Lately, CRISPR-Cas9 has become one of the most essential tools to understand gene’s function. In the honeybee, however, the application of CRISPR technology has been hindered by various factors leading to very few reports of success in genome editing. Among these, collection of honeybee embryos for microinjection has been a time-consuming procedure, mainly limiting the applicability of the genome editing technique to honeybees. To improve the drawbacks of the conventional plastic plug-based system, we have developed a film-assisted honeybee embryo collection system (FECS) using transparent film as a detachable bottom layer. In this new system, eggs are laid on the detachable film surface and collected in a batch, and thus no additional alignment is required for microinjectoin. As the film can be easily replaced with in a few seconds, embryo collection can be repeated continuously after a single caging of a queen. Also, unlike conventional plug-based systems, the new system utilizes 100% of the eggs laid by the queen, thereby increases the yield three times in theory. The main unit of the system can be printed with ordinary SLA/DLP type 3D printer and the stl file for 3D printing will be distributed online.

Embryo transfer (ET) could be a relevant tool for genetic improvement programs in horses similar to those already underway in other species and produce multiple foals from the same mare in one breeding season. However, there have been no reports describing equine embryo transfer performed in Korea. In the present study, we performed an equine embryo collection and transfer procedure for the first time. We examined the embryo collection and pregnancy, size of embryo during the incubation period after collection, and progesterone (P4) and estradiol-17ß (E2) concentrations in mare’s serum at embryo collection and transfer. A total of 16 donors responded to estrus synchronization; estrus was induced in 12 donors and 4 recipients, and artificial insemination was successful in 10 donors and six blastocysts were collected from donors. Of these blastocysts, we monitored the size of blastocysts for 3 day during incubation and transferred 2 blastocysts to a recipient, with 1 successful pregnancy and foal achieved. The dimensions of equine embryo at day 7 to day 9 were 409 μm, 814 μm and 1,200 μm. The serum P4 and E2 concentrations were 7.91±0.37 ng/μL and 45.45±12.65 ng/μL in the donor mare, and 16.06±3.27 ng/μL and 49.13±10.09 ng/μL in the recipient mare.

Embryo transfer (ET) has been applied to many species, which also useful tools for genetic improvement in horses. ET enables to produce a multiple foals from one donor mare in the same breeding season. However, there have been no reports describing equine embryo transfer performed in Korea. In the present study, we performed an equine embryo collection and transfer procedure for the first time. We examined the embryo collection and pregnancy, size of embryo during the incubation period after collection, and progesterone (P4) and estradiol-17ß (E2) concentrations in mare’s serum at embryo collection and transfer. A total of 16 donors responded to estrus synchronization; estrus was induced in 12 donors and 4 recipients, and artificial insemination was successful in 10 donors and six blastocysts were collected from donors. Of these blastocysts, we monitored the size of blastocysts for 3 day during incubation and transferred 2 blastocysts to a recipient, with 1 successful pregnancy and foal achieved. The dimensions of equine embryo at day 7 to day 9 were 409 μm, 814 μm and 1,200 μm. The serum P4 and E2 concentrations were 7.91±0.37 ng/μL and 45.45±12.65 ng/μL in the donor mare, and 16.06±3.27 ng/μL and 49.13±10.09 ng/μL in the recipient mare.

This study was performed in order to determine optimum flushing solution using the direct embryo collection (DEC). Donors, at random stages of the estrous cycle, received a CIDR. 7 days later, 200 mg FSH was treated with 40, 30, 20, 10 mg FSH levels in declining doses twice daily by intramuscular injection for 4 days. On the 3 day administration of FSH, 25 mg was administered and CIDR was withdrawn. After FSH injections were complete, donors were artificially inseminated twice at 12 hr intervals. The donor cattle received 250 GnRH at time of 1 insemination and embryos were recovered 8 days after the 1 insemination. Embryo collection from superovulated donors were performed to flushing by DEC and conventional method. As a results, the average number of recovered embryos were significantly higher as 19.11.40 with DEC method than 12.00.44 with conventional embryo collection method, respectively (p<0.05). Also, The average number of transferable embryos were significantly higher (p<0.05) as 15.81.72 with DEC method than 6.90.35 from conventional embryo recovery procedures. Meanwhile, number of recovered embryos and number of recovered transferable embryos following the number of flushing times until 6 flushing were significantly higher as 8.60.53 and 8.60.53 from 2 flushing time than other groups (p<0.05). No. of Ear. B stage embryos were significantly higher as 3.90.90 and 3.90.90 with 2 flushing time in total collected embryos and transferable embryos (p<0.05). Com M stage embryos were significantly higher as 3.71.00 in 2 flushing time and as 2.20.76 in 3 flushing time for recovered embryos (p<0.05). In transferable embryos, Com. M stage embryos were significantly higher (p<0.05) as 3.71.00 in 2 flushing time and as 2.20.76 in 34 flushing time, also. No. of degradation embryos was significantly higher as 2.20.72 in 5 flushing time, On the other hand, degradation embryos was not observed in transferable embryos (p<0.05). In conclusion, these results suggest that DEC method should effective methods for production of in vivo embryos using less flushing solution following perform until 4 flushing time than conventional embryo collecting method. Also, it might be effectively collection of transferable embryos following more less procedure times compared to conventional embryo recovery methods.

