Embryos produced with serum show the alterations in their ultrastructure, impaired compaction, abnormal blastulation, aberrant mRNA expression profiles and large calf syndrome with greater incidences of stillbirths and deaths after birth. The aim of the present study was to describe in vitro embryo production by analyzing embryo production, fetal production and pregnancy rate in free-serum medium. The OPU-IVP data used in this study from 2016. Approximately, sixteen cows (Hanwoo), which belonged to the Institute of Gyeongsang National University, were used. Two experimental group is used in this study. Serum groups were conducted in March to July and free-serum group was conducted in September to December. The recovered cumulus-oocyte complexes were morphologically classified to four grades based on the compaction of cumulus cells layers and homogeneity of the cytoplasm. The number of oocyte was significantly greater in serum groups than that in free-serum groups (29.61 ± 0.63 vs. 15.6 ± 0.62; p < 0.05). Between serum and free-serum groups indicate that average of 1st and 2nd grade oocytes were no difference (2.38 ± 1.67 vs. 2.38 ± 1.48; p > 0.05), but number of 3rd and 4th grade oocytes were greater in serum groups than that in free-serum groups (7.31 ± 7.64 vs. 5.60 ± 6.29; p < 0.05). Embryo cleaved competence was higher in rate in free-serum groups than that in serum groups (62.1% vs. 58.3; p < 0.05). However, blastocyst developmental rate was no difference between serum and free-serum groups (33.1% vs. 43.5%; p < 0.05). 986 recipients were used for embryo transfer. Pregnancy rate was indicated that between serum and free-serum group was no difference (54.6% vs. 56.3%; p < 0.05). In conclusion, we developed the free-serum system for production of in vitro bovine embryos in order to meet the developmental and qualitative requirements for large scale commercial use.

This study was conducted to examine the oocyte recovery efficiency through having an OPU session once and twice a week. Also, the oocyte recovery efficiency was examined by using OPU after two and three months of rest period. Six cows were used for oocytes collection and were randomly divided into two groups. In experiment 1, OPU sessions were conducted once and twice a week to collect oocytes. The collected oocytes between once and twice OPU groups were classified into four groups (grade 1, 2, 3 and 4) according to the quality of cumulus cells and ooplasm. Based on the result, the percentage of collected oocytes per aspirated follicle number was similar between once and twice OPU session groups (65.5 ± 1.9 and 68.7 ± 1.4 vs.). However, the percentage of grade 1 oocytes from the twice OPU session group was significantly high compared with that of the once a week OPU session group (25.3 ± 0.9 and 32.5 ± 1.2% vs. once and twice session group, respectively, p < 0.05). In experiment 2, the group with three months of rest period tended to have a high percentage of collected oocyte compared with the group with two months of rest period (64.6 and 70.9% vs. 2 and 3 months rest group, respectively, p = 0.62). The percentage of grade 4 in the group with three months of rest period was significantly low compared with the group with two months of rest period group (27.3 and 36.5% vs. two and three months rest group, respectively, p = 0.05). In conclusion, twice a week OPU session is suitable for collection of high quality oocytes by using OPU, and three months of rest period is needed for the recovery of oocyte quality of a donor cow.

Up-to-date artificial insemination (AI) using frozen sperm consider as the most widely using technology for improvement of Korean Native Cow (Hanwoo) embryo production. However, it is time consuming, required at least 15~20 years to make more than 6 generations, and their offspring number is limited. To overcome such limitations, superovulation and in vitro fertilization have been developed. For superovulation, the number of produced embryos are not enough for commercialization and donor cows need rest period. This led to use of slaughterhouse ovary for in vitro fertilization, but it is impossible to repeat the collection from the same individual and it only can improve the genetic merits of offspring for one generation. Production of embryos using Ovum Pick-Up (OPU) technique, where oocytes can be repeatedly collected from living elite donor, might overcome these limitations. In this study, we investigated the possibility of using OPU technique from donors at different age and different session periods for mass-embryo-production. Oocytes were collected from 26 donor cows twice per week, 3 - 4 months per year, between 2013 and 2016. Results showed that, the average number of embryo produced in first year used donor was significantly higher than that in second year used donor (3.89 ± 2.85 vs 3.29 ± 2.70), however, there was no significant difference between third year used donor (3.51 ± 3.32) and other groups. Taken together, our data showed that repeated using of donor up to three years is possible for in vitro embryo mass-production. Moreover, OPU can be used as suitable embryo producing technique for livestock breed improvement.

