外源基因对精子的影响及其在山羊早期胚胎中的表达

摘要: 在前期实验中发现, 山羊精子可自发结合外源DNA, 但结合能力在不同动物个体之间差异显著。挑选结合能力明显不同的3只公羊, 进一步探讨了外源DNA对精子的影响及其在早期胚胎中的表达, 结果发现: 外源基因与精子共同孵育后, 精子的活率、顶体反应发生率和受精能力均呈下降态势, 其降幅与精子的结合能力密切相关。利用与DNA共育后的精子进行体外受精, 外源基因可被导入卵母细胞并在早期胚胎中获得表达, 但胚胎阳性率因精子供体不同而差异显著(P<0.05); 其中来源于高、中结合能力供体生产的胚胎, 分别有16.2%(25/154)和5.3%(4/76)可检测到外源基因存在, 但表达仅见于高结合能力供体生产的早期胚胎, 表达率为6.5%(10/154); 低结合能力供体生产的胚胎无外源基因。研究表明, 在以精子载体方法生产转基因动物的实验过程中, 筛选对DNA结合能力较强的精子供体是提高转基因效率的前提, 但需要考虑外源DNA对精子受精能力的影响。     

精子介导转基因动物的制备

近年来 ,通过显微注射DNA至孵育的卵母细胞原核或外源基因转染后的胚胎干细胞进行转基因动物的生产已取得了令人瞩目的成就。在过去的 1 0年中 ,以精子作载体制备转基因哺乳动物或脊椎动物也取得了一些不同程度的进展。这些技术主要包括 :直接将外源DNA与精子共孵育至成熟 ;提取分离的精子DNA或进行预处理至精子发育成熟 ;以及在辅助受精前分离精子细胞等。此外 ,一些显微注射技术 ,如在输精管内进行体内直接转染雄性生殖细胞 ;将体内转染的雄性生殖细胞植入已分离的雄性生殖细胞 ,再显微注射至受体的睾丸 ,这些技术也逐渐成熟起来。研究表明 ,通过体内、体外转染外源DNA的显微操作技术只需将雄性受体与野生型雌性交配就可产生出转基因的后代个体 ,同时也避免了辅助受精和胚胎操作带来的机械损伤 ,因此具有一定的优势。本文综述了精子介导转基因 (SMGT)技术的发展历程、研究现状及前沿进展。     

精子介导GFP基因在小鼠早期胚胎中的表达

利用DIG末端标记技术和免疫组化技术分析了小鼠精子体外结合内化外源DNA的效率。试验结果表明,不同小鼠个体的精子结合外源DNA的阳性率有明显差异(P<0.01),平均为13%。利用考马斯亮蓝染色评价了小鼠精子顶体反应发生的情况,筛选出TYH培养液为较合适的体外受精液。利用小鼠体外受精技术,将体外转染GFP基因并获能的小鼠精子与成熟卵母细胞进行体外受精,受精卵进行体外培养,表达GFP胚胎的阳性率为4.7%。验证了精子介导制备转基因小鼠胚胎的可行性,并建立了利用精子载体法制备转基因小鼠胚胎的平台。     

精子介导GFP基因在小鼠早期胚胎中的表达

利用 DIG 末端标记技术和免疫组化技术分析了小鼠精子体外结合内化外源DNA的效率。试验结果表明,不同小鼠个体的精子结合外源DNA的阳性率有明显差异（P<0.01）,平均为13%。利用考马斯亮蓝染色评价了小鼠精子顶体反应发生的情况,筛选出TYH培养液为较合适的体外受精液。利用小鼠体外受精技术,将体外转染GFP基因并获能的小鼠精子与成熟卵母细胞进行体外受精,受精卵进行体外培养,表达GFP胎的阳性率为4.7%。验证了精子介导制备转基因小鼠胚胎的可行性,并建立了利用精子载体法制备转基因小鼠胚胎的平台。     

