Reliability and accuracy of the critical shoulder angle measured by anteroposterior radiographs: using digitally reconstructed radiograph from 3-dimensional computed tomography images

BACKGROUND

Accuracy of current standard radiographic measurement of the critical shoulder angle (CSA) is not well established. This study analyzed the reliability and accuracy of the CSA measurements obtained via anteroposterior (AP) radiographs, using a digitally reconstructed radiograph (true AP view) generated from a computed tomography image as the gold standard.

METHODS

The CSA was measured on the radiographs and true AP views of 88 consecutive patients who had undergone shoulder arthroscopy for rotator cuff tears. Intraobserver and interobserver reliabilities of the CSA, measured by 2 orthopedic surgeons, were evaluated, and the average deviation of the CSA between radiographs and true AP views was calculated. Moreover, we compared the deviation of CSA between standard AP films (types A1 and C1) and nonstandard AP films (other types) against the Suter-Henninger criteria.

RESULTS

Intraobserver and interobserver reliabilities were almost perfect on radiographs (0.96, 0.86) and true AP views (0.93, 0.85). The average deviation of CSA was 2.1° ± 1.6° for observer 1 and 2.2° ± 1.9° for observer 2. The percentage of cases with deviations of 2° or more when compared with the true AP view was 42% (37 of 88) for observer 1 and 53% (47 of 88) for observer 2. Only 22% (19 of 88) of films were standard AP films. The average deviation of CSA was not significantly different between standard and nonstandard AP films for observer 1 (standard 1.9° ± 1.3°; nonstandard 2.1° ± 1.7°; P = .76) and observer 2 (standard 1.6° ± 1.5°; nonstandard 2.4° ± 1.9°; P = .09).

CONCLUSION

The CSA measurements using radiography were highly congruent, but a large measurement deviation occurred between radiographs and true AP views. The clinical usefulness and role of CSA in diagnosis require careful consideration.

Diagnostic accuracy of magnetic resonance imaging for partial tears of the long head of the biceps tendon in patients with rotator cuff tears

Background

Magnetic resonance imaging (MRI) is useful for diagnosing shoulder diseases preoperatively. However, detection of partial tears of the long head of the biceps tendon (LHBT) using current clinical tests and imaging modalities is difficult. We aimed to evaluate the accuracy of radial-slice MRI for diagnosing partial tears of the LHBT. We hypothesized that radial-slice MRI may be a valuable diagnostic tool for assessing diagnosing tears of the LHBT.

Methods

We retrospectively investigated 118 patients who underwent shoulder arthroscopy for rotator cuff tears. Intraoperative LHBT findings were compared with the identification of partial tears of the LHBT on conventional-slice MRI and radial-slice MRI, using a 3.0-T system. We calculated sensitivity, specificity, accuracy, and positive and negative predictive values for the detection of LHBT tears. Inter- and intraobserver reliability for radial-slice MRI was calculated using kappa statistics.

Results

We diagnosed 69 patients (58%) without any LHBT tears and 49 with partial tears (42%), arthroscopically. Sensitivity, specificity, accuracy, and positive and negative predictive values of conventional-slice MRI for detection of partial tears of the LHBT were 52%, 94%, 78%, 92%, and 58%, respectively. Radial-slice MRI had 84% sensitivity, 90% specificity, 86% accuracy, and 92% positive and 80% negative predictive values for partial tears of the LHBT. Inter- and intraobserver reliability for radial-slice MRI was 0.69 and 0.74, respectively, corresponding to high reproducibility and defined as good.

Conclusion

Radial-slice MRI demonstrated significantly higher sensitivity than conventional-slice MRI. These results indicate that radial-slice MRI is useful for diagnosing LHBT partial tears.

Relationship between preoperative size of rotator cuff tears measured using radial-slice magnetic resonance images and postoperative rotator cuff integrity: a prospective case-control study

Background

Magnetic resonance imaging (MRI) is useful for diagnosing shoulder diseases preoperatively. However, preoperative risk factors for retears have not been previously reported using a radial-slice MRI. Here, we investigated the relationship between the preoperative tear area of the rotator cuff evaluated using radial-slice MRI and the postoperative rotator cuff integrity. Our hypothesis is that larger tear area of the rotator cuff measured using radial-slice MRI would be associated with increased retear rates.

