Effects of retinoic acid and dimethylsulfoxide on the morphogenesis of the sea urchin embryo

Sea urchin embryos of the species Paracentrotus lividus were treated continuously with different concentrations of all-trans retinoic acid (RA) or dimethylsulfoxide (DMSO) at different developmental stages. A delay in embryonic development was observed when embryos were cultured in the presence of 2x10^?5 M RA, between 1 and 12 hours of development. Hence, at 48 hours of development, while control embryos had reached the pluteus stage, RA-treated embryos were at the prism stage. At 72 hours of development RA-treated embryos recovered and continued normal development reaching the pluteus stage. No effect was observed when treatment was performed before 1 hour or after 12 hours of developmet. DMSO treatment had no effect on normal sea urchin embryo development, although we observed that pigment cells, clearly visible at the pluteus stage, become visible earlier with respect to control embryos. This report confirms the advantages that the sea urchin embryo offers for the study of problems in cellular and developmental biology.     

Effects of streptozotocin- and alloxan-induced diabetes mellitus on mouse follicular and early embryo development

Mice were made diabetic by intraperitoneal injection of streptozotocin or alloxan. Germinal vesicle breakdown in the ovarian follicles at 8 h after hCG in control animals (57%) was significantly greater than in streptozotocin-(24%) and alloxan-(42%) diabetic animals (P less than 0.001). This delay in oocyte maturation was reversible by in-vivo insulin administration to diabetic mice. A developmental delay was also found for embryos recovered from diabetic mice. This developmental delay extended into the 72 h in-vitro cultures. Compared to control embryos, those from alloxan- and streptozotocin-treated mice demonstrated marked impairment in development as assessed by (1) distribution of developmental cell stages at each observation period and (2) rates of development which increasingly diverged at each observation period. In diabetic mice treated with insulin in vivo, the percentage of 2-cell embryos recovered increased. Furthermore, in streptozotocin- and alloxan-animals treated with insulin, the rate of in-vitro development of embryos, as well as their developmental stage distribution improved. We therefore suggest that uncontrolled diabetes mellitus, as well as contributing to the development of congenital malformations, may deleteriously affect reproductive performance both before fertilization and at the very earliest gestational stages.     

Influence of time of gene microinjection on development and DNA detection frequency in bovine embryos

The effect of DNA microinjection at various times afterin vitro insemination on DNA detection and survival rates of bovine embryos was investigated. Oocytes were inseminated 24 h after maturation with frozen/thawed semen prepared with a Percoll separation procedure. At 11, 15 and 19 h after insemination, embryos were centrifuged to visualize pronuclei and microinjected with a murine whey acidic protein-human protein C genomic DNA construct. After culture for 7 days on Buffalo Rat Liver cells, embryos were assessed for stage of development and assayed for the presence of the transgene by polymerase chain reaction. Of zygotes in the 11h after insemination treatment, 16% (25/152) of non-injected and 7% (11/161) of injected embryos developed to the morula or blastocyst stage. Comparable development of non-injected and injected embryos treated at 15h after insemination was 15% (23/158) and 4% (6/159) and treated at 19 h after insemination was 14% (23/162) and 1% (1/165), respectively. Development of injected embryos was greater (p<0.05) when injection was performed at 11 h after insemination compared to 19 h after insemination. Development of non-injected embryos was greater (p<0.01) than that of injected embryos. There was no difference in transgene detection frequency in embryos of all developmental states between treatments (53% at 11; 50% at 15; 48% at 19h after insemination). Injected embryos testing positive for the presence of the transgene exhibited increased development over negative embryos (p<0.01). Greater development efficiencies can be obtained in microinjected bovine embryos when injection is performed early in pronuclear formation.     