The ovum pick up(OPU) technique can be used to produce embryos after in vitro culture of ovarian oocytes, can be used for early securement for effective herd early proliferation and excellent Hanwoo genetic resources, It is attracting attention as a very important technique for establishing technology. In addition to in vitro culture techniques, the number of oocytes retrieved depends on the environment and timing of the OPU. This study was conducted to compare and examine seasonal effect to the differences in the number of recovered oocytes, recovery rate and embryo development rate using Korean cattle kept in animal genetic resource research center by OPU technique. The grade of COCs was evaluated by microscopic examination. Grade A had 3 or more layers of cumulus cell and compact cytoplasm. Grade B had 1~3 layers of cumulus cell and compact cytoplasm. Grade C had 1 layers cumulus cell and compact cytoplasm. Grade D was denuded oocyte and poor cytoplasm. The recovery rate was 47.8±3.4% in summer (June to August) and 51.6±3.8% in autumn (September to October). The number of oocytes was 5.7±0.6 in summer and 5.2±0.7 in autumn. Oocyte grade A and B was 46.2%±6.3% in summer and 51.1±5.0% in autumn. The cleavage rate was 46.1±7.1% in summer and 65.0±11.3% in autumn. Blastocyst development rate was 19.9±9.4% in summer and 29.0±8.7% in autumn. There was no difference the recovery rate of oocytes and the number of embryos between summer and autumn. Cleavage rate and blastocyst rate of autumn was higher than summer. we will investigate to study the appropriate method for the production of Hanwoo embryos and the systematic comparison.

현재까지 한우개량을 위해 가장 보편적으로 활용되고 있는 기술은 웅성 유전자원의 동결용 정액을 활용하는 인공수정기술로서 개량에 최소 6 세대 이상 즉, 암송아지만을 생산한다는 가정에서 15~20 년 이상의 시간이 소요될 뿐만 아니라 생산되는 산자 수 또한 한정적이다. 가축개량 효율을 높이기 위해 수정란이식 기술이 개발되었으며, 호르몬 투여에 의한 과배란 유래 체내 수정란 및 체외 수정란 생산 방법이 개발되어 활용되어 왔다. 체내 수정란 생산방법은 혈통관리는 정확하나 수정란 생산을 위해 호르몬 과다 투여에 의한 휴식기간 등이 필요하며 수정란의 생산량의 한계로 산업화 적용에 비효율적이고, 근래에 체외수정란을 활용되면서 도축 유래 수정란을 활용하는 경향이 있으나 친자 검정의 한계로 인한 친자 불일치 및 고도근친 위험성 등이 상존하고 있다. 이러한 문제를 극복하고 효율적인 이식 가능한 수정란의 생산이 가능한 OPU 유래 수정란 생산기술은 살아있는 공란우에서 난자를 채취하여 체외수정란을 생산함으로써 혈통관리가 정확하고 우수유전 자원을 선발 활용함으로써 계획 교배에 의한 근친도와 개량의 폭을 예측할 수 있는 장점이 있다. 또한 수정란의 생산 가능 량은 3~4 개월에 약 60 여 개의 이식 가능한 수정란을 대량 생산으로 산업화에 적합한 수정란 생산기술이다. 본 연구에서는 선발된 공란우의 반복 사용으로 우수 유전자원의 수정란을 대량생산에 활용하기 위해서 2013-2016 년까지 매년 3-4 개월 동안 주 2 회 채란 및 수정란을 생산하였고 채란 완료 후 일정 기간의 휴식한 다음 다시 채란에 활용으로 2 회 이상 수정란 생산으로 수정란의 반복 생산 가능성 및 생산 효율에 대하여 조사하였다. 2 반복의 공란우는 총 24 두와 3 반복은 7 두를 3-4 개월 동안/년 매주 2 회 총 1,626 회 채란으로 평균 3.6±2.9 개의 수정란이 생산되었다. 특히 채란 시 생산된 수정란은 채란 횟수당 1 회 반복에서 3.9±2.8 개, 2 회 반복은 3.3±2.7 개 및 3 회 반복은 3.5±3.3 개로 확인되었고, 3 회 이상의 반복 채란된 개체 7 두를 분석한 결과 1 회 반복 채란에서 평균 3.63±2.79 개, 2 회 반복은 평균 3.70±2.84 개 및 3 회 반복은 년 3.51±3.32 개로 반복 채란에 수정란 생산에 활용하였으며 반복 채란에 의한 수정란의 생산효율에는 유의적인 차이를 보이지 않았다. 따라서 가축개량을 위해 산업화에 가장 적합한 수정란 생산방법으로 유전능력이 우수한 한우에서 대량의 수정란을 생산하여 우량한우 집단구축을 위하여 약 3-4 개월 동안 매주 2 회 수정란을 생산하고 일정기간을 휴식한 다음 공란우로써 재활용 가능성을 확인하였고 또한 OPU 유래 수정란 생산방법은 우수한 유전자원을 보유한 개체를 연속적이며 반복적으로 활용할 수 있는 가능성을 확인하였다

