Production and Characterization of a Conditionally Immortalized Dog Beta-Cell Line from Fetal Canine Pancreas

Since the 1970s, rodent and human insulin-secreting pancreatic beta-cell lines have been developed and found useful for studying beta-cell biology. Surprisingly, although the dog has been widely used as a translational model for diabetes, no canine insulin-secreting beta cells have ever been produced. Here, a targeted oncogenesis protocol previously described by some of us for generating human beta cells was adapted to produce canine beta cells. Canine fetal pancreata were obtained by cesarean section between 42 and 55 days of gestation, and fragments of fetal glands were transduced with a lentiviral vector expressing SV40LT under the control of the insulin promoter. Two Lox P sites flanking the sequence allowed subsequent transgene excision by Cre recombinase expression. When grafted into SCID mice, these transduced pancreata formed insulinomas. ACT-164 is the cell line described in this report. Insulin mRNA expression and protein content were lower than reported with adult cells, but the ACT-164 cells were functional, and their insulin production in vitro increased under glucose stimulation. Transgene excision upon Cre expression arrested proliferation and enhanced insulin expression and production. When grafted in SCID mice, intact and excised cells reversed chemically induced diabetes. We have thus produced an excisable canine beta-cell line. These cells may play an important role in the study of several aspects of the cell transplantation procedure including the encapsulation process, which is difficult to investigate in rodents. Although much more work is needed to improve the excision procedure and achieve 100% removal of large T antigen expression, we have shown that functional cells can be obtained and might in the future be used for replacement therapy in diabetic dogs.

The biological mechanisms regulating sperm selection by the ovine cervix

In species where semen is deposited in the vagina, the cervix has the unique function of facilitating progress of spermatozoa towards the site of fertilisation while also preventing the ascending influx of pathogens from the vagina. For the majority of species, advances in assisted reproduction techniques facilitate the bypassing of the cervix and therefore its effect on the transit of processed spermatozoa has been largely overlooked. The exception is in sheep, as it is currently not possible to traverse the ovine cervix with an inseminating catheter due to its complex anatomy, and semen must be deposited at the external cervical os. This results in unacceptably low pregnancy rates when frozen-thawed or liquid stored (>24 h) semen is inseminated. The objective of this review is to discuss the biological mechanisms which regulate cervical sperm selection. We assess the effects of endogenous and exogenous hormones on cervical mucus composition and discuss how increased mucus production and flow during oestrus stimulates sperm rheotaxis along the crypts and folds of the cervix. Emerging results shedding light on the sperm-cervical mucus interaction as well as the dialogue between spermatozoa and the innate immune system are outlined. Finally, ewe breed differences in cervical function and the impact of semen processing on the success of fertilisation, as well as the most fruitful avenues of further investigation in this area are proposed.

Production, Characterization, and Function of Pseudoislets from Perinatal Canine Pancreas

We evaluated the cell composition and function of canine pancreatic pseudoislets (PIs) produced from 42- to 55-day-old fetuses, 1- to 21-day-old pups, and an adult dog pancreas. After mild collagenase treatment, partially digested tissues were cultured for 2–3 weeks. PI production started on culture day 3, was marked for 6 to 9 days, and then stopped. PI production was greatest with the neonatal specimens, reaching about 12 million aggregates per litter (55-day-old fetus) or per pancreas (1-day-old pup). Cell composition at all stages was similar to that in adult pancreatic islets, with predominant β cells, scant α cells and, most importantly, presence of δ cells. Among pancreatic markers assessed by quantitative real-time PCR (qRT-PCR) mRNA assay, insulin showed the highest expression levels in PIs from newborn and adult pancreas, although these were more than 1000 times lower than in adult islets. Pdx1 mRNA expression was high in PIs from 55-day-old pancreases and was lower at later stages. Consistent with the qRT-PCR results, the insulin content was far lower than reported in adult dog pancreatic islets. However, insulin release by PIs from 1-day-old pups was demonstrated and was stimulated by a high-glucose medium. PIs were transplanted into euglycemic and diabetic SCID mice. In euglycemic animals, the transplant cell composition underwent maturation and transplants were still viable after 6 months. In diabetic mice, the PI transplants produced insulin and partially controlled the hyperglycemia. These data indicate that PIs can be produced ex vivo from canine fetal or postnatal pancreases. Although functional PIs can be obtained, the production yield is most likely insufficient to meet the requirements for diabetic dog transplantation without further innovation in cell culture amplification.

78 INTERCEPTION OF EXOSOMAL MESSAGES BETWEEN THE OVIDUCT AND THE EMBRYO: WHAT ARE THEY TWEETING ABOUT?

Successful pregnancy requires an appropriate communication between the mother and the embryo(s). Recent studies indicate that exosomes, small (30–100 nm) membrane-bound vesicles of endocytotic origin, could act as intercellular vehicles in this unique communication system in the uterus. However, little is known about the role of these vesicles in the oviduct. Our study aimed at (1) demonstrating the existence of oviducal-embryo communication via exosomes, (2) deciphering the exosomal dialogue between them at the proteomic level, and (3) comparing the exosomal proteomic content to the oviducal fluid proteomic content in order to highlight the key role of exosomes in this dialogue. Cow oviducts (pool of 6 oviducts at different stages of the cycle in 4 replicates) were flushed, and exosomes were isolated by serial ultracentrifugation. Exosomes were measured by dynamic light scattering analysis, resulting in exosomes (63.25–97.03 nm) and microvesicle observations (>100 nm). Bovine embryos were produced in vitro up to the blastocyst and hatching/hatched blastocyst stages. To demonstrate the existence of the oviducal-embryo communication via exosomes, oviducal exosomes were labelled with green fluorescent dye (PKH67), filtered (0.22 µm) to remove microvesicles, and co-incubated with blastocysts and hatching/hatched (H) blastocysts for 20 h, under 5% CO2 and 5% O2 conditions. Subsequently, embryos were washed in exosome-free medium, fixed in 4% paraformaldehyde, and labelled with Hoechst 33342 and Actin Red Phallodin. Confocal microscopy observations confirmed that exosomes were internalized by blastocysts and H-blastocysts and located around the nucleus, demonstrating the existence of an oviducal-embryo communication via exosomes. Moreover, our results showed that the zona pellucida does not represent a barrier for exosomes and they act as natural nanoshuttles bringing oviducal signals into the embryo. Then, proteomic analysis by LC1D-nanoESI-LTQ-Orbitrap was used to decipher oviducal exosomal content, identifying 480 proteins. Gene ontology analysis revealed that a high number of these proteins were involved in metabolism (24.9%), cellular process (19.3%), and 0.8% reproductive processes. Further analysis revealed that more than 56% of exosomal proteins involved in cellular process were associated with cell-to-cell communication. Finally, exosomal proteins were compared with proteins present in oviducal fluid from a pool of samples from cows at Day 0 and Day 10 of the oestrous cycle. Comparative analysis showed that from a total of 607 proteins identified in both oviducal exosomes and fluid sources, 105 were specific to exosomes, 127 were specific to fluid, whereas 375 were common to both sources. Our findings provide the first evidence of oviducal-embryo communication via exosomes, an important first step in furthering the understanding of the oviducal environment and the role of exosomes as early mediators of embryo-maternal cross talk. This research was supported by the EU AgreenSkills fellowship n° 267196 and EU FECUND Project no 312097.