Methods

From June 2010 to October 2015, we treated 102 consecutive patients who underwent shoulder arthroscopy for reparable rotator cuff tears. The patient demographics, medical comorbidities, radiologic factors, tear size, fatty infiltration, muscle atrophy measured using oblique coronal and oblique sagittal MRI, and the tear area calculated using radial-slice MRI were assessed to compare the intact and retear groups in univariate and multivariate logistic regression analyses. The cutoff values of the independent factors were obtained using the receiver operating characteristic curve.

Results

Retears occurred in 15 of 102 (14.7%) patients. In the univariate analysis, significant differences were found between the two groups for tear size, fatty infiltration of the supraspinatus and infraspinatus, muscle atrophy, and tear area. In the multivariate analysis, the tear area was the independent factor that significantly affected the rate of retear. A tear area of 6.3 cm² was the strongest predictor of retear with an area under the curve of 0.965, sensitivity of 86.7%, and specificity of 96.6%.

Conclusion

The tear area was the independent factor that most significantly affected the rate of retear and showed excellent accuracy with a cutoff value of 6.3 cm². Radial-slice MRI may be a valuable diagnostic tool for assessing the postoperative rotator cuff integrity.

59 IN VITRO DEVELOPMENT OF FELINE CLONED EMBRYOS RECONSTRUCTED WITH PREADIPOCYTES

The technique of somatic cell nuclear transfer (NT) in domestic cats is expected to contribute to the conservation of wildcats, for which extinction is a concern. In this study, we examined in vitro developmental ability of cloned embryos produced using the preadipocytes of domestic cats as nuclear donors. Primary cultures of preadipocytes were established as reported previously (Yagi et al. 2004 Biochem. Biophys. Res. Commun. 321, 967–974). Briefly, fat tissue (2–3 g) was excised from an adult female cat and digested using 0.1% collagenase for 1 h at 37�C followed by centrifugation. Only mature adipocytes that were floating near the surface of the supernatant were collected and placed in a 12.5-cm2 culture flask filled with DMEM containing 20% FBS. The flask was filled with medium, tightly capped, and cultured upside down for 7–10 days, so that the floating adipocytes attached to the inner ceiling surface of the flask. When firm attachment of the cells to the ceiling surface of the flask was confirmed, the flask was then inverted and culture was continued using the routine cell culture technique for adherent cells. In vivo-matured oocytes were collected from the ovaries of domestic cats superovulated by eCG and hCG. IVM oocytes were obtained by culturing cumulus–oocyte complexes from the ovaries collected at local veterinary clinics in TCM199-based medium for 24 to 30 h. In vivo-matured and IVM oocytes were enucleated by aspirating the first polar body and adjacent cytoplasm using a bevelled pipette in the presence of 7.5 µg mL–1 cytochalasin B. The nuclei of the donor cells were transferred to enucleated in vivo-matured and IVM oocytes by means of electric fusion (300 V mm–1, 30 µs, twice). The reconstructed embryos were activated electrically (125 V mm–1, 60 µs, twice), followed by treatment with 10 µg mL–1 cycloheximide and 5 µg mL–1 cytochalasin B. The cloned embryos were cultured in vitro for 7 days in MK-1 so that their developmental ability might be examined. The fusion rate of donor cells was similar between in vivo-matured and IVM oocytes (56.8%, 21/37 v. 54.5%, 42/77). The developmental ability of NT embryos reconstructed with in vivo-matured oocytes was similar to that of NT embryos reconstructed with IVM oocytes (cleavage: 52.4%, 11/21 v. 42.9%, 18/42; development to blastocysts: 9.5%, 2/21 v. 11.9%, 5/42). The results indicate that cloned feline embryos reconstructed using preadipocytes can develop in vitro into blastocysts.

