Naoki Maedomari

Production of viable piglets for the first time using sperm derived from ectopic testicular xenografts.

Xenografting of testicular tissue into immunodeficient mice is known to be a valuable tool for facilitating the development of immature germ cells present in mammalian gonads. Spermatogenesis in xenografts and/or in vitro embryonic development to the blastocyst stage after ICSI of xenogeneic sperm has already been reported in large animals, including pigs; however, development of the embryos to term has not yet been confirmed. Therefore, in pigs, we evaluated the in vivo developmental ability of oocytes injected after ICSI of xenogeneic sperm. Testicular tissues prepared from neonatal piglets, which contain seminiferous cords consisting of only gonocytes/spermatogonia, were transplanted under the back skin of castrated nude mice. Between 133 and 280 days after xenografting, morphologically normal sperm were recovered, and a single spermatozoon was then injected into an in vitro matured porcine oocyte. After ICSI, the oocytes were electrostimulated and transferred into estrus-synchronized recipients. Two out of 23 recipient gilts gave birth to six piglets. Here, we describe for the first time that oocytes fertilized with a sperm from ectopic xenografts have the ability to develop to viable offspring in large mammals.

Live Piglets Derived from In Vitro-Produced Zygotes Vitrified at the Pronuclear Stage

Abstract We report the successful cryopreservation of in vitro-produced porcine zygotes. Follicular oocytes from prepubertal gilts were matured (IVM), fertilized (IVF), and cultured (IVC) in vitro. At 10 or 23 h after IVF, the oocytes were centrifuged to visualize pronuclei. Zygotes with two or three pronuclei were used for solid surface vitrification (SSV). Survival of vitrified-warmed zygotes was determined by their morphology. To assess their developmental competence, vitrified (SSV), cryoprotectant-treated (CPA), and untreated (control) zygotes were subjected to IVC for 6 days. Survival and developmental competence did not differ between control and CPA zygotes. The proportion of live zygotes after SSV and warming (93.4%) was similar to that in the controls (100%). Cleavage and blastocyst formation rates of SSV zygotes after vitrification (71.7% and 15.8%, respectively) were significantly lower than those of controls (86.3% and 24.5%, respectively; ANOVA P < 0.05). Blastocyst cell numbers of SSV and control embryos were similar (41.2 ± 3.4 and 41.6 ± 3.3, respectively). There was no difference in developmental ability between zygotes cryopreserved at an early (10 h after IVF) or late (23 h after IVF) pronuclear stage. Storage in liquid nitrogen had no effect on the in vitro developmental competence of vitrified zygotes beyond the reduction induced by the vitrification itself. When the embryo culture medium was supplemented with 1 μM glutathione, the rate of development of cryopreserved zygotes to the blastocyst stage did not differ significantly from that of control glutathione-treated zygotes (18.6% and 22.1%, respectively). To test their ability to develop to term, vitrified zygotes were transferred to five recipients, resulting in three pregnancies and the production of a total of 17 piglets. These data demonstrate that IVM-IVF porcine zygotes can be cryopreserved at the pronuclear stage effectively without micromanipulation-derived delipation, preserving their full developmental competence to term.

Effects of chelating agents during freeze-drying of boar spermatozoa on DNA fragmentation and on developmental ability in vitro and in vivo after intracytoplasmic sperm head injection.

Successful offspring production after intracytoplasmic injection of freeze-dried sperm has been reported in laboratory animals but not in domesticated livestock, including pigs. The integrity of the DNA in the freeze-dried sperm is reported to affect embryogenesis. Release of endonucleases from the sperm is one of the causes of induction of sperm DNA fragmentation. We examined the effects of chelating agents, which inhibit the activation of such enzymes, on DNA fragmentation in freeze-dried sperm and on the in vitro and in vivo developmental ability of porcine oocytes following boar sperm head injection. Boar ejaculated sperm were sonicated, suspended in buffer supplemented with (1) 50 mM EGTA, (2) 50 mM EDTA, (3) 10 mM EDTA, or (4) no chelating agent and freeze-dried. A fertilization medium (Pig-FM) was used as a control. The rehydrated spermatozoa in each group were then incubated in Pig-FM at room temperature. The rate of DNA fragmentation in the control group, as assessed by the TUNEL method, increased gradually as time after rehydration elapsed (2.8% at 0 min to 12.2% at 180 min). However, the rates in all experimental groups (1-4) did not increase, even at 180 min (0.7-4.1%), which were all significantly lower (p < 0.05) than that of the control group. The rate of blastocyst formation after the injection in the control group (6.0%) was significantly lower (p < 0.05) than those in the 50 mM EGTA (23.1%) and 10 mM EDTA (22.6%) groups incubated for 120-180 min. The average number of blastocyst cells in the 50 mM EGTA group (33.1 cells) was significantly higher (p < 0.05) than that in the 10 mM EDTA group (17.8 cells). Finally, we transferred oocytes from 50 mM EGTA or control groups incubated for 0-60 min into estrous-synchronized recipients. The two recipients of the control oocytes became pregnant and one miscarried two fetuses on day 39. The results suggested that fragmentation of DNA in freeze-dried boar sperm is one of the causes of decreased in vitro developmental ability of injected oocytes to the blastocyst stage. Supplementation with EGTA in a freeze-drying buffer improves this ability.

