Preservation of mouse embryos by two-step freezing

Eight-cell mouse embryos in 1.5 M DMSO were preserved in LN₂ by a two-step procedure. Fifteen minutes exposure at ?20 °C protected the embryos against damage during rapid cooling to -196 °C and during rapid warming and rapid dilution. Since survival was poor on slow warming it is suggested that the method permits the formation of some intracellular ice.     

Liquid nitrogen vapour freezing of mouse embryos

Mouse morulae were frozen rapidly to -196 degrees C in the presence of glycerol by a two-step procedure; the embryos were transferred directly from -7 degrees C after seeding into liquid nitrogen vapour at -170 to -180 degrees C and then into liquid nitrogen 10-15 min later. Suitable conditions for the survival of embryos frozen with liquid nitrogen vapour were found to be: 2 M-glycerol, 2 M-propylene glycol, 2 M-ethylene glycol; 5-30 min equilibration time at 0 degrees C; 3-60 min holding time in liquid nitrogen vapour; dilution of glycerol with sucrose out of the frozen-thawed embryos; morula and early blastocyst stage embryos. Relatively high survival rates (69-74%) were obtained after rapid freezing by liquid nitrogen vapour. Morulae frozen in this fashion, cultured and transferred to recipients developed into normal young.     

A simplified method for freezing mouse embryos

Mouse oviducts containing eight-cell embryos were frozen to ?196 °C in 1.45 m DMSO. The cooling rate was 0.3 °C/min and thawing occurred at 3 °C/min. Dilution of DMSO took place either before or after flushing of the thawed oviducts. The yield of intact embryos was higher in the second group.In one particular series involving 21 donor mice (natural ovulation) 88 recovered embryos were transferred to the oviducts of recently mated pseudopregnant mice without prior in vitro culture to the blastocyst stage. Fifty-five live young were born.It is concluded that the freezing of embryos in the oviduct is a reliable method for establishing an embryo bank. Handling and collection of isolated embryos is not required and a large amount of material can be frozen at once. In vitro culturing of embryos is not required immediately after thawing in order to obtain a high yield of live young.     

A method for one-step freezing of mouse embryos

A simple one-step method of freezing mouse embryos directly in liquid nitrogen is described. The main objective of this study was to assess post-thaw survival following predehydration in various mixtures of glycerol and sucrose. Also investigated was pretreatment with glycerol prior to dehydration and effects of embryo stage. When sucrose was held constant (0.25 M) and glycerol concentration varied (1.0-4.0 M), post-thaw survival was best (67%) in 2.0 M glycerol. Pretreatment in glycerol provided no advantage over no pretreatment. When glycerol was held constant (2.0 M) and sucrose concentration varied (0-1.0 M), optimum post-thaw survival (81%) was found in 0.5 M sucrose. Morulae survived better than blastocysts (86% vs 72%, respectively). Transfer of thawed embryos frozen by the optimum treatment (2.0 M glycerol + 0.5 M sucrose) resulted in a birthrate of 41%, compared to 54% for fresh controls. This technique could find application in freezing and thawing of livestock embryos on the farm.     

Role of equilibration before rapid freezing of mouse embryos

The time requirements for permeation by glycerol and dehydration by sucrose before rapid freezing of Day-3 mouse embryos by direct transfer to -180 degrees C were studied. When the embryos were equilibrated in 2.0, 3.0, or 4.0 M-glycerol + 0.25 M-sucrose for 2.5 to 40 min, the post-thaw viability increased (P less than 0.001) with the length of equilibration period at 4 degrees C. At 20 degrees C the volume of embryos increased with the duration of equilibration up to 20 min (P less than 0.001), but the post-thaw viability was not affected. The effect of equilibration in glycerol-sucrose was determined at 20 degrees C for embryos which were previously permeated by glycerol, dehydrated by sucrose or left in PBS + 5% FCS. The survival of previously permeated embryos was not affected by equilibration for 1-16 min in glycerol-sucrose. The maximum survival rate was attained after shorter equilibration in glycerol-sucrose for embryos without pretreatment (4 min) than for those previously dehydrated (8 min). It is concluded that increases in the intracellular glycerol level are beneficial for the viability of rapidly frozen mouse embryos and previous or concomitant exposure to sucrose unfavourably affects glycerol permeation.     

