小鼠胚胎与子宫单层上皮细胞共培养的研究

本文报道建立了小鼠胚胎与小鼠子宫单层上皮细胞体外共培养系统。结果揭示;小鼠胚胎与 子宫单层上皮细胞共培养可以促进胚胎的发育、粘附和扩展;如果培养液中加入 ３、６７ × １０－６ｍｏｌ／Ｌ １７β－雌二醇,可以显著提高胚胎在共培养系统中的发育率、粘附率和扩展率。以上结果表明：小鼠 胚胎与小鼠子宫单层上皮细胞共培养系统是研究胚泡着床机理较理想的研究手段。     

共培养体系在牛核移植胚体外发育培养中的应用

采用电融合法构建牛体细胞核移植重构胚,分析共培养细胞类型、传代次数、细胞冻-融以及蛋白质添加物(BFF和FBS)对牛体细胞核移植胚体外发育的影响,探讨胚胎体外共培养的条件,以建立优化的共培养体系。结果表明与非共培养组相比,共培养组重构胚的囊胚发育率以及胚胎细胞数显著增加(P<0.05),而输卵管上皮细胞共培养组同颗粒细胞共培养组相比胚胎细胞数显著增加(P<0.05),更适合做共培养细胞;随着共培养细胞传代次数的增加重构胚囊胚发育率及胚胎细胞数显著下降(P<0.05),共培养细胞在冷冻处理后重构胚的囊胚率和胚胎细胞数都显著下降(P<0.05);BFF较FBS更能促进牛核移植胚的囊胚发育率(P<0.05)。表明应用新鲜原代输卵管上皮细胞进行牛核移植胚胎的共培养,并在SOFaa添加10?F能够有效促进核移植胚胎的体外发育。     

昆明小鼠原核胚在不同培养液中的体外发育

目的优化昆明小鼠原核胚胎体外培养系统,提高胚胎发育率.方法小鼠经超排获得原核期胚胎,制备小鼠输卵管上皮共培养系统,使用M16、CZB和KSOM培养液进行体外培养,并对体内和体外发育的囊胚细胞计数.结果在KSOM和CZB中添加胎牛血清能显著提高胚胎囊胚发育率(14.71%对85.71%;6.45%对10.81%);输卵管上皮共培养可以提高胚胎的卵裂率和囊胚发育率,同时提高胚胎质量和同步发育,小鼠胚胎在KSOMFBS中囊胚发育率达85.19%,显著高于CZB和M16.结论在小鼠输卵管上皮共培养条件下,KSOMFBS能够很好支持昆明小鼠原核期胚胎体外发育.     

不同培养条件对猪卵母细胞IVM、IVF的影响

通过优化猪卵母细胞体外成熟、体外受精和胚胎体外发育体系,以进一步提高体外胚胎的生产效率和质量.研究了激素存在时间、不同激素和不同血清对猪卵母细胞体外成熟的影响;共培养体系、精卵作用时间、去除卵丘细胞的方法对猪体外受精及早期胚胎发育的影响.猪卵母细胞IVM培养48h,前24h内加入PMSG、hCG,后24h将其去除,卵母细胞总成熟率为79.54%;培养液添加15?S或15%NCS,卵母细胞成熟率分别为79.48%和74.81%;PMSG、HCG和E2配合使用后卵母细胞成熟率为81.42%.在IVF前用吹打法获得的卵裂率、桑椹胚率分别为37.89%和8.54%,精卵共孵育6h或8h的卵裂率(40.52%,37.24%)、桑椹胚率(8.42%,7.85%),以及用输卵管上皮细胞共培养所获得的卵裂率(40.84%)、桑椹胚率(9.53%)均显著高于其它各组.     

小鼠胚胎干细胞对黑色素瘤细胞体外生物学行为的影响

探讨体外共培养环境中小鼠胚胎干细胞对小鼠黑色素瘤B16细胞的影响。建立C57BL/6小鼠胚胎干细胞系,通过小鼠胚胎干细胞与肿瘤细胞体外共培养模型观察小鼠胚胎干细胞对肿瘤细胞的形态及生长行为的影响,MTT法与transwell小室法分别检测共培养后肿瘤细胞粘附性、迁移性及侵袭性的变化。共培养中小鼠胚胎干细胞能够侵入并推开小鼠黑色素瘤细胞形成自己的生长空间,与对照组比较共培养后肿瘤细胞的粘附性、迁移性及侵袭性均显著降低(P<0.05,P<0.01)。结果表明体外共培养体系中小鼠胚胎干细胞能够侵袭肿瘤细胞,并降低细胞粘附、迁移及侵袭相关恶性生物学行为。     

