New Insights in Canine Reproduction (original) (raw)
Related papers
Molecular Reproduction and Development, 2005
Ability of ovarian oocytes from tine domestic dog to complete nuclear maturation in vitro (IVM) varies markedly among donors and generally is 20% or less of all oocytes cultured. To identify the cause(s) underlying these significant variations in meiotic maturation (to metaphase II; Mil), we retrospectively analyzed data from 1,643 oocytes recovered from 90 bitches for which stage of reproduction and season of year were known. Neither stage of reproduction (proestrus/estrus, diestrus, anestrus, or prepuberty) nor season (P>0.05) influenced the ability of oocytes to achieve nuclear maturation in vitro. A second study was conducted to examine the impact of follicular size on meiotic maturation. Populations of large oocytes were recovered from four categories of follicles (ranging from <0.5 to >2 mm in diameter) and cultured in TCM 199 for 48 hr. Follicular size influenced (P<0.05) meiotic competence. Mean percentages of Mil oocytes were 16.9 ±9.2, 26.1 ±7.6, 38.4±9.2, and 79.5± 10.9 for oocytes recovered from <0.5 mm, >0.5-<l mm, 1-2 mm, and >2 mm diameter follicles, respectively. In summary, stage of reproduction and season have no impact on the ability of dog oocytes to achieve nuclear maturation in vitro. However, we demonstrated for the first time that dog oocytes acquire meiotic competency during follicular development. IVM success of selected oocytes from large size follicles (almost 80%) is about 60% higher than measured in most previous studies involving randomly collected oocytes. Mol. Reprod. Dev.
Folliculogenesis, Ovulation and Endocrine Control of Oocytes and Embryos in the Dog
Reproduction in Domestic Animals, 2012
Reproductive physiology in dogs is quite unusual compared with that in other mammalian species. The peculiarities include the presence of numerous polyoocyte follicles, the ovulation of an immature oocyte (GV stage, non-fertilizable) and a periovulatory period during which concentrations of circulating progesterone are particularly high. The aim of this review is to examine the unusual aspects of the reproductive physiology of dogs and how this relates to the clinical biology of this species.
Responses of canine oocytes to in vitro maturation and in vitro fertilization outcome
Theriogenology, 2006
The potential benefits of assisted reproduction techniques, such as in vitro maturation (IVM) and in vitro fertilization (IVF) in canids, are linked to the protection and saving of species threatened by extinction due to worldwide habitat destruction and pollution. In both domestic and wild species, these technologies will form the basis for the next leap in reproductive performance by improving fertility rates in valuable middle-aged females, by improving pregnancy rate in infertile or sub-fertile populations and by rescuing biological material to replenish populations of endangered species. In vitro techniques are supposed to answer the reproductive questions of canids, to introduce new methods for contraception and to compete with artificial insemination (AI) as the major or predominant method of embryo production, oocyte-and embryo cryopreservation and cloning. The causes affecting in vitro meiosis of dog oocytes are likely to be diverse. Incomplete understanding of the events associated with oocyte developmental competence are imputed to species reproductive physiology, medium composition and source of ovarian oocyte population used for in vitro maturation. This review addresses some issues on the current state of in vitro maturation and in vitro fertilization of canine oocytes. #
Oocyte biology and challenges in developing in vitro maturation systems in the domestic dog
Animal Reproduction Science, 2007
The oocyte of the domestic dog is unique from that of other mammalian species studied to date. Ovulation occurs either once or twice per year, with the oocyte released at the germinal vesicle stage, and then completing nuclear and cytoplasmic maturation within the oviduct under the influence of rising circulating progesterone. In vivo meiotic maturation of the bitch oocyte is completed within 48-72 h after ovulation, which is longer than 12-36 h required for oocytes from most other mammalian species. Due to these inherently novel traits, in vitro culture systems developed for maturing oocytes of other species have been found inadequate for maturation of dog oocytes. On average, only 15-20% of ovarian oocytes achieve the metaphase II stage after 48-72 h of in vitro culture. Thus far, no offspring have been produced in the dog (or other canids) by transferring embryos derived from in vitro matured oocytes. This review addresses current knowledge about dog reproductive physiology, specifically those factors influencing in vitro developmental competence of the oocyte. This summary lays a foundation for identifying the next steps to understanding the mechanisms regulating meiotic maturation and developmental competence of the dog oocyte. Published by Elsevier B.V.