Quick freezing of one-cell mouse embryos using ethylene glycol with sucrose

One-cell mouse embryos were frozen by direct plunging into liquid nitrogen (LN(2)) vapor after equilibration in 3 M ethylene glycol with 0.25 M sucrose (freezing medium) for 5 to 40 minutes. After thawing, the embryos were cultured in vitro and the effects of the equilibration period and dilution method were examined. No significant difference was observed in the in vitro survival of embryos when 0.5 or 1.0 M sucrose was used for the dilution of the cryoprotectant for each equilibration period. The highest survival rate (67.2%) was obtained when the embryos were equilibrated for 10 minutes, and the cryoprotectant diluted with either 0.5 or 1.0 M sucrose after thawing. Shorter (5 minutes) or prolonged (40 minutes) equilibration of embryos in the freezing medium yielded significantly lower survival rates. Dilution by direct transfer of the frozen-thawed embryos into PB1 resulted in lower survival rates than when 0.5 or 1.0 M sucrose was used. The in vitro development to the blastocyst stage of one-cell mouse embryos frozen after 10 minutes equilibration in the freezing medium and diluted after thawing in 0.5 M sucrose was significantly lower than the control (68.0 vs 92.7%). However, transfer of the blastocysts developing from frozen-thawed one-cell mouse embryos into the uterine horns of the recipients resulted in fetal development and implantation rates similar to the control.     

Deep freezing of mouse one-cell embryos and oocytes using different cryoprotectants

The objective of this study was to compare iso-osmolar concentrations (1.5 M) of 1,2-propanediol, glycerol, dimethylsulphoxide and a combination of 1 M propanediol + 0.5M glycerol (PDGLY) as cryoprotectants for murine ovulated oocytes and one-cell embryos. A higher (P < 0.01) percentage of one-cell embryos developed to the two-cell stage when frozen-thawed with 1,2-propanediol (83%) as compared with glycerol (43%), dimethylsulfoxide (51%) or PDGLY (7%). Data recalculated on the basis of two-cell embryos/number of normal one-cell embryos after thawing indicated no differences among single cryoprotectant groups. More (P < 0.01) frozen-thawed, in-vitro fertilized oocytes developed to the two-cell stage when 1,2-propanediol (35%) was used as cryoprotectant as compared with glycerol (15%). Freezing-thawing resulted in a reduced number of two-cell embryos after oocytes were fertilized in-vitro as compared with fresh oocytes. 1,2-propanediol was a better cryoprotectant than glycerol, dimethylsulphoxide or PDGLY for deep freezing of murine oocytes or one-cell embryos.     

The response of Anisakis larvae to freezing

Anisakis third stage larvae utilize a variety of fish as intermediate hosts. Uncooked fish are rendered safe for human consumption by freezing. Larvae freeze by inoculative freezing from the surrounding medium but can survive freezing at temperatures down to -10 degrees C. This ability may be aided by the production of trehalose, which can act as a cryoprotectant, but does not involve recrystallization inhibition. Monitoring of fish freezing in commercial blast freezers and under conditions which simulate those of a domestic freezer, indicate that it can take a long time for all parts of the fish to reach a temperature that will kill the larvae. This, and the moderate freezing tolerance of larvae, emphasizes the need for fish to be frozen at a low enough temperature and for a sufficient time to ensure that fish are safe for consumption.     

The effects of ultrarapid freezing on meiotic and mitotic spindles of mouse oocytes and embryos

Preovulatory mouse oocytes and 2-cell embryos were frozen with dimethyl sulfoxide and propanediol by an ultrarapid method. The survival of frozen oocytes was low (33–34%) compared to that of 2-cell embryos (78–79%) with either cryoprotectant. Development to blastocysts after postthaw culture was about 7–15% for oocytes and 79–80% for the embryos. Ultrarapid freezing preserves cell structure quite well as revealed by electron microscopy, but meiotic oocytes and late 2-cell embryos undergoing mitosis showed evidence of spindle disorganization involving loss or clumping of microtubules resulting in some scattering of chromosomes. Embryos developed from frozen eggs showed clear evidence of micronuclear formation and incomplete incorporation of chromosomal material into main nuclei. These experiments confirm our observations on freezing of human oocytes and show that spindle microtubules are sensitive to freeze-thawing and that cryopreservation could cause chromosomal aberrations during early development. A cautious approach to the introduction of oocyte freezing in human in vitro fertilization (IVF) programs is advocated.     

The blebbing response of 2-4 cell stage mouse embryos to cytochalasin B.

In light and electron microscopic examination of 2–4-cell stage mouse embryos, the embryos showed transitory blebs on the blastomere surface when cytochalasin B (CB) was applied shortly before or after mitosis. A similar effect was obtained in blastomeres removed from the drug at these stages but not in blastomeres maintained in the continued presence of the drug. CB also promoted the precocious deposition of crystalloid bodies and inhibited the formation of intercellular contacts. Microvilli and coated pits were not affected.     

Effects of cryopreservation of mouse embryos and in vitro fertilization on genotypic frequencies in colonies

To evaluate the effects of cryopreservation and in vitro fertilization (IVF) on genotypic frequencies in mouse colonies, genotypic frequencies at 15 biochemical, 4 immunological and 20 microsatellite loci were examined in three colonies of MCH (ICR) mice derived from noncryopreserved embryos obtained by natural mating without the induction of superovulation, cryopreserved embryos obtained by natural mating with the induction of superovulation, and cryopreserved embryos obtained by the induction of superovulation and IVF. Three (Pgm-1, Ldr-1 and Hbb) out of the 15 biochemical loci, two (Thy-1 and H2K) out of four immunological loci and five (D5Mit18, D6Mit15, D12Mit5, D13Mit26, and D14Mit7) out of 20 microsatellite loci that showed polymorphisms in every colony were used for detection of genotypic frequencies. The genotypic frequencies of the loci in the three colonies did not differ from the predicted genotypic frequencies (P > 0.05). The results suggested that genetic drift does not occur among colonies established from treated and untreated embryos, and it was clear that the embryo banking by cryopreservation is suitable for preservation of outbred stock without genetic drift.     