Generation of porcine diploid blastocysts after injection of spermatozoa grown in nude mice

It is anticipated that the utilization of spermatogonia through testicular xenografting will open new avenues for the conservation of male gametes. With the aim of establishing this new technique for genetic preservation of pigs, we used it in combination with intracytoplasmic sperm injection (ICSI). Testicular tissues derived from neonatal piglets, which contained seminiferous cords consisting of only gonocytes/spermatogonia, were transplanted under the back skin of castrated nude mice. Between 125 and 192 d after xenografting, sperm (morphologically similar to epididymal sperm) were recovered from 41 of the 65 host mice (63.1%). Testicular spermatozoa from adult boars were used as a positive control. A single spermatozoon was injected into an in vitro matured porcine oocyte, and the oocytes were electro-stimulated and cultured (graft-ICSI and testis-ICSI, respectively). Blastocyst rates in both ICSI groups (24.9% and 37.4%, respectively) were higher (P<0.05) than those without the injection procedure (parthenogenetic; 12.7%) and after injection of a small amount of injection buffer (sham; 13.0%). Rates of diploid blastocysts in both graft-ICSI and testis-ICSI groups (48.9% and 60.6%) were higher (P<0.05) than those in the parthenogenetic and sham groups (13.5% and 28.0%). Therefore, we demonstrated that porcine oocytes injected with xenogeneic sperm have in vitro developmental ability to the blastocyst stage.

Cumulus cell-enclosed oocytes acquire a capacity to synthesize GSH by FSH stimulation during in vitro maturation in pigs.

We investigated (i) follicle stimulating hormone (FSH)‐modulated changes in the expression of glutathione (GSH) and its rate‐limiting enzyme, glutamate cysteine ligase (GCL), in porcine oocytes and cumulus cells, and (ii) the contribution of gap‐junctional communications (GJCs) in cumulus‐oocyte complexes (COCs) to intraoocyte GSH accumulation. In experiment (i), COCs were cultured for 48 h with (+FSH group) or without FSH (−FSH group). The GSH content of oocytes increased with cultivation time in the +FSH group, but decreased in the −FSH group. The GSH content of cumulus cells at 48 h was also higher in the +FSH group than that in the −FSH group. Expression of GCL subunit mRNAs in oocytes and cumulus cells was increased by FSH stimulation until 12 h, and then fell to the baseline level. On the other hand, the amount of GCL subunit proteins in oocytes and cumulus cells increased gradually throughout the period of culture with FSH. In experiment (ii), blocking of GJCs in COCs during 0–24 h of culture led to a decrease in the GSH content of oocytes at 24 h of culture, whereas the GSH content at 48 h of culture did not differ even after blocking of the GJCs during 24–48 h of culture. These findings indicate that FSH initiates GSH synthesis in cumulus cells and oocytes by modulating the expression of GCL, and that porcine oocytes are able to synthesize GSH without GJC‐mediated support from cumulus cells, at least in the later half of maturation culture. J. Cell. Physiol. 222: 294–301, 2010.

Techniques for in vitro and in vivo fertilization in the rat.

Although in vitro and in vivo fertilization are powerful tools for restoring conserved sperm as well as stocked males in the rat, the techniques have progressively gained importance. However, the techniques are not used extensively for efficient production of rat offspring, because the techniques require a great deal of skill. This chapter describes the protocols for in vitro and in vivo fertilization in the rat. Namely, sperm collection, sperm cryopreservation, pre-incubation of sperm, and insemination (co-culture with sperm and oocytes) for in vitro fertilization and intrauterine insemination for in vivo fertilization with fresh or frozen/thawed spermatozoa are provided.