This study was performed in order to simplify the operation and minimize stress of donor and be readily available in the field with low cost and high quality embryos using the Direct Embryo Collection (DEC). Donors, at random stages of the estrous cycle, received a CIDR. 7 days later, 200 mg FSH was treated with 40, 30, 20, 10 mg FSH levels in declining doses twice daily by intramuscular injection for 4 days. On the 3rd day administration of FSH, 25 mg was administered and CIDR was withdrawn. After FSH injections were complete, donors were artificially inseminated twice at 12 hr intervals. The donor cattle received 250 GnRH at time of 1 st insemination and embryos were recovered 8 days after the 1st insemination. Embryo collection from superovulated donors was performed to flushing by non-surgical methods of 3-way, 2-way and DEC (l-way). The average number of recovered embryos were 11.250.63, 12.50.65 and 11.750.48 from operations of 3-way, 2-way and DEC methods, respectively. There were no significant differences among the embryo collection methods. Also, The average number of transferable embryos were 6.250.48, 7.250.48 and 7.250.63 from each embryo collection procedures. The number of transferable embryos was no differences among the 3-way, 2-way and DEC methods, respectively. Meanwhile, the ratio of transferable embryos for all recovered embryos from DEC methods was higher as 61.7 % than 55.6 %, 58 % from methods of 3-way, 2-way. And the flushing solution required for recovering embryos by DEC method was significantly lower as 0.280.32 1 than 1.80.12 1, 1.750.10 1 from 3-way, 2-way methods (p<0.05). Also, the time required for recovering embryos by DEC methods was significantly lower as 272 min than 513, 452 min, respectively (p<0.05). In conclusion, these results suggest that DEC method for embryo collection may be effectively used for production of in vivo embryos using less flushing solution and, it might be effectively available in the field compared to conventional embryo recovery methods using 3-way or 2-way balloon catheter.

도축장에서 회수한 한우 난소로부터 난자를 회수하기 위한 방법으로 흡입법 후 세절법과 흡입법으로 난자를 회수하여, 난자의 회수율과 채란된 난자를 체외수정 후 발달율과 수정란 이식 후 수태율에 영향을 조사한 결과는 다음과 같다. 1. 난자 회수율은 각 난소당 회수된 난자수는 흡입 후 세절법이 8.2개, 흡입법이 6.5개로서 흡입 후 세절법을 병용하는 것이 난자 회수율에서 유의적으로 많았다. 2. 채란방법에 따른 체외수정란의 분할율은 흡입 후 세절법이 , 흡

본 연구는 고능력 한우 공란우의 이용효율을 극대화하기 위하여 반복 과배란처리가 수정란회수율에 미치는 영향을 알아보고자 수행하였다 공란우의 선발은 DNA marker에 의한 고급육을 선발하였다. 선발된 공란우는 Folltropin-V와 PG를 병용 처리하여 과배란을 유도하였고, FSH 처리 6회째 PG를 처리하여 발정을 유도하였다. 발정유도된 공란우의 수정은 12시간 간격으로 3회, 1회당 2 straw식 인공수정을 실시하였다. 수정 후 7~8일째 비외과

본 연구는 고품질육의 DNA marker가 규떵된 한우로부터 초음파유노 난포란의 연속적 채취를 통하여 능력이 우수한 한우 수정란온 대량생산하는 방법의 확립과 이를 한우농가에 응용하고자 초음파 난자채취기를 이용하여 등지방층두께, 일당증체량, 근내지방도 및배최장근 단면적에 연관된 DNA marker를 보유하고 있는 한우 5두로부터 개체및 난포수, 채취방법, 회수한 난포란의 등급 등을 조사하였다. 한우 5두의 개체별 난포수는 6, 10, 5, 4 및 11회

This experiment was carried out to study the behavior of the estrus cycle in sows shortened uterine horns and to see whether the embryos could be recovered nonsurgically. The uteri of sows(n=4) were surgically shortened. It took about 3 hours to surgically remove the middle section of both uterine horns. The lengths of the shortened uterine horns were 18.7 to 29.5cm. After treatment, two sows exhibited natural estrus and the intevals from surgery to estrus were 8 days and 15 days, respectively. But the sows were not successful on synchronization and superovulation with PMSG and PGF. In the resurgery for confirmative examination, the sows had 6 and 7 corpus lutelin in ovaries, respectively. One sow had a small adhesion between the infundibulum and ovary, and the other sow had unilateral uterine obstruction at the sutured position and purulent materials in the uterus.

The aims of this study are 1) to test oocytes and embryos collected from in-vivo and in-vitro to achieving the valuable protocol by culturing, vitrifying and thawing of oocytes/embryos, and 2) to transfer them to recipient, and finally have resulted in pregnancies from recipient females after surgical or nonsurgical transfer. In vitro maturation and fertilization were performed according to the procedures of Funahashi et al. Fertilized oocytes were cultured in glucose-free NCSU 23 supplemented with 5 mM sodium pyruvate, 0.5 mM sodium lactate and 4 mg/ml bovine serum albumin for 2 days at 39, and 10% fetal bovine serum was added to the culture medium thereafter. Embryos were treated with 7.5g/ml cytochalasin-B for 30 min, centrifuged at 13,000 g for 13 min and then exposed sequentially to an ethylene glycol (EG) vitrification solution, aspirated into OPSs, and plunged/thawed into/from liquid nitrogen. In vivo embryos were surgically collected from three donors after Al. Forty-six embryos (18, 9 and 19 embryos, respectively) were washed 3 times in mPBS+10%FBS, followed treatments : cultured, centrifuged, vitrified, recovered and transferred to recipients as in vitro prepared embryos. Three recipients received surgically 34(control), 188 and 184 embryos (derived from abattoir), respectively. Another three recipients were received nonsurgically 150, 100 and 150 embryos, respectively. All recipient sows exhibited delayed returns to estrus. To our knowledge, these results suggest that required an improved techniques, more vigorous embryos preparation and cleaner uterous condition(use gilt).