Seminal fluid promotes in vitro sperm-oviduct binding in the domestic cat (Felis catus)

From many endangered or threatened species which are expected to profit from assisted reproduction techniques, mainly epididymal sperm of dead or freshly castrated males are available. These sperm had contact to epididymal secretion products but not to seminal fluid components. Notably, products of accessory sex glands have been shown in domestic animals to condition sperm for fertilization, in particular by mediating sperm-oviduct interaction. We report for the first time that motile epididymal sperm from domestic cats are able to bind to fresh oviduct epithelial cell explants from preovulatory females (median [min, max] of 10 [8, 16] and 10 [8, 17] sperm per 0.01 mm(2) explant surface from both isthmic and ampullar regions, respectively). More sperm attach to the explants when epididymal sperm were preincubated for 30 minutes with seminal fluid separated from electroejaculates of mature tomcats (median [min, max] of 17 [13, 25] and 16 [12, 21] sperm per 0.01 mm(2) explant surface from isthmus and ampulla, respectively). The proportion of bound sperm increased from a median of 54% to 62% by seminal fluid treatment. Sperm-oviduct binding could be facilitated by the decelerated sperm motion which was observed in seminal fluid-treated samples or supported by seminal fluid proteins newly attached to the sperm surface. Seminal fluid had no effect on the proportion of sperm with active mitochondria. Extent and pattern of sperm interaction in vitro were independent of explant origin from isthmus or ampulla. Sperm were attached to both cilia and microvilli of the main epithelial cell types present in all explants. In contrast to published sperm-binding studies with porcine and bovine oviduct explants where predominantly the anterior head region of sperm was attached to ciliated cells, the tails of some cat sperm were firmly stuck to the oviduct cell surfaces, whereas the heads were wobbling. Whether this response is a preliminary step toward phagocytosis or a precondition to capacitation and fertilization remains to be determined. In conclusion, treatment of epididymal sperm with seminal fluid or particular protein components should be considered in future investigations for its potential to improve the outcome of artificial insemination in felids.

Lack of transplacental transmission of Bartonella bovis

Transplacental transmission of Bartonella spp. has been reported for rodents, but not for cats and has never been investigated in cattle. The objective of this study was to assess vertical transmission of Bartonella in cattle. Fifty-six cow-calf pairs were tested before (cows) and after (calves) caesarean section for Bartonella bacteremia and/or serology, and the cotyledons were checked for gross lesions and presence of the bacteria. None of the 29 (52%) bacteremic cows gave birth to bacteremic calves, and all calves were seronegative at birth. Neither placentitis nor vasculitis were observed in all collected cotyledons. Bartonella bovis was not detected in placental cotyledons. Therefore, transplacental transmission of B. bovis and multiplication of the bacteria in the placenta do not seem likely. The lack of transplacental transmission may be associated with the particular structure of the placenta in ruminants or to a poor affinity/agressiveness of B. bovis for this tissue.

Expression of nuclear and membrane progesterone receptors in the canine oviduct during the periovulatory period

Important reproductive events take place in the canine oviduct in the presence of increasing concentrations of progesterone (P4). To investigate the potential effects of P4 on the canine oviduct, the expression of nuclear (PR) and membrane (PGRMC1 and 2, mPRα, β and γ) P4 receptors was studied by quantitative RT-PCR and immunohistochemistry. Oviducts were collected from Beagle bitches after the onset of pro-oestrus and before the LH peak (Pre-LH), after the LH peak and before ovulation (Pre-ov) and on Days 1, 4 and 7 post-ovulation (n=6 bitches/stage). PR mRNA concentrations decreased from Pre-LH to Day 7 in the ampulla and isthmus, whereas both PGRMC1 and 2 mRNA levels increased over the same period. The main change in mPR expression was an increase in mPRβ and γ mRNAs at Day 7 in the isthmus. Furthermore, PR proteins were expressed in the nuclei of luminal epithelial, stromal and muscular cells, whereas the expression of PGRMCs and mPRs was primarily cytoplasmic and localised in the luminal epithelium. The immunostaining for PR decreased at Day 4 in the stroma and muscle, whereas it remained strong in the epithelium from Pre-LH to Day 7. PGRMC1 staining was strong at Days 4 and 7 whereas PGRMC2 was highly expressed from Pre-ov to Day 7. The most intense immunostaining signals for all three mPRs were observed at Day 7. Our results strongly support the hypothesis that P4 is an important regulator of oviductal functions in the bitch through complementary classical and non-classical P4 pathways.

148 EXPRESSION OF OVIDUCT-SPECIFIC GLYCOPROTEIN IN THE CANINE OVIDUCT DURING THE PERIOVULATORY PERIOD

In the canine species, the oocyte is ovulated at the immature germinal vesicle (GV) stage and will reach metaphase II stage after 3 to 4 days spent in the oviduct. Fertilization and embryonic development to the blastocyst stage also take place in the oviduct. In a previous study (Tahir et al. 2012 Reprod. Domest. Anim. 47, 487), we reported the expression of oviductin (oviduct-specific glycoprotein) mRNA in the oviduct. The present study aimed to describe the oviductin protein expression (immunolocalization and Western blot quantification) and the effect of the oviducal region and the ovarian cycle. Beagle bitches were ovariectomized at 6 stages (6 bitches/stage): anestrus, after the onset of proestrus and before the LH peak (Pre-LH), after the LH peak and before ovulation (Pre-ov), 1 day (Day 1), 4 days (Day 4), and 7 days (Day 7) after ovulation. Three oviducal regions were collected [i.e. ampulla, isthmus, and ampulla-isthmus junction (AIJ)]. Ampulla and isthmus were fixed in paraformaldehyde, embedded in paraffin, and 7-μm sections were used for immuno-histochemistry using a goat polyclonal anti-human oviductin (N20; Santa Cruz Biotechnology, Santa Cruz, CA, USA) and the ImmPress kit (Vector Laboratories, Burlingame, CA, USA). Total protein from the AIJ was extracted and used for Western Blot using a mouse monoclonal anti-mouse antibody (H8; Santa Cruz Biotechnology). The expression of oviductin in AIJ was quantified in duplicate on blots using ImageJ software and normalized with actin levels. Relative amounts of oviductin were compared between stages by ANOVA followed by a Tukey test. Immuno-histochemistry revealed that oviductin was specifically expressed in the nonciliated cells of the oviducal epithelium from Pre-LH to Day 7, with a stronger staining in the isthmus than in the ampulla at all stages. Furthermore, the expression of oviduct-specific glycoprotein, detected by Western Blot, varied significantly with the stage (P < 0.0001). The oviductin protein expression was at its lowest level at anestrus, then increased significantly at Pre-LH and Pre-ov (35- and 41-fold higher levels than anestrus, respectively), reached a maximal level at Day 1 (66-fold higher than anestrus), then decreased at Days 4 and 7 (47- and 20-fold higher than anestrus, respectively). In conclusion, this is the first report of oviductin protein expression in the canine oviduct. The region-specific higher expression of oviductin at Day 1 post-ovulation suggests a potential role of this glycoprotein in gamete maturation and fertilization in the bitch.

121 EXPRESSION OF STEROID RECEPTORS IN THE CUMULUS - OOCYTE COMPLEX AROUND OVULATION IN THE BITCH

In the bitch, oocytes are ovulated at an immature stage (prophase I) and resume meiosis in the oviduct, 3 to 4 days after ovulation while they are still surrounded by 2 to 3 layers of cumulus cells. Canine cumulus-oocyte complexes (COC) are exposed to high and changing plasma concentrations of 17β-oestradiol (E2) and progesterone (P4) during the periovulatory period. In order to explore whether oocyte maturation may be regulated by steroids in this species, the expression of E2 (ERα, ERβ) and P4 (nuclear: PR; membrane: PGRMC1, PGRMC2, mPRα, mPRβ, mPRγ) receptors was studied in COC at precise times around ovulation. Ovaries were collected from Beagle bitches during anestrus (n = 4), after the beginning of proestrus, and before the LH peak (Pre-LH, n = 7), after the LH peak and before ovulation (Pre-ov, n = 8), and at Day 1 (n = 11) and Day 4 (n = 8) post-ovulation. Anoestrus COC were recovered from follicles smaller than 1 mm in diameter. The COC at the Pre-LH and Pre-ov stages were aspirated from preovulatory follicles (4.5–6 mm in diameter). Such follicular COC were partially denuded to leave the 2 to 3 innermost cumulus layers firmly attached to the zona pellucida. Post-ovulatory COC, naturally surrounded by 2 to 3 cumulus layers, were recovered by oviductal flushing. Total RNA was extracted from 3 batches of 10 COC per stage, then reverse transcribed. The expression of steroid receptors was assessed in duplicate by qPCR (LightCycler® 480, Roche Diagnostics) using the relative standard curve method and normalized by the geometric mean value of the two most stable reference genes (BGLR and RPS5; NormFinder software) chosen among four genes previously tested. Relative amounts of mRNA levels were compared between stages by ANOVA followed, when necessary, by a Tukey test. The ERα and ERβ expression did not vary significantly with the stage. In contrast, a significant variation between stages in nuclear and 4 membrane P4 receptor expression was observed (P < 0.0001 for PR; P < 0.001 for PGRMC1 and mPRβ; P < 0.05 for PGRMC2 and mPRγ). The PR mRNA levels were significantly higher at Pre-ov than at any other stage. PGRMC1 expression was significantly higher at Pre-ov and Day 4 compared with anestrus and Pre-LH, and was at an intermediate level at Day 1. The expression of PGRMC2, mPRβ, and mPRγ remained low from anestrus to Day 1 and increased significantly at Day 4. Lastly, mRNA levels of mPRα were below the detection limit at all stages. This is the first report of steroid receptor expression in canine COC at precise times around ovulation. The stage-specific variation in expression of nuclear and of several membrane P4 receptors around ovulation suggests a role for P4 in canine oocyte maturation. The exact localisation of these receptors in cumulus cells, oocytes, or both remains to be determined.