Delay in Cleavage of Porcine Embryos after Intracytoplasmic Sperm Injection (ICSI) Shows Poorer Embryonic Development

In pigs, the embryonic developmental ability after intracytoplasmic sperm injection (ICSI) is inferior to that resulting from in vitro fertilization (IVF). We evaluated the timing of cell division up to blastocyst formation on embryonic development after ICSI using either whole sperm (w-ICSI) or the sperm head alone (h-ICSI) and IVF as a control. At 10 h after ICSI or IVF, we selected only zygotes, and each of the zygotes/embryos was evaluated for cleavage every 24 h until 168 h. We then observed a delay in the 1st and 2nd cleavages of h-ICSI embryos and also in blastocoele formation by w-ICSI embryos in comparison with IVF embryos. The rate of blastocyst formation and the quality of blastocysts in both ICSI groups were inferior to those in the IVF group. In conclusion, the delay in cleavage of porcine ICSI embryos shows poorer embryonic development.

Nuclear Replacement of In Vitro-Matured Porcine Oocytes by a Serial Centrifugation and Fusion Method

The objective of the present study was to establish a method for nuclear replacement in metaphase-II (M-II) stage porcine oocytes. Karyoplasts containing M-II chromosomes (K) and cytoplasts without chromosomes (C) were produced from in vitro-matured oocytes by a serial centrifugation method. The oocytes were then reconstructed by fusion of one karyoplast with 1, 2, 3 or 4 cytoplasts (K + 1C, K + 2C, K + 3C and K + 4C, respectively). Reconstructed oocytes, karyoplasts without fusion of any cytoplast (K) and zona-free M-II oocytes (control) were used for experiments. The rates of female pronucleus formation after parthenogenetic activation in all groups of reconstructed oocytes (58.2-77.4%) were not different from those of the K and control groups (58.2% and 66.0%, respectively). In vitro fertilization was carried out to assay the fertilization ability and subsequent embryonic development of the reconstructed oocytes. The cytoplast : karyoplast ratio did not affect the fertilization status (penetration and male pronuclear formation rates) of the oocytes. A significantly high monospermy rate was found in K oocytes (p < 0.05, 61.6%) compared with the other groups (18.2-32.8%). Blastocyst formation rates increased significantly as the number of the cytoplasts fused with karyoplasts increased (p < 0.05, 0.0-15.3%). The blastocyst rate in the K + 4C group (15.3%) was comparable with that of the control (17.8%). Total cell numbers in both the K + 3C and K + 4C groups (16.0 and 15.3 cells, respectively) were comparable with that of the control (26.2 cells). Our results demonstrate that a serial centrifugation and fusion (Centri-Fusion) is an effective method for producing M-II chromosome transferred oocytes with normal fertilization ability and in vitro development. It is suggested that the number of cytoplasts fused with a karyoplast plays a critical role in embryonic development.

93 Production of live piglets by cryopreservation of in vitro-produced porcine zygotes

Successful cryopreservation of in vitro-produced porcine zygotes is reported in the present study. Follicular oocytes were collected from prepubertal gilts. They were matured (IVM), fertilized (IVF), and cultured (IVC) in vitro (Kikuchi et al. 2002 Biol. Reprod. 66, 1033–1041). Ten or 23 h after IVF, the oocytes were centrifuged at 10 000g at 37°C for 20 min to permit visualization of pronuclei. Zygotes with two or three pronuclei were selected under stereomicroscope and used for solid surface vitrification (SSV). Briefly, after equilibration in 4% ethylene glycol (EG) for 15 min, zygotes were washed in vitrification solution (35% EG, 5% polyvinyl pyrrolidone, and 0.3 m trehalose), and then dropped with about 2 µL vitrification solution onto the dry surface of aluminum foil floating on the surface of liquid nitrogen (LN2). Microdroplets were transferred into cryotubes and stored in LN2. During warming, vitrified droplets were transferred in warming solution (0.4 m trehalose) at 37°C for 1 min, and then consecutively transferred for 1-min periods into 0.2 m, 0.1 m, or 0.05 m trehalose solutions. Survival of vitrified/warmed zygotes was determined by their morphology. To assess their developmental competence, vitrified (SSV), cryoprotectant-treated (CT), and untreated (control) zygotes were cultured in vitro for 6 days. There was no difference in developmental competence between control and CT zygotes in terms of cleavage rates (88.1% and 86.1%, respectively), blastocyst rates (23.2% and 20.8%, respectively), and blastocyst cell numbers (38.0 ± 2.0 and 41.2 ± 1.7, respectively). The rate of live zygotes after SSV and warming was similar to that of the control (93.4% and 100%, respectively). Cleavage rates (71.7% and 86.3%, respectively) and blastocyst rates (15.8% and 24.5%, respectively) of SSV were significantly reduced after vitrification compared to control (P < 0.05, ANOVA). Blastocyst cell numbers of SSV and control embryos were similar (41.2 ± 3.4 and 41.6 ± 3.3, respectively). There was no difference in developmental ability between zygotes cryopreserved at an early (10 h after IVF) or late (23 h after IVF) pronuclear stage. When embryo culture medium was supplemented with 1 µm of the antioxidant glutathione, development of cryopreserved zygotes to the blastocyst stage did not differ significantly from that of the control zygotes (18.6% and 22.1%, respectively). To test their ability to develop to term, 150 vitrified zygotes were transferred into a recipient, resulting in pregnancy and the production of five live piglets. These data demonstrate that a high rate of porcine zygotes could be successfully cryopreserved at the pronuclear stage, preserving their full developmental competence.