한우의 암소 개량을 목적으로 다양한 번식우의 활용 기술이 개발되어 오고 있다. 특히 수정란 을 이용한 개량 연구 중 생체난포란 (ovum pick-up, OPU) 방법은 체내수정란 생산을 위한 과배 란처리 방법 보다 공란우의 활용성을 높이기 위해서 사용되고 있는 기법이다. 따라서 본 연구에 서는 한우의 생체에서 난포란의 채란의 효율성에 관한 연구를 수행하였다. 생체난포란 채란을 위한 한우 공란우는 한우연구소에서 사육중인 한우에서 실시하였다. 생체 내 난포란의 관찰은 MyLabTM30VETGOLD (Esaote, Genova, ITALY) 및 탐촉자 (EC123; Micro-Convex 9∼3 MHz, Esaote, Genova, ITALY)는 6.6 MHz convex scanner를 사용하였고, 난포란 채란에 사용된 주사침은 19G 주사침을 사용하였다. 초음파상에서 2mm 이상의 난포 수량을 확인하고 난포란을 흡인하였다. 흡입된 난포란은 2∼3회 washing으로 혈액 등의 이물질을 제거하여 실체현미경 하에서 회수하였 고, 난포란의 등급분류는 세포질 균일도와 난구세포의 부착 정도에 따라 평가기준을 1등급에서 3 등급까지 분류하였다. 체외발달을 유도하기 위해서 회수된 난포란의 체외성숙배양은 TCM 199 기 본배양액에 소 태아혈청 (Fetal Bovine Serum) 0.5%와 LH, FSH, FGF, EGF 첨가하여 22시간 동안 배양하였고, 체외수정은 IVF 100 (IFP, Japan) 배양액 50μl 미소적에 성숙 난포란 20개씩 넣어서 체 외수정을 실시하였다. 체외수정을 위해서 KPN 동결정액을 사용하였고 수정을 위한 정자의 최종 농도는 2x106/ml로 6시간 동안 체외수정을 유도하였다. 체외발달유도는 SOF 배양액으로 5% O2, 5% CO2, 그리고 90% N2 와 38.5°C 인큐베이터에서 8일째 까지 배양하였다. 4두의 공란우로부터 개체당 8session 을 실시하였다. 개체별 회수효율은 평균 6.6±1.30, 7.5±2.20, 6.13±1.13, 4.9±1.36개의 결과를 보였다. 평균 1등급 43개, 2등급 9.5개, 3등급4.8개로 나타났다. 회수된 난자의 체외발달율 에서 분할율은 68.8%, 배반포 발생율은 28.4%의 결과를 보였다. 따라서 본 연구 결과로 미루어 볼 때 사료급여 방법에 따른 연구도 병행하여 추진해야 할 것으로 사료된다.

