首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到20条相似文献,搜索用时 187 毫秒
1.
鸡X期胚盘细胞体外培养   总被引:4,自引:0,他引:4  
杜立新  尹春光 《动物学报》2002,48(4):549-553
为证实经遗传修饰的鸡X期胚盘细胞具有参与受体胚胎发育和形成嵌合体的能力,本研究将由鸡X期胚盘制成的细胞悬液与经脂质体包埋的抗鸡传染性支气管炎病毒基因重组质粒PGS1共孵育后,直接显微注入同期受体胚盘(140枚);或对转染后供体细胞进行G418抗性筛选性后显微注入同期受体鸡胚盘(140枚);或将供体细胞体外培养48h,再与脂质体-P^GSI复合物共孵育后显微注入同期受体鸡胚盘(190枚),制备转基因嵌合体鸡,并应用PCR和RAPD方法,对鸡胚和雏鸡不同组织或血液中的DNA进行检测。结果表明:直接注射组孵化率(5.7%)显著(P<0.01)高于G418筛选处理组(1.4%)和培养48h处理组(2.1%);G418筛选处理组不同胚龄鸡胚组织、器官中外源DNA的PCR检测阳性率均高于其它二个组。实验结果证明,体外培养48h并经遗传修饰的胚盘细胞仍然具有形成嵌合体的能力,利用早期胚盘细胞途径制备转基因鸡是可行的。  相似文献   

2.
从原代培养的人脐静脉血管内皮细胞(HUVEC)提取细胞总RNA,采用逆转录PCR(RT-PCR)方法得到VEGF受体Flt-1胞外区前3个IgG样区域cDNA片段(Flt-1n3).将获得的受体基因克隆到真核表达载体pcDNA3.1中,得到重组质粒pcDNA3.1/Flt-1n3,通过脂质体转染方法将其转入中国仓鼠卵巢细胞(CHO),用G418筛选得到稳定表达目的蛋白的细胞克隆.经固相结合实验筛选得到表达与VEGF特异结合的目的蛋白的细胞克隆,细胞测活结果表明,表达产物具有抑制人脐静脉内皮细胞(HUVEC)增殖的活性.鸡胚测活结果表明,CHO细胞表达的r Flt-1n3能抑制鸡胚绒毛尿囊膜的血管形成.  相似文献   

3.
通过体细胞核移植技术制作了人胰岛素原转基因牛。在CMV启动子指导下以内部核糖体进入位点序列(IRES)连接的新霉素抗性基因和绿色荧光蛋白基因组成了双重标记基因的筛选系统,用于转基因细胞的富集以及细胞和植入前胚胎的筛选。转基因通过电穿孔的方法(900V/cm,5ms)转入体外培养的牛胎儿成纤维细胞,基因转染细胞在添加G418 (800μg/mL)的培养基中培养10天以富集转基因细胞。选择表达绿色荧光蛋白的转基因细胞作为核供体进行体细胞核移植,重构胚经体外培养至囊胚阶段,选择表达绿色荧光蛋白的囊胚进行胚胎移植。为比较基因转染以及供体细胞所处周期对转基因细胞核移植胚胎发育的影响,用作核移植供体的转基因细胞或非转基因细胞先饥饿培养2—4天(0.5 ?S) ,然后恢复培养(10?S) 10 h使细胞同步化于G1期,以正常培养的细胞作为对照进行核移植。结果表明,转基因细胞作为核供体得到的核移植胚胎的体外囊胚发育率低于以非转基因细胞为核供体的对照组(23.2% VS 35.2 %,P<0.05) ;转基因细胞周期同步化处理与否对其克隆胚囊胚发育率无显著影响(23.2% VS 18.9 %,P>0.05)。胚胎移植后2个月直肠检查发现7头受体牛(每头移植2—4枚胚胎)中有一头妊娠,并最终发育足月产下一头小牛。聚合酶链反应(PCR)检测和DNA测序分析表明其为转人胰岛素原基因的转基因克隆牛。  相似文献   

4.
鸡蛋开窗法导入供体胚盘细胞对家鸡胚胎发育的影响研究   总被引:8,自引:0,他引:8  
通过4批孵化实验,研究鸡蛋开窗法注射供体胚盘细胞对受体鸡胚发育及孵化率的影响。GLM方差分析表明,开窗处理极显著降低整个孵化期(21d)的活胚比例(P<0.01),至21日龄出壳时,处理组的孵化率为.8%-6.0%。导入供体胚盘细胞对受体鸡胚的发育仅为阶段性影响,表现在显著性孵化第8日龄左右的活胚比例(P<0.05)。而对后期发育的影响不显著(P>0.05)。因经,鸡蛋开窗处理是降低受体胚胎成活率和孵化率的主要原因,如何降低开窗处理对受体胚胎的应激和不利影响则是今后研究的一个课题。  相似文献   

