Reversal of postmortem degeneration of mouse oocytes during meiotic maturation in vitro

Oocyte recovery after overnight ovary transport provides an alternative source of cumulus oocyte complexes that are competent to produce live piglets

COVID-19 impacted abattoirs worldwide. The processing lines became a hotspot for the spread of COVID-19 resulting in plant restructuring and ultimately a critical loss of pig material for research. Commercial sources of pig oocytes are available but are costly and companies were already operating at a maximum capacity for supplying the oocyte needs around the United States. Here, we provide an alternative source of oocytes that are competent to produce live, healthy piglets.

Rescue of oocytes recovered from postmortem mouse ovaries

It is well known that the survivability of gametes of postmortem carcass was decreased as time passes after death. In this study, it was examined whether cytoplasmic replacement rescues the survivability of germinal vesicle stage (GV) oocytes of postmortem carcass in the mouse. Reactive oxygen species (ROS) levels and mitochondria numbers in GV oocytes of the dead mice stored at 4 degrees were significantly impaired after 44 h postmortem compared to the control (0 h). However, when kayoplasts of GV oocytes of postmortem carcass was transferred to recipient ooplasts (GV transfer), proportion of in vitro maturation (IVM), normal spindle morphology, in vitro and in vivo developmental ability after in vitro fertilization (IVF) of reconstituted oocytes was improved. Moreover, secondary follicle oocytes of postmortem carcass were developed, matured and fertilized in vitro and developed to go to term, when GV transfer was conducted at the GV phase. Thus, transfer of GV karyoplast recovered from postmortem carcass, which viability was decreased, into fresh GV recipient ooplasm, rescues survivability of reconstituted oocytes. It suggested the effective use of oocytes of dead animals in the mouse and this achievement must apply to other rare animal species, especially animals under control by human.

Effects of postmortem interval on mouse ovary oocyte survival and maturation

To study the time- and temperature-dependent survival of ovarian oocytes collected from postmortem carcass, ICR mice were killed and placed for different periods (0, 1, 2, 4, 6, 8 and 10 h) at different temperatures (25°C, 4°C and 37°C). After preservation, oocyte morphology, germinal vesicle (GV) oocyte number, oocyte meiotic maturation percentage, mitochondrial distribution and intracellular glutathione (GSH) level were evaluated. The results showed no surviving oocytes could be collected by 2h, 6h, and 12 h after carcass preservation at 37°C, 25°C and 4°C, respectively. The number of collected GV oocytes in the ovary deceased as the preservation time lasted at the same temperature. Meanwhile at the same point in time, the ratio of germinal vesicle breakdown (GVBD) and the first polar body emission (PBE) gradually reduced as preservation temperature increased. In addition, the percentage of abnormal mitochondrial distribution in the preserved oocytes was obviously higher than that in the control oocytes, while GSH level was not altered in collected oocytes. Unexpectedly, neither chromosome arrangement nor spindle organization was affected as long as the oocytes from preserved carcasses could complete maturation. These data are helpful for proper use of ovary oocytes from postmortem carcass of valuable individuals.

Strategies and considerations for distributing and recovering mouse lines

As more and more genetically modified mouse lines are being generated, it becomes increasingly common to share animal models among different research institutions. Live mice are routinely transferred between animal facilities. Due to various issues concerning animal welfare, intellectual property rights, colony health status and biohazard, significant paperwork and coordination are required before any animal travel can take place. Shipping fresh or frozen preimplantation embryos, gametes, or reproductive organs can bypass some of the issues associated with live animal transfer, but it requires the receiving facilities to be able to perform delicate and sometimes intricate procedures such as embryo transfer, in vitro fertilization (IVF), or ovary transplantation. Here, we summarize the general requirements for live animal transport and review some of the assisted reproductive technologies (ART) that can be applied to shipping and reviving mouse lines. Intended users of these methods should consult their institution's responsible official to find out whether each specific method is legal or appropriate in their own animal facilities.