Phenotypic variability in human embryonic holoprosencephaly in the Kyoto Collection

BACKGROUND: Holoprosencephaly (HPE) is one of the most common developmental disorders of the brain associated with specific craniofacial dysmorphogenesis. Although numerous postnatal cases have been reported, early phases of its pathogenesis are not well understood. We examined over 200 cases of HPE human embryos both grossly and histologically, and studied their phenotypic variability and stage-specific characteristics. METHODS: Among over 44,000 human embryos in the Kyoto Collection of Human Embryos, 221 embryos have been diagnosed as HPE. Their developmental stages ranged from Carnegie stage (CS) 13 to CS 23. They were examined grossly and were also serially sectioned for detailed histological analysis. RESULTS: HPE embryos after CS 18 were classified into complete (true) cyclopia, synophthalmia (partially fused eyes in a single eye fissure), closely apposed separate eyes (possible forerunners of ethmocephaly and cebocephaly), and milder HPE with median cleft lip (premaxillary agenesis). At CS 13-17, when facial morphogenesis is not completed, HPE embryos had some facial characteristics that are specific to these stages and different from those in older HPE embryos. The midline structures of the brain, including the pituitary gland, were lacking or seriously hypoplastic in HPE embryos. Complete cyclopia was found in two cases after CS 18 but none at earlier stages. CONCLUSIONS: The early development of HPE in human embryos was systematically studied for the first time. The pathogenesis of craniofacial abnormalities, especially eye anomalies, in HPE was discussed in the light of recent studies with mutant laboratory animals.     

Biological effects of low-frequency pulsed magnetic fields on the embryonic central nervous system development. A histological and histochemical study

Numerous experiments have yielded contradictory results on the harmful action of magnetic fields on embryonic development. Pulsed magnetic fields appear to be able to delay normal development of embryos. In the present study, fertilized Gallus domesticus eggs were exposed during incubation to pulsed magnetic fields (harmonic signals of 10 μT for 1 second with silences of 0.5 seconds) of 50 or 100 Hz frequency. Embryos extracted at 45 h of exposure to fields of 50 Hz or 100 Hz frequency had significantly (p<0.05) fewer somite pairs compared with controls of the same age. At 15 days of incubation, only embryos exposed to a 10 μT- 50 Hz field had a significantly (p<0.05) higher somatic weight. At 21 days of incubation, a significantly lower somatic weight (p<0.01) and development stage (p<0.05) was found in embryos exposed to a 10 μT-100 Hz field than in controls, while a lower development stage (p<0.05) alone was observed in those exposed to a 10 μT-50 Hz field. In addition, animals showed higher expression of the neural marker NSE (neural specific enolase) after 21 days of development as determined by immunohistochemistry, with very low expression of glycosaminoglycans identified by alcyan blue staining. These results suggest that pulsed magnetic fields may be able to hinder normal embryonic development in vivo and to alter normal neural function, at least at the intensities and frequencies analyzed in the present study.     

The embryonic development of Xenopus laevis under a low frequency electric field

The aim of this study was to determine the effects of a low frequency electric field on the early embryonic development of frogs. The embryos of African clawed toads, Xenopus laevis, were exposed to a 20-μA electric current during the cleavage stages. The developmental processes of embryos during and after electric field exposure were monitored for teratogenic effects. All the embryos continuously exposed to the electric field died without undergoing any developmental processes. However, when the embryos were exposed to the electric field for 20-min periods (four times/over 2 d), the embryos developed into both normal tadpoles (70 %) and malformed tadpoles with light edema, reduced pigmentation, or axial anomalies, such as crooked tails. After exposure, the control embryos were at development stage 35.5 (2 d 2 h), while the normal embryos of the assay group were at developmental stage 41(3 d 4 h). There was a 1 d 2 h difference between the two developmental stages, revealing the importance of that time period for embryogenesis. In conclusion, the effects of electric current on Xenopus embryos are dependent on the initial developmental stage and the duration of exposure.     

水稻胚胎发育与萌发过程中凝集素的生物合成及其对转录与翻译抑制剂的敏感性

稻胚凝集素(RGL)在开花后7—13天之间合成活性很强,15天以后明显下降。7—13天之间RGL合成相当旺盛是由于这一时期编码RGL的mRNA得到迅速转录,而在开花后15—30天之间以及萌发4小时内RGL的合成主要是由胚分化发育期间(7—13天)所形成的mRNA所指导的。RGL主要在水稻胚胎发育过程中合成、积累,在萌发过程中几乎不表达,所以RGL是胚胎特异的蛋白质。     