5.
带npt-Ⅱ基因转基因水稻快速检测技术的建立   总被引:7,自引:0,他引:7  
以转溶菌酶基因水稻纯系材料中花9号(ZH9(R))及其受体品种中花9号(ZH9(CK))为材料, 以ZH9(R)中携带的npt-Ⅱ基因作为辅助筛选标记, 利用抗生素对其进行处理, 建立了一套快速检测带npt-Ⅱ基因转基因水稻的技术体系。使用不同浓度的卡那霉素(Kanamycin, Kan)和G418溶液将ZH9(R)和ZH9(CK)成株离体叶片于室内室温下置于培养皿中浸泡处理, 通过观察叶片变化, 确定G418为检测带npt-Ⅱ基因转基因水稻的最佳抗生素, 将G418(溶液)80 mg/L浓度(处理4天)作为检测该类转基因水稻成株离体叶片的临界浓度。进一步用G418对ZH9(R)和ZH9(CK)种子、幼胚和幼苗进行了不同处理。确定: (1) G418(溶液)300 mg/L浓度(处理7天)作为检测该类转基因水稻种子的临界浓度; (2) G418(1/2 MS+0.5 mg/L 6-BA+1.5%蔗糖培养基)200 mg/L浓度(处理10天)作为检测该类转基因水稻幼胚的临界浓度; (3) G418(1/2 MS+0.5 mg/L 6-BA+1.5%蔗糖培养基)150 mg/L浓度(处理12天)作为检测该类转基因水稻幼苗的临界浓度, 并且通过PCR方法证实了上述结论。将这些结论应用于ZH9(R)转育后代叶片、种子、幼胚和幼苗群体的检测, 检测效果都非常明显。这为带npt-Ⅱ基因转基因水稻建立了一套简便、直观且准确的检测方法。  相似文献   

6.
通过体细胞核移植技术制作了人胰岛素原转基因牛。在CMV启动子指导下以内部核糖体进入位点序列(IRES)连接的新霉素抗性基因和绿色荧光蛋白基因组成了双重标记基因的筛选系统,用于转基因细胞的富集以及细胞和植入前胚胎的筛选。转基因通过电穿孔的方法(900 V/cm, 5 ms)转入体外培养的牛胎儿成纤维细胞,基因转染细胞在添加G418(800 μg/mL) 的培养基中培养10天以富集转基因细胞。选择表达绿色荧光蛋白的转基因细胞作为核供体进行体细胞核移植,重构胚经体外培养至囊胚阶段,选择表达绿色荧光蛋白的囊胚进行胚胎移植。为比较基因转染以及供体细胞所处周期对转基因细胞核移植胚胎发育的影响,用作核移植供体的转基因细胞或非转基因细胞先饥饿培养2—4天(0.5% FBS),然后恢复培养(10% FBS)10?h使细胞同步化于G1期,以正常培养的细胞作为对照进行核移植。 结果表明,转基因细胞作为核供体得到的核移植胚胎的体外囊胚发育率低于以非转基因细胞为核供体的对照组(23.2% VS 35.2%, P<0.05);转基因细胞周期同步化处理与否对其克隆胚囊胚发育率无显著影响(23.2% VS 18.9%, P>0.05)。胚胎移植后2个月直肠检查发现7头受体牛(每头移植2—4枚胚胎)中有一头妊娠,并最终发育足月产下一头小牛。聚合酶链反应(PCR)检测和DNA测序分析表明其为转人胰岛素原基因的转基因克隆牛。  相似文献   

7.
2N-4N嵌合体是由二倍体(2N)的胚胎细胞(或ES细胞)与四倍体(4N)的胚胎细胞组构成的一种拯救型嵌合体。这种嵌合体由于4N胚胎细胞独特的胚外组织发育特性,从而可获得完全源自2N细胞成份的仔鼠(或胎儿)。这一特性最终在ES细胞转基因的基因功能研究中极具重要价值。综述了2N-4N嵌合体研究进展及其在基因功能研究领域的应用。  相似文献   