小鼠胚胎对人卵巢癌细胞生物学行为影响的体外研究

探讨体外共培养环境中小鼠胚胎对人卵巢癌细胞HO8910PM的影响.通过小鼠胚胎与肿瘤细胞体外共培养模型观察小鼠胚胎对肿瘤细胞的形态及生长行为的影响,Annexin V-EGFP/PI原位检测与小鼠胚胎共培养后肿瘤细胞的凋亡情况,MTT粘附实验、transwell迁移及侵袭实验研究与小鼠胚胎共培养后的人卵巢癌细胞的粘附性、迁移性及侵袭性的变化.共培养时小鼠胚胎能够侵入人卵巢癌细胞并推开肿瘤细胞形成自己的生长空间,激光共聚焦显微镜下见胚胎周围的肿瘤细胞凋亡增加,与对照组比较共培养后的HO8910PM肿瘤细胞的粘附性、迁移性及侵袭性均显著降低(P0.05、P0.01).结果表明体外共培养体系中小鼠胚胎能够侵袭肿瘤细胞,促进人卵巢癌细胞的凋亡,并使其粘附性、迁移及侵袭相关恶性行为降低.     

影响水稻幼穗培养体细胞胚胎发生因素的研究

用水稻幼穗为外植体进行组织培养,研究了影响其体细胞胚胎发生的有关因素,建立了高频率体细胞胚胎发生的培养程序。结果表明不同基因型之间体细胞胚胎发生率的差异达到61．2％;生长素2,4－D对诱导水稻体细胞胚起重要的调控作用,细胞分裂素BA有一定的协同促进作用。干燥处理可提高愈伤组织体细胞胚胎发生率,愈伤组织含水量在60％～80％范围的培养效果较好;外源DNA溶液浸泡发育早期的心状体细胞胚．其进一步发育时异常胚的频率显著增加．成苗率降低。     

白蜡树属植物体细胞胚胎发生进展

综述了近年来国内外对白蜡树属植物体细胞胚胎发生的研究概况,对影响体细胞胚胎发生的主要可控因素以及体细胞胚胎发生过程、机理、组织学方面作了介绍,并提出了白蜡树属体细胞胚胎发生研究的应用前景。     

山羊体外受精胚胎序贯培养的研究

目的：根据早期胚胎不同发育阶段的营养需求设计体外培养体系,以建立适于山羊早期胚胎体外发育的序贯培养方法。方法：对屠宰场来源山羊卵巢卵母细胞进行体外成熟和体外受精后移入添加不同胚胎发育影响因子的培养体系中进行体外培养,显微镜观察、统计各阶段胚胎发育情况,并对培养的胚胎进行移植。结果：BSA和EGF对山羊体外受精卵具有明显促卵裂作用,培养系统中添加EGS、EGF、HTAU或p—Me可有效支持8-细胞期山羊胚胎克服发育阻滞而提高桑葚胚发育率;在不同胚胎期添加各发育影响因子进行序贯培养的卵裂率、≥8-细胞率和桑葚胚发育率分别为45．2％、60．6％和23．4％,序贯培养的胚胎移植后产羔率为11．1％。结论：宜根据早期胚胎各时期代谢特点和营养需求对山羊胚胎进行序贯培养。     

人胚胎干细胞高效分化为巨核细胞模型的建立

人胚胎干细胞具有无限增殖潜能,且能够分化为包括巨核细胞在内的大多数的成熟血细胞。因此,为解决临床治疗血小板来源不足而建立一种由人胚胎干细胞高效分化获得成熟巨核细胞的分化模型具有重要应用前景。该文利用人胚胎干细胞与m AGM-S3基质细胞系共培养进行早期造血前体细胞的定向分化,并在分化第14 d获得大量"卵石样"造血前体细胞(CD43+细胞、CD45+细胞)。将"卵石样"造血前体细胞分离后,用无血清培养基分阶段添加SCF、TPO、IL-6、IL-3、FLt-3、IL-11等细胞因子进行巨核细胞定向诱导分化。结果显示,在分化的第3 d,CD41a+细胞比例可高达48.5%,CD42b+细胞比例可高达30.0%。对分化第6 d的细胞进行Wright-Giemsa染色,可见形态典型的巨核细胞。综上所述,该研究初步建立了一种人胚胎干细胞高效分化为巨核细胞的模型,为体外获得大量巨核细胞奠定了基础。     

Bovine oviductal epithelial cells: their cell culture and applications in studies for reproductive biology

