Production of chimeric calves by aggregation of in vitro-fertilized bovine embryos without zonae pellucidae

Bovine embryos produced by in vitro maturation (IVM), fertilization (IVF) and culture (IVC) were used to produce aggregation chimeras. An aggregated chimera was produced by combining bovine IVF embryos (Holstein × Japanese Black and Japanese Brown × Limousin breeds) which were cultured in vitro without the zonae pellucidae. Forty-eight hours after IVF, embryos at the 8 cell-stage were used to produce aggregation chimeras. In Experiment I, the zonae pellucidae was removed by a microsurgical method using a microblade or by treatment with 0.25% pronase. Holstein × Japanese Black embryos were aggregated with Japanese Brown × Limousin embryos after zonae removal by hand manipulation in culture medium. In Experiment II, the viability of the aggregated embryos developing into blastocysts was examined by measuring the extent of development. The number of aggregated embryos and embryos developed into blastocysts was 34 (91.9%) and 24 (70.6%), respectively, when the zonae pellucidae was removed by the microsurgical method; and 12 (92.3%) and 6 (50.0%), respectively, when the zonae pellucidae was removed using the 0.25% pronase treatment. The size of the aggregated embryos was significantly different from that of the normal embryos when cultured in vitro until Day 10, but not different thereafter. Five aggregated embryos were transferred nonsurgically to the recipients, resulting in 1 pregnancy and the birth of 2 chimeric calves. Skin color was used as evidence of chimerism.     

Unexpected durability of PKH 26 staining on rat adipocytes

In a case of autologous mature fat cell transplantation to an individual rat, persistence of adipose staining with PKH26 was detected 14.5 months later. Fluorescent fat cells with spotty surface markings were easily visible. Such a long period of persistence and stability of staining exceeds the expectation from previous reports, and the given half-life of the substance. This finding encourages the use of the dye for long-term follow-up of connective tissue cells, especially adipocytes and preadipocytes, following transplantation.     

Time-lapse cinematography study of the germinal vesicle behaviour in mouse primary oocytes treated with activators of protein kinases A and C

Previous studies have shown that early embryos contain information that can alter the developmental fate of adjacent cells and transferred nuclei. In this report we show that a specific combination of cells from early murine embryos, a single blastomere from an eight-cell embryo placed under the zona pellucida with a two-cell embryo, results in a difference in incorporation of ³H-uridine and expression of two protein bands between the chimeric treatment group and the nonchimeric controls, a single blastomere from an eight-cell embryo in a separate zona pellucida and a two-cell embryo. The incorporation of ³H-uridine in the chimeric group and nonchimeric control group was significantly different at 45 hours after chimerization (P < .02). A stage-specific protein band (52k) on a polyacrylamide gel detected with fluorography was found to be qualitatively different (present more often; P < .01) and another stage-specific protein band (48k) was found to be quantitatively different (more protein; P equals; .07) in the chimeric treatment vs. the nonchimeric controls at 45 hours after chimerization. These results suggest communication between the cells resulting in a change in their incorporation of uridine and protein synthetic profiles.     

Requirement of N-myc protein down-regulation for neuronal differentiation in the spinal cord

Previous work has indicated that N-myc expression occurs widely in the developing central nervous system, but its level changes dynamically with region- and stage-specificities. We show in the present report that in the developing spinal cord of the mouse, N-myc protein expression takes place in the ventricular zone and reaches its maximum at the outermost layer, but is extinct in the intermediate zone, indicating that N-myc protein is not expressed in mature neurons. We examined the effect of forced, persistent N-myc expression in development of the spinal cord in order to understand the functional significance of N-myc down-regulation. We made embryonic stem (ES) cell lines that constitutively expressed N-myc at a high level, then produced mouse embryo chimeras with a high contribution of the ES cells. The majority of the chimeras developed to day 12 with normal gross morphology, but in these chimeras neuronal differentiation in the spinal cord was perturbed at the histological level. Intermediate zones and ventral horns were formed, but the expression of N-CAM and neurofilaments was diminished. Chimeras using β-galactosidase-expressing recipient embryos indicated that inhibition of the neuronal differentiation was a cell-autonomous effect of persistent N-myc expression. These observations indicate that N-myc down-regulation in individual cells is required for full differentiation of neurons.     