84 PRODUCTION OF CLONED PIGLETS FROM NUCLEAR TRANSFER EMBRYOS AFTER VITRIFICATION

Cryopreservation of cloned embryos is expected to be beneficial in improving the efficiency of somatic cell cloning in pigs. We have already demonstrated that normal piglets can be produced from in vitro-matured and fertilized (IVM/IVF) embryos vitrified at an early cleavage stage after delipation (Nagashima et al. 2007 Biol. Reprod. 76, 900–905). In this study we utilized this technique in an attempt to produce piglets from cloned embryos reconstructed with IVM oocytes. Nuclear transfer (NT) embryos were reconstructed using oocytes matured in vitro in NCSU23 and preadipocytes as nuclear donors. The embryos were cultured in PZM-5 for approximately 98 h, and those that had developed to the morula stage were delipated using a noninvasive method described previously (Esaki et al. 2004 Biol. Reprod. 71, 432–437). The embryos were treated with 4% trypsin at 38�C for 1 to 4 min to induce a slight swelling of the zona pellucida, and then centrifuged (12 000g, 38�C, 23 min) with 7.5 µg mL–1 cytochalasin B to polarize cytoplasmic lipid droplets within the perivitelline space. The embryos were cultured for 1 h and vitrified by the minimum volume cooling (MVC) method using a MVC plate (Cryotop�; Kitasato Supply Co., Tokyo, Japan) in the presence of 15% ethylene glycol, 15% DMSO, and 0.5 m sucrose as cryoprotectants. Vitrified embryos were rewarmed by immersing the MVC plate diretly into rewarming solution containing 1 m sucrose and 20% calf serum at 38�C for 1 min, followed by stepwise dilution of the cryoprotectants. The rewarmed embryos were cultured for 2 days to the blastocyst stage, and then treated with 0.5% pronase to remove the zona pellucida before transfer to the uterine horn of recipients. A total of 103 vitrified blastocysts were transferred to 2 recipient gilts. Both gilts became pregnant and farrowed 2 and 4 piglets, respectively (6/103, 5.8%). These results demonstrate that cloned piglets can be produced from NT embryos that have been cryopreserved at the morula stage using noninvasive delipation and vitrification procedures. This study was supported by PROBRAIN.

126 CRYOPRESERVATION OF PORCINE EMBRYOS DERIVED FROM IVM OOCYTES

We have reported that a combination of delipation (removal of cytoplasmic lipid droplets from blastomeres) and vitrification by means of the minimum-volume cooling (MVC) method successfully cryopreserves porcine in vitro-matured/fertilized (IVM/IVF) embryos, and that normal piglets are produced from these embryos (Hiruma et al. 2006 Reprod. Fertil. Dev. 18, 157). We have also reported that IVM-derived embryos that undergo noninvasive delipation (i.e. micromanipulation is not required) and vitrification develop into blastocysts at a high rate (Esaki et al. 2004 Biol. Reprod. 71, 432–437). In this study, we examined whether fetuses can be produced from the IVM-derived embryos that have been delipated noninvasively and vitrified. Cumulus–oocyte complexes that had been collected from slaughterhouse ovaries were in vitro-matured in NCSU23 medium. The IVM oocytes were activated to produce parthenogenetic embryos. We used the embryos at the 4- to 8-cell (67 h after activation) and morula (98 h) stages in the following experiments. Embryos were treated with 4% trypsin (in PBS) at 38�C for 1 to 4 min to expand the zona pellucida. Next, the embryos were centrifuged (12 000g, 38�C, 23 min) in TL-HEPES-PVP containing 7.5 �g mL-1 cytochalasin B to polarize cytoplasmic lipid droplets within the perivitelline space. These embryos were cultured for 1 to 3 h and then vitrified. The post-thaw viability of the embryos was assessed based on their ability to develop into blastocysts and fetuses (21 to 23 days old). The embryos were vitrified using the MVC method with 15% ethylene glycol, 15% DMSO, and 0.5 M sucrose as cryoprotective agents. PZM-5 was used for culturing the embryos. In embryo transfer experiments, after thawing, the embryos were cultured for 36 or 72 h until they developed into morulae or 4- to 8-cell blastocysts, respectively; they were then treated with 0.5% pronase to remove the zona pellucida, and transferred to the uterine horns of estrus-synchronized recipients 6 days after onset of estrus. The proportion of vitrified embryos that developed into blastocysts and the mean cell number of the blastocysts were similar to those of non-vitrified control embryos, irrespective of the embryonic stage (4- to 8-cell stage: 42.1%, 22/51, 63.0 � 7.8 vs. 64.7%, 22/34, 74.2 � 7.1, respectively; morula stage: 77.6%, 38/49, 69.6 � 7.2 vs. 83.3%, 45/54, 66.2 � 5.9, respectively). Seventeen embryos that had been vitrified at the 4- to 8-cell stage gave rise to 3 fetuses after transfer into one recipient (17.6%). Fifty-three embryos that had been vitrified at the morula stage were transferred into 3 recipients. All recipients became pregnant and produced a total of 17 fetuses (32.1%). These results suggest that porcine IVM-derived embryos that have been cryopreserved by the combination of noninvasive delipation and vitrification by the MVC method are highly viable.

