Efficient collection and cryopreservation of embryos in F344 strain inbred rats

In vivo fertilization improved the cryotolerance and developmental ability of vitrified-warmed rat fertilized oocytes

The cryopreservation of rat embryos is useful for efficiently archiving rat resources in bioresource repositories. The cryopreserved fertilized oocytes can be quickly reanimated to rats with homozygous mutations using embryo transfer. In addition, cryopreserved rat fertilized oocytes are easier to transport than live animals. Before cryopreservation, fertilized oocytes are obtained by mating or in vitro fertilization. However, it is not clear which fertilized oocytes are most suited to cryopreservation. In this study, we performed a systematic comparison of the fertilizing ability, cryotolerance, and developmental ability of cryopreserved fertilized oocytes at the pronuclear stage produced either by mating (in vivo) or in vitro fertilization (in vitro) in SD and F344 rats. In vivo-fertilized oocytes had higher cryotolerance and developmental ability than in vitro-fertilized oocytes in SD and F344 rats. Furthermore, the fertilization ability, cryotolerance, and developmental ability of vitrified-warmed fertilized oocytes differed between SD and F344 rats. In conclusion, our study suggests that in vivo-fertilized rat oocytes were more suitable for cryopreservation. Our protocol provides an optimized system for the management of rat colonies using fertilized oocytes cryopreservation and contributes to the 3Rs principle by reducing the number of animals used for research.

Improvement of survivability and developmental ability in vitrified rat oocytes

Oocyte cryopreservation is useful for human fertility treatment and strain preservation in both experimental and domestic animals. However, the embryonic development of vitrified rat oocytes was lower than that of vitrified embryos. To increase the viability of vitrified oocytes, intracellular ice formation during cooling and warming must be prevented. Rapid warming is important to prevent ice formation. Furthermore, suppressing the spontaneous activation of oocytes is also important because vitrification promotes the spontaneous activation of rat oocytes, and thus compromise developmental competence of the gametes. MG132, a proteasome inhibitor, suppresses the spontaneous activation of rat oocytes. Here, we examined the effects of rapid warming and MG132 treatment on the survival and embryonic development of vitrified rat oocytes. The warming rate was adjusted by changing the vitrification solution volume and warming solution temperature. The survival rate of oocytes vitrified in 10 μL solution and warmed at 50 °C (94%) was significantly higher than that of oocytes vitrified in 100 μL and 10 μL solution and warmed at 37 °C (49% and 81%, respectively). Furthermore, the rate of embryonic development of vitrified oocytes treated with MG132 during vitrification, warming, and intracytoplasmic sperm injection (ICSI) (44%) was significantly higher than that of untreated gametes (10%). Offspring were obtained after transferring embryos derived from MG132-treated vitrified oocytes (14%). Altogether, the survivability of vitrified rat oocytes increased by rapid warming, and MG132 improved embryonic development after ICSI.

Cryopreservation of rat embryos at all developmental stages by small-volume vitrification procedure and rapid warming in cryotubes

Intracellular ice formation during cryopreservation is lethal to the cell, including during warming. Here, we examined the effect of sample volume and warming rate on the cryopreservation success of 1-cell rat embryos based on successful development into blastocysts in vitro and to term in vivo following embryo transfer. Embryos were equilibrated in 5% propylene glycol solution for 10 min, held for 40 s at 0 °C in cryopreservation solution (5%PG + PEPeS), and cooled by immersion in liquid nitrogen. When 1-cell embryos were cryopreserved in a volume of 30-100 μL at a cooling rate of 5830-7160 °C/min and warmed at 35,480-49,400 °C/min by adding 1 mL of 0.3 M sucrose solution at 50 °C, 17.3-28.8% developed into blastocysts, compared with 57.0% of untreated embryos. However, when 1-cell embryos were cryopreserved in a smaller volume of 15 μl at 7950 °C/min and warmed at 68,850 °C/min, 58.8 ± 10.6% developed into blastocysts and 50.0 ± 7.4% developed to term, comparable to that of non-treated embryos (57.0 ± 5.4% and 51.4 ± 3.1%, respectively). Cryopreserved embryos at other developmental stages also showed high in vitro culture potential similar to that of the control. Using a conventional cryotube and a small-volume vitrification procedure with rapid warming, we achieved high levels of subsequent rat embryonic development at all developmental stages.

