국립중앙도서관 "우편 복사 서비스"로 연결 됩니다.
Natural fertilization in avian species occurs in the infundibulum shortly after oocyte is ovulated. Once the ovum moves beyond the infundibulum, the secretions from magnum hinder sperm to interact with the oocyte, but intracytoplasmic sperm injection ...
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RISS 인기검색어
https://www.riss.kr/link?id=T12947650
- 저자
-
발행사항
서울 : 서울대학교 대학원, 2012
-
학위논문사항
학위논문 (석사) -- 서울대학교 대학원 , 농생명공학부(바이오모듈레이션전공) , 2012. 8
-
발행연도
2012
-
작성언어
영어
- 주제어
-
DDC
571 판사항(22)
-
발행국(도시)
서울
-
기타서명
메추리 난자의 배란 후 발생 능력과 분자적 특성에 관한 연구
-
형태사항
xi, 85장 : 삽화 ; 26 cm
-
일반주기명
참고문헌 수록
- DOI식별코드
-
소장기관
- 서울대학교 중앙도서관
- 서울대학교 중앙도서관
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
Natural fertilization in avian species occurs in the infundibulum shortly after oocyte is ovulated. Once the ovum moves beyond the infundibulum, the secretions from magnum hinder sperm to interact with the oocyte, but intracytoplasmic sperm injection (ICSI) enabling the fertilization of oocytes from magnum has been demonstrated in past studies. However, in these studies, birds must have been sacrificed for oocyte collection. If the oocyte in the shell gland can be used for ICSI studies, animal ethnic issue of sacrificing birds can be avoided and it is expected that the study can be applied to save the endangered avian species. Accordingly, the objective of the first study was to determine fertilizing capability of the oocytes with the time elapsed after ovulation.
First, Japanese quail sperm and inositol 1,4,5-trisphosphate (IP3) were injected by ICSI technique to induce ex ovo fertilization. Injection was performed to the oocytes collected at (1) 0.5-1.5 (2) 3.5-4 (3) 5-6 (4) 9-10 and (5) 22-23 hr after ovulation. The injected oocytes were cultured in DMEM inside a CO2 incubator for 24 hr. In order to determine the fertilization and blastoderm development rates of the oocytes, the morphology of the blastoderms was observed under a stereo microscope and histological verification was conducted after staining with 4.6-diamidino-2-phenylindole (DAPI), respectively. The highest rate of fertilization (60%) was observed in oocytes collected at 0.5-1.5 hr post ovulation, whereas it ranged between 36.4-18.8% in oocytes collected at other hours. 16.7% of oocytes collected at 0.5-1.5 hr post ovulation were developed beyond Eyal-Giladi and Kochav (EG&K) stage IV. However, the development of the oocytes collected at later hours post ovulation ceased development before EG&K stage IV. In this study, the positive sign for fertilization was seen in oocytes collected at all hours post ovulation. This indicates that the
fertilization capability is maintained until the egg is oviposited. However, the embryonic development of the eggs collected from isthmus and beyond ceases before EG&K stage IV. Therefore, an additional treatment to reverse the aging process of the oocytes can assist the embryonic development.
In order to improve the fertilization rate and further embryonic development, it seems necessary to elucidate underlining mechanism of incompetency of oocyte development. Accordingly, the molecular changes in unfertilized oocytes were studied in relation to times after ovulation. Also, responsiveness of oocytes to IP3 injection was evaluated in terms of changes in mRNA expression. Here, quantitative RT-PCR analysis was employed to assess expression of several mRNA transcripts in the oocytes which may be associated with decay of fertilization and development. In order to observe the expression of the selected genes, the unfertilized oocytes were collected at 0.5-1.5 hrs post ovulation for negative control. For the IP3 injected group, the unfertilized oocytes collected at 0.5-1.5, 5-6 and 22-23 hrs post ovulation and injected with IP3 using ICSI method. Both groups of oocytes were incubated in DMEM for 3 hrs and each of the oocytes was subjected to total RNA extraction and cDNA synthesis for the Real time PCR analysis.
ITPR3 mRNA expression was variable among the unfertilized and IP3-induced groups. Hence, there was no significant difference. On the other hand, as for mRNA expression of ITPR1 in the unfertilized oocyte and the IP3-injected oocytes, the up-regulated expression was observed at 0.5-1.5 hr post ovulation but much lower expression was at 5-6 hr and 22-23 hr post ovulation. The same expression pattern in ITPR2 mRNA was seen both in the unfertilized and IP3-injected oocytes. These correlated expression patterns of up-regulation at 0.5-1.5 hr and low expression at later hours post ovulation may indicate that IP3 receptors type 1 and type 2 are involved in the process of calcium release and oocyte activation. The same tendency of gene expression patterns were observed for BCL2L1, CDK1 and MAD2L2. The expression of BCL2L1, CDK1, MAPK1 and MAD2L2 was highly upregulated in the injected oocytes at 0.5-1.5 hr post ovulation when compared to oocytes at other time. This indicates that the oocytes 0.5-1.5 hr post ovulation showed the significantly high responsiveness to IP3 compared to other oocytes. Therefore, the low mRNA expression of ITPR1 and ITPR2 may be associated with the low fertilization rate in oocytes collected from shell gland and oviposited eggs.