183 CANINE EMBRYOS OBTAINED BY INTRACYTOPLASMIC SPERM INJECTION

In vitro fertilization encounters 2 specific difficulties in the canine species, with no puppies born to date: low penetration rates (10–50%) and high polyspermia (around 50% of fertilized oocytes; Saint-Dizier et al. 2001 J. Reprod. Fert. Suppl. 57, 147–150). The objectives of the study were to test whether intracytoplasmic sperm injection (ICSI), which overcomes these 2 obstacles, could allow production of canine embryos, using in vivo- or in vitro-matured oocytes. The time of ovulation was determined on 8 Beagle bitches from our experimental kennel by blood progesterone assay and transabdominal ultrasound examination. After ovariohysterectomy 82 to 100 h after ovulation, 58 metaphase II (MII) oocytes were collected by tubal flushing. In parallel, 88 oocytes from 6 anoestrus bitches were matured in vitro (M199 + 20% fetal calf serum for 72 h in 5% CO2 at 38°C). Sperm was collected from 1 Beagle dog with excellent fertility record at natural mating. The sperm was diluted 1 : 100 in PBS/BSA without any selection process. Intracytoplasmic sperm injection was performed at 38°C in M199 HEPES + 20% BSA (4-μm injection pipette; 120-μm holding pipette). One motile spermatozoon of normal morphology was injected per oocyte. Injected oocytes were cultured in vitro for 48 h after injection (M199 + 20% fetal calf serum in 5% CO2 at 38°C) in 4-well open dishes. Oocytes were then fixed and DNA and tubulin were stained for observation by confocal microscopy (Chebrout et al. 2012 Microsc. Microanal. 18, 483–492). Among the 58 MII oocytes recovered in vivo, 7.4% lysed at injection and 20% degenerated during the 48 h after injection. Among the 40 injected oocytes still alive, 6 fragmented (15%) and 4 developed as embryos [10%; 2-pronuclei (n = 2), 2-cell and 6-cell). None of the other oocytes showed decondensed female chromatin. Among the 88 oocytes incubated for in vitro maturation, 13 (14.8%) reached MII. These were successfully injected; 48 h after injection, 3 were embryos at the 2-cell stage and 10 were at the MII stage with a condensed sperm head. Fifty-one non-mature oocytes were injected; 31 were at the germinal vesicle (GV) stage and the stage of others was not determined. Of the GV oocytes, 71% degenerated during culture after injection. The 9 surviving oocytes were still at the GV stage with condensed sperm head 48 h after injection. In conclusion, canine embryos can be obtained through ICSI. Nevertheless, this procedure induced low activation rates. Development at later stages, especially after transfer into a recipient female, is to be evaluated, in particular for in vitro-produced MII oocytes, of lower cytoplasmic competence (Viaris et al. 2008 Reprod. Fert. Dev. 20, 626–639).

90 CHARACTERIZATION OF A PRIMARY CULTURE OF OVIDUCTAL CELLS IN THE BITCH

The oviduct is of particular importance in canine reproduction as it supports oocyte meiosis resumption, sperm capacitation and storage, fertilization and embryo development to the morula/blastocyst stage for 8 to 10 days post-ovulation. A long-time co-culture with oviducal cells could be employed to improve the yield of reproductive biotechnologies in this species, but no characterisation of canine oviduct cells in vitro has been reported to date. The objectives of this study were to (1) evaluate the viability and proportion of epithelial/fibroblast cells in a primary culture of canine oviducal cells collected around ovulation; (2) study the responsiveness of the cultured cells to steroids. Beagle bitches (n = 9) were ovariectomized between Day –1 and Day +1 around ovulation, and their oviducts were sectioned at the ampulla-isthmus junction. Mucosal cells (including stromal and epithelial cells) were collected by squeezing from the ampulla and isthmus sections and cultured separately at a concentration of 5 × 105 cells/well in 500 μL of M199 + 10% FCS at 39°C for 9 days. At Days 3 and 6, 1 × 106 cells were stimulated with 17β-oestradiol (E2, 20 pg mL–1) or progesterone (P4, 20 ng mL–1) for 6 h. At Days 3, 6, and 9 of culture, the viability of the cells was evaluated using the Live/Dead kit (Invitrogen, Carlsbad, CA, USA), and proportions of fibroblast and epithelial ciliated cells were evaluated by immuno-cytochemistry using anti-vimentin and anti-tubulin antibodies, respectively. At Days 0, 3 and 6, the total RNA was extracted from cells and mRNA levels of the oviduct-specific glycoprotein (OVGP, synthesised by nonciliated epithelial cells), E2 (ERα, ERβ) and P4 (PR) receptors were evaluated by RT-qPCR. The effects of the day of culture and of steroid exposure on mRNA levels were analysed by ANOVA followed by a Tukey test. Cell confluence was observed around Day 6 of culture and more than 90% of cells survived during the 9-day culture period. From Day 3 to Day 9, the proportion of vimentin-positive (fibroblast) cells was greater than 68% in both ampulla and isthmus cells. In contrast, the proportion of epithelial ciliated cells was low at Day 3 (9% in ampulla, 12% in isthmus) and null at Days 6 and 9 in both regions. The mRNA levels of OVGP, ER, and PR decreased significantly after 3 days of culture, and then remained stable in both ampulla and isthmus cells (P < 0.001). The steroid exposure had no effect on gene expression, except for ERα mRNA levels at Day 3, which was increased by E2 and reduced by P4 (P < 0.05). In conclusion, the method of collection did not allow us to collect a high proportion of epithelial oviducal cells. However, the relatively stable gene expression of PR and ER during the culture period provides us with a useful tool to study the steroid regulation of canine oviduct mucosal cell functions.

176 IN VITRO MATURATION OF DOG OOCYTES IN CANINE FOLLICULAR FLUID

In the canine species, assisted reproductive technologies, especially in vitro maturation (IVM) and IVF, are still ineffective. The main limiting factor remains the immaturity of the oocytes collected from anestrus ovaries. The ability of an oocyte to reach the MII stage in vitro is linked to the diameter of its follicle and anestrus oocytes, collected from small (<1 mm) follicles, are profoundly immature (De Lesegno et al. 2008). The objective of this study was to improve cytoplasmic quality by mimicking in vivo conditions; that is, to test the effect of pure preovulatory follicular fluid (FF) on survival and IVM rates of anestrus dog oocytes, in order to improve the nuclear and cytoplasmic maturation of these immature oocytes. Follicular fluids samples were collected from 54 Beagle bitches at 2 stages: before the LH peak (n = 23 bitches) and after the LH peak (n = 31 bitches). Only follicular fluid samples from large (>4 mm) follicles were collected and pooled by stage. Control oocytes were matured in 20% FCS/M199 medium. Groups of 5 oocytes were in vitro matured in 30 μL of follicular fluid, in half-area 96-well plates (5% CO2, 38°C). After 72 h of IVM, oocytes were denuded, fixed, and stained for DNA and tubulin before observation by confocal microscopy, and nuclear stages were classified as GV-A to GV-E, MI, and MII (Reynaud et al. 2012). A total of 460 oocytes were collected from 13 anestrus bitches and allocated to either the control medium (n = 155), the Pre-LH FF (n = 145) or the Post-LH FF (n = 160) groups. After 72 h of IVM, the morphology of the cumulus–oocyte complexes (COC) in the post-LH group was different from that of the others: cumulus cells appeared more compact and darker. Analysis of the nuclear stages showed that the degeneration rate was significantly higher (P < 0.05) in the post-LH group (58.7%) than in the pre-LH (40.9%) or in the control group (34.4%). No significant differences (P > 0.05) were observed between the 3 groups in the rate of immature GVA-B oocytes (36.4, 28.5, and 25.3% in the control, Pre-LH, and Post-LH groups, respectively), in the rate of meiotic resumption (GV-C/D/E, MI, MII stages, 44.4, 51.9, and 38.7% in the control, Pre-LH, and Post-LH groups, respectively). Metaphase II rates were not significantly different (12.1, 8.6, and 4.8% in the control, Pre-LH, and Post-LH groups, respectively). In conclusion, canine COC may survive when exposed to IVM in pure follicular fluid, but the degeneration rate was higher in the post-LH group. The presence of follicular fluid did not inhibit meiosis resumption, but did not significantly improve IVM rates. To better mimic in vivo conditions, IVM in a sequence of media, such as IVM in follicular fluid followed by IVM in oviducal fluid remains to be tested.