Epithelial cells of the mammalian oviduct play an important role in reproductive and developmental events that occur there. Oviductal epithelial cells from several mammalian species can be isolated and cultured in serum or serum-free medium in vitro and cell culture of bovine oviductal epithelial cells (BOEC) has been described by many investigators. Cultured BOEC show a wide variety of secretory activities and these secretory factors may influence early embryonic development or sperm function. Monolayer cultures of BOEC have been widely used for in vitro co-culture of bovine preimplantation embryos. The use of BOEC co-culture systems has improved embryonic development in nearly all the studies conducted. In addition, interaction of bovine spermatozoa with BOEC, in a similar manner to that observed for spermatozoa in vivo, induced specific changes in sperm capacitation and consequently improved the fertilizing capacity of bovine spermatozoa in vitro. Thus co-culture systems with BOEC may not only offer an excellent model for studying the mechanisms of capacitation and acrosome reaction of bovine spermatozoa but also provide a useful tool for the improvement of embryo development in vitro.     

Autologous embryo-cumulus cells co-culture and blastocyst transfer in repeated implantation failures: a collaborative prospective randomized study

In repeated implantation failure, the co-culture of human embryos with somatic cells has been reported to promote the improvement of embryos quality, implantation and pregnancy rate. It was reported that feeder cells can be more beneficial to the oocyte and embryo by detoxifying the culture medium and supporting embryo development via different pathways. In this study, 432 patients, each with a minimum of three repeated implantation failures, were accepted for a prospective randomized study with or without autologous cumulus cell embryo co-culture and transfer at day 3 or day 5-6. We also investigated the expression of leukaemia inhibitor factor (LIF) and platelet activating factor receptor (PAF-R) on day 3 confluent cumulus cells. The statistic analysis of the data showed significant difference of implantation and clinical pregnancy rates between classical culture and day 3 compared with co-culture and day 5-6 transfer. The molecular analysis showed that cumulus cells express the LIF and the PAF-R genes and confirmed the possible positive role of growth factors and cytokines in early embryo development. Embryo co-culture systems with autologous cells can be beneficial in routine in vitro fertilization for embryo selection and implantation improvement. More molecular investigations need to be done to improve elucidation of the complex dialogue between the embryo and feeder cells prior to implantation and to understand the involved biological function and molecular process during embryo development.     

Evaluation of mitomycin-treated vero cells as a co-culture system for IVM/IVF-derived bovine embryos

Support of the in vitro development of IVM/IVF-derived bovine embryos by Vero cells was evaluated by comparing the following treatment groups: 1) proliferating (Unt-Vero) vs nonproliferating (Mit-Vero) cells; 2) supplementation of medium with estrous cow serum (ECS) vs bovine serum albumin (BSA); 3) Mit-Vero cells vs bovine oviduct epithelial cells (BOECs); and 4) addition of leukemia inhibitory factor (LIF) to Mit-Vero cell co-cultures at Day 1 vs Day 4. Mit-Vero cells stimulated higher rates of blastocysts (Day 7, 40 vs 27%) and hatched blastocyst (Day 10, 38 vs 12%) formation than Unt-Vero cells. These rates were comparable to those obtained with BOECs; blastocyst hatching was slightly higher following co-culture with Mit-Vero cells (36%) than BOECs (29%). Blastocyst formation was similar in ECS- vs BSA-supplemented medium; however, hatching was greatest (37%) during co-culture in medium +10% ECS. While the addition of LIF throughout the co-culture period was ineffective, addition of the cytokine beginning at Day 4 slightly increased blastocyst formation rates. Evaluation of LIF secretion using ELISA revealed detectable levels of the cytokine in Mit-Vero-conditioned medium (50 pg/10(5) cells); this may explain the minimal influence of exogenous LIF during embryo co-culture. Mit-Vero cells provided comparable support of bovine embryo development when used even up to 2 wk after establishment as monolayers. In conclusion, Mit-Vero cells provide a readily-available, safe and easy-to-use co-culture method which is at least as supporting of bovine embryo development as BOECs. One contribution of these cells may be secretion of the cytokine LIF.     