The OPU technology has been largely used in order to enhance genetic improvement in domestic animals. This study demonstrated that OPU in Hanwoo can be used for the effective technique to improve the reproductive efficiency. This experiment showed the longest times of OPU ever carried out in Hanwoo. In this study four donors were selected from Hanwoo by using DNA extraction and SNP maker. Individual donors have genes which are CAPN1, CAST and FASN and that contain dominant position. CAPN1, CAST genes are often thought to be related with tenderness and FASN gene is thought to be associated with oleic acid which is identified a monounsaturated fatty acid found naturally in many plant and animal products. In experiment 1, OPU technique was used to evaluate the influence of the number of oocytes recovery rate per session. Totally 50 times OPU sessions were performed and oocytes recovery at every 10 times session was evaluated. In case of H4, the OPU session could be done around 30 times after her calving. Compared to the average number of oocytes recovery, H1 was more efficient than H3. Considering this results, the current study showed that animals have considerable individual variation in numbers of oocytes. In this study, the average recovery rate in Hanwoo is similar to the recovery rate of the Bos Taurus. Individual donors have no significant difference among group for recovery rate during 30 sessions. However, Thoese showed significant decrease in the number of oocytes recovery rate after 40 session of OPU treatment. Therefore we conclude that the Hanwoo donor is considered to be suitable for 30 times of OPU treatment. In experiment 2, OPU technique was used to evaluate the influence of the number of recovery rate monthly. The average number of oocytes recovery rate showed no significantly difference for five months. However, the number of oocytes recovery rate decreased significantly during three months after first five months experiments. In experiment 3, whether donors are parity or non-parity, the average number of oocytes recovery rate was checked. However, we could not find any significant result from this experiment. In experiment 4, the developmental rate of in vitro produced embryos from OPU was compared with that from slaughterhouse. From this, cleavage rate of oocytes from OPU is significantly less than that from slaughterhouse. In conclusion, this study included a thorough analysis of oocytes and embryo production by OPU from Hanwoo. OPU can be successfully performed under a continuous regime for 8 month in Hanwoo. The current study shows the clear proof that OPU could be adopted to produce oocytes and embryos of better quality as an advanced technique replacing the usage of MOET in Korea. Finally, elucidation the basis for numerous oocytes obtained from Hanwoo may contribute to a better understanding of reproductive physiology in cattle.

난자생검(Ovum pick up, 이하 OPU) 기법은 유효축군 조기확보 및 우수한우 유전자 원의 조기증식, 희소유전자원 다량확보를 위해 매우 중요한 기법으로 주목받고 있다. 이 러한 OPU기술에는 체외배양기술 외에도 현장의 환경과 시기에 따라 회수되는 난자의 수 역시 중요하다. 현재, 가축센터에서는 한우의 유전자 다양성 확보를 위한 일반 한우 외에 도 희소한우 증식을 위한 연구를 진행 중에 있다. 본 연구는 OPU기법을 활용하여 가축 유전자원센터에서 보유중인 한우 또는 칡소를 대상으로 계절별 및 모색별로 난포란의 개 수와 난자회수율의 차이를 비교 · 검토하고자 실험을 진행하였다. 실험시기는 3월에서 5 월(봄), 6월에서 8월(여름), 9월부터 11월(가을)까지 구분하여 실시하였으며, 계절별 및 모 색별로 채취되는 난자의 개수와 회수율을 분석을 하였다. 봄에는 8.20±6.57, 여름에는 5.47±4.01, 가을에는 5.88±3.65개가 회수되었으며, 또한 계통별로는 가을에 실시한 결과 한 우는 6.40±6.15개, 칡소는 2.75±0.55개가 회수되었다. 그리고, 계통별로 수정란발달률은 한 우는 난할률이 25.0±44.4%, 배반포발달률이 6.3±50.0%, 칡소의 경우 난할률이 27.3±21.0%, 배반포발달률이 9.1±16.7%로 나타났다. 계절별로 OPU를 실시한 결과 여름, 가을경에 실 시하는 것에 비해서 봄에 실시를 하였을 경우 회수되는 난자의 수가 많은 것으로 확인을 하였다. 그리고, 현재 일반한우가 칡소에 비해서 회수되는 난자가 더 많은 것으로 확인되 었다. 이에 반하여 난할률 및 배반포발달률은 차이가 없는 것으로 확인되었으나, 향후 실 험진행에 따라 정확한 결과를 도출할 것으로 사료된다.