Effect of blood handling conditions on progesterone assay results obtained by chemiluminescence in the bitch

Assay of blood progesterone (P4) is commonly practiced to determine the time of ovulation, diagnose luteal insufficiency, and predict time of parturition in bitches. Because of practical constraints, most blood samples cannot be assayed on site immediately after collection. The aim of this work was to evaluate the effects of various sampling and storage conditions on concentrations of P4 as determined by chemiluminescence immunoassay. The blood of 5 Beagle bitches was collected from the jugular vein to study the effect of the type of collection tube (silicone, lithium heparin, EDTA), the storage time of unseparated or separated plasma (2 h to 14 d), and the number of freeze-thaw cycles (1-10) on P4. The effect of each factor was tested within one assay session. None of the factors significantly affected P4. Thus, P4 appears to remain relatively stable in canine blood samples exposed to various processing and storage conditions.

Immunolocalization of progesterone receptors in the canine oviduct around ovulation

In the bitch, oocyte maturation, sperm storage, fertilization and early embryo development take place within the oviducts under high and increasing circulating progesterone concentrations. To investigate the potential effects of progesterone on the canine oviduct, nuclear progesterone receptors (PR) were localized. Oviducts were collected by ovariectomy from adult Beagle bitches during anestrus, after the onset of proestrus but prior to the Luteinizing Hormone (LH) peak (Pre-LH), after the LH peak but before ovulation (Pre-ov) and on Days 1, 4 and 7 after ovulation (n = 3 bitches per stage). The cellular distribution of PR was studied by immunohistochemistry (IHC) in the ampulla, isthmus and tubal part of the utero-tubal junction (UTJ). Plasma progesterone and 17β-oestradiol were assayed on the day of surgery. PR were specifically expressed in the nuclei of epithelial, stromal and muscular cells in the ampulla, isthmus and UTJ. The IHC scores did not vary from one oviductal region to another. However, the epithelium displayed higher scores than the stroma at anestrus, Pre-ov, Days 4 and 7, and also higher scores than muscle at Days 4 and 7 (p < 0.05). Immunohistochemistry scores in the stroma and muscle decreased at Days 4 and 7 compared with previous stages (p < 0.05). Furthermore, muscular IHC scores were positively correlated with circulating 17β-oestradiol concentrations and negatively correlated with circulating progesterone concentrations (p < 0.05). In conclusion, PR were identified in the canine oviduct, with differences in expression between tissues and times around ovulation, suggesting that progesterone may regulate tubal functions and reproductive events in this species.

Timing of the intestinal barrier closure in puppies

As puppies are born with very low immunoglobulin concentrations, they rely on passive immune transfer from ingested colostrum to acquire a protective immunity during the first few weeks of life. The purpose of this study was to describe the timing of gut closure in canine neonates. Twenty-two Beagle puppies received 3 ml of standardized canine colostrum at 0, 4, 8, 12, 16 or 24 h after birth using a feeding tube. Blood immunoglobulins G (IgG, M and A) were assayed 0, 4 and 48 h after colostrum ingestion. IgG absorption rate was significantly affected by the time of colostrum administration, and the IgG concentrations in puppies serum 48 h after administration were significantly higher when colostrum was ingested at 0-4 h of age than at 8-12 h or 16-24 h (1.68 ± 0.4, 0.79 ± 0.07 and 0.35 ± 0.08 g/l, respectively; p < 0.001). In the canine species, gut closure seems thus to begin as early as 4-8 h after birth and to be complete at 16-24 h. Consequently, this phenomenon appears to occur earlier in puppies than in most other species.

Chromatin patterns of immature canine oocytes after in vitro maturation

In canine species, in vitro maturation (IVM) rates of oocytes collected from anoestrous ovaries are low (<20%). Several IVM media have been tested without significant improvements. A critical step in the evaluation of culture conditions is the observation of the meiotic stage reached by the oocytes. The present study was designed to investigate the chromatin patterns of in vitro matured oocytes by visualizing Germinal Vesicle (GV) and Germinal Vesicle Breakdown (GVBD) structures at 72 h of IVM. Nuclear stages of 1678 oocytes were evaluated by confocal microscopy after IVM. 1204 oocytes were non-degenerated, and 94.4% were still immature and at GV stage. Five different patterns of chromatin configuration were observed. Higher percentages of oocytes with unmodified GV and with diffuse (58%; Type A) and filamentous chromatin (19%; Type B) were observed in comparison with those with modifications in the GV such as patched chromatin (12.5%; Type C), surrounded-nucleolus (3%; Type D) and in vivo type chromatin/fully grouped chromatin (2.5%; Type E). These results indicate that GVBD (absence of nucleolus, nucleus breakdown) is rarely observed in vitro. The percentage of type C-D-E GVs and MI (meiotic resumption) and of MII (completion of meiosis) can be used to evaluate meiotic resumption after IVM. Our results indicate that although a low number of in vitro matured oocytes exhibit the chromatin configurations observed in in vivo collected oocytes, chromatin changes in the GV can be induced during IVM.

69 DIFFERENTIAL AND QUANTITATIVE ANALYSIS OF DOG OVIDUCTAL FLUID

The major reproductive peculiarity of the bitch is that ovulation releases prophase I (germinal vesicle, GV, immature) oocytes. Resumption of meiotic maturation, as well as fertilisation and embryonic development to the morula stage occur in the oviduct. Because the dog is a biomedical model for human diseases and also a model for endangered canid species, the development of assisted reproduction techniques would be of great interest. To date, in vitro-produced canine embryos remain exceptional and no puppy has been born. The main limiting factors of in vitro embryo production are the low oocyte maturation rates, the poor oocyte quality and the high polyspermy. A better knowledge of the composition of oviductal fluid during the periovulatory period may help to mimic the in vivo conditions for in vitro oocyte culture and, thereafter, their fertilisation and embryonic development. The objective of this study was to analyse the oviductal fluid by a label-free quantitative proteomic workflow based on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) protein separation, nano-scale liquid chromatography-tandem mass spectrometry (nano-LC-MS/MS) analysis and quantitative method using spectral counting. Ovarian cycles were followed by vaginal smears, ultrasonography and progesterone blood assays. Oviductal fluids were collected from 3 beagle bitches, after ovariectomies performed 3.5 days after ovulation. After dissection, the ampulla and isthmus were separated and flushed with 50 μL of PBS. Oviductal fluids were submitted to 1D SDS-PAGE and all bands were digested with trypsin. Peptide extracts were analysed on an Ettan multidimensional LC (MDLC) system coupled to a linear ion trap quadrupole (LTQ) mass spectrometer. After protein identification using Mascot server and with Swiss-Prot and National Center for Biotechnology Information (NCBI) databases, bioinformatic processing of data and statistic analysis (t-test with P < 0.05) were performed using the spectral counting quantitative module of the Scaffold software. Using this strategy, 427 proteins were qualitatively identified in canine oviductal fluid. Three proteins were specific of the ampulla, 10 specific of the isthmus and 414 were found in both oviductal parts. Among these common proteins, some were differentially expressed, from 1.25 to 9 times higher (HV303_Human, RLA2_Horse, SPRL1_Human, SODC_CANFA, PROF1_Human, ARF4_Bovin and TRXR1_Bovin). The gene ontology analysis displayed biological pathways specific to the biology of reproduction (6 proteins; RUVB1_Human, OVGP1_Pig, STAT3_Human, PLAK_Human, GPX3_Rat and DYL1_Human). These candidate proteins and especially oviduct-specific glycoprotein and glutathione peroxidase, will now be validated by immunodetection methods.