408 FOREIGN GENE INTEGRATION PATTERNS IN TRANSGENIC PORCINE FETUSES PRODUCED BY ICSI-MEDIATED GENE TRANSFER

We previously reported that transgenic (TG) pigs can be produced from in vitro-matured oocytes using intracytoplasmic sperm injection-mediated gene transfer (ICSI-mediated method) (Kurome et al. 2006 Transgenic Res. 15, 229–240). We subsequently studied the expression of a foreign gene which had been introduced by the ICSI-mediated method. We found that the ICSI-mediated method is considerably less likely than the pronuclear microinjection method to produce embryos in which transgene-positive and transgene-negative cells co-exist, that is, mosaic embryos (Saito et al. 2006 Reprod. Fertil. Dev. 18, 297 abst). Therefore, in order to further investigate the ICSI-mediated method, the present study was conducted to address the integration patterns of foreign genes introduced by this method. In particular, we wished to determine the number of transgene copies and number of chromosomal integration sites. TG pig fetuses, obtained by the ICSI-mediated method in a separate cardiac disease model study, were used in the present study. Porcine cumulus-oocyte complexes that had been collected from slaughterhouse ovaries were subjected to in vitro maturation in NCSU23 medium to produce MII oocytes to be used in this study. Porcine spermatozoa frozen in Beltsville Thawing Solution (BTS) were thawed rapidly in a 37�C water bath, and each spermatozoon was decapitated using ultrasound (28 kHz, 100 W; W-113; Honda Electronics Co., Ltd, Aichi, Japan). The heads (2 to 5 � 105/10 �L) were co-incubated with 2.5 ng �L-1 of rabbit calreticulin cDNA (�MHC-CRT-HA: 7.5 kb) for five min at room temperature, and then microinjected into MII oocytes using a piezo-micromanipulator. An electric stimulus (DC 150 V mm-1, 100 �s) was applied 10 to 40 min after microinjection in order to activate the oocytes. The embryos were cultured in PZM-5 medium for one to two days, and then transferred into the oviducts of recipient gilts, whose estrous cycle had been synchronized using 1000 IU eCG and 1500 IU hCG. Fetuses were collected 33 or 50 days later, and a primary cell line (fibroblast) was established. For each fetus, the number of transgene copies was determined by Southern blot. In addition, the chromosomal sites, where the foreign gene had integrated, were identified, and the number of integration sites was determined by fluoresent in situ hybridization (FISH). A total of 454 ICSI embryos were transferred to 4 recipients (92 to 135 embryos/recipient). All recipients became pregnant and 23 fetuses (5.1%, 23/454), including 7 TG fetuses (30.4%, 7/23), were obtained. Southern blot analysis showed that the number of transgene copies varied between 1 and 300 (1 copy: 1 fetus; 10 copies: 2 fetuses; 30 copies: 3 fetuses; 300 copies: 1 fetus). FISH analysis showed that in TG fetuses, the foreign gene had integrated at only a single chromosomal site, and this site varied from TG fetus to TG fetus. These results demonstrate that, in the case of ICSI-mediated gene transfer, as is the case for gene transfer by pronuclear microinjection, the integration patterns are: multiple copy, random site, and single site integration. This study was supported by PROBRAIN.