8.
以转染了质粒pEGFP-N1的猪胎儿成纤维细胞与体外成熟(in vitro maturation, IVM)的猪卵母细胞构建克隆胚, 比较了细胞转染后G418筛选与否, 卵母细胞IVM持续时间及IVM时氧分压高低对克隆胚早期发育的影响. 结果如下: (ⅰ) G418连续筛选10天所得转GFP细胞的克隆胚卵裂率显著低于非筛选组(47.5% vs. 71.6%, P<0.05), 而囊胚率差异不显著(10% vs. 10.4%, P>0.05); (ⅱ) 相比于36 h IVM, 延长IVM时间至 42 h卵母细胞的核成熟明显改善(83.6% vs. 96.7%, P<0.05); 另外, 虽然IVM 42 h也使得克隆胚卵裂率(59.3% vs. 73.6%)及囊胚率(9. 3% vs. 13.2%)都略有提高, 但效果不显著 (P>0.05); (ⅲ) 7%氧IVM 42 h 的卵母细胞与20%氧处理组相比, 克隆胚的卵裂率(70.6% vs. 67.1%)以及囊胚率(11.8% vs. 12.3%)差异都不明显(P>0.05). 上述结果显示: (ⅰ) G418筛选对转绿色荧光蛋白基因(GFP)克隆胚卵裂不利; (ⅱ) IVM 36和42 h的卵母细胞对克隆胚早期发育影响不明显, 但IVM 42 h有利于核成熟, 因此构建克隆胚时仍以IVM 42 h的卵母细胞为宜; (ⅲ) 低氧对猪转GFP克隆胚早期发育无明显促进作用.  相似文献   

9.
云南水牛的同期发情、超数排卵和胚胎移植试验   总被引:6,自引:0,他引:6  
为探讨水牛胚胎移植的效果 ,于 2 0 0 2年对云南水牛进行了胚胎移植试验 :①用国产氯前列烯醇(PG) 0 6mg/头·次处理供、受体水牛的同期发情率和可用率分别为 4 3 33% (13/ 30 )和 16 6 7% (5 / 30 ) ;同期发情率经产水牛高于青年水牛 (P =0 0 86 ) ,杂交水牛高于德宏水牛 (P =0 15 3) ,体重 4 0 1~ 5 30kg水牛显著高于体重 30 0~ 4 0 0kg水牛 (P <0 0 5 ) ;发情明显水牛的可用率极显著高于发情不明显的水牛 (P <0 0 1)。②选用河流型摩拉水牛与沼泽型德宏水牛的杂交一代 5头为供体 ,分进口激素组 (n =2 )和国产激素组 (n =3)进行超数排卵 ,共有 2头获 9枚胚胎 ;进口激素组供体的平均获胚数和可移植胚数分别为 2 0枚和 1 5枚 ,比国产激素组分别多 0 33枚 (P =0 4 5 4 )和 1 17枚 (P =0 2 88)。③所获 4枚可用鲜胚分别移植 3头受体 ,结果 90d的妊娠率为 33 33% ,但最终无一头产犊。试验结果表明使用进口FSH 2 4mg +PG (Lutalyse○R) 35mg和国产FSH 11mg +PG 0 8mg对水牛超数排卵有效 ,同时提示需要足够数量的受体 ,从中选用发情表现明显、黄体发育良好的进行胚胎移植 ,才能取得良好效果。  相似文献   

10.
本文的主要目标是建立绵羊胞内单精子注射技术(intracyioplasmic sperm injection,ICSI)。并且尝试了ICSI技术生产绵羊转基因胚胎的可能性。实验1比较了绵羊卵母细胞孤雌激活的3种化学方法。结果显示,Ionomvcin/3 h/6-dimethylaminopurine(6-DMAP)和Ionomycin激活胚的卵裂率(71.7%和91.8%)和囊胚率(17.4%和11%)显著(P<0.01)高于Ca~(2+)激活胚(18.4%和0)。Ionomycin/3 h/6-DMAP激活胚的囊胚发育形态和比例相对较高。实验2中,活精子注射至卵母细胞质后,用Ionomycin/3 h/6-DMAP激活,排出第二极体(PB2)的71枚ICSI胚胎用SOFaaBSA溶液培养,卵裂率为71.8%(51/71),显著(P<0.01)高于体外受精(41.4%,IVF)和阴性对照胚胎(30.2%,sham-ICSI)。培养7天后,sham-ICSI组没有囊胚生成;ICSI和IVF胚胎的囊胚率分别为7.0%(5/71)和16.1%(9/56),两者差异不显著(P>0.05)。这些ICSI囊胚在冷冻前后均能孵化,显示初步建立了绵羊ICSI技术。另外,我们探索了ICSI技术生产转基因胚胎的可能性,-20℃冻融1次的死精子与pEGFP-N1质粒共注射,33枚2-细胞期ICSI胚胎中,2枚可见GFP蛋白。其中1枚停止发育,另外1枚继续发育至16-细胞期,仍然可见GFP基因的表达。4枚解冻的ICSI囊胚手术移植给2只发情同期化受体绵羊,60天时,B超未见怀孕。本文初步结果表明,ICSI技术生产转基因绵羊有可能性,需深入研究。  相似文献   