70 EXPRESSION OF NUCLEAR AND MEMBRANE PROGESTERONE RECEPTORS IN THE CANINE OVIDUCT DURING THE PERIOVULATORY PERIOD

In the bitch, the oviduct is the site of oocyte maturation (Day 1 to 3 after ovulation), sperm transport/capacitation, fertilization (Day 3 to 4) and embryo development to the morula/blastocyst stage (Day 4 to 8). Unlike other mammals, these events occur in the presence of high (>6 ng mL–1) and increasing plasma levels of progesterone (P4), but little is known about the regulation of oviductal functions by P4 in the bitch. The objective of this work was to study the mRNA expression of nuclear (PR) and membrane (PGRMC1, PGRMC2, mPRβ and mPRγ) P4 receptors in the canine oviduct during the periovulatory period. Thirty-six Beagle bitches were ovariectomized at 6 stages: anestrus, before the LH peak (pre-LH), after the LH peak (pre-ov) and after ovulation (Day 1, 4 and 7). Three oviductal regions were collected [i.e. ampulla, isthmus and utero-tubal junction (UTJ)]. Total RNA was extracted and then reverse transcribed. The expression of target genes was assessed in duplicate by quantitative PCR (LightCycler® 480; Roche Diagnostics, Meylan, France) using the relative standard curve method and normalized by the geometric mean of 2 reference genes (RPS19 and GAPDH). Relative amounts of mRNA were compared between groups by ANOVA followed, when necessary, by Duncan's test. The expression of nuclear and membrane P4 receptor mRNA varied according to the stage. Expression of PR mRNA was significantly higher at pre-LH, pre-ov and Day 1 stages [means of 1.8, 1.6 and 1.5 arbitrary units (AU), respectively] than at anoestrus, Day 4 and Day 7 (1, 0.4 and 0.5 AU, respectively) in the ampulla. Same patterns of expression were observed for PR in the isthmus and UTJ. Expression of PGRMC1 and PGRMC2 mRNA were at the lowest level during anoestrus (1 AU) and increased significantly from pre-LH to Day 7 in the ampulla (from 2.2 to 8.3 AU and from 1.3 to 5.4 AU for PGRMC1 and PGRMC2, respectively) and in the isthmus (from 0.4 to 2.6 AU and from 0.5 to 1.8 AU for PGRMC1 and PGRMC2, respectively). In the UTJ, mRNA levels for PGRMC1 and PGRMC2 were the highest at Day 4 (3.9 AU) and pre-LH (2.1 AU), respectively, compared to other stages. Expression of mPRβ mRNA did not vary according to the stage in the ampulla and the isthmus, whereas it was significantly lower at Days 4 and 7 (0.6–0.7 AU) compared to other stages (1–1.2 AU) in the UTJ. Expression of mPRγ was significantly higher at Day 7 (5.0 AU) compared to other stages (0.2–1 AU) in the ampulla and was significantly higher at both anoestrus (1 AU) and Day 7 (0.9 AU) compared to other stages (0.02–0.09 AU) in the isthmus, whereas it did not vary significantly in the UTJ. In conclusion, our data suggests that P4 may be an important regulating factor of oviductal functions and could mediate its actions through genomic as well as non-genomic pathways.

68 TRANSCRIPTIONAL GENOME ACTIVATION IN CANINE EMBRYOS COLLECTED IN VIVO

Early embryonic stages are supported by maternal transcripts from the oocyte cytoplasm. Progressive transcription of embryonic genome is a key step for further embryonic development, especially during in vitro culture. To date, in vitro culture from fertilization to the blastocyst stage is inefficient in the canine species. The objective of this work was to identify minor and major activation in in vivo-produced dog embryos. Ovariectomies were performed in 31 Beagle bitches from 102 to 266 h after ovulation (post-ov), precisely timed by transabdominal ultrasonography. Embryos were collected by tubal flushing with M199-Hepes and immediately transferred into transcription buffer. Transcriptional activity was evaluated through 5-bromouridine 5′-triphosphate (BrUTP) incorporation in nascent RNA, without microinjection (Aoki et al. 1997). Oocytes from anoestrus ovaries were used as positive controls. 5-Bromouridine 5′-triphosphate incorporation was revealed by immunocytochemistry (anti-bromodeoxyuridine primary antibody) and embryonic DNA was stained by ethidium homodimer-2. Staining was quantified under laser scanning confocal microscopy. Transcriptional activity was calculated as (mean nuclear intensity – cytoplasmic mean intensity) × nuclear area and expressed in arbitrary units (AU). It was compared to 1 (similar intensity in nucleus and cytoplasm; i.e. no transcriptional activity) by t-test; levels of transcriptional activity were compared between stages by variance analysis. Seventy embryos (from 7 to 21 per stage) from 31 bitches were analysed, from 2 pronuclei to morula stage. Between 28 and 125 nuclei were quantified per stage. At each stage, transcriptional activity was calculated per embryo and per nucleus. A significant transcriptional activity was detected as early as the 2 pronuclei stage (102–132 h post-ov; 1.15 ± 0.05 AU). Transcriptional activity per embryo significantly increased between the 2- and the 4-cell stage and between the 8-cell and the morula stage. In early 8-cell embryos, staining intensity of the various nuclei was markedly heterogeneous within the same embryo, all nuclei being intensively stained from the late 8-cell stage onwards. Transcriptional activity per nucleus increased also from the 2- to the 4-cell stage (respectively, 120–161 h post-ov, 1.15 ± 0.02 AU and 133–154 h post-ov, 1.35 ± 0.04 AU) until the 8-cell stage (153–225 h post-ov, 5.12 ± 0.55 AU). Transcriptional levels at these 3 stages differed significantly. It decreased between the 8-cell and the morula stage (230–266 h post-ov, 3.06 ± 0.13 AU), probably reflecting the acquisition of a selectivity in gene expression at major activation, as in other species; Nothias et al. 1995). Addition of the transcriptional inhibitor α-amanitin during BrUTP incubation decreased the transcriptional activity by 60% (P < 0.05). Embryonic gene expression (minor activation) thus begins in the canine embryo as early as the 2 pronuclei stage, with major activation taking place during the 8-cell stage.

130 EXPRESSION OF STEROIDOGENIC ENZYMES IN THE CAT OVARY DURING FOLLICULAR GROWTH

This study was designed to describe the expression of steroidogenic enzymes in the various compartments of the feline ovary, from primordial to preovulatory follicles: P450 side-chain cleavage (P450scc), 17α-hydroxylase (17α-OH), 3β-hydroxysteroid dehydrogenase (3β-HSD). Nine female cats were ovariectomized during behavioural oestrus. After validation of their specificity by Western blot on feline tissue, 3 polyclonal antibodies obtained in the rabbit were used for immunohistochemistry (anti-bovine P450scc; anti-pig 17α-OH; anti-human 3β-HSD). Three successive ovarian cryosections were incubated with antibodies and 2 sections were used as controls (purified immunoglobulin G from a nonimmunized rabbit). Immunostaining was revealed by streptavidin-biotin system (LSAB kit, DAKO S.A., Trappes, France), with aminoethylcarbazole as a chromogen. The staining was evaluated according to its localization, intensity (from 1 to 4) and number of cell layers stained. Histological examination after haematoxylin-eosin-safran staining allowed follicle diameter measurement and evaluation of the atresia. Analysis of variance was used to compare follicles from various size classes. A total of 343 follicles from 140 to 3250 μm in diameter were observed (i.e. all follicles present on the slides), of which 15.2% were atretic. The observations were similar for the 3 enzymes. From the preantral stage onward (diameter >140 μm), more than 85% of the healthy follicles had the theca interna positive for P450scc, 3β-HSD and 17α-OH (respectively, 87.3, 86.0 and 99.0%). Approximately 20 to 25% were also positive in the theca externa. Granulosa were stained in 9.5% (P450scc), 0.8% (3β-HSD) and 1.8% (17α-OH) of the healthy follicles, but always with a low intensity (<2). The follicular size did not affect the proportion of stained follicles, but the staining intensity decreased progressively until 1200 μm and increased thereafter. The number of positive layers decreased continuously until 1500 μm in diameter. Between 90 and 95% of the preovulatory follicles (>2000 μm) were positive in the theca interna; the signal was more intense and the number of stained layers was higher than in smaller follicles. The 3 enzymes were detected in all the atretic follicles, with a similar intensity as in healthy ones; they were also present in the interstitial tissue, but with a higher intensity. The staining pattern in the various ovarian compartments suggests that the major steroidogenic tissues in the cat ovary are the theca interna of healthy follicles and the interstitial tissue. The lack of expression of the 3 key enzymes in the granulosa cells, even in preovulatory follicles, strongly suggests that these cells, shaping the future corpus luteum, are probably unable to produce progesterone.