Successful induction of pseudopregnancy using sonic vibration in mice

Embryo transfer (ET) is an essential reproductive technology for the production of new animal strains and maintenance of genetic resources. We developed a method, named Easy-ET, to induce pseudopregnancy in female rats by artificial stimulation using sonic vibration instead of mating with vasectomized males. This study examined the application of this method for the induction of pseudopregnancy in mice. Offspring were obtained from two-cell embryos transferred into females with pseudopregnancy induced using sonic vibration in proestrus on the day before embryo transfer. Furthermore, high developmental rates of offspring were observed when pronuclear and two-cell embryos were transferred to females in estrus that were stimulated on the day of embryo transfer. Genome-edited mice were also obtained using frozen-warmed pronuclear embryos with clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR-associated system (Cas) nucleases introduced using the technique for animal knockout system by electroporation (TAKE) method, which were transferred to females with pseudopregnancy induced on the day of embryo transfer. This study demonstrated that induction of pseudopregnancy by sonic vibration was also possible in mice.

Genome Editing of Rat

Many genetically engineered rat strains have been produced by the development of genome editing technology, although it used to be technical difficulty and low production efficiency. Knockout and knock-in strains can be simple and quick produced using zinc finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN), or clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9. Presently, genome edited strains have been produced by microinjection and a new electroporation method named technique for animal knockout system by electroporation (TAKE). This chapter presents the latest protocols for producing genome edited rats.

Genome Editing in Mouse and Rat by Electroporation

Many genome-edited mouse and rat strains have been produced using engineered endonucleases, including zinc finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN), or clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9. Especially, CRISPR-Cas9 is powerful tool that can be easy, rapid, and high-efficiency-produced new genome-edited strains. Furthermore, new technique, Technique for Animal Knockout system by Electroporation (TAKE), efficiently accelerate production of new strains by direct nuclease introduction into intact embryos using electroporation. This chapter presents a latest technical information in the production of genome-edited mouse and rat by TAKE method.

Survivability and subsequent development of vitrified early-stage mouse embryos after warming at different temperatures

Cryopreservation of embryos is a useful method for stably preserving various strains for a long time, and the cryopreserved embryos can be used at any time by simple warming. However, the viability of cryopreserved embryos, particularly vitrification at an early stage, is low compared to that of fresh embryos. As the warming process during vitrification is known to affect the survivability and subsequent development of embryos, the present study aimed to examine the viability and subsequent development of vitrified early-stage mouse embryos after warming at different temperatures. The survival rate of pronuclear and 2-cell stage embryos warmed at 60 °C (97% and 88%, respectively) was significantly higher than that of the embryos warmed at 37 °C (46% and 48%, respectively). The pronuclear and 2-cell stage embryos warmed at 60 °C (86% and 100%) showed better development to the blastocyst stage than the embryos warmed at 37 °C (72% and 84%, respectively). The development of offspring of the surviving embryos was similar at both the warming temperatures. These results showed that the survivability and subsequent development of vitrified early-stage mouse embryos were obviously increased upon rapid warming. This improved warming process could be helpful for the maintenance and reproduction of genetic resources.