11.
Chicken blastodermal cells (BCs) from stage X embryos produce both somatic and germline chimeras when injected into the subgerminal cavity of recipient embryos. Transfection of the donor cells in vitro could lead to the production of chimeras capable of transmitting the transgene to their offspring. The aim of this study was to transfer and express foreign genes under control of the ovalbumin promoter in the BCs. The results showed that luciferase activity in the BCs reached a plateau value with a 2.0:1.0 or 5.0:1.0 liposome-DNA ratio and using 1 microg of DNA. Under this same condition, no difference was found in relative activity between the pGL-control and pOVALUC plasmid. The expression of other exogenous genes (green fluorescent protein and interferon alpha2a) driven by the chicken ovalbumin promoter in cultured chicken blastodermal cells in vitro is possible by this assay. Hatchability of recipient embryos after injection of 1,500 or 800 transfected BCs was compared. The advantage of using a smaller number (800) of injected transfected BCs was that early embryonic mortality was reduced and resulted in higher (P<0.01) hatchability (24.5%) than in the case of 1,500 BCs injected.  相似文献   

12.
Primordial germ cells (PGCs) from stage 27 (5.5-day-old) Korean native ogol chicken embryonic germinal ridges were cultured in vitro for 5 days. As in in vivo culture, these cultured PGCs were expected to have already passed beyond the migration stage. Approximately 200 of these PGCs were transferred into 2.5-day-old white leghorn embryonic blood stream, and then the recipient embryos were incubated until hatching. The rate of hatching was 58.8% in the manipulated eggs. Six out of 60 recipients were identified as germline chimeric chickens by their feather colour. The frequency of germline transmission of donor PGCs was 1.3–3.1% regardless of sex. The stage 27 PGCs will be very useful for collecting large numbers of PGCs, handling of exogenous DNA transfection during culture, and for the production of desired transgenic chickens.  相似文献   

13.
This study was performed to investigate whether the embryonic somatic cells are capable of reconstituting and participating in the embryonic development of chickens to produce chimeras. In order to track the migration behavior of the donor cells, a cell line, originally isolated from an Indian peafowl embryo, was fluorescent-labeled by transfection of the cells with enhanced Green Fluorescent Protein (GFP) and Neomycin resistant (Neo) genes prior to injection into the stage X blastoderm of White Leghorn chickens. The injection was performed with a medium in the presence of 1-5% polyethylene glycol. The development of putative chimeric embryos between the stages three and 24 was examined for GFP expression under fluorescent light. To trace the peafowl cells in the developing chicken embryos, both a species-specific genetic marker originating from the mitochondrial DNA cytochrome b (cyt b) gene and a DNA fragment of GFP gene were used. Of the 185 fertile eggs manipulated, 173 developed into embryos. Fifty-five of them showed positive GFP patches in extra-embryonic tissues, and 15 expressed GFP in intra-embryonic tissues such as those of the head, heart, and gonad. PCR analysis revealed that PCR fragments for the peafowl mitochondrial DNA cyt b and GFP genes were detected in the samples of the GFP positive extra- and intra-embryonic tissues of the chimeras. The present results provide evidence that fluorescent-labeled peafowl embryonic cells carrying GFP and Neo genes are able to participate in the development of chicken embryos to generate chimeras.  相似文献   