Since the fertilization competency is maintained until the egg is oviposited, if the reversal of the oocyte aging is possible, the oocytes collected from shell gland and oviposited eggs can be used for successful fertilization and embryonic development and finally hatch. The present study is the first step towards understanding the fertilization capability in the avian species and to apply the new findings to contribute towards saving birds from being sacrificed and protecting endangered avian species.
First, Japanese quail sperm and inositol 1,4,5-trisphosphate (IP3) were injected by ICSI technique to induce ex ovo fertilization. Injection was performed to the oocytes collected at (1) 0.5-1.5 (2) 3.5-4 (3) 5-6 (4) 9-10 and (5) 22-23 hr after ovulation. The injected oocytes were cultured in DMEM inside a CO2 incubator for 24 hr. In order to determine the fertilization and blastoderm development rates of the oocytes, the morphology of the blastoderms was observed under a stereo microscope and histological verification was conducted after staining with 4.6-diamidino-2-phenylindole (DAPI), respectively. The highest rate of fertilization (60%) was observed in oocytes collected at 0.5-1.5 hr post ovulation, whereas it ranged between 36.4-18.8% in oocytes collected at other hours. 16.7% of oocytes collected at 0.5-1.5 hr post ovulation were developed beyond Eyal-Giladi and Kochav (EG&K) stage IV. However, the development of the oocytes collected at later hours post ovulation ceased development before EG&K stage IV. In this study, the positive sign for fertilization was seen in oocytes collected at all hours post ovulation. This indicates that the
fertilization capability is maintained until the egg is oviposited. However, the embryonic development of the eggs collected from isthmus and beyond ceases before EG&K stage IV. Therefore, an additional treatment to reverse the aging process of the oocytes can assist the embryonic development.
In order to improve the fertilization rate and further embryonic development, it seems necessary to elucidate underlining mechanism of incompetency of oocyte development. Accordingly, the molecular changes in unfertilized oocytes were studied in relation to times after ovulation. Also, responsiveness of oocytes to IP3 injection was evaluated in terms of changes in mRNA expression. Here, quantitative RT-PCR analysis was employed to assess expression of several mRNA transcripts in the oocytes which may be associated with decay of fertilization and development. In order to observe the expression of the selected genes, the unfertilized oocytes were collected at 0.5-1.5 hrs post ovulation for negative control. For the IP3 injected group, the unfertilized oocytes collected at 0.5-1.5, 5-6 and 22-23 hrs post ovulation and injected with IP3 using ICSI method. Both groups of oocytes were incubated in DMEM for 3 hrs and each of the oocytes was subjected to total RNA extraction and cDNA synthesis for the Real time PCR analysis.
ITPR3 mRNA expression was variable among the unfertilized and IP3-induced groups. Hence, there was no significant difference. On the other hand, as for mRNA expression of ITPR1 in the unfertilized oocyte and the IP3-injected oocytes, the up-regulated expression was observed at 0.5-1.5 hr post ovulation but much lower expression was at 5-6 hr and 22-23 hr post ovulation. The same expression pattern in ITPR2 mRNA was seen both in the unfertilized and IP3-injected oocytes. These correlated expression patterns of up-regulation at 0.5-1.5 hr and low expression at later hours post ovulation may indicate that IP3 receptors type 1 and type 2 are involved in the process of calcium release and oocyte activation. The same tendency of gene expression patterns were observed for BCL2L1, CDK1 and MAD2L2. The expression of BCL2L1, CDK1, MAPK1 and MAD2L2 was highly upregulated in the injected oocytes at 0.5-1.5 hr post ovulation when compared to oocytes at other time. This indicates that the oocytes 0.5-1.5 hr post ovulation showed the significantly high responsiveness to IP3 compared to other oocytes. Therefore, the low mRNA expression of ITPR1 and ITPR2 may be associated with the low fertilization rate in oocytes collected from shell gland and oviposited eggs.
Since the fertilization competency is maintained until the egg is oviposited, if the reversal of the oocyte aging is possible, the oocytes collected from shell gland and oviposited eggs can be used for successful fertilization and embryonic development and finally hatch. The present study is the first step towards understanding the fertilization capability in the avian species and to apply the new findings to contribute towards saving birds from being sacrificed and protecting endangered avian species.
Natural fertilization in avian species occurs in the infundibulum shortly after oocyte is ovulated. Once the ovum moves beyond the infundibulum, the secretions from magnum hinder sperm to interact with the oocyte, but intracytoplasmic sperm injection (ICSI) enabling the fertilization of oocytes from magnum has been demonstrated in past studies. However, in these studies, birds must have been sacrificed for oocyte collection. If the oocyte in the shell gland can be used for ICSI studies, animal ethnic issue of sacrificing birds can be avoided and it is expected that the study can be applied to save the endangered avian species. Accordingly, the objective of the first study was to determine fertilizing capability of the oocytes with the time elapsed after ovulation.