Successful pseudopregnancy of rats by short period artificial stimulation using sonic vibration

Psuedopregnancy for embryo transfer (ET) is usually induced in rats by mating with vasectomized males. Previously, we successfully induced pseudopregnancy using sonic vibration instead (Easy-ET method). The transferred embryos developed normally. Conventionally, stimulation is performed 7 × 30 s with 5 min intervals at the day before ET. However, this protocol is time-consuming because it imitates natural mating behavior. Here, we investigated pseudopregnancy induction with shorter stimulation times. Stimulation was performed 2 × 30 s, with 30 s intervals at the proestrus stage at the day before ET. Of the transferred pronuclear or two-cell embryos, 43% or 62% developed normally, respectively. Furthermore, 67% or 68% of transferred pronuclear or two-cell embryos in rats at estrus stage stimulated on the day of ET developed normally, respectively. Pseudopregnancy was successfully induced with shorter stimulation. Furthermore, this protocol may be used to perform a single-day stimulation and ET operation at the estrus stage.

Small-volume vitrification and rapid warming yield high survivals of one-cell rat embryos in cryotubes†

To cryopreserve cells, it is essential to avoid intracellular ice formation during cooling and warming. One way to achieve this is to convert the water inside the cells into a non-crystalline glass. It is currently believed that to accomplish this vitrification, the cells must be suspended in a very high concentration (20-40%) of a glass-inducing solute, and subsequently cooled very rapidly. Herein, we report that this belief is erroneous with respect to the vitrification of one-cell rat embryos. In the present study, one-cell rat embryos were vitrified with 5 μL of EFS10 (a mixture of 10% ethylene glycol (EG), 27% Ficoll, and 0.45 M sucrose) in cryotubes at a moderate cooling rate, and warmed at various rates. Survival was assessed according to the ability of the cells to develop into blastocysts and to develop to term. When embryos were vitrified at a 2613 °C/min cooling rate and thawed by adding 1 mL of sucrose solution (0.3 M, 50 °C) at a warming rate of 18 467 °C/min, 58.1 ± 3.5% of the EFS10-vitrified embryos developed into blastocysts, and 50.0 ± 4.7% developed to term. These rates were similar to those of non-treated intact embryos. Using a conventional cryotube, we achieved developmental capabilities in one-cell rat embryos by rapid warming that were comparable to those of intact embryos, even using low concentrations (10%) of cell-permeating cryoprotectant and at low cooling rates.

Simple induction of pseudopregnancy by artificial stimulation using a sonic vibration in rats

Embryo transfer has been used as one of the essential reproductive technologies for production of new strains and maintenance of genetic resources in animals. Mating with vasectomised male rats is a requirement for inducing pseudopregnancy in female rats selected for embryo transfer. Although this procedure has been used routinely, large breeding space and high expenditure are required to maintain a sufficient number of females and vasectomised males. This study was performed to induce pseudopregnancy in females by artificial stimulation using sonic vibration instead of vasectomised males. The females continued to be in the dioestrus stage for at least 14 days after artificial stimulation was performed. Of fresh 2-cell embryos that transferred into the oviducts of females after artificial stimulation, 56% was implanted and 50% was developed to offspring. Approximately 46% of the frozen 2-cell embryos were implanted and 24% developed into offspring. Furthermore, 66% of the fresh pronuclear embryos were implanted and 60% developed into offspring. This study successfully induced pseudopregnancy in rat females by artificial stimulation using a sonic vibration. This method, ‘Easy-ET’, was useful for efficient production and maintenance of rat strains.

Genome editing of rodents by electroporation of CRISPR/Cas9 into frozen-warmed pronuclear-stage embryos

Genome edited animals can now be easily produced using the clustered regularly interspaced short palindromic repeat (CRISPR) and CRISPR-associated protein 9 (Cas9) system. Traditionally, these animals have been produced by the introduction of endonucleases into pronuclear-stage embryos. Recently, a novel electroporation method, the "Technique for Animal Knockout system by Electroporation (TAKE)," has been established as a simple and highly efficient tool to introduce endonucleases into embryos instead of methods such as microinjection. Use of frozen-warmed pronuclear-stage embryos in this method has further contributed to efficient production of genome edited animals. However, early developmental stage embryos, including pronuclear-stage embryos, especially those of rats, sometimes show low resistance to physical damage by vitrification and introduction of endonucleases during microinjection. In this study, we propose an ethanol-free, slow-freezing method to reduce physical damage to pronuclear-stage embryos followed by the TAKE method. All mouse and rat frozen embryos were survived after electroporation, and 18% and 100% of offspring were edited target gene, respectively. The resulting protocol is an efficient method for producing genome edited animals.