64 PRODUCTION OF TRANSGENIC CLONED PIGS BY MEANS OF SOMATIC CELL NUCLEAR TRANSFER USING KUSABIRA-ORANGE GENE-TRANSFECTED CELLS

Cloned pigs that express cell markers such as fluorescent proteins (Vintersten et al. 2004 Genesis 40, 241–246) are useful in biomedical research in areas such as cell/tissue transplantation and regenerative medicine. In this study, we attempted to produce transgenic cloned pigs from porcine fetal fibroblasts which carry the gene of red fluorescent protein, humanized Kusabira-Orange (huKO). We examined whether huKO-transfected cells are suitable as nuclear donors for somatic cell cloning, and whether red fluorescence can be detected in the cloned embryos. We used porcine fetal fibroblasts transfected with the huKO gene and a retroviral vector as the nuclear donor cells. Non-transfected cells were used as the control. Cumulus–oocyte complexes collected from slaughterhouse ovaries were in vitro-matured in NCSU23 medium to produce recipient oocytes. Nuclear transfer was conducted using a previously reported method (Kurome et al. 2003 Cloning Stem Cells 5, 367–377); the following parameters which determine the overall efficiency of nuclear transfer were investigated: (1) fusion rate between the donor cells and recipient oocytes, (2) rates of normal cleavage and blastocyst formation of the NT embryos, and (3) cell numbers in each blastocyst. A DC pulse (190 V mm-1) was used for electric fusion, and NCSU23 or PZM-5 medium was used for culturing the cloned embryos. The NT embryos on Day 7 were examined under a fluorescence microscope (G excitation) in order to evaluate the expression of red fluorescence. Some cloned embryos at the 1- to 8-cell stage (Day 1 or 2) were transferred into oviducts of estrus-synchronized recipient gilts. There was no significant difference (chi-square test) between the huKO and the control groups in the rate of fusion (132/151, 87.4% vs. 134/147, 91.2%, respectively) and cleavage rate (78/132, 59.1% vs. 86/134, 64.2%, respectively). A significantly greater percentage of huKO cell-derived embryos developed into blastocysts than did control cell-derived embryos (37/132, 28.0% vs. 20/134, 14.9%, respectively; P < 0.05). However, there was no significant difference in the blastocyst cell numbers (Student's t-test: 48.6 ± 4.8 vs. 42.3 ± 4.9, respectively). Of the 132 NT embryos, 116 (87.9%) expressed red fluorescence. The percentage of blastocysts expressing red fluorescence was 94.6% (35/37). These results demonstrate that it is possible to obtain cloned blastocysts at a high rate by nuclear transfer of cells that have been transfected with huKO using a retroviral vector, and that it is possible to observe the expression of red fluorescence in cloned embryos. With respect to the cloned embryos that did not show expression of red fluorescence, we hypothesize that this was the result of a small proportion (<1%) of donor cells which also lacked red fluorescence expression. An ultrasonic echo examination has confirmed that all 3 of the recipients which had received 93 to 119 embryos became pregnant. This study was supported by PROBRAIN.

185 EMBRYONIC LOSS IN PIGS ASSOCIATED WITH OVIDUCT TRANSPLANTATION OF EARLY-STAGE EMBRYOS WITH DAMAGES IN THE ZONA PELLUCIDA

It is assumed that if porcine early-stage embryos with damages in their zonae pellucidae are transplanted to the recipient's oviduct, they may suffer from mechanical and immunological stresses by oviduct contraction and the recipient's immune response. This study aimed to examine the impact of zona pellucida damages, which might arise during nuclear transfer and intra cytoplasmic sperm injection (ICSI), on the development and survival of transplanted embryos. Cumulus-oocyte complexes were collected from ovaries obtained at a local slaughterhouse and matured in vitro in NCSU23 to prepare MII-stage oocytes. The zonae pellucidae of these oocytes were either penetrated with 8- to 10-�m square-ended microinjection pipettes or incised with 35- to 40-�m beveled enucleation pipettes. Intact oocytes were used as controls. The oocytes were electroactivated to induce parthenogenesis and transplanted to the oviducts of estrus-synchronized recipient gilts (estrus-synchronized with 1000 IU eCG and 1500 IU hCG). After 5 to 7 days, the recipient uteri were flushed with PBS supplemented with 1% fetal bovine serum (FBS) to collect embryos, and their development (morula-blastocyst stage embryos/collected embryos) and survival (viable embryos/collected embryos) were determined. In total, 221 zona-penetrated, 129 zona-incised, and 57 intact embryos were transplanted to four, two and two gilts, respectively. The efficiency of embryo recovery was similar in all groups (59.0 to 81.8%). However, the zona-penetrated and zona-incised embryos showed inconsistent development and survival compared with controls; the development and survival rate were 92.6% (25/27) to 96.7% (29/30) and 77.8% (21/27) to 96.7% (29/30) in control embryos, respectively, whereas those of zona-penetrated embryos were 57.1% (28/49) to 95.7% (22/23) and 8.2% (4/49) to 78.3% (18/30), and those of zona-incised embryos were 47.6% (30/63) to 92.3% (36/39) and 23.8% (15/63) to 92.3% (22/23), respectively. Large foci of cells that appeared to be macrophage giant cells were observed at the surface or inside of the degenerated zona-damaged embryos. These results indicate that the recipient's immune response may impair development after transplantation of the embryo to the oviduct, when there is damage in the zona pellucida. This may be one of the factors attributable to the reduced efficiency of live progeny production by ICSI and nuclear transfer. This work was supported by PROBRAIN.