186 RELIABILITY OF HOECHST 33342 STAINING UNDER STANDARD EPIFLUORESCENCE MICROSCOPY FOR EVALUATION OF THE NUCLEAR STATUS OF LIVING DOG OOCYTES

Hoechst 33342 staining detected by standard epifluorescence microscopy (Epi) is widely used for nuclear stage determination of oocytes in numerous species. Because it maintains cell viability, observed oocytes can be further processed for assisted reproduction. This sorting would be of great interest in the canine, where oocytes resuming meiosis in vitro remain scarce. But because of the cytoplasmic opacity of the canine oocyte, the accuracy of this technique is questionable. The objective of this study was to evaluate the accuracy of Epi by comparison to a reference technique (confocal microscopy; Conf). Oocytes were obtained from anestrus ovaries of 46 pubertal bitches. In vitro maturation was conducted with 20 oocytes/well in 500 μL M199 with 20% fetal calf serum in a humidified atmosphere of 5% CO2 at 39°C for 72 h. After Hoechst 33342 staining (20 min at RT), oocytes were observed without fixation under Epi (IX70, Olympus, France) with the excitation beam attenuated by 150-fold and emission detected by a high sensitivity camera (CCD, Olympus). The mean time for capture was 300 ms. For Conf, oocytes were fixed, stained with Ethidium Homodimer-2 (2 μM for 20 min at RT) and examined with an Ion-Argon laser (LSM 310, Carl Zeiss, Germany). For each oocyte, the nuclear stage was successively determined by Epi and by Conf. The results of both observations were compared by chi-square analysis. The optimal concentration of Hoechst dye was first determined on 401 oocytes (200 ng, 500 ng, 1 μg, or 2 μg mL–1). The 1 μg mL–1 was the lowest concentration allowing the identification of the nuclear stage by Epi in the largest proportion of living oocytes seen with DNA by Conf. At this dye concentration, Epi did not significantly impact degeneration or meiosis resumption rates: 33.3 and 22.4%, respectively for 183 oocytes submitted to Epi before Conf, compared to 37.4 and 13.6% for 147 oocytes observed only under Conf. Finally, the concordance of the nuclear stage diagnosis was tested on 379 oocytes observed individually with Epi and Conf successively. On Epi, 149 oocytes were seen without DNA. Observed on Conf, 37.5% of these were also seen without DNA, 59.7% were in the germinal vesicle stage and 2% were in metaphase. On Epi, 89 oocytes were considered as having resumed meiosis. On Conf, meiosis resumption was confirmed for 88.7% of them, but Epi failed to detect 31.4% of the oocytes having resumed meiosis among the 379 cultured oocytes. Although 80% of the metaphase II oocytes identified by Epi were confirmed to have reached this stage, 23% of metaphase II oocytes present in the culture dishes were missed. In conclusion, probably because of the high density in lipids of the cytoplasm, Hoechst staining detected by Epi for canine oocytes sorting after in vitro maturation leads to erroneously discarding a high proportion of oocytes.

Folliculogenesis and morphometry of oocyte and follicle growth in the feline ovary

This study was designed to describe, both quantitatively (morphometry) and qualitatively (histological differentiation), follicle and oocyte growth in the feline ovary. The ovaries of 43 cats were collected and processed for histology. The diameters of 832 follicle/oocyte pairs were measured, with and without zona pellucida (ZP), and a special emphasis was placed on the study of early folliculogenesis. Primordial, primary, secondary, pre-antral and early antral follicles were measured at 44.3, 86.2, 126.0, 155.6 and 223.8 microm in diameter respectively. A biphasic pattern of follicle and oocyte growth was observed. Before antrum formation, follicle (x) and oocyte (y) size were positively and linearly correlated (y = 0.500x + 20.01, r(2) = 0.89). Antrum formation occurred when the follicle reached 160-200 microm in diameter (when oocyte was at 102 microm). After antrum formation, a decoupling was observed, a minimal increase in oocyte size contrasting with a significant follicle development (y = 0.001x + 114.39, r(2) = 0.01). The pre-ovulatory follicle diameter was approximately 3500 microm and the maximal oocyte diameter was 115 microm. The ZP, absent in primordial and primary follicles, appeared at the secondary stage and reached almost 6 microm at the pre-ovulatory stage. These results suggest that (i) in feline ovary, follicle and oocyte growth pattern is similar to that observed in other mammals; (ii) the antrum forms in 160-200 microm follicles, which represents 5% of the pre-ovulatory diameter and (iii) the oocyte had achieved more than 90% of its maximal growth at the stage of antrum formation.

In vivo meiotic resumption, fertilization and early embryonic development in the bitch

Early development in canine species follows a very specific pattern. Oocytes are ovulated at the germinal vesicle stage and meiotic resumption occurs in the oviduct. However, because of difficulties in the accurate determination of ovulation time and in the observation of oocyte nuclear stage by light microscopy, these early events have not been fully described. Moreover, the oocyte stage at which sperm penetration occurs is still uncertain since fertilization of immature oocytes has been reported in vivo and in vitro. The aim of this study was to establish the exact timing of in vivo meiotic resumption, fertilization and early embryo development in the bitch with reference to ovulation. Ovulation was first determined by ultrasonography, artificial inseminations were performed daily and oocytes/embryos were collected between 17 and 138 h after ovulation. After fixation and DNA/tubulin staining, the nuclear stage was observed by confocal microscopy. Of the 195 oocytes/embryos collected from 50 bitches, the germinal vesicle stage was the only one present until 44 h post-ovulation, and the first metaphase II stage was observed for the first time at 54 h. Sperm penetration of immature oocytes appeared to be exceptional (three out of 112 immature oocytes). In most cases, fertilization occurred from 90 h post-ovulation in metaphase II oocytes. Embryonic development was observed up to the eight-cell stage. No significant influence of bitch breed and age on ovulation rate, maturation and developmental kinetics was observed. However, some heterogeneity in the maturation/development process was observed within the cohort of oocytes/embryos collected from one bitch. In conclusion, the most peculiar aspect of the canine species remains oocyte meiotic maturation whereas fertilization follows the same pattern as in other mammals.

[Specificities of prepubertal follicles and oocytes]

Ovarian physiology of prepubertal and adult animals is different. Some characteristics as follicular dynamics (follicular waves and growth) are similar but total follicular population and number of growing follicles are higher in prepubertal ovary. Prepubertal oocytes represent a negative model for in vitro studies since they lead to lower cleavage and blastocyst rates when they are used to produce embryos. This reduced ability to support embryonic development is due to follicular and oocyte differences. Follicular fluid and granulosa cells proteins, and steroidogenic potential differ between prepubertal and adult animals. Moreover, experiments using nuclear transfer demonstrate that cytoplasmic maturation of prepubertal oocytes is incomplete. These deficient oocytes are smaller, contain lower levels of MPF and MAP Kinase and differences in metabolism and cytoplasmic organelles are observed.