Efficient derivation of knock-out and knock-in rats using embryos obtained by in vitro fertilization

Rats are effective model animals and have contributed to the development of human medicine and basic research. However, the application of reproductive engineering techniques to rats is not as advanced compared with mice, and genome editing in rats has not been achieved using embryos obtained by in vitro fertilization (IVF). In this study, we conducted superovulation, IVF, and knock out and knock in using IVF rat embryos. We found that superovulation effectively occurred in the synchronized oestrus cycle and with anti-inhibin antiserum treatment in immature rats, including the Brown Norway rat, which is a very difficult rat strain to superovulate. Next, we collected superovulated oocytes under anaesthesia, and offspring derived from IVF embryos were obtained from all of the rat strains that we examined. When the tyrosinase gene was targeted by electroporation in these embryos, both alleles were disrupted with 100% efficiency. Furthermore, we conducted long DNA fragment knock in using adeno-associated virus and found that the knock-in litter was obtained with high efficiency (33.3–47.4%). Thus, in this study, we developed methods to allow the simple and efficient production of model rats.

Reproductive technologies for the generation and maintenance of valuable animal strains

Many types of mutant and genetically engineered strains have been produced in various animal species. Their numbers have dramatically increased in recent years, with new strains being rapidly produced using genome editing techniques. In the rat, it has been difficult to produce knockout and knock-in strains because the establishment of stem cells has been insufficient. However, a large number of knockout and knock-in strains can currently be produced using genome editing techniques, including zinc-finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN), and the clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated protein 9 (Cas9) system. Microinjection technique has also contributed widely to the production of various kinds of genome edited animal strains. A novel electroporation method, the “Technique for Animal Knockout system by Electroporation (TAKE)” method, is a simple and highly efficient tool that has accelerated the production of new strains. Gamete preservation is extremely useful for maintaining large numbers of these valuable strains as genetic resources in the long term. These reproductive technologies, including microinjection, TAKE method, and gamete preservation, strongly support biomedical research and the bio-resource banking of animal models. In this review, we introduce the latest reproductive technologies used for the production of genetically engineered animals, especially rats, using genome editing techniques and the efficient maintenance of valuable strains as genetic resources. These technologies can also be applied to other laboratory animals, including mice, and domestic and wild animal species.

Genome Editing in Mouse and Rat by Electroporation

Many knock-out/knock-in mouse and rat strains have been produced by genome editing techniques using engineered endonucleases, including zinc finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN), or clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9. Microinjection of engineered endonucleases into pronuclear-stage embryos is required to produce genome-edited rodents and the development of easy, rapid, and high-efficiency methods that do not require special skills such as microinjection is needed. This chapter presents a new technique called Technique for Animal Knockout system by Electroporation (TAKE), which produces genome-edited rodents by direct introduction of engineered endonucleases into intact embryos using electroporation.

Genome Editing of Rat

Many genetically engineered rat strains have been produced for biomedical research. The simple and quick production of knock-out and knock-in rats is currently possible using genome editing techniques incorporating zinc finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN), or clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9. Genome-edited animals have been produced by the introduction of endonucleases into embryos using conventional microinjection and a new electroporation method named Technique for Animal Knockout system by Electroporation (TAKE). This chapter introduces the latest protocols for producing genetically engineered rats using genome editing.