Nonequilibrium freezing of one-cell mouse embryos. Membrane integrity and developmental potential.

A thermodynamic model was used to evaluate and optimize a rapid three-step nonequilibrium freezing protocol for one-cell mouse embryos in the absence of cryoprotectants (CPAs) that avoided lethal intracellular ice formation (IIF). Biophysical parameters of one-cell mouse embryos were determined at subzero temperatures using cryomicroscopic investigations (i.e., the water permeability of the plasma membrane, its temperature dependence, and the parameters for heterogeneous IIF). The parameters were then incorporated into the thermodynamic model, which predicted the likelihood of IIF. Model predictions showed that IIF could be prevented at a cooling rate of 120 degrees C/min when a 5-min holding period was inserted at -10 degrees C to assure cellular dehydration. This predicted freezing protocol, which avoided IIF in the absence of CPAs, was two orders of magnitude faster than conventional embryo cryopreservation cooling rates of between 0.5 and 1 degree C/min. At slow cooling rates, embryos predominantly follow the equilibrium phase diagram and do not undergo IIF, but mechanisms other than IIF (e.g., high electrolyte concentrations, mechanical effects, and others) cause cellular damage. We tested the predictions of our thermodynamic model using a programmable freezer and confirmed the theoretical predictions. The membrane integrity of one-cell mouse embryos, as assessed by fluorescein diacetate retention, was approximately 80% after freezing down to -45 degrees C by the rapid nonequilibrium protocol derived from our model. The fact that embryos could be rapidly frozen in the absence of CPAs without damage to the plasma membrane as assessed by fluorescein diacetate retention is a new and exciting finding. Further refinements of this protocol is necessary to retain the developmental competence of the embryos.     

经程序化冷冻的小鼠休眠胚胎的基因表达谱差异分析

目的探讨小鼠休眠胚胎经程序化冷冻后基因表达谱的变化及相关信号通路的改变趋势。方法采用Affymetrix基因芯片检测小鼠正常休眠胚胎和经程序化冷冻后的休眠胚胎的差异表达基因;采用GO分析和Pathway分析等生物信息学方法进一步了解相关信号通路的改变。结果经程序化冷冻后的小鼠休眠胚胎与正常休眠胚胎相比,存在228个差异表达基因,其中50个基因表达上调,178个基因表达下调。Pathway分析显示黏着斑通路、细胞外基质受体相互作用通路、肌动蛋白细胞骨架调节通路、细胞凋亡通路、细胞通讯通路、泛素介导的蛋白质水解通路、甘油磷脂代谢通路、小细胞肺癌通路、TGF-β信号通路、MAPK信号通路等基因差异表达变化趋势明显。结论小鼠休眠胚胎经程序化冷冻后会导致一系列基因调控变化,并可能影响多条信号通路的协同变化。     

Deep freezing of horse embryos

Fourteen horse embryos recovered non-surgically on Days 6-8 after ovulation (Day 0) were cooled slowly to - 35 degrees C (7 embryos) or - 40 degrees C (7 embryos) and stored in liquid nitrogen (- 196 degrees C) for 4-98 days. Surgical transfer of the thawed embryos to unmated recipient mares that had ovulated - 2 to + 1 days with respect to the embryo donors resulted initially in the establishment of 4 conceptuses. However, only one mare maintained her pregnancy to term.     

Quick freezing of rat embryos

Quick freezing of rat morulae and blastocysts was attempted after they were dehydrated at room temperature. Combined solutions of 2.8 M glycerol and 0.125, 0.25, 0.50 and 1.0 M sucrose in phosphate buffered saline + 20% steer serum were compared. Survival rates (expanding blastocysts 15 h after thawing) were 42.1, 79.4, 87.5 and 16.7%, respectively (P<0.01). Freezing procedures consisted of either a direct plunge into liquid nitrogen (48.8%), holding for 5 min in the neck of a liquid nitrogen container or holding the samples for 60 min at -30 degrees C before insertion into liquid nitrogen. The direct plunge method resulted in a lower survival rate than either the 5- or the 60-min treatments (48.8% vs 76.9% and 77.6%, respectively). After thawing, dilution at room temperature in sucrose solutions of 0.25, 0.50 and 1.0 M gave survival rates of 80.0, 90.6 and 69.4%, respectively (NS). If diluted directly in PBS + 20% steer serum, 86.8% of embryos survived at +37 degrees C vs 0% at 0 degrees C (P<0.01).