98 SUCCESSFUL PREGNANCIES FOLLOWING TRANSFER OF VITRIFIED PORCINE EMBRYOS DERIVED FROM IN VITRO-MATURED OOCYTES

To date only in vivo-produced embryos have successfully produced live piglets after cryopreservation. In this study, we aimed to produce piglets from vitrified embryos derived from in vitro matured (IVM) oocytes. Cumulus-oocyte complexes collected from ovaries obtained at a local slaughterhouse were matured for 44 to 45 h in NCSU23 MEDIUM supplemented with 0.6 mM cysteine, 10 ng/mL epidermal growth factor, 10% (v/v) porcine follicular fluid, 75 �g/mL potassium penicillin G, 50 �g/mL streptomycin sulfate, and 10 IU/mL eCG/ hCG. These IVM oocytes were either activated for parthenogenesis or in vitro-fertilized (IVF). For IVF, oocytes were incubated with 5 � 106/mL of cryopreserved epididymal sperm in PGM-tac medium (Yoshioka et al. 2003 Biol. Reprod. 69, 2092-2099) for 20 h. Embryos were treated for removal of cytoplasmic lipid droplets (delipation; Nagashima et al. 1995 Nature 374, 416) at the 4- to 8-cell stages, around 50 to 54 h after activation or insemination. After culture in NCSU23 for 15 h, they were vitrified by the minimum volume cooling (MVC) method. Embryos were equilibrated with equilibration solution containing 7.5% (v/v) ethylene glycol (EG), 7.5% (v/v) dimethylsulfoxide (DMSO), and 20% (v/v) calf serum for 4 min, followed by exposure to vitrification solution containing 15% EG, 15% DMSO, 0.5 M sucrose, and 20% calf serum. Embryos were then loaded onto a Cryotop (Kitazato Supply Co., Tokyo, Japan) and immediately plunged into liquid nitrogen. Vitrified embryos were examined for viability in vitro and in vivo after warming. Their in vitro developmental competence was compared to that of corresponding control (nonvitrified) embryos. Vitrified 4- to 8-cell stage embryos, both parthenogenetic and IVF, showed developmental competence into blastocysts comparable to that of control embryos (parthenogenetic: 46.8%, 36/77 vs. 51.7%, 31/60; IVF: 40.0%, 30/75 vs. 44.3%, 35/79). Of four surrogate gilts that received a total of 251 vitrified parthenogenetic embryos, three became pregnant and had 20 fetuses (8.0%, 22 to 23 days old). Three surrogates gilts that received 267 vitrified IVF embryos all became pregnant. Of those, the one that received 47 embryos was confirmed to have eight fetuses (17.0%, 22 days old) by autopsy. The other two were examined by ultrasonography at 56 and 95 days of gestation and found to be pregnant. These results suggest that porcine embryos derived from IVM oocytes have a potential to develop into live offspring after delipation and MVC vitrification. This study was supported by PROBRAIN.