山羊精子介导法转染外源基因影响因素及最适条件的研究

探讨山羊精子与外源DNA共孵育转染外源DNA效率的影响因素,优化精子转染程序.用DIG免疫组化方法检测和比较精子转染效率,因素为精子洗涤程度、转染缓冲液、精予活力、BSA、肝素、异种动物精浆等.离心洗涤3次以内的山羊精子DNase Ⅰ消化前、后阳性率随洗涤次数增加而显著增加(P＜0.05),而离心3次以上的转染效率略有下降;以mDM为共孵育缓冲体系可获得较高的转染效率;活力为0.55的精子转基因阳性率显著低于活力为0.9的精子(消化前、后阳性率分别为35.4±2.9%和21.8±5.3% vs 63.5±7.2%和50.3±2.8%,P＜0.os);共孵育体系中异种动物精浆可显著降低转染效率(P＜0.01),甚至与肝素可置换出已结合和内化转运到精子内的外源DNA,而共孵育体系中的BSA可抑制精子内化外源DNA.山羊共孵育法转染外源基因最适转染条件为mDM缓冲液洗涤3次后上浮收集高活力精子进行转染.     

采用高分子介导精子作载体制备转基因泥鳅

为探讨树形高分子介导精子载体技术产生转基因动物,将泥鳅精子与具有标记基因LacZ的pCH110重组质粒和树形高分子在保存液内孵育,经DNA原位杂交检测发现树形高分子介导下精子携事外源DNA的效率得到较大的提高,将捕获了外源DNA的精子,再与泥鳅卵进行体外人工受精。由此发育的鱼苗经PCR和LacZ组织化学检测,获得了高比例的转基因泥鳅,外源基因LacZ在泥鳅幼苗头部得到了明显表达。     

利用雄性生殖细胞建立转基因动物的研究进展

随着科学研究的不断深入及临床治疗的需要,人们对转基因动物的需求越来越大;但是传统的转基因动物技术大多操作复杂、成本高、效率低,从而限制了转基因技术的广泛应用。利用雄性生殖细胞作为载体介导外源基因导入受精卵来建立转基因动物具有操作简便、经济、易于推广的优点,发展前景广阔。该文就利用雄性生殖细胞建立转基因动物的发展历程和方法进行系统的阐述和分析。从利用精子和精原干细胞携带外源DNA两个方向展开,分别分析和评价了恒温共孵育法、脂质体介导法、电穿孔法、胞浆内单精子注射法、输精管注射法、体外转染精原干细胞法以及体内转染精原干细胞法七种实验设计方法。     

猪胞浆内单精子注射研究进展

胞浆内单精子注射将体外受精和显微操作技术相结合,已成功应用于哺乳动物受精机理研究,家畜性控胚胎生产,动物转基因等领域。综述了猪胞浆内单精子注射的主要影响因素,包括卵母细胞体外成熟和预处理、精子的选择和处理、注射卵的人工激活以及操作技术的改进,为进一步提高猪胞浆内单精子注射的效率以及该技术的应用提供参考。     

精子介导转基因动物的研究进展

精子是高度分化的细胞,它具有潜在的结合外源DNA并在受精过程中将其转入到卵内的能力。随着受精卵的发育,外源基因将随机整合到受体基因组中,部分基因能在成体中表达,部分基因不仅能表达还能遗传给后代。一旦精子能表达外源基因,那么将很容易得到大量的转基因后代。因此,精子能携带外源基因入卵和产量丰富这两大特性使精子作为载体制备转基因动物成为一个简便的途径。精子载体法制备转基因动物无需昂贵的实验设备,亦无需专门的技术。因此,提出后就备受关注。介绍精子介导的转基因动物的制作原理及具体方法的研究进展。     

精子因素对精子载体法制备转基因山羊的影响

精子具有主动结合、转运、整合外源DNA的能力,并在受精时导入卵母细胞,获得转基因动物.精子介导基因转移(sperm-mediated gene transfer,SMGT)是目前获得转基因动物简单而高效的方法之一.精子因素是影响SMGT方法生产转基因动物的重要方面.本论文结合我们的研究针对转染用山羊(Capra hircus)精液的来源、精子质膜完整性、精液品质及发育阶段等精子因素影响精子结合外源DNA和SMGT方法生产转基因山羊的效率进行了论述,并从这些影响因素入手,提出了筛选精子供体、保持精液品质、调控质膜等措施,提高精子转染外源DNA能力和生产转基因动物的效率.     