Effects of delayed excision of oviducts/ovaries on mouse oocytes and embryos

To achieve the best and reproducible results of experiments, effects of delayed excision of oviducts/ovaries on mouse ovarian/ovulated oocytes and embryos have been studied. Oviducts/ovaries were excised at different times after death of mice and effects of the postmortem interval on ovarian/ovulated oocytes and embryos were analyzed. When oviduct excision was delayed 10 min, many ovulated oocytes lysed or underwent in vitro spontaneous activation, and this postmortem effect aggravated with the extension of postmortem interval and oocyte aging. Oocytes from different mouse strains responded differently to delayed oviduct removal. Delayed oviduct excision did not cause lysis of zygotes or embryos but compromised their developmental potential. When ovaries were excised at 30 min after death, percentages of atretic follicles increased while blastocyst cell number declined significantly after oocyte maturation in vitro. Preservation of oviducts in vitro, in intact or opened abdomen at different temperatures and histological analysis of oviducts from different treatments suggested that toxic substance(s) were secreted from the dying oviducts which induced oocyte lysis and spontaneous activation and both this effect itself and the sensitivity of oocytes to this effect was temperature dependent. It is concluded that a short delay of oviduct/ovary removal had marked detrimental effects on oocytes and embryos. This must be taken into account in experiments using oocytes or embryos from slaughtered animals. The data may also be important for estimation of the time of death in forensic medicine and for rescue of oocytes from deceased valuable or endangered mammals.

Effect of ovary holding temperature and time on equine granulosa cell apoptosis, oocyte chromatin configuration and cumulus morphology

The effects of ovary holding time and temperature on granulosa cell apoptosis, oocyte chromatin configuration and cumulus morphology were investigated through a series of experiments. Three experiments were performed to determine the effect of ovary holding time and temperature on granulosa cell apoptosis. Ovaries were held (1) at 20, 30 or 35-37 degrees C for up to 2h, (2) at 30 degrees C for 0-1, 1-2, 2-3, 3-4, 4-6 or 6-10h, and (3) granulosa cells were held for 0, 1, 2, 3, 5, 12 or 24h in M199 with Hank's salts at room temperature (suboptimal incubation). Granulosa cell DNA was analysed by ethidium bromide staining or 3'-end labelling. Two experiments were performed to determine the effect of ovary holding time and temperature on oocyte chromatin configuration. Ovaries were held (1) at 20, 30 or 35-37 degrees C for up to 3h and (2) at 20-37 degrees C for 0-1, 1-2, 2-3, 3-4, 4-6, 6-8 or 8-12h. The oocytes were stained with Hoechst stain 33258 and the chromatin configuration was evaluated. Two experiments were performed to determine the effect of ovary holding time and temperature on cumulus oophorus morphology. Ovaries were held at (1) 20-30 or 35-37 degrees C for up to 2h and (2) for 0-2, 2-4, 4-6, and 6-10h at 35-37 degrees C. The cumulus oocyte complex (COC) were retrieved and the cumulus morphology was evaluated. There was no difference in proportion of follicles with non-apoptotic granulosa cells in the two groups below body temperature (20 and 30 degrees C), but more follicles had apoptotic granulosa cells when the ovaries were held at 35-37 degrees C (P < 0.001). Holding ovaries at 30 degrees C for more than 3h increased the proportion of follicles with apoptotic granulosa cells (P < 0.01). When follicles with non-apoptotic granulosa cells were incubated at room temperature, there was no granulosa cell apoptosis in any of the follicles within the first 3h, but at 5h apoptosis was present in the granulosa cells of 22% of the follicles, and 78% of the follicles contained apoptotic granulosa cells at 24h (P < 0.001). The temperature at which the ovaries were held did not influence oocyte chromatin, although there was a tendency towards more condensed chromatin configurations in the groups below body temperature. More denuded and expanded COCs were present in the lower temperature group (P < 0.001). Oocyte chromatin configuration changed after 6h of holding (P < 0.001), and numbers of compact COCs decreased after 2h (P < 0.05). The present studies suggest that equine follicles should be held for no more than 3h at 20-30 degrees C if granulosa cell apoptosis is to be avoided. To avoid changes in cumulus oophorus morphology, ovaries should be held at 35-37 degrees C and for less than 2h before processing, and to avoid oocyte chromatin configuration changes, ovaries should be stored for less than 6h. When ovaries are to be used in oocyte maturation studies, and assuming that (1) CC is the chromatin configuration of choice for oocyte maturation, (2) that presence of granulosa cell apoptosis promotes maturation of the oocyte and (3) that expanded cumulus oocytes are preferable, the present data suggests that ovaries should be stored for 4-6h before oocyte retrieval.