Mitochondrial Distribution Patterns in Canine Oocytes as Related to the Reproductive Cycle Stage
This study investigates the mitochondrial (mt) distribution in canine ovarian oocytes examined at recovery time, as related to the reproductive cycle stage, and in oviductal oocytes. Ovarian Germinal Vesicle (GV) stage oocytes were recovered from bitches in anestrous (A, n = 2), follicular phase (F, n = 4), ovulation (O, n = 2), early luteal (EL, n = 7) and mid/late luteal phase (MLL, n = 2). Oviductal GV, metaphase I (MI) or MII stage oocytes were recovered from six bitches between 56 and 110 h after ovulation. Mitochondria were revealed by using MitoTracker Orange CMTM Ros and confocal microscopy. In ovarian oocytes, three mt distribution patterns were found: (I) small aggregates diffused throughout the cytoplasm; (II) diffused tubular networks; (III) pericortical tubular networks. Significantly higher rates of oocytes showing heterogeneous mt patterns (II + III) were obtained from bitches in F (75%) and in O (96%) compared with bitches in A (31%; F vs. A: P < 0.05; O vs. A: P < 0.001), in EL (61%; O vs. EL: P < 0.01), or in MLL (0%; F vs. MLL: P < 0.05; O vs. MLL: P < 0.001). Fluorescence intensity did not vary according to mt distribution pattern except that it was lower in oocytes recovered in EL phase and showing small mt aggregations (P < 0.001). The majority of ovulated MII stage oocytes (79%) showed diffused tubular mt network. We conclude that mt distribution pattern of canine ovarian immature oocytes changes in relation to reproductive cycle stage and that patterns observed in oocytes recovered from bitches in periovulatory phases are heterogeneous and similar to those of in vivo matured oocytes.
The canine oocyte: uncommon features of in vivo and in vitro maturation
The biology of the canine oocyte is unusual compared with that of other mammalian females. The present paper reviews both in vivo and in vitro specificities of canine oocytes. Final follicular growth in the bitch is characterised by an early appearance of LH binding sites in the granulosa, a high proportion of polyovular follicles and a preovulatory luteinisation, starting at the time of the LH surge. Through follicular fluid, preovulatory oocytes are thus exposed to high levels of progesterone, as high as 1000-fold plasma concentrations. The composition of the follicular fluid is affected by the size of the female. The more specific aspect of oocyte biology in the bitch is ovulation: oocytes are expelled immature, at the Prophase I stage. Ovulatory follicles are 6-8 mm in diameter, releasing oocytes from 110 mm, with dark cytoplasm. Resumption of meiosis occurs from 48 h postovulation, MII stages appearing 48-54 h after ovulation. The mechanisms controlling such a late meiotic resumption are still unknown. Granulosa cells seem to play a central role as in other mammalian species, but not with cAMP as the principal mediator. The importance of a transient reactivation of oocyte transcription a few hours before meiotic resumption is to be explored. These specific features may contribute to the low efficiency of IVM. Only 10-20% oocytes reach the metaphase stage and suffer from a poor cytoplasmic maturation. Moreover, in vitro culture of canine oocytes is associated with a high proportion of degeneration. To date, IVM of the oocytes is the main limiting factor for the development of assisted reproductive techniques in the canine. A better knowledge of the basic physiology of folliculogenesis and the molecular mechanisms controlling oocyte meiosis resumption in this species may allow us to overcome this obstacle.
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. Reproduction (2005) 130 193-201 q 2005 Society for Reproduction and Fertility
Cloning and Stem Cells, 2008
The collection of in vivo matured canine oocytes relies on the accurate prediction of ovulation. The present study was designed to develop a protocol for the recovery of in vivo matured canine oocytes based on once daily measurements of serum progesterone (P 4) concentrations. Blood samples (2 mL) were collected every day at 0900 h, and P 4 concentrations were analyzed using a DSL-3900 ACTIVE ® Progesterone Coated-Tube Radioimmunoassay Kit. The average number of oocytes at the metaphase II (M II) stage was significantly higher at or after 72 h (6.7 to 7.5) compared to 56 h (1.7) following ovulation. The highest numbers of corpora lutea, and therefore the highest numbers of oocytes, were recovered from bitches with initial ovulatory P 4 concentrations ranging from 6.0 to 8.0 ng/ mL (12.2 and 11.4, respectively) compared to from 4.0 to 4.9 ng/ mL (9.6 and 8.8, respectively; p Ͻ 0.05). The average number of M II oocytes recovered at 84 h from bitches with initial ovulatory P 4 levels of 5.0 to 5.9 ng/mL (7.7) was higher compared to bitches with P 4 levels of 4.0 to 4.9 ng/ mL (3.5) and 6.0 to 8.0 ng/ mL (4.8; p Ͻ 0.05). When oocyte recovery time was adjusted for initial ovulatory P 4 concentration, no significant difference in recovery rates or oocyte quality were observed. In conclusion, once daily measurements of P 4 can be used to predict ovulation in bitches, and oocyte recovery time should be adjusted for initial ovulatory serum P 4 concentrations.