冷冻对山羊精子转染外源DNA和体外制备转基因胚胎的影响

本实验将鲜精和冻精分别与地高锌标记的线形化的pEGFP-N,质粒孵育转染,用原位杂交方法检测转染效率;PCR和Southern Blotting检测精子与外源DNA的整合效率;与成熟卵母细胞体外受精,PCR检测阳性胚胎比率,用透射电镜技术、碘化丙锭和羟化荧光素双探针技术和单细胞电泳（Single Cell Gel Electrophoresis,SCGE）技术,观察精子冷冻前后的超微结构、精子质膜完整性和精子核DNA损伤的变化,研究冷冻对山羊（Caprahircus）精子转染内化外源DNA和体外制备转基因胚胎的影响及机理。结果表明,冻精显著提高了转染外源DNA的效率（81．60％&#177;16．59％VS32．95％&#177;2．93％,t=4．873,P=0．003;41．80％&#177;6．26％vs27．89％&#177;8．64％,t=2．634,P=0．039）。PCR和Southern Blotting检测表明外源DNA已经整合到精子基因组上。用冻精与成熟卵母细胞体外受精,体外受精穿透率和卵裂率显著低于鲜精组（24．19％&#177;3．15％vs58．86％&#177;3．73％,t=7．131,P〈0．001;11．83％&#177;2．37％vs29．71&#177;3．47％,t=4．302,P〈0．001）,但体外生产的胚胎PCR阳性率比鲜精组显著提高（45．45％&#177;10．87％VS24．44％&#177;6．06％,t=1．750,P=0．013）。超微结构观察和双荧光探针检测都发现冷冻-解冻精子质膜完整性降低（8．34％&#177;4．21％VS65．67％&#177;6．46％,t=12．492,P〈0．001）,SCGE显示冷冻极显著增加了精子彗尾长度和彗星细胞比例（42．67μm&#177;4．56μmvs21．14／Lm&#177;2．36μm,t=5．644,P=0．005;60．00％&#177;4．00％vs17．37％&#177;2．57％;t=15．787,P〈0．001）。冷冻-解冻可以提高山羊精子转染外源DNA的效率,冷冻破坏精子质膜完整性,解除质膜的阻碍作用,是提高外源DNA转染效率的一个主要原因[动物学报54（6）：1089-1097,2008]。     

In vitro and in vivo development of bovine embryos from zygotes and 2-cell embryos microinjected with exogenous DNA

The objectives of these experiments were: 1) to determine an effective culture method for production of transferable bovine embryos following exogenous DNA microinjection; 2) to determine the effect of these methods on the ability of the injected zygotes and 2-cell embryos to develop in vivo; and, 3) to compare development of embryos microinjected as zygotes or 2-cell embryos. DNA fragments encoding bovine growth hormone (bGH), bGH-10Delta6, and a bGH antagonist, bGH-M8 (5) were used. A total of 639 zygotes and 153 2-cell embryos were injected. Zygotes and 2-cell embryos microinjected with bGH-M8 were incubated for 6 days in oviducts of intermediate recipients (rabbits or sheep) or co-cultured in vitro with bovine oviduct epithelial cells. Zygotes and 2-cell embryos microinjected with bGH-10Delta6 were co-cultured in vitro only. The most effective method for the production of transferable bovine embryos following exogenous DNA microinjection was via in vitro co-culturing with bovine epithelial cells. For example, 32.3% of the bGH-M8 and 33.5% of the bGH-10Delta6 microinjected zygotes reached the morula/blastocyst stage while 48.4% and 63.0% of the 2-cell embryos injected with bGH-M8 and bGH-10Delta6, respectively, developed to the morula/blastocyst stage. The percentage of blastocysts obtained for control, non-injected zygotes and 2-cell embryos was 34.5% and 69.6%, respectively. The developmental rate to the morula/blastocyst stage was approximately 20% greater for embryos obtained from microinjected 2-cell embryos relative to microinjected zygotes. However, there was no significant difference in pregnancy rates following transfer of these blastocysts to cow uteri.     