Historically, Korea old cattle had been consisted with various lines of coat color brindle, black and white-brown breeds or more. The two rare lines of black and white coat color are maintained for animal resources and preserved critically. The present study was carried out to evaluate potential usage of cysteamine supplementation during in vitro matration (IVM) and in vitro culture/production of embryo (IVP) by transvaginal ultrasound-guided follicle aspiration (Ovum Pick-Up: OPU) for the establishment of cryo-banking system. Immature slaughterhouse-derived cumulus-oocyte complexes (SL-COCs) were matured in IVM medium supplemented with 0, 0.1, 0.3 or 0.9 mM cysteamine, and then cultured in mSOF-BAS for 8 days after in vitro fertilization. The treatment of 0.1 mM cysteamine on SL-COCs showed higher rate of blastocyst, so OPU-derived COCs from rare breeds were matured in TCM media supplemented with or without 0.1 mM cysteamine, FSH and 5% FBS. The embryos were evaluated their developmental stages on day 8. During IVM, cysteamine treatment significantly increased the embryo production rate of slaughterhouse-derived COCs (19.6% vs. 30.5%). The presence of cysteamine during IVM of OPU-derived COCs from rare Korean cattle breeds (albino white and black line) also increased embryo production rates than those from SL-COCs (27.4% vs. 41.9% and 36.4%). With these results, cysteamine treatment during IVM is one of key factors IVP of blastocysts to establish banking system of endangered rare Koarean cattle with OPU derived transferable blastocysts.

This study was designed to know the possibility in repeat uses of elite donor cows for getting mass production of OPU-derived embryo production (OPU-IVP). Ultrasound transvaginal ovum pick-up (OPU) performed in 6 Korean native cows was aged 4 to 10 years old. The aspiration of immature oocytes for OPU derived embryo was carried out 2 times per week, and OPU-IVP of 1st period was carried out 22∼48 sessions from each donors. And the break time for OPU-IVP of 2nd period after 1st OPU from each donors were 2∼25 months. The OPU-IVP of 2nd period each donors conducted total 15∼65 times for 2∼8 months by an ultrasonographic, was guided follicular aspiration system. The average numbers of collected oocytes, grade 1 + grade 2(G1+G2) oocytes and cleavage embryo from 1st period OPU-IVP were significantly differences between donors (p<0.05). Total collected oocytes of donor D were significantly higher compared with donors of A, B, C, E and F (average 17.0 per session vs. 11.2, 10.1, 8.5, 10.2 and 9.6; p<0.05) and also oocytes of G1+G2 were significantly higher compared with r A and D and subsequently to donors of B, C, E and F (average 7.9 and 8.5 per session vs. 5.0, 2.7, 6.0 and 1.6; p<0.05). Cleavage rate of donor D was significantly higher compared with donors of A, B, C, E and F (average 13.1 per session vs. 10.1, 9.1, 6.9, 8.9 and 6.7; p<0.05). The average numbers of OPU-IVP for 1st period was significantly higher from donors of B, D and E than those from donors of A, C and F (average 6.5, 7.1 and 6.5 per session vs. 3.5, 4.2 and 2.8; p<0.05). The possibility investigation of 2nd OPU-IVP was carried out after 2∼25 months rest periods from 1st period OPU session. Total average numbers of collected oocytes, cleavages and blastocyst development rates were significantly higher from 1st period OPU compared with 2nd period one (p<0.05). The OPU-IVP efficiency by break for more embryo production from elite cow was analysis comparing without rest of donor A, under 6 months rest period as B and over 6 months rest period as C and then the average numbers of collected oocytes, cleavages and blastocysts were significantly higher from A group (11.8, 9.5 and 5.2 per session) than those from B and C groups (7.9, 6.2 and 2.6 vs. 9.2, 7.5 and 3.9, p<0.05), and also C group was significantly higher than B group. In conclusion, 1st period OPU-IVP was more efficient compared with 2nd period repeated uses of donor, and the break times for additional production of embryo on donor were needed more than over 6 months after 1st period OPU-IVP. This repeating uses of elite donor cows given more emphasis for getting the opportunity on mass production of elite cow OPU-IVP embryo should be increased G1+G2 possibility of genetic improvement of livestock within short period.