Rabbit and pig ear skin sample cryobanking: effects of storage time and temperature of the whole ear extirpated immediately after death

The post-mortem temporal and thermal limits within which there will be ample guarantees of rescuing living skin cells from dead specimens of two species, rabbit and pig, were studied. Post-mortem extirpated whole ears were stored (in non-aseptic conditions) either at 4 degrees C or at room temperature (from 22 to 25 degrees C) or at 35 degrees C for different time lapses after animal death. In both species, the post-mortem maximum time lapses where cell viability was not significantly reduced were 240, 72, and 24 h post-mortem (hpm) for 4, 22-25 and 35 degrees C, respectively. Once the post-mortem temporal limits for each tested thermal level at which cells from skin samples are able to grow in culture were defined, the survival ability of skin samples submitted to these temporal limits and cryopreserved were tested. In the pig, skin samples stored at the three tested thermal levels survived after vitrification-warming, reaching confluence in culture. In rabbit, only tissue samples from ears stored at 35 degrees C for 24 hpm did not survive after vitrification-warming. In conclusion, we should remark that cell survival rates obtained according to the assayed post-mortem time lapses and thermal levels are sufficient to collect and to cryopreserve skin samples from the majority of dead specimens.

Cryopreservation of mouse ovarian tissue following prolonged exposure to an Ischemic environment

In cases in which ovarian tissue is to be cryopreserved for tissue or gene banking it is important to maintain its integrity and viability. This study examined how delays between the death of an animal and the collection/cryopreservation of its ovarian tissue influenced follicle viability. Mouse ovaries were placed in PBS+antibiotic (in vitro) or left within the body (in situ) at room temperature for 0, 3, 6, 12, or 24 h following the death of the donor. These ovaries were cryopreserved at 1 degrees C/min on dry ice or in a -84 degrees C freezer using a passive cooling device or by conventional slow cooling (0.3 degrees C/min). The ovaries were grafted under the kidney capsule of ovariectomized recipient mice and collected 2 weeks later, and the size and number of follicles were determined. Cryopreserved ovarian tissue grafted immediately after the death of the donor contained numerous viable and healthy follicles independent of the cooling procedure (dry ice, 134 +/- 32; -84 degrees C, 165 +/- 54; slow, 214 +/- 55 follicles per half ovary). Tissues stored in vitro before cryopreservation retained viable follicles up to 12 h after death (dry ice, 30 +/- 15; -84 degrees C, 86 +/- 45; slow, 93 +/- 33), whereas tissue left in situ had significantly reduced follicle numbers within 3 h of death (dry ice, 36 +/- 12; -84 degrees C, 19 +/- 6; slow, 28 +/- 7). No significant difference was found between the cooling rates tested, indicating that a passive cooling container which cools at 1 degrees C/min is a suitable alternative to conventional slow cooling. We conclude that ovarian tissues for cryobanking should be cryopreserved as soon as possible after collection or death of the animal to ensure maximal follicular survival.

Rescue of oocytes from antral follicles of cryopreserved mouse ovaries: competence to undergo maturation, embryogenesis, and development to term

Only primordial and primary follicles of frozen-thawed mouse ovaries survive after grafting to the ovarian bursa; large secondary follicles and antral follicles together with the oocytes contained in them degenerate. This study was undertaken to determine whether fully grown oocytes isolated from the antral follicles of frozen-thawed mouse ovaries are viable and can be rescued to undergo maturation, fertilization, and embryo development in vitro. Ovaries were cryopreserved after removal from 22-day-old (C57BL/6J x SJL/J)F(1) mice, with or without prior priming with equine chorionic gonadotrophin, and fresh non-frozen ovaries were used as controls. Only cumulus cell-denuded oocytes were recovered from frozen unprimed ovaries while both cumulus cell-enclosed and denuded oocytes were retrieved from frozen primed ovaries. Oocytes from both groups of frozen-thawed ovaries were able to undergo maturation, fertilization, and development to the blastocyst stage in vitro, though at lower percentages than oocytes from control unfrozen ovaries. Moreover, 19% of 2-cell stage embryos derived from frozen-thawed primed ovaries, compared with 42% of embryos derived from control primed ovaries, developed to term after transfer to pseudopregnant foster mothers (not significantly different). Therefore, fully grown oocytes in antral follicles survive the cryopreservation protocol, as demonstrated by maturation, fertilization and embryo development in vitro, and development to term after embryo transfer.