Development of chick embryos in 1 Hz to 100 kHz magnetic fields

Summary Chick embryos were exposed during their 48 first hours of development to sinusoidally oscillating magnetic fields. The frequencies 1 Hz, 10 Hz, 16.7 Hz, 30 Hz, 50 Hz, 1 kHz, 10 kHz and 100 kHz, and the field strengths 0.1, 1, 10 and 100 A/m were used. Each exposure group consisted of 20 eggs. After the exposure, the embryos were examined for abnormalities and classified by the developmental stage. The percentage of abnormal embryos (%AE) was significantly increased at frequencies from 16.7 Hz to 100 kHz. Above a threshold field strength of about 0.1 to 1 A/m, %AE was rather independent of the field strength, varying from 16% to 56% in different exposure groups. 13% of the sham-exposed control embryos (n = 150) were abnormal. Only the 0.1 A/m exposure group differed significantly from the controls at 1 Hz, and no significant effect was found at 10 Hz. The developmental stage was in general not affected by the magnetic fields, but some abnormal embryos showed retarded development.     

The effect of quick-freezing in ethylene glycol on morphological survival and in vitro development of mouse embryos frozen at different preimplantation stages

This study was conducted to examine the effect of a quick-freezing protocol on morphological survival and in vitro development of mouse embryos cryopreserved in ethylene glycol (EG) at different preimplantation stages. One-cell embryos were harvested from 6-to 8-wk-old CB6F1 superovulated mice, 20 to 23 h after pairing with males of the same strain and hCG injection. The embryos were cultured in human tubal fluid (HTF) containing 4 mg/ml BSA under mineral oil at 37 degrees C in 5% CO(2) plus 95% room air at maximal humidity. Twenty-four to 96 h after collection, the embryos were removed from culture and frozen at the 2 cell, 4 to 8-cell, compact morula, early blastocyst, expanding blastocyst and expanded blastocyst stages. To perform the quick-freeze procedure, embryos were equilibrated in Dulbecco's phosphate buffered saline (DPBS) + 10 % fetal bovine serum (FBS) + 0.25 M sucrose + 3 M ethylene glycol (freeze medium) for 20 min at room temperature (22 to 26 degrees C) and loaded in a single column of freeze medium into 0.25-ml straws (4 to 5 embryos per straw). The straws were held in liquid nitrogen vapor for 2 min and immersed in liquid nitrogen. Embryos were thawed by gentle agitation in a 37 degrees C water bath for 20 sec and transferred to DPBS + 10 % FBS + 0.5 M sucrose (re-hydration medium) for 10 min at room temperature, rinsed 2 times in HTF plus 4 mg/ml BSA and then cultured for 24 to 96 h. Survival of embryos was based on their general morphological appearance after thawing and their ability to continue development upon subsequent culture in vitro. Survival of blastocysts after thawing also required expansion or reexpansion of the blastocoel after several hours in culture. Significant differences were found in the survival and development of mouse embryos at different developmental stages quick-frozen in ethylene glycol and sucrose: 2-cell embryos 43/84 (51%), 4 to 8-cell embryos 44/94 (47%), morulae and early blastocysts 56/70 (80%; P相似文献   

Utility of rapidly matured oocytes as recipients for production of cloned embryos from somatic cells in the pig

The present study was conducted to examine the utility of rapidly matured oocytes as recipients for production of porcine embryos reconstituted with adult skin fibroblasts and whether arrest of meiotic resumption of recipient oocytes at the germinal vesicle (GV) stage by dibutyryl cyclic AMP (dbcAMP) improves in vitro developmental rates after reconstruction. At 24 h of maturation in the medium, 36.3% of oocytes reached the metaphase II (MII) stage. At 30 h of maturation, the percentage (71.4%) of MII oocytes did not significantly differ from that (78.0%) at 42 h of maturation. When MII oocytes recovered at 24 h of maturation were used as recipients, 22/156 (14.1%) cloned embryos developing to the blastocyst stage was significantly (P < 0.05) higher than those of embryos reconstituted with oocytes collected at 30 h (5/168; 3.0%) and 42 h (13/217; 6.0%) of maturation. Culture of oocytes in medium containing 1 mM dbcAMP for 20 h maintained 72.9% in the GV stage, whereas only 15.0% of nontreated oocytes were in the GV stage (P < 0.05). The effect of dbcAMP was reversible. However, the treatment of recipient oocytes with dbcAMP did not affect the development of reconstructed embryos when compared with nontreated oocytes. These results indicate that rapidly matured oocytes are superior in their ability to support development of porcine reconstructed embryos; however, arrest of meiotic resumption of recipient oocytes at the GV stage by dbcAMP does not improve reconstructed embryo developmental rates.     