This study was designed to evaluate the possibility of increase through dairy female offspring’s ratio by transfer of pre-selected transferrable blastocyst that was produced by pre-selected X-bearing semen with OPU derived oocytes. Elite dairy female cow is demanded strongly compared with male, the so called, farmer wants to produce only an elite female dairy offspring as a candidate female dairy cow for producing milk. In our study, we selected 2 elite dairy bull semen from National Agricultural Cooperative Federation to pre-select X-bearing semen and 5 elite dairy female cows as donor for collecting of OPU derived oocytes. OPU derived embryo production system was carried out an aspiration of immature oocytes from 5 donor cows 2 times per week, total 200 times for 2 to 7 months by an ultrasonographic guided follicular aspiration system and then produced in vitro-produced blastocysts by in vitro maturation, fertilization and culture. Dairy donor semen selected H-319, 320 bull in National Agricultural Cooperative federation was sorted X-bearing semen by flow-cytometer and frozen for using IVF with OPU derived oocytes. Donor cows were selected 5 elite dairy cows from Gyeongju Dairy Cow Community and then disease tests such as 4 kinds of disease before selecting was checked. Oocyte proportion of grade 1 to 3 from total collected oocytes was significantly lower in donor A and B than those in donor C, D and E (82.16 and 70.03% vs. 90.0, 91.78 and 93.57%), respectively (p<0.05). However, number of oocytes per session in donor A, C and E was significantly higher than those in donor B and D (7.77 ± 3.26, 5.85 ± 2.10 and 7.03 ± 2.14 vs. 4.68 ± 2.61 and 5.21 ± 1.97 oocytes), but donor A was significantly higher than donor C (p<0.05). Development to blastocyst in donor B, C and E was significantly higher than those in donor A and D (31.0, 25.0 and 25.0% vs. 14.3 and 4.5%), but donor A was not different in donor C and E (p<0.05). Nine out of 10 blastocysts (90.0%) derived from OPU blastocysts were confirmed male embryos that was induced with Y-bearing semen to confirm sex ratio only. Total 96 blastocysts derived from female bearing semen were transferred into synchronized recipients and then confirmed 42 recipients (43.8%) pregnancy rate, 36 offspring (37.5%) and 91.7% female sex ratio (33 female vs. 3 male offspring). Taken together all data, elite dairy female offspring could be produced effectively by in vitro production system between pre-selected x-bearing semen and OPU derived oocytes that would be influential breeder in the breeding of dairy farm to increase effectively elite dairy offspring ratio as well as net income in the dairy farmer.

This study was carried out to establish the system of OPU derived embryo production, management of recipients as well as offspring production. OPU derived embryo production system was carried out of aspiration of immature oocytes 2 times per week, total 24 times for 3 months by an ultrasonographic guided follicular aspiration system and then produced in vitro-produced blastocysts by in vitro maturation, fertilization and culture system. This work was collected total 13,866 oocytes, average 8.2±4.5 oocytes per session and 8,170 G1 + G2 grade oocytes, average 4.8 oocytes per session by 1,692 times session of total 71 donors for 4 years from 2010 to 2013. The rate of cleavage and blastocyst developmental competence were obtained 11,825 (85.3%) and 5,032 (36.3%) that was 7.0±3.8 cleaved embryos and 3.0±2.5 blastocysts per session. OPU derived embryo transfer were taken place in 2, 4, 6 and 7 local governments at 2010, 2011, 2012 and 2013 for 4 years and pregnancy rate were obtained 41.2, 43.9, 46.5 and 49.7% in each years. It means that pregnancy rate was continuously improved according of every year for 4 years. Pregnancy rate was significantly different according to individual local government in which was 62.7% in B, but 24.2% in F at 2012. Paternity identification was carried out total 26 offspring in C local government of 2012 and then confirmed 100% agreement of its analysis. In conclusion, the results obtained the possibility of mass production of elite cow embryos as well as offspring by OPU derived embryo production system, of which could be decreased the required time of genetic improvement.