Effect of time during transport of excised mare ovaries on oocyte recovery rate and quality after in vitro maturation

In the mare only a limited number of oocytes can be successfully collected in vivo, so that when large numbers of oocytes are needed for experimentation, ovaries harvested from slaughtered mares must be used. The resulting temperature changes and time intervals mandated by handling and transport of ovaries from the slaughterhouse to the laboratory adversely affect the rate of oocyte recovery and their quality after IVF and maturation. We chose to study the effect of temperature and time in transit of excised ovaries by evaluating rate of oocyte recovery, nuclear maturation stage reached before, and cleavage rate reached after IVF, following short (1.5 to 4 h) and long (6 to 8 h) storage. Temperatures in the storage container decreased from 37-C to 32 degrees and 27.5 degrees C during the short and long interval, respectively. The cumulus-oocytes complexes (COCs) were classified as having a compact cumulus, completely or partially surrounding the oocyte (compact); those having only a corona radiata surrounding the oocyte (corona); those having a completely or partially expanded cumulus, showing a cellular or sparsely cellular, gelatinous cloud around the oocyte (expanded); and those that were completely denuded of both cumulus and corona cells (denuded). All COCs, except the denuded ones, which were discarded, were matured in vitro for 30 h at 38.5 degrees C in 5% CO2. The recovery rate of oocytes was significantly higher after long vs short storage (48 vs 35%; P < 0.01), but the distribution of the collected COCs into the 4 classes was not affected by the storage time. After in vitro maturation nuclear maturity was not affected by the storage time, but oocytes with intact cytoplasmic membranes were more frequently found after short than after long storage (54 vs 34%; P = 0.07), and fully matured oocytes were more often seen with intact membrane (P < 0.01). Moreover, oocytes with intact membranes in metaphase II (MII) were associated with short storage intervals and the corona COC class, while damaged membranes and incomplete maturation were associated with the long storage and the compact COC class.

Viable spermatozoa can be recovered from refrigerated mice up to 7 days after death

To develop a model for utilizing germ cells collected from dead animals, male mice were euthanized and refrigerated for various periods, and the viability of the epididymal spermatozoa was examined by in vitro fertilization, embryo culture, and embryo transfer. Higher proportions of fresh oocytes were fertilized when males had been stored at 4-6 or 8-10 degrees C than at 0 degrees C. By partially dissecting the zona of freshly ovulated oocytes, spermatozoa from ICR male mice could fertilize oocytes (21% fertilization rate) after being stored for 5 days at 4-6 degrees C, and spermatozoa from BDF1 male mice could fertilize oocytes (39%) after being stored for 7 days at 4-6 degrees C. The resulting two-cell embryos had the ability to develop into expanded blastocysts in culture (81-100%) and into live young after transfer (34-47%). With further refinement of this system, it should be applicable not only for rescuing valuable genetic variants in laboratory animals or livestock animals but also for wild species in the future.

Birth of live mice derived by in vitro fertilization with spermatozoa retrieved up to twenty-four hours after death

The objective of this study was to determine the viability and fertility of mouse spermatozoa obtained at various postmortem intervals. Male mice were euthanized, and the bodies were kept at approximately 22 degrees C for up to 24 hr. The epididymides were removed and spermatozoa were allowed to swim out into Minimum Essential Medium supplemented with bovine serum albumin. Motility of spermatozoa retrieved within 12 hr postmortem was approximately 60%, whereas motility of those obtained 6 to 12 hr later decreased significantly (P < 0.05). There appeared to be no differences in the percentages of spermatozoa with intact plasma and acrosomal membranes regardless of the time after death. After in vitro fertilization of oocytes with spermatozoa collected immediately after death or at 6, 12, 18, or 24 hr postmortem, the cleavage rates were 81%, 70%, 64%, 34%, and 19%, respectively. Once oocytes were fertilized, more than 65% developed into morulae/blastocysts. Transfer of a total of 166 embryos produced in vitro with postmortem spermatozoa resulted in the birth of 44 live pups (26.5%). Of these 44, 3 live mice were derived by transfer of 11 embryos (27.3%) produced with 24-hr postmortem spermatozoa. Histological examination of the testes and epididymides obtained at various postmortem intervals revealed that degenerative changes of the testes occurred within 6 hr, whereas those of the epididymides were less obvious until 6 hr later. These changes included pyknosis, release of intracellular contents, and disruption of intercellular bridges of the germ cells. This study has demonstrated that spermatozoa recovered from a dead animal as long as 24 hr after death can be used to fertilize oocytes, and that the resulting zygotes can develop into live young.