380 COMPARISON OF TRANSGENE EXPRESSIONS BY ICSI AND PRONUCLEAR MICROINJECTION IN MURINE AND PORCINE EMBRYOS

Intracytoplasmic sperm injection (ICSI) of DNA-binding sperm produces transgenic offspring as effectively as pronuclear microinjection (PNM). A significant difference in these two methods is that DNA is introduced into MII oocytes during ICSI, which is likely to allow earlier gene integration compared to PNM. This leads us to hypothesize that ICSI reduces the chance of development of a mosaic embryo, a mixture of transgene-positive and -negative cells. To test this hypothesis, we compared expression patterns of the green flourescent protein (GFP) gene introduced by ICSI and PNM into murine and porcine oocytes. For ICSI, 2 to 5 × 105/μL of sperm frozen-thawed in CZB (for mice) or NIM (for pigs) were co-incubated with 2.5 ng/μL of transgene fragments (CAG-EGFP; 3 kb) for 5 min. Murine sperm were microinjected into in vivo-matured oocytes, and porcine sperm into in vitro-matured oocytes. PNM was performed by microinjection of several picoliters of the transgene fragments (10 ng/μL) into pronuclei of in vivo-fertilized oocytes for mice and in vitro-matured and -fertilized oocytes for pigs. ICSI and PNM embryos were cultured in vitro to the morula stage and treated with 0.5% pronase to remove the zona pellucida. These morulae were disassembled into individual blastomeres by pipetting into PBS containing 100 μM EDTA and examined for GFP expression under fluorescence microscopy. As shown in Table 1, the rate of mosaicism in GFP-expressing embryos was significantly lower for ICSI than for PNM (P < 0.01). In addition, GFP-expressing ICSI embryos were likely to contain high percentages, 81 to 100%, of GFP-positive cells, whereas GFP-expressing PNM embryos were significantly less likely to contain such high percentages of GFP-positive cells (P < 0.01). From these results, we conclude that transgenesis by ICSI was less likely to produce mosaic embryos, and that produced transgenic embryos contained higher proportions of transgene-positive cells, although genomic integration remains to be determined. Table 1. Transgene expression by ICSI and pronuclear microinjection in murine and porcine embryos This work was supported by PROBRAIN.

50 PRODUCTION OF THIRD-GENERATION CLONES OF A PIG BY SOMATIC CELL NUCLEAR TRANSFER

There has been a dominant view that serial cloning, i.e., cloning of a cloned animal, is only possible for a few generations. In this study, we examined the reproduction efficiency and normality of porcine offspring generated by serial somatic cell cloning. Salivary gland progenitor (SGP) cells were collected from a 4-month-old female cloned Landrace large white Duroc (LWD) pig (first generation, G1), which had been cloned from a fibroblast, and used as nuclear donors for second-generation clones (G2). The third generation of clones (G3) was produced by nuclear transfer using SGP cells from the G2 clones. Nuclear transfer was carried out by electric cell fusion using in vitro matured oocytes as recipients. Reconstructed embryos were electroactivated 1 to 1.5 hr after nuclear transfer, cultured for 1 to 2 days, and transplanted to the oviducts of estrus-synchronized surrogate gilts. A total of 391 embryos cloned from G1 animals were transplanted to three surrogates. All of the surrogates became pregnant and gave birth to a total of 13 (3.3%) of G2 clones (including two stillbirths). The average birth weight and size of eleven live piglets were 1203.6 � 113.5 g and 27.1 � 1.2 cm, both within the standard ranges of the original donor strain (LWD). Their growths until 8 months old were comparable to those of normal piglets of the same strain. For the generation of G3 clones, transplantation of 242 G2-derived embryos to two surrogate gilts resulted in one pregnant surrogate and three G3 clones (1.2%; average weight 1196.7 � 267.1 g and average size 35.7 � 2.3 cm), including a stillbirth. These results indicate that porcine serial cloning can efficiently generate up to three generations of apparently healthy clones, when SGP cells are used as nuclear donors. This study was supported by PROBRAIN.