First, Japanese quail sperm and inositol 1,4,5-trisphosphate (IP3) were injected by ICSI technique to induce ex ovo fertilization. Injection was performed to the oocytes collected at (1) 0.5-1.5 (2) 3.5-4 (3) 5-6 (4) 9-10 and (5) 22-23 hr after ovulation. The injected oocytes were cultured in DMEM inside a CO2 incubator for 24 hr. In order to determine the fertilization and blastoderm development rates of the oocytes, the morphology of the blastoderms was observed under a stereo microscope and histological verification was conducted after staining with 4.6-diamidino-2-phenylindole (DAPI), respectively. The highest rate of fertilization (60%) was observed in oocytes collected at 0.5-1.5 hr post ovulation, whereas it ranged between 36.4-18.8% in oocytes collected at other hours. 16.7% of oocytes collected at 0.5-1.5 hr post ovulation were developed beyond Eyal-Giladi and Kochav (EG&K) stage IV. However, the development of the oocytes collected at later hours post ovulation ceased development before EG&K stage IV. In this study, the positive sign for fertilization was seen in oocytes collected at all hours post ovulation. This indicates that the
fertilization capability is maintained until the egg is oviposited. However, the embryonic development of the eggs collected from isthmus and beyond ceases before EG&K stage IV. Therefore, an additional treatment to reverse the aging process of the oocytes can assist the embryonic development.
In order to improve the fertilization rate and further embryonic development, it seems necessary to elucidate underlining mechanism of incompetency of oocyte development. Accordingly, the molecular changes in unfertilized oocytes were studied in relation to times after ovulation. Also, responsiveness of oocytes to IP3 injection was evaluated in terms of changes in mRNA expression. Here, quantitative RT-PCR analysis was employed to assess expression of several mRNA transcripts in the oocytes which may be associated with decay of fertilization and development. In order to observe the expression of the selected genes, the unfertilized oocytes were collected at 0.5-1.5 hrs post ovulation for negative control. For the IP3 injected group, the unfertilized oocytes collected at 0.5-1.5, 5-6 and 22-23 hrs post ovulation and injected with IP3 using ICSI method. Both groups of oocytes were incubated in DMEM for 3 hrs and each of the oocytes was subjected to total RNA extraction and cDNA synthesis for the Real time PCR analysis.
ITPR3 mRNA expression was variable among the unfertilized and IP3-induced groups. Hence, there was no significant difference. On the other hand, as for mRNA expression of ITPR1 in the unfertilized oocyte and the IP3-injected oocytes, the up-regulated expression was observed at 0.5-1.5 hr post ovulation but much lower expression was at 5-6 hr and 22-23 hr post ovulation. The same expression pattern in ITPR2 mRNA was seen both in the unfertilized and IP3-injected oocytes. These correlated expression patterns of up-regulation at 0.5-1.5 hr and low expression at later hours post ovulation may indicate that IP3 receptors type 1 and type 2 are involved in the process of calcium release and oocyte activation. The same tendency of gene expression patterns were observed for BCL2L1, CDK1 and MAD2L2. The expression of BCL2L1, CDK1, MAPK1 and MAD2L2 was highly upregulated in the injected oocytes at 0.5-1.5 hr post ovulation when compared to oocytes at other time. This indicates that the oocytes 0.5-1.5 hr post ovulation showed the significantly high responsiveness to IP3 compared to other oocytes. Therefore, the low mRNA expression of ITPR1 and ITPR2 may be associated with the low fertilization rate in oocytes collected from shell gland and oviposited eggs.
Since the fertilization competency is maintained until the egg is oviposited, if the reversal of the oocyte aging is possible, the oocytes collected from shell gland and oviposited eggs can be used for successful fertilization and embryonic development and finally hatch. The present study is the first step towards understanding the fertilization capability in the avian species and to apply the new findings to contribute towards saving birds from being sacrificed and protecting endangered avian species.
목차 (Table of Contents)
- CHAPTER 1 GERNERAL INTRODUCTION 1
- CHAPTER 2 LITERATURE REVIEW 4
- 1.Fertilization and oocyte activation in mammalian species 5
- 2.Fertilization and oocyte activation in avian species 14
- 3.Molecular changes in oocyte aging 18
- CHAPTER 1 GERNERAL INTRODUCTION 1
- CHAPTER 2 LITERATURE REVIEW 4
- 1.Fertilization and oocyte activation in mammalian species 5
- 2.Fertilization and oocyte activation in avian species 14
- 3.Molecular changes in oocyte aging 18
- CHAPTER 3 Fertilization and developmental competence of quail oocyte after ovulation 22
- 1. Introduction 23
- 2. Material and methods 25
- 3. Results 29
- 4. Discussion 36
- CHAPTER 4 Quantitative expression of genes related to oocyte activation and fertilization 40
- 1. Introduction 41
- 2. Material and methods 44
- 3. Results 46
- 4. Discussion 56
- CHAPTER 5 GENERAL DISCUSSION 60
- REFERENCE. 63
- SUMMARY IN KOREAN 82
- ACKNOWLEDGEMENTS 84
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