본 연구에서 한우를 공란우로 사용하여 OPU 방법으로 가장 더운 계절의 hot season과 선선한 cool season의 두 계절의 차이에 따른 생성된 난포의 수, 난자 회수율, 난자 등급율, 수정율 및 배반포 발달 능력을 분석하여, 두 계절이 공란우의 번식 능력에 미치는 영향에 관하여 조사하였다. 1. 계절의 영향이 OPU 공란우의 난포 생성 수에 미치는 결과는 난포 생성 개수는 1154개(18.32±2.26), 971개(15.41±3.34)로 hot season 그룹이 유의적으로 높은 것을 알 수 있었다(p＜0.05). 2. 계절에 따른 난자 수 및 난자 회수율은 hot season 그룹의 475개(7.54±3.14), 41.16%로 cool season 그룹 448개(7.11±3.42), 46.14%와 비교하여 유의적인 차이가 없었다(p＜0.05). 3. OPU를 통하여 회수된 두 계절별 난자 등급은 Grade A는 Hot season 그룹 110개(1.75±1.86), Cool season 그룹 63개(1.00±1.46)로 hot season 그룹이 cool season 그룹과 비교하여 유의적으로 높았다(p＜0.05). 하지만 다른 등급인 Grade B는 87개(1.38±1.60) vs. 97개(1.54±1.39), Grade C는 166개(2.63±2.43) vs. 170개(2.70±2.04), Grade D는 112개(1.78±2.65) vs. 118개(1.87±1.86)로 hot season과 cool season 간의 유의적인 차이를 보이지 않았다(p＜0.05). 4. 계절에 따른 체외 수정 후의 수정률은 hot season과 cool season 각각 242(66.67%)와 209(63.3%), 배반포 발달율 214(58.95%) vs. 188(56.97%)로 수정률과 배반포 발달율은 유의적인 차이가 없었다(p＜0.05). 본 연구의 결과로 계절에 따른 영향에 의해 공란우의 난포생성수와 A등급의 난자 출현율에서 유의적인 차이를 보였다. 하지만 나머지 등급의 난자 출현율, 수정률 및 배반포 발달율은 차이가 없는 것으로 보아, 계절의 차이로 인한 한우 공란우의 번식 능력에 미치는 영향은 미비하다고 판단된다.

The objective of this study was to evaluate the comparison of production efficiency of oocytes and OPU (ovum pick‐up) derived embryos of Hanwoo with Holstein. The OPU session of each species (6 cows) was carried out from the Hanwoo (106 sessions) and Holstein (114 sessions) at intervals of 3 4 days (2 times per week) for 3 months. Cumulus‐oocyte‐complexes (COCs) retrieved were classified into 4 grades by the status of oocyte cytoplasm and cumulus cells. The COCs collected were matured in vitro in TCM‐199 supplemented with 10% FBS, 10 mg/ml FSH and 1 mg/ml estradiol‐ 17β in 5% CO2 and over 99% humidity for 24 h. After 24 h co‐incubation with post‐thaw sperm, the presumed zygotes were cultured in CR1aa medium with 4 mg/ml BSA for 3 days and then changed CR1aa medium with 10% of FBS for another 3 4 days. The Mean number of aspirated follicles and collected oocytes were not significantly different between Hanwoo and Holstein spacies (10.4±0.42 vs. 11.4±0.41 and 7.5±0.38 vs. 6.1±0.37 per session). But the collection rate of oocytes from aspirated follicles were significantly higher in Hanwoo (72.8%) than that in Holstein (53.6%) (p< 0.05). Furthermore, the average number of good quality oocytes (Grade I and II) was 5.9±0.28 and 4.1±0.27 (Mean±SD), and the cleavage rate and the development rate to blastocysts was significantly (p<0.05) higher in Hanwoo (40.0%) than Holstein (21.6%). The OPU derived embryos of Hanwoo were transferred 83 times into 52 recipients and then 42 calves were produced from 44 pregnancy recipients. In conclusion, the efficiency of OPU derived embryo was significantly different between Hanwoo and Holstein species. In vitro culture system for OPU derived embryo production should be optimized for industrialization and the improvement of livestock.

본 연구는 OPU 유래 한우 수정란을 이식한 대리모의 품종이 임신 기간과 산자의 생시 체중에 미치는 영향을 분석하고자 6~7일차 OPU 유래 한우 체외수정란을 한우와 젖소 대리모에 이식하여 산자를 생산하였다. 1. 대리모에 따른 평균 임신 기간(젖소: 일, 한우: 일)과 산자의 생시 체중(젖소: , 한우: )에서 유의적인 차이가 없었다. 2. 임신 기간은 수송아지를 생산한 대리모(한우: 일, 젖소: 일)가 암송아지(한우: 일, 젖소: 일)를 임신한 대리