Restoring the endothelium of cryopreserved arterial grafts: co-culture of venous and arterial endothelial cells

The use of arterial homografts in clinical practice is becoming increasingly common, yet there is an urgent need to address one of the most well-established problems associated with their use: the loss of integrity of the endothelium following cryopreservation. The partial lack of endothelium causes contact between the extracellular matrix and blood flow, which, in turn, often gives rise to thrombosis and/or restenosis. Our objective was first to attempt to replace the arterial endothelial cells lost during the cryopreservation process by seeding autologous venous endothelial cells, and to evaluate the behaviour of venous and arterial endothelial cells in co-culture. The idea was to establish whether venous endothelial cells would be accepted by arterial endothelial cells and could therefore be used to restore the endothelial lining for the subsequent use of these vessels in in vivo grafting procedures. For the co-culture experiments, endothelial cells were obtained from the jugular vein and both iliac arteries of the minipig by treatment with 0.1% type I collagenase. The venous endothelial cells were fluorescently labelled with the membrane intercalating dye PKH26. Equal numbers of venous and arterial endothelial cells were mixed and co-cultured for 24h, 48h or 4 days. Cell viability, determined by 2% trypan blue staining and the TUNEL method, was established before and after fluorescence labelling. Cellular activity was determined by estimating PGI2 levels in the cultures. The proliferation index was established by [H(3)]thymidine (1muCi/ml) in the cell culture medium. For the in vivo tests, 5 cm length segments of minipig iliac artery were used to establish the groups: control (n = 6), fresh arterial segments; group I (n = 16), cryopreserved arterial segments and group II (n = 16), cryopreserved arterial segments seeded with autologous venous endothelial cells. The cryopreserved vessels in group II were seeded by flooding with a labelled venous endothelial cell suspension. Once seeded, the arterial segments were included in an in vitro flow circuit. All the specimens were processed for fluorescence and light microscopy, and scanning electron microscopy. The denuded endothelial surface was determined in each group. Cell death was evaluated by the TUNEL method. We confirmed the existence of intercellular PECAM1-type junctions between venous (PKH26+) and arterial cells in co-culture and the functional activity of the cells. The cryopreserved arterial segments showed a well-preserved wall structure. However, different size areas of marked endothelial denudation were detected. After seeding with labelled cells (PKH26+), these denuded areas of the cryopreserved artery were entirely covered by fluorescent cells. After seeding, a drop in the proportion of damaged endothelial cells was recorded. Despite some loss of seeded cells after inclusion in the in vitro flow circuit, the endothelial cell count was not significantly different to those recorded for control, non-cryopreserved specimens. In conclusion arterial and venous endothelial cells growing in co-culture modify their behaviour to form multilayers. The two cell populations form normal PECAM1 junctions and preserve their functional properties. Seeding autologous venous endothelial cells on the luminal surface of cryopreserved arterial segments serves to restore the integrity of the endothelial layer.     

Birds bias offspring sex ratio in response to livestock grazing

Livestock grazing, which has a large influence on habitat structure, is associated with the widespread decline of various bird species across the world, yet there are few experimental studies that investigate how grazing pressure influences avian reproduction. We manipulated grazing pressure using a replicated field experiment, and found that the offspring sex ratio of a common upland passerine, the meadow pipit Anthus pratensis, varied significantly between grazing treatments. The proportion of sons was lowest in the ungrazed and intensively grazed treatments and highest in treatments grazed at low intensity (by sheep, or a mixture of sheep and cattle). This response was not related to maternal body condition. These results demonstrate the sensitivity of avian reproductive biology to variation in local conditions, and support growing evidence that too much grazing, or the complete removal of livestock from upland areas, is detrimental for common breeding birds.     

肿瘤,一个发育生物学问题

发育生物学是研究生物变化过程的科学,尤其是对胚胎,因为胚胎是动植物从受精卵发育到成体的必经之途,是介于基因型和表型之间的过渡体。肿瘤,是分化异常、生长失控的细胞集合体,恶性肿瘤严重威胁着人们的身心健康。在发育生物学领域,人类对自身的认识,尤其是对受精卵到个体发育的解读在不断地探索。同样,人们对肿瘤的研究也在不断地深入。研究发现肿瘤细胞和胚胎细胞生物学行为存在某些相似之处,这启发人们从发育生物学角度去认识肿瘤的发生、发展。本文从发育生物学角度详细评述了肿瘤细胞的起源、胚胎与肿瘤相似性和差异性比较及肿瘤与胚胎相互作用的研究进展。     

Sexing and detection of gene construct in microinjected bovine blastocysts using the polymerase chain reaction

We present a polymerase chain reaction (PCR)-based procedure for rapid bovine embryo sexing and classifying embryos for the presence of exogenous DNA. Fourteen bovine blastocysts microinjected with gene construct DNA at the pronuclear stage were divided into quarters and subjected to amplification with construct-specific and sex gene-specific (ZFY/ZFX) primers in the same initial PCR reaction. Blastocysts carrying microinjected construct DNA could be identified by the presence of construct-specific PCR product in approximately 4 h. Approximately half of the microinjected and two of 16 non-microinjected blastocysts typed PCR-positive for the construct DNA. Owing to erroneous amplifications in the two non-microinjected control blastocysts, and the inability of the system to distinguish integrated from non-integrated copies of the microinjected construct, the number of construct-positive blastocysts determined in our assay most likely overestimates the number of true transgenic embryos. Nevertheless, using this assay, we were able to determine that approximately half of the microinjected embryos were negative for the transgene construct and thus could be eliminated from transfer to a recipient cow. Embryo sexing was achieved in less than 6 h by restriction fragment length polymorphism analysis of nestedZFY/ZFXPCR products reamplified from initial PCR reactions. In 11/14 microinjected blastocysts all sections assayed unambiguously as the same sex. In one embryo, only one section was analysed, while two other blastocysts whowed some discrepancies of sexing results between the sections analysed. The approach employed here to determine the sex and presence of microinjected construct DNA in bovine preimplantation embryos is rapid, accurate among different sections of an embryo and can be used to increase the efficiency of current transgenic cattle production procedures.     