Nucleolar changes in bovine nucleotransferred embryos.

This study focused on nucleolar changes in bovine embryos reconstructed from enucleated mature oocytes fused with blastomeres of morulae or with cultured, serum unstarved bovine fetal skin fibroblasts (embryonic vs. somatic cloning). The nucleotransferred (NT) embryos were collected and fixed at time intervals of 1-2 h (early 1-cell stage), 10-15 h (late 1-cell stage), 22-24 h (2-cell stage), 37-38 h (4-cell stage), 40-41 h (early 8-cell stage), 47-48 h (late 8-cell stage), and 55 h (16-cell stage) after fusion. Immunocytochemistry by light and electron microscopy was used for structure-function characterization of nucleolar components. Antibodies against RNA, protein B23, protein C23, and fibrillarin were applied. In addition, DNA was localized by the terminal deoxynucleotidyl transferase (TdT) technique, and the functional organization of chromatin was determined with the nick-translation immunogold approach. The results show that fully reticulated (active) nucleoli observed in donor cells immediately before fusion as well as in the early 1-cell stage after fusion were progressively transformed into nucleolar bodies displaying decreasing numbers of vacuoles from the 2- to 4-cell stage in both types of reconstructed embryos. At the late 8-cell stage, morphological signs of resuming nucleolar activity were detected. Numerous new small vacuoles appeared, and chromatin blocks reassociated with the nucleolar body. During this period, nick-translation technique revealed numerous active DNA sites in the periphery of chromatin blocks associated with the nucleolar body. Fully reticulated nucleoli were again observed as early as the 16-cell stage of embryonic cloned embryos. In comparison, the embryos obtained by fetal cloning displayed a lower tendency to develop, mainly during the first cell cycle and during the period of presumed reactivation. Correlatively, the changes in nucleolar morphology (desegregation and rebuilding) were at least delayed in many somatic NT embryos in comparison with the embryonic NT group. It is concluded that complete reprogramming of rRNA gene expression is part of the general nuclear reprogramming necessary for development after NT.     

Development of hamster one-cell embryos recovered under different conditions to the blastocyst stage

One-cell stage embryos, recovered from superovulated golden hamsters (8 to 12 weeks of age) 12 hours after egg activation, were cultured in HECM-1 medium at 37 degrees C and 5% CO(2) in air. The culture conditions investigated were the time and temperature required for embro recovery, the pH shift of the washing medium, and the oxygen concentration of the gas phase during and after embryo recovery. Each condition was assessed by the developmental efficiency of the embryo as determined by morphological criteria. As the time required for embryo recovery was reduced, the developmental rates of the embryos were improved: 2.3% (3 128 ) 26.9% (35 130 ) at 5 and 3 minutes, respectively, as determined by the number of embryos developed to the blastocyst stage. No blastocysts were obtained when more than 10 minutes were required for embryo recovery. As the oxygen concentration was reduced from 40 to 20% or to 5%, rather high developmental rates were obtained even when the time required for embryo recovery was prolonged: 6.9% (9 130 ) and 21.7% (28 129 ) of the embryos developed to the blastocyst stage when they were recovered under 5% oxygen within 10 and 5 minutes, respectively. Neither the temperature during embryo recovery (37 degrees C and 25 degrees C) nor the pH shift (pH 7.22 to 7.52) of the washing medium used in embryo recovery procedures influenced the development of the embryos. These findings suggest that the developmental block in hamster embryos may involve oxidative stress, which may result from exposure to high oxygen concentration and light during the manipulation of oocytes and embryos.     

Production of F0 mice from embryonic stem cells injected eight-cell stage embryos which stored at refrigeration temperature

At refrigeration temperature, mouse embryos can retain their developmental ability for a couple of days. Previous research reports have focused on the effect of cool temperature on the development of 2-cell stage embryos, morulae or blastocysts and determined that the embryo still has the ability to produce offspring after about 48 h storage at refrigeration temperature. Here we examined whether refrigeration temperature affects the development of the eight-cell stage and if the stored eight-cell stage embryo can still be used as a host embryo for ES cell injection. Our results show that eight-cell stage embryos can develop into blastocysts and yield pups after cold storage for 24 and 48 h. After ES cell injection, stored eight-cell stage embryos can support ES cells developing to F0 pups. In summary, cool storage can preserve the developmental ability of eight-cell stage embryos for at least 48 h, allowing transportation of the embryos at refrigeration temperature between different labs and their subsequent use as host embryos for ES cell injection.     