42 PRODUCTION OF CLONED PIGS FROM SOMATIC STEM CELLS DERIVED FROM SALIVARY GLAND

The aim of the present study was to investigate whether a somatic stem cell derived from the salivary gland can be an efficient donor cell for pig cloning. Somatic stem cells (salivary gland progenitor cells, SGP) were isolated from the salivary gland of a 4-month old male pig (Matsumoto et al. 2004). Briefly, tissue sections of salivary gland were gently digested by collagenase/hyaluronidase and dispersed into single cells. Isolated cells (5 × 104) were cultured on a type I collagen-coated dish in William's medium E; then colonies having epithelial-like morphology were picked to establish the primary culture of SGP cells (CD49, intracellular laminin-positive) which have the potential to differentiate in vitro into hepatic and pancreatic endocrine cells after spherical body formation in vitro. SGP cells to be used as nuclear donors were cultured for 2 days under serum starvation. Fetal fibroblast (FF) cells were used as control nuclear donors. IVM oocytes were obtained from abattoir ovaries and matured in NCSU23. Donor cells were fused with the enucleated recipient oocytes by a single DC pulse of 190 V/mm for 10 μs in 0.28 M mannitol + 0.15 mM MgSO4. Reconstructed embryos were electrically activated by DC pulse of 150 V/mm for 100 μs in 0.28 M mannitol + 0.05 mM CaCl2 + 0.1 mM MgSO4 at 1–1.5 h after the NT, followed by cytochalasin B treatment for 3 h. Development of the NT embryos was assessed in vitro by fixing and staining at either 2 h post NT or after culture for 7 days in NCSU23, or in vivo by transfer to the oviducts of estrus-synchronized recipient gilts. Incidence of premature chromosome condensation was similar regardless of donor cell type. Development of the NT embryos reconstructed with SGP to the blastocyst stage was significantly higher compared to that of the FF group (38/137, 27.7% vs. 19/168, 11.3%, respectively; P < 0.05). Transfer of 278 cloned embryos reconstructed with SGP to two recipients resulted in the production of three live piglets. Production efficiency of piglets from the cloned embryos reconstructed with FF was 2/263. Based on the in vitro development of the reconstructed embryos, SGP is a promising nuclear donor cell for pig cloning; further transfer experiments are to be carried out. This study was supported by PROBRAIN.

69 PRODUCTION OF CLONED PIGS BY NUCLEAR TRANSFER OF PREADIPOCYTES

Since the first success in producing cloned pigs, donor cells have been limited to fetal fibroblasts and a few other cell types. The aim of the present study was to determine if porcine preadipocytes can be efficient donor cells for somatic cell nuclear transfer (NT) in pigs. Preadipocytes established from subcutaneous adipose tissue of a male adult pig were used as nuclear donor cells. Cell cycle synchronization was carried out by serum starvation (5 days), confluency (5 days), roscovitine treatment (15 μM, 2 days), or differentiation induction by 0.5 mM 3-Isobutyl-1-methylxanthine, 0.25 μM dexamethasone, and 5 μg/mL insulin (5 days). Cell cycle synchronization and apoptosis of the donor cells were examined by flow cytometry and Annexin V staining and TUNEL. IVM oocytes were obtained from abattoir ovaries and matured in NCSU23. Donor cells were fused with the enucleated recipient oocytes by a single DC pulse of 200 V/mm for 10 μs in 0.28 M mannitol + 0.15 mM MgSO4. Reconstructed embryos were electrically activated at 1–1.5 h after the NT, followed by cytochalasin B treatment for 3 h. Development of the NT embryos was assessed by fixation/staining at 3 h after NT, culture for 7 days in NCSU23, and transfer to the oviducts of estrus-synchronized recipient gilts. The cells immediately entered the G0 phase by differentiation induction (92.5 ± 0.4%), with higher efficiency of synchronization than for the other methods (roscovitine: 80.3 ± 0.2%; confluency: 79.9 ± 0.3%, P < 0.05) except for serum starvation (89.8 ± 0.6%). The proportion of apoptotic cells in the differentiation group was significantly lower than the other groups (Annexin V: 7.7% vs. 15.7 to 19.3%, TUNEL: 8.3% vs. 12.8 to 14.0%, P < 0.05). Incidence of premature chromosome condensation following NT (88.0%) was as high as that observed after NT with fetal fibroblasts previously (data not shown). In vitro developmental rates of the NT embryos did not differ significantly among the cell cycle synchronization methods of the donor cells (7.2 to 10.8%). Cell number of the blastocysts was highest in the differentiation group (49.0 vs. 30.2 to 41.9, P < 0.05). Transfer of 1004 cloned embryos of the serum starvation group to 5 recipients resulted in the production of 4 live and 1 stillborn piglets from 1 recipient. Transfer of cloned embryos reconstructed of donor cells treated by differentiation induction is currently underway. These data demonstrate that preadipocytes collected from an adult pig are promising nuclear donor cells for pig cloning. This study was supported by PROBRAIN.