5% CO2, and maximum humidity >95%). Maturation was completed by incubation in TCM-199 medium supplemented with 10% heat-treated Fetal Calf Serum (FCS), 10 ng/mL EGF, 1 microg/mL FSH, 1 microg/mL E2 and 500 microM cysteamine for 30 h. In vitro fertilization was performed using fresh semen (0.5 x 10(6) spermatozoa/mL in modified TALP-solution). Fertilized oocytes were cultured in mKSOMaa, under 38.5 degrees C, 5% CO2 and 90% N2 with maximum humidity (>95%). All IVC steps were done in seven replicates. The cleavage rate (two cells to blastocyst stage) was 64% (425/664) and the percentage of oocytes reaching the blastocyst stage was 23% (155/664). The hatching rate of blastocyst obtained after culture was 46% (71/155). Good quality hatched blastocysts (n = 66) were transferred individually to synchronized recipients. Pregnancy rates, determined by ultrasonography at 15, 60 and 90 days after embryo transfer (ET), were 38%, 32% and 27%, respectively. Out of 18 pregnant females 5 aborted between the fifth and seventh month of pregnancy and 13 females (20%) remained pregnant. After 385 days of pregnancy, the first healthy and normal male-dromedary offspring produced fully in vitro was born at a birth weight of 38 kg. More dromedary calves (n = 4) were born later on. The remaining pregnant females (n = 8) are due to calf within the next months. In conclusion, this is the first reported offspring in camelids obtained by transfer of embryos produced by IVM, IVF and IVC using abattoir-derived oocytes, fresh semen and culture in a semi-defined medium.

Production of dromedary (Camelus dromedarius) embryos by IVM and IVF and co-culture with oviductal or granulosa cells.

The general objective of this work was to produce dromedary embryos from cumulus-oocyte complexes (COCs) that were matured, fertilized and co-cultured in vitro. A total of 1598 COCs were recovered from 457 ovaries; 1308 were deemed suitable for IVM and were cultured at 38.5 degrees C, 5% CO2, and >95% humidity for 36 h in TCM-199 supplemented with 10% heat-treated fetal calf serum (FCS), 10 ng/ml epidermal growth factor (EGF), 1 microg/ml FSH, and 500 microM cysteamine. Matured COCs (n = 88) were denuded, fixed, and stained to determine nuclear status; 63% (56/88) had reached metaphase II (MII) at 36 h. Overall, 1135 COCs were inseminated with ejaculated fresh semen (0.5 x 10(6)spermatozoa/ml in modified TALP-solution). Inseminated oocytes (n = 155) were examined for evidence of fertilization; 68% (106/155) were penetrated by spermatozoa, including 52% (55/106) with two pronuclei and 34% (36/106) with polyspermy. Inseminated, denuded oocytes (n = 819) were co-cultured with dromedary oviductal epithelial or granulosa cells in TCM-199 supplemented with 10% heat-treated FCS. Although the rate of first cleavage (two to eight cells) was similar for the two co-culture systems (32 versus 33%, respectively), more embryos (two-cell to blastocyst stage) were obtained from oocytes co-cultured with oviductal versus granulosa cells (61 versus 45%; P < 0.05). The proportions of fertilized oocytes developing to the early morula stage were 19% (80/417) and 12% (48/402) for oocytes co-cultured for 7 days with oviductal or granulosa cells, respectively (P > 0.05). However, development to the blastocyst stage (10% of fertilized oocytes) occurred only in oocytes co-cultured with oviductal cells. In conclusion, dromedary embryos were produced in vitro using abattoir-derived oocytes, fresh (ejaculated) semen, and oviductal cell co-culture.