In vitro development up to hatching of bovine in vitro-matured and fertilized oocytes with or without support from somatic cells

To verify the importance of somatic cells upon in vitro embryo development, in vitro-matured (IVM) and -fertilized (IVF) bovine oocytes were cultured in TCM 199 supplemented with estrous cow serum (10% v/v) and 0.25 mM sodium pyruvate (ECSTCM) under the following treatments: 1) ECSTCM alone; 2) together with bovine oviduct epithelial cells (BOEC); 3) with cumulus cells (CC); 4) in fresh BOEC conditioned ECSTCM; or 5) in frozen-thawed BOEC conditioned ECSTCM. Culturing zygotes encased in cumulus cells significantly reduced the cleavage rate (P<0.05). There was no difference between culture systems in the proportions of embryo development through the 8-cell stage (P=0.42) up to the morula/blastocyst stages (P=0.50) at Day 7 post insemination. However, co-culture with BOEC yielded the highest percentage (21.2% of zygotes; P<0.05) of quality Grade-1 and Grade-2 embryos with the number of blastomeres per embryo (114.4) comparable to that of 7-day-old in vivo-developed embryos of similar grades (102.5), and higher (P<0.05) than those of the other treatments. The ratio of blastocysts to total morulae/blastocysts obtained from frozen-thawed conditioned medium was lower (P<0.05) than that from ECSTCM or after co-culture with BOEC at Day 7 post insemination. On average, 7.5 to 17.5% of the zygotes developed to blastocyst, expanded blastocyst and hatched blastocyst stages by Day 10 post insemination, depending upon the culture system. The difference between treatments, however, was not significant (P=0.68). The results indicate that chronological development up to hatching of bovine IVM-IVF embryos is not favored by somatic cells; however, the presence of viable oviduct epithelial cells in culture significantly improves the quality of 7-day-old embryos.     

Development of a bovine luteal cell in vitro culture system suitable for co-culture with early embryos

The cross talk between the corpus luteum (CL) and the early embryo, potentially relevant to pregnancy establishment, is difficult to evaluate in the in vivo bovine model. In vitro co-culture of bovine luteal cells and early embryos (days?2?C8 post in vitro fertilization) may allow the deciphering of this poorly understood cross talk. However, early embryos and somatic cells require different in vitro culture conditions. The objective of this study was to develop a bovine luteal cell in vitro culture system suitable for co-culture with early embryos in order to evaluate their putative steroidogenic and prostanoid interactions. The corpora lutea of the different stages of the estrous cycle (early, mid, and late) were recovered postmortem and enriched luteal cell populations were obtained. In experiments 1 and 2, the effects of CL stage, culture medium (TCM, DMEM-F12, or SOF), serum concentration (5 or 10%), atmosphere oxygen tension (5 or 20%), and refreshment of the medium on the ability of luteal cells to produce progesterone (P₄) were evaluated. The production of P₄ was significantly increased in early CL cultures, and luteal cells adapted well to simple media (SOF), low serum concentrations (5%), and oxygen tensions (5%). In experiment 3, previous luteal cell cryopreservation did not affect the production of P₄, PGF_2??, and PGE₂ compared to fresh cell cultures. This enables the use of pools of frozen?Cthawed cells to decrease the variation in cell function associated with primary cell cultures. In experiment 4, mineral oil overlaying culture wells resulted in a 50-fold decrease of the P₄ quantified in the medium, but had no effect on PGF_2?? and PGE₂ quantification. In conclusion, a luteal cell in vitro culture system suitable for the 5-d-long co-culture with early embryos was developed.     

Serum free embryo culture medium improves in vitro survival of bovine blastocysts to vitrification

The aim of this study was to examine the effects of co-culture with Vero cells during the in vitro maturation (IVM) and three culture media, B2+5% fetal calf serum (FCS) on Vero cells, synthetic oviduct fluid (SOF)+5% FCS, and SOF+20 gL(-1) bovine serum albumin (BSA), on the developmental competence of the embryos and their ability to survive vitrification/warming. We also tested the effect of morphological quality and the age of the embryo on its sensitivity to vitrification. The IVM system neither affects the embryo development up to Day 7 nor survival rates after vitrification. The culture of embryos in SOF+FCS and in Vero cells+B2 allowed obtaining more Day 6 and Day 7 blastocysts, and a higher % of Day 7 blastocysts vitrified than culture in SOF+BSA. Contrarily, on Day 8, more blastocysts were vitrified in SOF+BSA than in SOF+FCS. Blastocysts quality affected development after vitrification/warming, and Day 7 embryos showed higher survival rates than their Day 8 counterparts. Day 7 blastocysts produced in Vero cells or in SOF+BSA survived at higher rates than those produced in SOF+FCS at 24 and 48 h after warming. Embryo culture with BSA allows obtaining hatching rates after vitrification/warming higher than those obtained after co-culture with Vero cells in B2 and FCS. Moreover, this system provides hatching rates from Day 8 blastocysts comparable to those obtained on Day 7 in Vero cells. Further studies, including embryo transfer to recipients, are needed to clarify factors affecting the freezability of in vitro produced bovine embryos.     