Tolerance to vitrification of rat embryos at various developmental stages

Numerous genetically engineered rat strains have been produced via genome editing. Although freezing of embryos is helpful for the production and storage of these valuable strains, the tolerance to freezing of embryos varies at each developmental stage of the embryo. This study examined the tolerance to freezing of rat embryos at various developmental stages, particularly at the pronuclear stage. Embryos that had developed to the pronuclear, 2-cell, and morula stages were frozen via vitrification using ethylene glycol- and propylene glycol-based solutions. More than 90% of the embryos at all developmental stages survived after warming. The developmental rates to offspring of thawed embryos at the pronuclear, 2-cell, and morula stages were 19%, 41%, and 52%, respectively. Pronuclear stage embryos between the early and late developmental stages were then vitrified. The developmental rates to offspring of the thawed pronuclear stage embryos collected at 24, 28, and 31 h after the induction of ovulation were 17%, 21%, and 23%, respectively. These results indicated that the tolerance to vitrification of rat embryos increased with the development of embryos. The establishment of vitrification method of rat embryos at various developmental stages is helpful for improving the production and storage of valuable rat strains used for biomedical science.     

An unusual radiation-induced G2 arrest in the zygote of the BALB/c mouse strain

Female mice of the BALB/c strain were superovulated, mated with males of the same strain, and irradiated with 1 Gy of X-rays at hourly intervals during the first cell cycle of the embryos. Two types of effects were found in the embryos, depending on the time of X-irradiation. When irradiation was delivered between 14 and 21 h after human chorionic gonadotrophin (hCG) injection, cultured two-cell embryos developed normally up to the morula stage, where a high mortality occurred. On the other hand, when irradiation was given between 17 and 24 h after hCG injection, a high proportion of the eggs was unable to cleave and remained blocked at the one-cell stage. Cytofluorometric analysis of the pronuclear DNA content of uncleaved zygotes showed that DNA synthesis was unaffected by X-irradiation, and that they were blocked in G2 phase of the first cell cycle. Similar studies on other strains, as well as reciprocal crosses between BALB/c and F1(female BALB/c X male C57 BLACK) mice showed that the 'one-cell block' is determined by the maternal genotype and results most probably from a direct action of X-rays on a radiosensitive cytoplasmic factor necessary for the first embryonic cell division, and appearing 17 h after hCG injection. A high proportion of blocked zygotes (30-40 per cent) recovered partially, cleaved with a delay of about 20 h, and died soon after, almost none of them being able to reach the blastocyst stage. At the time of maximum radiosensitivity, the LD50 for development up to the blastocyst stage was 0.95 Gy.     

Development of chicken embryos exposed to an intermittent horizontal sinusoidal 50 Hz magnetic field

The effects of intermittent exposure (2 h on/22 h off) to a 200 μT horizontal, sinusoidally oscillating (50 Hz) magnetic field were studied in 210 fertilized chicken eggs. Two hundred ten control eggs (sham-exposed) were incubated in the same chamber as the experimental eggs. Chick embryos were examined for developmental anomalies and maturity stage after 48 h of incubation. Immunohistochemical analysis of extracellular membrane components (laminin, fibronectin, and type IV collagen) were conducted on day 7 and histological examinations for malformations of brain, liver, and heart, on days 7, 12, and 18 of incubation. Furthermore, egg fertility and egg weights were evaluated on days 2, 7, 12, and 18. The investigation also measured the body weight of chickens for 90 days from hatching and included histological analysis of body organs. Each variable was investigated blind. Statistical comparison between exposed and sham-exposed values did not show significant differences in any of the variables investigated. Thus, it appears that the exposure of embryos to an intermittent 200 μT magnetic field at 50 Hz does not cause developmental anomalies, changes in maturity stage, alterations in distribution of extracellular membrane components, or malformations in the brain, liver, or heart. Moreover, there were no differences in body weight, morphology, or histology of central nervous system, liver, heart, or testis in 90-day-old chickens hatched from exposed in comparison to sham-exposed eggs. © 1996 Wiley-Liss, Inc.     