Differences in follicular function of 3-month-old calves and mature cows

After in vitro maturation, fertilization and development, the percentage of fertilized eggs developing to the blastocyst stage is usually lower in calves compared with cows. It is unknown whether this low ability to develop in vitro is inherent to calf oocytes or is caused by altered follicular maturation. The latter possibility was explored in the present study using two markers of follicle function: in vitro steroidogenesis by intact follicles and aromatase activity of follicular walls. Calf follicles > 9 mm in diameter had a low ability to produce oestradiol (ten times reduction compared with cows) despite a testosterone output by theca cells which was similar to that observed in cows. This finding is in agreement with the low aromatase activity of granulosa cells of calf follicles measured by tritiated water release assay. Qualitative and quantitative differences between calf and cow follicular fluids were assessed using western blotting (inhibin and activin, heat shock protein 90, Mullerian inhibiting substance) and assays (inhibin and activin) to determine whether this defective aromatase could be produced by alterations in the amounts of follicular proteins modulating aromatase (inhibin and activin, heat shock protein 90, Mullerian inhibiting substance). Western blotting of follicular fluid proteins demonstrated three main bands (59, 57 and < 30 kDa) and one minor band (34 kDa) with the anti-alpha inhibin antibody, whereas a single 18 kDa band was detected when an anti-beta inhibin antibody was used. Calf follicular fluid contained similar amounts of all main inhibin forms (alpha and beta) but a 34 kDa alpha inhibin form was missing. The amounts of dimeric inhibin were similar between cows and calves but small follicles from calves contained more activin. Single bands at 70 kDa (Mullerian inhibiting substance) and 90 kDa (heat shock protein 90) were detected by western blotting. Mullerian inhibiting substance was missing from calf follicular fluid and heat shock protein 90 was present in smaller amounts in calf versus cow follicular fluid. None of the above differences could explain the defective aromatase of calf follicles. Two-dimensional separation of the [35S]-labelled proteins secreted by follicular walls originating from calf or cow follicles matched for size and follicle health was performed and 151 spots were observed on the master gel, which summarized all the spots present at least once. Fifteen spots were present in calves and not in cows. Quantitative differences were also detected with three spots containing more proteins in cows than in calves. Whether some of these proteins can alter maturation of follicles or oocytes requires further investigation.

Differences in follicular function of 3-month-old calves and mature cows

After in vitro maturation, fertilization and development, the percentage of fertilized eggs developing to the blastocyst stage is usually lower in calves compared with cows. It is unknown whether this low ability to develop in vitro is inherent to calf oocytes or is caused by altered follicular maturation. The latter possibility was explored in the present study using two markers of follicle function: in vitro steroidogenesis by intact follicles and aromatase activity of follicular walls. Calf follicles > 9 mm in diameter had a low ability to produce oestradiol (ten times reduction compared with cows) despite a testosterone output by theca cells which was similar to that observed in cows. This finding is in agreement with the low aromatase activity of granulosa cells of calf follicles measured by tritiated water release assay. Qualitative and quantitative differences between calf and cow follicular fluids were assessed using western blotting (inhibin and activin, heat shock protein 90, Müllerian inhibiting substance) and assays (inhibin and activin) to determine whether this defective aromatase could be produced by alterations in the amounts of follicular proteins modulating aromatase (inhibin and activin, heat shock protein 90, Müllerian inhibiting substance). Western blotting of follicular fluid proteins demonstrated three main bands (59, 57 and < 30 kDa) and one minor band (34 kDa) with the anti-alpha inhibin antibody, whereas a single 18 kDa band was detected when an anti-beta inhibin antibody was used. Calf follicular fluid contained similar amounts of all main inhibin forms (alpha and beta) but a 34 kDa alpha inhibin form was missing. The amounts of dimeric inhibin were similar between cows and calves but small follicles from calves contained more activin. Single bands at 70 kDa (Müllerian inhibiting substance) and 90 kDa (heat shock protein 90) were detected by western blotting. Müllerian inhibiting substance was missing from calf follicular fluid and heat shock protein 90 was present in smaller amounts in calf versus cow follicular fluid. None of the above differences could explain the defective aromatase of calf follicles. Two-dimensional separation of the [35S]-labelled proteins secreted by follicular walls originating from calf or cow follicles matched for size and follicle health was performed and 151 spots were observed on the master gel, which summarized all the spots present at least once. Fifteen spots were present in calves and not in cows. Quantitative differences were also detected with three spots containing more proteins in cows than in calves. Whether some of these proteins can alter maturation of follicles or oocytes requires further investigation.

Alterations in ovarian function of mice with reduced amounts of KIT receptor

The KIT receptor, present on oocyte and theca cells in ovarian follicles, and its ligand, KIT LIGAND, produced by granulosa cells, are encoded at the Kit gene and the Mgf gene, respectively. Both Kit and Mgf mutations affect oogenesis and folliculogenesis. In this study, the ovarian function of heterozygous mice with a mutation Kit(W-lacZ) was examined. Firstly, the amounts of KIT and KIT LIGAND proteins in the ovaries of mice at different ages were determined. Secondly, in vivo and in vitro folliculogenesis of wild type and heterozygous mice were compared. Western blotting showed that the amounts of both KIT and KIT LIGAND proteins were decreased in mutant mice. Ovarian follicle populations were counted and more type 5a follicles and fewer type 5b (preantral follicles) were present in ovaries from Kit(W-lacZ/+) ovaries. Furthermore, the relationships between oocyte size and follicle size differed between wild type and heterozygous mice. This finding may be a consequence of altered proliferation of granulosa cells or of altered oocyte growth in mutant mice. Other features of folliculogenesis, such as initiation of follicular growth, total follicle population and follicular atresia, were not affected by the mutation. Analysis of in vitro folliculogenesis did not reveal other differences between wild type and mutant mice. It is concluded that the Kit(W-lacZ) mutation affects the expression of KIT and KIT LIGAND proteins, resulting in alterations in granulosa cell proliferation and/or oocyte growth in preantral follicles.

Confocal microscopy: principles and applications to the field of reproductive biology

Confocal microscopy allows analysis of fluorescent labeled thick specimens without physical sectioning. Optical sections are generated by eliminating out-of-focus fluorescence and displayed as digitalized images. It allows 3-dimensional reconstruction (XYZ) and time-analysis (XYT), thus providing unique chance to link morphology with cell function. Since images are obtained by scanning, excess illumination of the specimen and quick decrease of the fluorescent signal are avoided. Resolution obtained with a Laser Scanning Confocal Microscopy (LSCM) is theoretically better than that of a conventional microscope. The preparation of the specimen may be based on standard techniques, such as immunocytochemistry applied to fixed cells, or on staining of living cells, following the use of different fluorescent probes at the same time (colocalization). In our laboratory, we use the LSCM system Fluoview version 2.1 (Olympus) to study reproductive biology of animals and humans. We work on stainings of oocytes and blastocysts (mouse, bovine, human), and human ovarian tissues. We study mitochondrial distribution, cortical granule migration, calcium oscillations and spindle quality to link culture conditions and oocyte quality. Staining of F-actin is used to check transzonal projections (in zona pellucida) or to detect abnormalities following experimental treatment. Blastocyst quality is analyzed in sequential optical sections for microfilament organization and counting of total cell number (staining with phalloidin (actin) and picogreen (DNA). Trophectoderm and inner cell mass distribution (differential staining), apoptotic cells (TUNEL method) and viable cells (live/dead test) are also evaluated. Confocal imaging can be helpful for rapid determination of follicle density (staining with AM Calcein) and follicle morphology (picogreen) in ovarian cortical biopsies. The current review describes the principles of confocal microscopy and illustrates its applications to the field of reproductive biology by a large collection of pictures.

Roles of KIT and KIT LIGAND in ovarian function

Evidence from mouse mutants indicates that the Kit gene encoding KIT, a receptor present on the oocyte and theca cells, and the Mgf gene encoding KIT LIGAND, the ligand of KIT, are important regulators of oogenesis and folliculogenesis. Recently, in vitro cultures of fetal gonads, of follicles and of oocytes have identified specific targets for the KIT-KIT LIGAND interaction. In fetal gonads, an anti-apoptotic effect of KIT-KIT LIGAND interactions on primordial germ cells, oogonia and oocytes has been demonstrated. In postnatal ovaries, the initiation of follicular growth from the primordial pool and progression beyond the primary follicle stage appear to involve KIT-KIT LIGAND interactions. During early folliculogenesis, KIT together with KIT LIGAND controls oocyte growth and theca cell differentiation, and protects preantral follicles from apoptosis. Formation of an antral cavity requires a functional KIT-KIT LIGAND system. In large antral follicles, the KIT-KIT LIGAND interaction modulates the ability of the oocyte to undergo cytoplasmic maturation and helps to maximize thecal androgen output. Hence, many steps of oogenesis and folliculogenesis appear to be, at least in part, controlled by paracrine interactions between these two proteins.