14.
Ha JY  Park TS  Hong YH  Jeong DK  Kim JN  Kim KD  Lim JM 《Theriogenology》2002,58(8):1531-1539
We previously reported that germline chimeras could be produced by transfer of chicken gonadal primordial germ cells (gPGCs) cultured for a short term (5 days). This study was subsequently undertaken to examine whether gPGCs maintained in vitro for an extended period could retain their specific characteristics to induce germline transmission. Chicken (White Leghorn, WL) gPGCs were retrieved from embryos at stage 28 (5.5 days of incubation) and continuously cultured for 2 months in modified Dulbecco's minimal essential medium without subpassage and changing of the feeder cell layer. After the identification of gPGC characteristics using Periodic acid-Shiff's (PAS) reaction and anti stage-specific embryonic antigen-1 (SSEA-1) antibody staining at the end of the culture, cultured gPGCs were injected into the dorsal aorta of Korean Ogol Chicken (KOC) recipient embryos at stage 17 (2.5 days of incubation). Nineteen chickens (13 males and 6 females) were hatched, grown to sexual maturity, and subsequently subjected to testcross analysis employing artificial insemination with adult KOC. Of these, four (three males and one female) hatched chickens with white coat color. The percentage of germline chimerism was 21% (4/19). The results of this study demonstrated that gPGCs could maintain their specific characteristics for up to 2 months in vitro, resulting in the birth of germline chimeras following transfer to recipient embryos.  相似文献   

15.
In previous experiments in our laboratories, chickens that are chimeric in their gamete, melanocyte, and blood cell populations have been produced by injection of dispersed stage X blastodermal donor cells into the subgerminal cavity of stage X recipient embryos. In some experiments, donor cells were transfected with reporter gene constructs prior to injection as a preliminary step in the production of transgenic birds. Chimerism was assessed by test mating, observation of plumage, and DNA fingerprinting. Methods were sought that would provide a relatively rapid analysis of the spatial distribution of descendants of donor cells in chimeras to assess the efficacy of various methods of chimera construction. To date, the sex of donor and recipient embryos was not known and, therefore, numerous mixed sex chimeras must have been constructed by chance, since donor cells were usually collected from several embryos rather than from individual embryos. The presence of female-derived cells was determined by in situ hybridization using a W-chromosome-specific DNA probe, using smears of washed erythrocytes from 16 phenotypically male chimeric chickens ranging in age from 4 days to 42 months posthatching. The proportion of female cells detected in the erythrocyte samples was zero (eight samples) or very low (0.020-0.083%), although 1% of the erythrocytes from a phenotypically male chick that was killed 4 days after hatch were female-derived. The low proportions of female-derived cells were surprising, considering that most of these chimeras had been produced by the injection of cells pooled from several donor embryos and most recipients had been exposed to gamma irradiation prior to injection, thus dramatically enhancing the level of incorporation of donor cells into the resulting chimeras. By contrast, 0-100% of the erythrocytes were female-derived in blood samples taken at 10 days of incubation from the chorioallantois of seven phenotypically normal male embryos that resulted from the injection of blastodermal cells pooled from five embryos into irradiated recipient embryos. Approximately 70% of the erythrocytes in a blood sample from a phenotypically normal female chimeric embryo were female-derived, and 100% of the erythrocytes examined from an intersex embryo bearing a right testis and a left ovary were female-derived. These results indicate that female-derived cells can contribute to the formation of erythropoietic tissue during the early development of what will become a phenotypically male chimeric embryo. It would appear, therefore, that female-derived cells are blocked in development or destroyed, or certain male-female combinations of cells may be lethal prior to hatching.(ABSTRACT TRUNCATED AT 400 WORDS)  相似文献   

16.
This study reports for the first time the production of chicken germline chimeras by transfer of embryonic germ (EG) cells into recipient embryos of different strain. EG cells were established by the subculture of gonadal tissue cells retrieved from stage 28 White Leghorn (WL) embryos with I/I gene. During primary culture (P(0)), gonadal primordial germ cells (gPGCs) in the stromal cells began to form colonies after 7 days in culture with significant (P < 0.0001) increase in cell population. Colonized gPGCs were then subcultured with chicken embryonic fibroblast monolayer for EG cell preparation. Prepared EG cells or gPGCs at P(0) were transferred to stage 17 Korean Ogol chicken (KOC) embryos with i/i gene. The recipient chickens were raised for 6 months to sexual maturity, then a testcross analysis by artificial insemination was conducted for evaluating germline chimerism. As results, transfer of EG cells and gPGCs yielded total 17 germline chimeras; 2 out of 15 (13.3%) and 15 of 176 sexually matured chickens (8.5%), respectively. The efficiency of germline transmission in the chimeras was 1.5-14.6% in EG cells, while 1.3-27.6% in gPGCs. In conclusion, chicken germline chimeras could be produced by the transfer of EG cells, as well as gPGCs, which might enormously contribute to establishing various innovative technologies in the field of avian transgenic research for bioreactor production.  相似文献   