In vitro maturation of immature rat oocytes under simple culture conditions and subsequent developmental ability

Rat oocytes can be produced artificially by superovulation. Because some strains show low sensitivity to superovulation treatment, in vitro maturation is an alternative method to produce numerous matured oocytes. Furthermore, establishment of an in vitro maturation system with simple culture conditions is cost effective and leads to easy handling of oocytes. This study examined developmental ability of rat germinal vesicle (GV) oocytes maturing in vitro under simple culture conditions. Significantly different numbers of ovulated oocytes reached the second metaphase of meiosis (MII) among Jcl:Wistar (17.0), F344/Stm (31.0), and BN/SsNSlc (2.2) rats in whom superovulation was induced by pregnant mare serum gonadotropin (PMSG) and human chorionic gonadotropin. However, similar numbers of GV oocytes were obtained from ovaries of PMSG-injected Wistar (27.7), F344 (34.7), and BN (24.7) rats. These GV oocytes were cultured in vitro in HTF, αMEM, and a 1:1 HTF + αMEM or TYH + αMEM mixture. High proportions of Wistar and F344 oocytes that matured to MII in αMEM were parthenogenetically activated by strontium chloride treatment (78% and 74%, respectively). Additionally, 10% of matured oocytes of both strains developed into offspring after intracytoplasmic sperm injection and embryo transfer to foster mothers. Although BN oocytes cultured in αMEM could be parthenogenetically activated and developed into offspring, the success rate was lower than that for Wistar and F344 oocytes. This study demonstrated that numerous GV oocytes were produced in rat ovaries by PMSG injection. This simple in vitro maturation system of immature oocytes could be further developed to maintain valuable rat strains experiencing reproductive difficulties.

Creating knockout and knockin rodents using engineered endonucleases via direct embryo injection

Genetically engineered rodents have been generated worldwide for biomedical research. Recently, gene targeting techniques have been developed by using engineered endonucleases such as zinc-finger nucleases (ZFN), transcription activator-like effector nucleases (TALEN) and clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9. These endonucleases are useful for simple and rapid production of gene knockout/knockin animals without using embryonic stem (ES) cells. This chapter introduces the latest protocols for producing genetically modified rodents using ZFN, TALEN, and CRISPR/Cas9.

Simple sperm preservation by freeze-drying for conserving animal strains

Freeze-drying spermatozoa is the ultimate method for the maintenance of animal strains, in that the gametes can be preserved for a long time in a refrigerator at 4 °C. Furthermore, it is possible to realize easy and safe transportation of spermatozoa at an ambient temperature that requires neither liquid nitrogen nor dry ice. Freeze-drying spermatozoa has been established as a new method for storing genetic resources instead of cryopreservation using liquid nitrogen. This chapter introduces our latest protocols for freeze-drying of mouse and rat spermatozoa, and the anticipated results of the fertilizing ability of these gametes following long-term preservation or transportation.

Allele-specific genome editing and correction of disease-associated phenotypes in rats using the CRISPR-Cas platform

The bacterial CRISPR/Cas system has proven to be an efficient gene-targeting tool in various organisms. Here we employ CRISPR/Cas for accurate and efficient genome editing in rats. The synthetic chimeric guide RNAs (gRNAs) discriminate a single-nucleotide polymorphism (SNP) difference in rat embryonic fibroblasts, allowing allele-specific genome editing of the dominant phenotype in (F344 × DA)F1 hybrid embryos. Interestingly, the targeted allele, initially assessed by the allele-specific gRNA, is repaired by an interallelic gene conversion between homologous chromosomes. Using single-stranded oligodeoxynucleotides, we recover three recessive phenotypes: the albino phenotype by SNP exchange; the non-agouti phenotype by integration of a 19-bp DNA fragment; and the hooded phenotype by eliminating a 7,098-bp insertional DNA fragment, evolutionary-derived from an endogenous retrovirus. Successful in vivo application of the CRISPR/Cas system confirms its importance as a genetic engineering tool for creating animal models of human diseases and its potential use in gene therapy.