Effects of Kit Ligand and anti-Kit antibody on growth of cultured mouse preantral follicles

Paracrine regulations between the oocyte and granulosa cells are likely to be key regulators of early folliculogenesis. Evidence obtained from genetic mutants as well as in vivo experiments suggest that Kit and Kit Ligand (KL) may regulate early follicular morphogenesis and function. In this study, we used in vitro culture of intact mouse follicles to confirm and extend these findings. Two concentrations of Kit Ligand (20 and 50 ng/ml) or an antibody blocking the Kit-Kit Ligand interactions (SC1494) were added to preantral follicles grown individually for 12 days and which were finally triggered to ovulate. Effects on follicle and oocyte survival, granulosa cell function (antrum formation, cell numbers, steroidogenesis), and oocyte function (growth, survival, nuclear and/or cytoplasmic maturation) were then analyzed. In optimal culture conditions (presence of 5% fetal calf serum), 50 ng/ml of KL significantly improved cytoplasmic maturation of the oocyte and increased follicular testosterone output, but other parameters were not altered. In serum-free culture conditions, KL was mitogenic for granulosa cells at 50 ng/ml, but could not induce antrum formation and no differences were observed between control and treated groups for steroidogenesis or oocyte growth. Blockade of Kit-Kit Ligand interactions by addition of a blocking antibody decreased oocyte survival 6-9 days after addition of the antibody, but did not upset granulosa cell proliferation. Antrum formation was, however, strongly inhibited. In addition, the blocking antibody markedly reduced aromatase activity of granulosa cells. We conclude that Kit/KL interactions are important for antrum formation and follicular steroidogenesis and regulate survival and cytoplasmic maturation of the oocyte.

Oocyte attrition

During oogenesis, germ cell numbers sharply decrease when meiosis is initiated. There is solid evidence (DNA ladders, in situ detection) that this loss is through apoptosis. Oocyte apoptosis appears to hit mitotic primordial germ cells (PGC), pachytene oocytes and early primordial follicles. The control of oocyte apoptosis is not fully understood, although survival factors (LIF, kit ligand and FGF), as well as death inducing factors (fas ligand, TGFbeta), have been identified. Fas ligand binding on oocytic fas may result in caspase 8 activation. Two pathways inducing oocyte apoptosis may then be operating. In the first one, activated caspase 8 will induce activation of executioner caspases. In the second one, activated caspase 8 will trigger the cleavage of the bcl(2) family member Bid, which will act on mitochondria, resulting in cytochrome c release, caspase 9 activation and finally, activation of all executioner caspases. As a consequence of caspase activation, alterations in the cell nucleus (DNAse activation, PARP fragmentation), in the cell cytoskeleton (lamin) and cell metabolism will occur, producing cell death. During folliculogenesis, germ cell loss, owing to oocyte apoptosis, has been postulated within primordial and preantral follicles. Its regulatory mechanisms may be even more complex than those operating in foetal oocytes since additional control factors include EGF/TGFalpha and bcl(2) (survival) and activin (death inducer). In contrast, oocytes from antral follicles appear to be very unsensitive to death inducing stimuli.

Markers of follicle function in Belclare-cross ewes differing widely in ovulation rate

High prolificacy due to a gene that has a large effect on ovulation rate has been noted in Booroola and Inverdale ewes. High prolificacy in the Belclare breed (a composite developed from stocks selected for very large litter size or high ovulation rate) may be related to the segregation of two genes. The aims of this study were (i) to compare the morphological and functional features of ovulatory follicles from carriers (which could only be heterozygous for the genes of interest) and non-carriers, and (ii) to identify markers of the Belclare genes among secreted or cellular ovarian proteins. Belclare carrier ewes had more ovulatory follicles (4.9 +/- 0.4) than did non-carrier ewes (2.0 +/- 0.2) (P < 0.001). Ovulatory follicles from carriers were also smaller (4.4 +/- 0.1 mm versus 5.7 +/- 0.2 mm, P < 0.001) and contained a significantly reduced number of granulosa cells (P < 0.001). However, the proportion of proliferating granulosa cells in ovulatory follicles was similar in both groups. The in vitro secretion of steroids per follicle was only marginally lower in follicles from Belclare carriers compared with non-carriers. Furthermore, similar concentrations of steroidogenic enzymes were present in both groups, indicating that steroidogenic potential per granulosa cell is similar between carriers and non-carriers. Possible markers of the Belclare genes were identified among cellular proteins of follicular walls by two-dimensional PAGE and image analysis. Two spots at 78 and 49 kDa were always absent in samples from non-carriers. When secreted proteins in follicles from carriers were compared with those from non-carriers, two spots at 53 and 41 kDa were restricted to samples from carriers and three spots at 97, 91 and 45 kDa were unique to samples from non-carriers. Interestingly, the spot at 91 kDa is also affected by the Booroola gene.

Presence of an aromatase inhibitor, possibly heat shock protein 90, in dominant follicles of cattle

In cattle, it has been suggested that follicular fluid has direct modulatory effects on follicular growth and maturation. In the first part of this study, an in vitro test using aromatase activity of follicular wall fragments as an end point was validated for cattle follicles and was used to test whether follicular fluid (from dominant or non-dominant follicles) modulates aromatase activity. Fluid from dominant follicles at a concentration of 24 or 12% (obtained during the luteal and follicular phases, respectively) significantly inhibited aromatase activity. Inhibitory activity was low or absent in fluid from non-dominant follicles. FSH-stimulated aromatase activity was also reduced by fluid from dominant follicles, but not to a greater extent than in basal conditions. Finally, charcoal-treated fluid from dominant follicles retained its inhibitory activity. In contrast, ovarian venous serum draining a dominant follicle had no activity at the three concentrations tested (6, 12 and 24%). In the second part of the study, identification of the compounds involved in this modulatory activity was attempted using SDS-PAGE. Comparison of the fluorographs from de novo synthesized proteins stored in follicular fluid (inhibitory medium) with those secreted in incubation medium (inactive medium) demonstrated that one protein (90 kDa, pI 5.8) was significantly (P < 0.05) more abundant in fluid from dominant follicles (2.0 +/- 0.09%) than in the culture medium (1.3 +/- 0.1% of the total proteins). This protein had characteristics similar to those of heat shock protein 90 (hsp 90). Therefore, in the final part of the study, the presence of hsp 90 in ovarian cells and follicular fluid was investigated using immunohistochemistry and western blot analysis. After immunohistochemistry, a positive signal was detected mainly in the granulosa cells of larger follicles and to a smaller extent in thecal cells and oocytes. Western blot analysis also demonstrated the presence of hsp 90 in follicular wall fragments and fluid. When blotting was achieved on a sample of follicular fluid resolved by two-dimensional PAGE, the spot detected had a similar location to that at 90 kDa and pI 5.8. Addition of purified hsp 90 to bovine follicles in vitro depressed aromatase activity by altering the K(m) value (and possibly the Vmax value) of the enzyme. It is proposed that hsp 90 is a functional regulator of follicular maturation through its action on aromatase.

[Oocyte apoptosis: when, how, why?]

The store of primordial follicles used for folliculogenesis is formed during oogenesis. Its size is the consequence of three processes: oogonia multiplication, time of meiosis initiation and extent of loss of germ cells (atretic oogonia, oocytes at the pachytene stage and newly formed primordial follicles). Apoptosis is causing this loss but its mechanisms are poorly documented. Both death signals (TNT alpha, Fas ligand) and survival signals (LIF, kit ligand) are present in the embryonic gonad. The apoptotic cascade then involves bclz, bax and caspases since knock out of these genes alters the store of primordial follicles. Apoptosis also exists within primordial follicles in adult ovaries and involves oocyte death. Its control has not been extensively studied.