Metabolite availability as a window to view the early embryo microenvironment in vivo

A preimplantation embryo exists independent of blood supply, and relies on energy sources from its in vivo environment (e.g., oviduct and uterine fluid) to sustain its development. The embryos can survive in this aqueous environment because it contains amino acids, proteins, lactate, pyruvate, oxygen, glucose, antioxidants, ions, growth factors, hormones, and phospholipids—albeit the concentration of each component varies by species, stage of the estrous cycle, and anatomical location. The dynamic nature of this environment sustains early development from the one‐cell zygote to blastocyst, and is reciprocally influenced by the embryo at each embryonic stage. Focusing on embryo metabolism allowed us to identify how the local environment was deliberately selected to meet the dynamic needs of the preimplantation embryo, and helped reveal approaches to improve the in vitro culture of human embryos for improved implantation rates and pregnancy outcome.     

Mammalian embryo co-culture: trials and tribulations of a misunderstood method

Embryo-somatic cell co-culture was devised over 40 years ago in an attempt to improve the development and viability of mammalian preimplantation embryos generated and cultured in vitro. While initial endeavours were successful in this respect, other studies soon highlighted a number of significant long-term detrimental impacts of this approach. Surprisingly little is known about the mechanisms underlying the beneficial effects of co-culture, although the production of embryotrophic compounds, modulation of nutrient profile, protection against culture-induced stress and/or toxin clearance are all contenders. The extent to which the inadvertent exposure of embryos to serum accounts for many of these effects remains open to question. Although the popularity of somatic cell co-culture has recently declined in favour of the use of sequential media due to concerns associated with its risk of disease transmission and long-term sequelae, we argue that complete dismissal of this technique is ill advised, given that our limited understanding of basic somatic cell interactions has prevented us from fully exploiting its potential. In this respect, there is some merit in focussing future research strategies based on reconstructed maternal tract tissue. Although the use of co-culture in clinical practice is unacceptable and its implementation in domestic species for commercial purposes should be viewed with diffidence, this technique can still provide a wealth of information on the development of novel, more physiological embryo in vitro culture systems. The proviso for acquiring such information is to gain a fuller understanding of the culture requirements/biochemistry of somatic cells and their interaction with the early conceptus.     

Bovine embryo morphology and evaluation

The following paper briefly reviews the morphology of the bovine embryo and presents a retrospective analysis of bovine embryo transfer results accumulated from April to December of 1982 at a commercial embryo transfer center. Of particular interests were bovine embryo morphology, assessment of embryo quality, and recipient-donor, recipient-embryo synchrony requirements. Embryos were recovered from superovulated donors five to nine days after estrus (estrus = day O). All embryos were individually examined at 200X for cell stage of development and embryo quality. Embryos were nonsurgically transferred to recipients that were within two days of estrous cycle synchrony with the donor. Attempts were made to synchronize estimated developmental age of embryos to the day of the recipient cycle. A high degree of variability was observed in morphological development and embryo quality within and among donors. Embryo recovery in individual donors resulted in a wide range of embryonic cell stages, often differing in estimated developmental ages from 24 to 48 hours. A total of 783 embryos were transferred, resulting in 308 pregnancies. Stage of embryonic development (16-cell through hatched blastocyst) had little effect on pregnancy rates. Embryo quality was a more accurate predictor of success. Embryos of excellent, good, fair and poor categories resulted in 45%, 44%, 27% and 20% pregnancy rates, respectively. Recipient-donor estrous cycle synchrony of two days in either direction did not significantly alter pregnancy rates. However, 88% of 258 pregnancies (584 total transfers) occurred with a +/-1 day recipient-embryo synchrony compared to 74% based on +/-1 day recipient-donor cycle synchrony (P<0.001). Results suggest that transfer of bovine embryos based on synchrony between day of recipient cycle and state of embryonic development provides higher pregnancy rates than transfers based on recipient-donor cycle synchrony.     

Co-culture,oviduct secretion and the function of oviduct-specific glycoproteins.

Co-cultures of embryos with somatic cells, usually in the form of monolayers, or conditioned medium from these somatic cells, results in development past the early stage blocks and the formation of hatched blastocysts. Optimum rates of development are not achieved, however, and the task is to investigate components of the oviduct that are obligatory or facilitative for embryo development. Glycine and alanine are amino acids present in much higher concentrations in oviduct fluid than in serum or culture media. Glycoproteins specifically produced by the oviduct around oestrus bind to embryos and aid development but are absent from most culture media. These glycoproteins are induced by oestrogen in vivo but not in vitro. It is our contention that co-cultures of mammalian embryos should include appropriate concentrations of amino acids and a source of embryotrophic glycoproteins as an additive or by including stromal cells in addition to epithelial cells.