Expression of foreign DNA is associated with paternal chromosome degradation in intracytoplasmic sperm injection-mediated transgenesis in the mouse

The efficiency of intracytoplasmic sperm injection (ICSI)-mediated transgenesis is often limited by poor embryo development. Because our previous work indicated that impairment of embryo development is frequently related to chromosomal abnormalities, we hypothesized that foreign DNA and/or conditions used to enhance integration of the DNA might induce chromosome damage. Therefore, we examined the chromosomes of mouse embryos produced by transgenesis with the EGFP gene. Spermatozoa were processed with three methods that cause membrane disruption: freeze-thawing, Triton X-100, or Triton X-100 followed by a sucrose wash. Membrane-disrupted spermatozoa were mixed with EGFP plasmids and injected into metaphase II oocytes. Three endpoints were evaluated: paternal chromosomes of the zygote, embryo capacity to develop in vitro, and expression of the transgene at the morula/blastocyst stage. In all pretreatments, we observed a significant decrease (approximately 2-fold) in the frequency of normal karyoplates when spermatozoa were incubated with exogenous DNA as compared with the treatment when no DNA was added. As predicted, embryo development was correlated with the integrity of the paternal chromosomes of the zygote. Searching for the possible mechanism of chromosome degradation, we used the ion chelators EGTA and EDTA and found that they neutralize the harmful effect of the transgene and stabilize the paternal chromosomes. In the presence of chelating agents, however, the number of embryos expressing EGFP produced with ICSI-mediated transgenesis decreased significantly. The results suggest that treatment of spermatozoa with exogenous DNA leads to paternal chromosome degradation in the zygote. Furthermore, the mechanisms of disruption of paternal chromosomes and the integration of foreign DNA may be closely related.     

Factors affecting the efficiency of producing porcine embryos expressing enhanced green fluorescence protein by ICSI-mediated gene transfer method

This study aims to investigate factors that affect the efficiency of blastocyst development and enhanced green fluorescence protein (EGFP) expression in porcine embryos following intracytoplasmic sperm injection (ICSI)-mediated DNA transfer. Frozen-thawed dead spermatozoa were exposed to different concentrations (0.01 microg/mL, 0.05 microg/mL or 0.1 microg/mL) of EGFP DNA solution, and then microinjected into in vitro matured oocytes. The optimal concentration for EGFP expression of resultant embryos was 0.05 microg/mL. When oocytes were microinjected on a warm stage at 30 degrees C, the percentage of EGFP-expressing embryos was higher than that at 38.5 degrees C (40.1% vs. 20.9%, P<0.01). The efficiency of EGFP expression in embryos following ICSI using linear EGFP DNA-exposed spermatozoa was higher than using circular DNA (40.8% vs. 28.2%, P<0.05). ICSI oocytes treated with 6-DMAP after electro-activation had a higher percentage of embryos expressing EGFP than those not treated (52.5% vs. 26.3%, P<0.01). However, neither incubation temperatures of spermatozoa and DNA (4 degrees C, 24 degrees C or 39 degrees C) nor BSA addition to the incubation medium affected the efficiency of producing EGFP-expressing embryos. Furthermore, treatment with DNase I after preincubation of sperm and DNA prevented the embryos from expressing EGFP. The EGFP expression of ICSI oocytes was affected neither by intracytoplasmic injection using sperm heads or whole spermatozoa, nor by washing of the sperm after preincubation. The above-mentioned factors did not affect embryonic developmental competence, apart from 6-DMAP treatment after electro-activation. In conclusion, most exogenous DNA molecules were tightly bound on the membranes of sperm head after incubation of DNA and sperm, and the temperature during ICSI, 6-DMAP treatment, exogenous DNA concentrations and constructs could significantly affect EGFP expression in porcine embryos following ICSI-mediated DNA transfer.     