17.
用显微注射法把含有E.coli galk和gpt基因的环状和线状重组DNApIDB103分别导入金鱼受精卵的细胞质内。这些注射过的卵子一般都能正常发育。从各不同发育时期的胚胎分离DNA与~(32)P标记的pIDB103探针杂交表明,导入的环状外源重组DNA在胚胎发育的早期,绝大部分以各种环状构型存在。从原肠胚晚期开始,它们逐渐形成串联状高分子量DNA。在尾芽期仍能检测到它们的序列。但尚未证明,它们是否与受体的染色体DNA发生整合。我们从囊胚期的胚胎中回收到了能转化大肠杆菌的环状重组DNA,它的酶切图谱和pIDB103极其相似。导入金鱼受精卵内的线状重组质粒pIDB103,除少量DNA与金鱼的染色体DNA可能发生整合外,其余绝大部分也形成高分子量DNA。  相似文献   

18.
The Cre-loxP site-specific recombination system was used for cell lineage analysis in mammals. We constructed an expression plasmid, pCETZ-17, which consists of cytomegalovirus enhancer/chicken beta-actin promoter (CAG), a portion of the rabbit beta-globin gene, loxP-flanked DNA sequence (containing enhanced green fluorescent protein (EGFP) cDNA), and lacZ gene encoding E. coli beta-galactosidase (beta-gal). When circular pCETZ-17 plasmid DNA was microinjected into the pronuclei of fertilized eggs and these eggs were allowed to develop to two-cell stage, 62.8% (59/94) of the two-cell embryos exhibited distinct fluorescence in one or both blastomeres, but never expressed lacZ protein, as evaluated by histochemical staining with X-Gal, a substrate for beta-gal. When both circular plasmids, pCETZ-17 and pCAG/NCre (containing CAG and DNA sequences encoding nuclear location signal and Cre), were co-injected into fertilized eggs, almost all (87.0%, 47/54) embryos exhibited low or no fluorescence, but 51.9% (27/52) exhibited positive staining for beta-gal activity. This indicates that transient expression of the Cre recombinase gene removed the loxP-flanked DNA sequence in pCETZ-17 and then caused expression of the downstream lacZ sequence. We next microinjected pCETZ-17 into the pronuclei of fertilized eggs, cultured these injected eggs for 1 day, and collected only two-cell embryos expressing EGFP in both blastomeres. One blastomere of the EGFP-expressing two-cell embryos was microinjected with pCAG/NCre, and these treated embryos were cultured for 1 day up to four-cell stage. When the developing four-cell embryos were subjected to staining with X-Gal, cell lineage-related staining pattern for beta-gal activity was observed in most (77.8%, 7/9) embryos. These findings were further confirmed using two-cell embryos derived from a transgenic mouse line carrying CETZ-17 transgene. Thus, our system, which is based on transient expression of the Cre recombinase gene directly introduced into nuclei of embryonic cells by microinjection, is a powerful means for cell lineage analysis in mammals.  相似文献   

19.
Experiments with mouse embryos were designed to assess the feasibility of freezing embryos after DNA microinjection. One-cell pronuclear stage mouse embryos were microinjected with cloned deoxyribonucleic acid (DNA) and cultured in vitro to the late eight-cell stage. Microinjected and matched control embryos were frozen and stored in liquid nitrogen. Following thawing, embryos were cultured for 8 h and transferred to recipient females. In a separate set of experiments, embryos were transferred to recipients immediately following DNA microinjection. Control (uninjected) embryos developed to the late eight-cell stage significantly better than surviving microinjected embryos. Of the embryos thawed, 76% of the microinjected and 60% of the control embryos survived to be transferred to recipients. Progeny were obtained with similar survival rates from both groups following embryo transfer with transgenic mice identified among the progeny from microinjected embryos. Mouse embryos can be microinjected with DNA, cultured in vitro, frozen, thawed, transferred to recipients and transgenic progeny can be obtained.  相似文献   

20.
Transgenic chickens have, in general, been produced by two different procedures. The first procedure is based on viral transfection systems. The second procedure, the non-viral method, is based on genetically modified embryonic cells transferred directly into the recipient embryo. In this review, we analyzed the effectiveness of important elements of the non-viral, cell-based strategy of transgenic chicken production. The main elements of this strategy are: isolation and cultivation of donor embryonic cells; transgene construction; cell transfection in vitro; and chimera production: injection of cells into recipient embryos, raising and identification of germline chimeras, mating germline chimeras, transgene inheritance, and transgene expression. In this overview, recent progress and important limitations in the development of transgenic chickens are presented.  相似文献   

设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号