Offspring born from chimeras reconstructed from parthenogenetic and in vitro fertilized bovine embryos

Chimeric embryos were produced by aggregation of parthenogenetic (Japanese Red breed) and in vitro fertilized (Holstein breed) bovine embryos at the Yamaguchi Research Station in Japan and by aggregation of parthenogenetic (Red Angus breed) and in vitro fertilized (Holstein breed) embryos at the St. Gabriel Research Station in Louisiana. After embryo reconstruction, live offspring were produced at each station from transplanting these embryos. The objective of this joint study was to evaluate the developmental capacity of reconstructed parthenogenetic and in vitro fertilized bovine embryos. In experiment I, chimeric embryos were constructed: by aggregation of four 8‐cell (demi‐embryo) parthenogenetic and four 8‐cell stage (demi‐embryo) IVF‐derived blastomeres (method 1) and by aggregation of a whole parthenogenetic embryo (8‐cell stage) and a whole IVF‐derived embryo (8‐cell stage) (method 2). Similarly in experiment II, chimeric embryos were constructed by aggregating IVF‐derived blastomeres with parthenogenetic blsatomeres. In this experiment, three categories of chimeric embryos with different parthenogenetic IVF‐derived blastomere ratios (2:6; 4:4, and 6:2) were constructed from 8‐cell stage bovine embryos. In experiment III, chimeric embryos composed of four 8‐cell parthenogenetic and two 4‐cell IVF‐derived blastomeres or eight 16‐cell parthenogenetic and four 8‐cell IVF‐derived blastomeres were constructed. Parthenogenetic demi‐embryos were aggregated with sexed (male) IVF demi‐embryos to produce chimeric blastocysts (experiment IV). In the blastocyst stage, hatching and hatched embryos were karyotyped. In experiment V, chimeric embryos that developed to blastocysts (zona‐free) were cryopreserved in ethylene glycol (EG) plus trehalose (T) with different concentrations of polyvinylpyrrolidone (PVP; 5%, 7.5%, and 10%). In experiment I, the aggregation rate of the reconstructed demi‐embryos cultured in vitro without agar embedding was significantly lower than with agar embedding (53% for 0% agar, 93% for 1% agar, and 95% for 1.2% agar, respectively). The aggregation was also lower when the aggregation resulted from a whole parthenogenetic and IVF‐derived embryos cultured without agar than when cultured with agar (70% for 0% agar, 94% for 1% agar, and 93% for 1.2% agar, respectively). The development rate to blastocysts, however, was not different among the treatments. In experiment II, the developmental rates to the morula and blastocyst stages were 81%, 89%, and 28% for the chimeric embryos with parthenogenetic:IVF blastomere ratios of 2:6, 4:4, and 6:2, respectively. In experiment III, the developmental rate to the morula and blastocyst stages was 60% and 65% for the two 4‐cell and four 8‐cell chimeric embryos compared with 10% for intact 8‐cell parthenogenetic embryos and 15% for intact 16‐cell parthenogenetic embryos. To verify participation of parthenogenetic and the cells derived from the male IVF embryos in blastocyst formation, 51 embryos (hatching and hatched) were karyotyped, resulting in 27 embryos having both XX and XY chromosome plates in the same sample, 14 embryos with XY and 10 embryos with XX. The viability and the percentage of zona‐free chimeric embryos at 24 hr following cryopreservation in EG plus T with 10% PVP were significantly greater than those cryopreserved without PVP (89% vs. 56%). Pregnancies were diagnosed in both stations after the transfer of chimeric blastocysts. Twin male (stillbirths) and single chimeric calves were delivered at the Yamaguchi station, with each having both XX and XY chromosomes detected. Three pregnancies resulted from the transferred 40 chimeric embryos at the Louisiana station. Two pregnancies were lost prior to 4 months and one phenotypically‐ chimeric viable male calf was born. We conclude that the IVF‐derived blastomeres were able to stimulate the development of bovine parthenogenetic blastomeres and that the chimeric parthenogenetic bovine embryos were developmentally competent. Mol. Reprod. Dev. 53:159–170, 1999. © 1999 Wiley‐Liss, Inc.