Effects of metabolic substrates and ionic environment on in-vitro activation of delayed implanting mouse blastocysts

The possibility that the embryonic diapause associated with delayed implantation in mice is maintained by limitation of an essential amino acid, energy substrate or concentration of ions was examined by comparing the rates of DNA synthesis in delayed implanting embryos that were 'reactivated' by incubation in 'complete' medium or in one of several specially formulated 'deficient' media. It was found, in agreement with earlier observations, that an increase in the rate of DNA synthesis could be detected within 12 h and continued through 72 h in complete medium. An identical pattern was found when embryos were incubated in medium deficient in amino acids and vitamins. Similar patterns of activation were observed in the absence of all metabolizable substrates, a drastically reduced concentration of Na+, and even in a medium consisting only of 25 mM-bicarbonate buffer, NaCl and KCl. The embryos incubated in the more drastically deficient media appeared to be damaged after 18-24 h. Nevertheless, the observation that the rate of DNA synthesis did not remain depressed suggests that such deficiencies are not the means by which embryonic dormancy is maintained in utero.     

Excess methionine suppresses the methylation cycle and inhibits neural tube closure in mouse embryos

Suppression of one-carbon metabolism or insufficient methionine intake are suggested to increase risk of neural tube defects (NTD). Here, exogenous methionine unexpectedly caused frequent NTD in cultured mouse embryos. NTD were associated with reduced cranial mesenchyme cell density, which may result from a preceding reduction in proliferation. The abundance ratio of S-adenosylmethionine to S-adenosylhomocysteine was also decreased in treated embryos, suggesting methylation reactions may be suppressed. Such an effect is potentially causative as NTD were also observed when DNA methylation was specifically inhibited. Thus, reduced cranial mesenchyme density and impairment of critical methylation reactions may contribute to development of methionine-induced NTD.     

鸡Ⅹ期胚盘细胞体外培养

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 (14 0枚 ) ;或对转染后供体细胞进行G418抗性筛选后显微注入同期受体鸡胚盘 (14 0枚 ) ;或将供体细胞体外培养 4 8h ,再与脂质体 PGS1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 0 1)高于G418筛选处理组 (1 4 % )和培养 4 8h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 4 8h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。     

Comparison of cell proliferation index in equine and caprine embryos using a modified BrdU incorporation assay

The measurement of cell proliferation and cell viability using 5'bromo-2'deoxy-uridine (BrdU) labelling has been described in several cell types and species. The aim of this study was to adapt this technique to equine embryos and to compare the index of DNA replication (S-phase) between equine and caprine embryos. Seventeen equine embryos were recovered at day 6.5 post-ovulation and 20 caprine embryos were recovered at day 7 after the onset of estrus. Equine embryos were incubated during 1h at 39 degrees C in PBS containing 1mM of BrdU. Embryos were then treated in 0.05% trypsin during 15 min at 39 degrees C to permeabilise the capsule, and then embryos were rinsed in PBS containing 10% of foetal calf serum. After washing, embryos were immediately fixed in 2.5% paraformaldehyde with 0.3M NaOH during 15 min at ambient temperature. The S-phase was detected by immunocytochemistry technique. In caprine embryos, BrdU was visualised by the same technique but without the trypsin treatment. The percentage of cells (+/-S.E.M.) with BrdU incorporated into newly synthesised DNA strands was significantly higher in equine embryos (74+/-1) than in caprine (38+/-2). Our results demonstrated that BrdU incorporation assay can be used in equine embryos. This assay allows the determination of the proliferation index of live cells and could be used as an additional tool for evaluating the viability of embryos. The high percentage of cells incorporating BrdU during 1h of incubation with BrdU suggests that in comparison with the caprine embryos the cellular activity of proliferation is more intense in equine embryos and suggests that the cellular cycle is shorter in equine embryos.