蛋白激酶Cα在小鼠孤雌及四倍体胚胎早期发育过程中的分布和作用

为了观察蛋白激酶Cα(protein kinase Cα,PKCα在昆明白小鼠受精卵、孤雌激活和四倍体胚胎早期发育阶段的亚细胞定位和致密化进程中的表达变化,本实验利用免疫荧光化学染色与激光共聚焦显微镜观察相结合的方法,对受精卵、孤雌激活和四倍体胚胎早期发育阶段PKCα的表达进行了定位观察,并利用Western blot对三组胚胎致密化进程中PKCα的表达进行定量分析.结果显示,PKCα在上述三组胚胎发育的2-细胞期至囊胚期均有表达,虽然不同胚胎PKCα的分布在同一发育阶段存在差异,却表现出在各胚胎期主要分布于卵裂球核染色质内,以及在胚胎致密化开始,PKCα在卵裂球连接处发生重新分布的共同特点.此外,三组胚胎PKCα在致密化进程中的表达呈升高趋势,即致密化后的表达高于敛密化前.结果表明,PKCct对胚胎致密化的调节具有重要作用,其在8-细胞/4-细胞期的重新分布是胚胎进入桑椹胚期的必然事件,是胚胎致密化的前提,同时伴随蛋白表达增多.此外,PKCα在囊胚期发生了植入前的第二次重新分布.PKCα在三组胚胎各发育阶段表达情况各不相同,它对小鼠胚胎发育的影响体现在整个早期发育阶段.PKCα在小鼠受精卵早期发育阶段的两次重新分布可能与在致密化开始时启动的细胞黏附事件存在某种必然联系.     

Osmolarity and composition of cell culture media affect further development and survival in zebrafish embryos

With the aim of carrying out chimaerism and somatic cell-midblastula transition (MBT) embryos co-culture experiments in freshwater fish species, we evaluated the effect of osmolarity and composition of two media commonly used in cell fish culture on MBT zebrafish embryos and their further development and survival. To this end, wild zebrafish dechorionated embryos in midblastula stage were cultured for 6 days (Experiment 1: 189 embryos) or 1 h (Experiment 2: 150 embryos) in three different media: Hanks' 10% (H-10), 35 mOsm; Hanks' 100% (CH), 315 mOsm; and L-15 with serum (L-15: 315 mOsm). High osmolarity affected the survival rate (6 days: L-15: 45.1% v. CH: 72.34% v. H-10: 100%, P < 0.05; after 6 days: 0% both in L-15 and CH) and slowed their developmental timing. Embryos showed tail deformation (curly) as well as body paralysis at 48 h when they showed tail movements at 28 h. Differences in tail deformation were observed between high-osmolarity groups (CH: 85.10% v. L-15: 98.04%; P < 0.05). In Experiment 2, no effects on survival rate were observed. Teratogenic effects were only observed in L-15 (L-15: 12.98% v. CH: 0%; P< 0.05). Loss of motility was not detected in any group at 48 h. Optimum osmolar condition for cultured cells and also embryonic cells is around 315 mOsm and so, during chimaerism experiments (usually practised at MBT stage), present results indicate that midblastula embryos can acceptably bear the effects caused by 315 mOsm (CH) for 1 h, even though this involves a certain delay in developmental timing.     

Effects of 100-Hz magnetic fields with various waveforms on the development of chick embryos

Summary Chick embroys were exposed during their 52 first hours of development to 100-Hz magnetic fields. Sinusoidal, square and pulsed waveforms were used at average field strengths from 0.1 A/m to 80 A/m. After exposure, the embryos were examined for abnormalities and classified by the developmental stages. When bipolar oscillations (oscillating at both sides of the zero-level) were used, the percentage of abnormal embryos was significantly increased above 1 A/m. In exposure to unipolar square waves, no significant effect on the percentage of abnormalities could be demonstrated. The developmental stage was possibly affected by unipolar square waves at 0.1 A/m, all other field strengths and wave-forms being apparently ineffective.