44 EFFECT OF CYTOPLAST VOLUME ON FERTILIZATION AND EMBRYO DEVELOPMENT IN PORCINE M-II OOCYTES RECONSTRUCTED WITH KARYOPLASTS AND CYTOPLASTS OBTAINED BY THE 'CENTRI-FUSION' METHOD

Metaphase-II chromosome transfer (M-II transfer) of oocytes is considered to be one of the advanced procedures to improve fertilization and developmental abilities of oocytes with poor cytoplasmic maturation. The aim of this study was to investigate the developmental capacity after IVF and IVC of porcine oocytes reconstructed from karyoplasts and cytoplasts produced by centri-fusion (Fahrudin et al. 2007 Cloning Stem Cells 9, 216–228). In brief, IVM oocytes (Kikuchi et al. 2002 Biol. Reprod. 66, 1033–1041) with a visible first polar body were centrifuged at 13 000g for 9 min to stratify the cytoplasm. Then the zonae pellucidae were removed with pronase treatment. Zona-free oocytes were layered on a 300-µL discontinuous gradient of Percoll in TCM-HEPES with 5 µg mL–1 of cytochalasin B. After centrifugation at 6000g for 4 s, fragmented cytoplasms with approximately equal volumes were obtained, stained with Hoechst-33342, and classified into cytoplasm with (K; karyoplast) or without (C; cytoplast) chromosomes. One karyoplast was fused with 0, 1, 2, 3, and 4 cytoplasts (K, K + 1C, K + 2C, K + 3C, and K + 4C, respectively) by an electric stimulation with a single DC pulse (1.5 kV cm–1 for 20 µs) and cultured for 1 h. Zona-free oocytes without any reconstruction served as control oocytes. The diameters of the reconstructed and control oocytes were measured. All specimens were fertilized in vitro with frozen–thawed boar sperm, and cultured using the well of the well (WOW) system (Vajta et al. 2000 Mol. Reprod. Dev. 55, 256–264). Their fertilization status and developmental competence were examined. Data were analyzed by ANOVA followed by Duncans multiple range tests. The diameter differed significantly among K to K + 4C oocytes (75.0–127.1 µm; P < 0.05), whereas the diameter of K + 2C oocytes was similar to that of the control oocytes (110.5 µm). Regardless of the cytoplast volume, sperm penetration rates (73.1–93.8%) for K to K + 4C oocytes were not significantly different compared to control oocytes (78.0%). Male pronuclear formation rates of K to K + 4C oocytes (92.3–97.1%) were also not different significantly different compared to control oocytes (96.6%). However, monospermy rates of K oocytes was significantly higher (61.6%; P < 0.05) than those of the reconstructed (K + 1C to K + 4C; 18.2–34.9%) and control oocytes (32.9%). The blastocyst formation rates in K, K + 1C, K + 2C, and K + 3C groups (0.0–9.8%; P < 0.05) were significantly lower than those in the control and K + 4C groups (17.8% and 15.3%, respectively; P < 0.05). The total cell numbers per blastocyst in K + 1C and K + 2C groups (7.5 and 8.3 cells, respectively) were significantly lower than in the control, K + 3C, and K + 4C groups (15.3–26.2 cells; P < 0.05). These results suggest that the cytoplast volume of porcine M-II transferred oocytes, produced by reconstruction from a karyoplast and cytoplast(s) and centri-fusion, is important for their ability to develop to the blastocyst stage and influences cell number.