Follicle-oocyte atresia and temporal taphonomy in cold-stored domestic cat ovaries

In vitro oocyte maturation followed by in vitro fertilization (IVM/IVF) success in the domestic cat remains inferior to commonly studied livestock or laboratory species. The objectives here were (1) to histologically assess atresia status of freshly excised follicle/oocyte complexes, and (2) to evaluate taphonomic change (deterioration after excision) of these complexes after ovarian cold storage for up to 48 h. After excision of 50 ovarian pairs, one ovary was preserved immediately and the other stored in phosphate buffered saline (4 degrees C) for 4, 8, 12, 24, or 48 h before fixation and examination. Ovaries were classified as luteal if prominent corpora lutea (CL) were present or as follicular if antral follicles and no CL were present. Two classes of follicle-oocyte complexes (preantral and antral) were microscopically evaluated. Of the 2,280 complexes examined, 64.3% demonstrated clear evidence of slight to severe degeneration, with various stages being described and photographed for the first time. There was no histological evidence indicating distinctive morphological differences between oocytes recovered from follicular versus luteal donors. Storage of whole ovaries in cold saline inhibited taphonomic changes for 48 h after excision. In summary, there is marked variability in the number and quality of follicle populations in cat ovaries. A high percentage of full-sized follicular oocytes are undergoing atresia at any given time. However, additional gross degeneration as a result of cold-storage appears modest for up to 48 h. Nonetheless, this high level of natural atresia in the cat likely contributes to comparatively lower IVM/IVF success than in other species.

In vitro maturation and fertilization of oocytes isolated from aged mice: a strategy to rescue valuable genetic resources

PURPOSE

This project was to determine whether oocytes isolated from virgin aged mice, up to 18 months old, are competent to undergo cytoplasmic maturation in vitro and undergo fertilization and embryonic development. If so, oocyte maturation in vitro could be used as a strategy to rescue valuable genetic resources.

RESULTS

Although the number of oocytes recovered from mice was greatly reduced with increasing age, the percentage of oocytes that underwent fertilization, cleavage, and development to the blastocyst stage was essentially unchanged up to 18 months of age. The success of cleavage to the two-cell stage was greater after maturation in vitro (81%) than gonadotropin-induced maturation in vivo (55%). About 20% (20/106) of the embryos derived from oocytes isolated from 18-month-old mice developed to term after embryo transfer.

CONCLUSION

Oocytes from virgin aged mice undergo normal cytoplasmic maturation in vitro. Higher percentages of oocytes from aged mice cleave to the two-cell stage after spontaneous maturation in vitro than after gonadotropin-induced maturation in vivo. Therefore, in vitro maturation and fertilization of oocytes could be used to rescue valuable genetic resources that might otherwise be lost because of age-related infertility.

Oocyte recovery and maturation in the American black bear (Ursus americanus): a model for endangered ursids

A study was conducted to determine if meiotic maturation could be induced in ovarian oocytes of the American black bear (Ursus americanus), a model for gamete "rescue" techniques for endangered ursids. Ovaries obtained from 48 black bears yielded 2,403 oocytes (51.1 +/- 4.9/female), of which 777 (32.3%) were morphologically classified as excellent quality. More total oocytes were recovered from donors that were anestrous compared to luteal/pregnant (P < 0.05) at the time of ovarian excision. Delaying the recovery of oocytes from antral follicles within excised ovaries from 12-24 hr to 25-36 hr had no effect (P > 0.05) on the overall number of high quality oocytes recovered or subsequent maturational ability. The highest incidence of metaphase II was reached between 48 and 60 hr of in vitro incubation. Donor status (anestrous vs. luteal/pregnant) had no influence on the oocyte maturation rate by 24 or 48 hr, but by 60 hr, more (P < 0.05) oocytes recovered from anestrous females (43.9%) had achieved metaphase II compared to luteal/pregnant counterparts (23.1%). In preliminary trials involving endangered ursids, 54 ovarian oocytes were recovered from three aged sun bears (Helarctos malayanus), of which 72.2% were excellent quality and 15.4% matured in vitro to metaphase II. Similarly, 119 antral oocytes were recovered from two aged sloth bears (Melursus ursinus), of which 41.2% were excellent and 17.5% matured in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)