Antifreeze protein from Anatolia polita (ApAFP914) improved outcome of vitrified in vitro sheep embryos

Embryo cryopreservation is an important tool to preserve endangered species. As a cryoprotectant for mouse oocytes, antifreeze protein from Anatolica polita (ApAFP914) has demonstrated utility. In the present study, the effects of controlled slow freezing and vitrification methods on the survival rate of sheep oocytes fertilized in vitro after freezing-thawing were compared. Different ApAFP914 concentrations were added to the vitrification liquid for exploring the effect of antifreeze protein on the warmed embryos. The results showed that the survival and hatching rates of in vitro derived embryos were significantly higher than that of the slow freezing method. Furthermore, among the cryopreserved embryos at different developmental stages, the survival and hatching rates of the expanded blastocyst were significantly higher than those of the blastocysts, early blastocysts and morula. The survival and the hatching rates of the fast-growing embryos were both significantly higher than that of the slow-growing embryos. Additionally, treatment of ApAFP914 (5–30 μg/mL) did not increase the freezing efficiency of the 6–6.5 d embryos. However, addition of 10 μg/mL of ApAFP914 significantly increased the hatching rate of slow-growing embryos. In conclusion, our study suggests that the vitrification is better than the slow freezing method for the conservation of in vitro sheep embryos, and supplementation of ApAFP914 (10 μg/mL) significantly increased the hatching rate of slow-growing embryos after cryopreservation.     

Hatching mechanism and delayed hatching of the eggs of three broadcast spawning euphausiid species under laboratory conditions

Three different egg hatching mechanisms were observed underlaboratory conditions in Euphausia pacifica Hansen, Thysanoessaspinifera Holmes and Thysanoessa inspinata Nemoto: backward,forward and flipping. Like all broadcast spawning euphausiids,these species usually hatch as nauplius 1 (N1). Some hours beforehatching the vitelline membrane breaks and the embryo is freelysuspended within the chorion; later the embryo takes on a slightlyoval shape. When ready to hatch, the N1 pushes against the chorionwith the posterior part of the abdomen producing a protuberance.No spine or egg tooth is present to break the chorion. The pressurebreaks the chorion, and the nauplius pushes itself backwardswith the first and second antennae and mandible to slide fromthe chorion. After about three quarters of the body is outside,the nauplius brings all the appendages together to move backwardswithout becoming stuck in the chorion. This is the backwardhatching mechanism. The vitelline membrane remains within theegg after the nauplius leaves the chorion. Hatching takes 5–20s, and most of the eggs in a clutch hatch during <2 h. Severaleggs of E. pacifica hatched as meta-nauplii (MN) (>200 hafter spawning) or as calyptopis 1 (C1) stage (>232 h), ratherthan as N1. Delayed hatching of embryos also was observed inT. spinifera as nauplius 2 (N2) (>120 h) or as MN stage (>180h), and in T. inspinata as N2 (106 h) after spawning. Eggs withlarvae in stages of development beyond N1 have not been observedfrom preserved zooplankton samples. However, eggs spawned inthe field and incubated in the laboratory also had extendeddevelopment and late hatching but with low frequency (<0.06%).It is proposed that, if the backward hatching mechanism fails,alternate hatching mechanisms can be used by the euphausiid.There is high flexibility in their hatching modes. The N2 andMN break the chorion with the first and second antennae, hatchingforwards, and the C1 breaks it with the telson spines and byflipping of the abdomen, resembling the decapod hatching mechanism.Delayed hatching using the forward and flipping mechanisms wereassociated with low hatching success in comparison with thebackward hatching mechanism.     

Effect of different cryoprotectants and vitrificant solutions on the hatching rate of turbot embryos (Scophthalmus maximus)

Vitrification could provide a promising tool for the cryopreservation of fish embryos. However, in order to achieve a vitrifiable medium, a high concentration of permeable cryoprotectants must be employed, and the incorporation of high molecular weight compounds should also be considered. The toxicity of these permeable and non-permeable agents has to be assessed, particularly when high concentrations are required. In the present study, permeable and non-permeable cryoprotectant toxicity was determined in turbot embryos at two development stages (F stage-tail bud and G stage-tail bud free). Embryos treated with pronase (2mg/ml, 10 min at 22 degrees C) were incubated in dimethyl sulfoxide (Me2SO), methanol (Meth.) or ethylene glycol (EG) in concentrations ranging from 0.5 to 6M for periods of 10 or 30 min, and in 5, 10, and 15% polyvinylpyrrolidone (PVP), 10, 15, and 20% sucrose or 0.1, 1, and 2% X-1000 for 2 min. The embryos were then washed well and incubated in seawater until hatching. The toxicity of permeable cryoprotectants increased with concentration and exposure time. There were no significant differences between permeable cryoprotectants. However, embryos tolerated higher concentrations of Me2SO than other cryoprotectants. Exposure to permeable cryoprotectants did not affect the hatching rate except at G stage with X-1000 treatment and 20% sucrose. Taking into account the cryoprotectant toxicity and the vitrification ability of cryoprotectant mixtures, three vitrification solutions (V1, V2, and V3), and one protocol for stepwise incorporation were designed. The tested solutions contained 5M Me2SO+2M Meth+1M EG plus 5% PVP, 10% sucrose or 2% X-1000. The hatching rate of embryos that had been exposed to the the vitrification solutions was analyzed and no significant differences were noticed compared with the controls. Our results demonstrate that turbot embryos can be subject to this cryoprotectant protocol without deleterious effect on the hatching rate.     

Cryopreservation of in vitro produced bovine embryos: effects of lipid segregation and post-thaw laser assisted hatching

The objective was to determine if lipid segregation, with or without post-thaw laser assisted hatching (LAH) of in vitro produced (IVP) bovine embryos, would enhance in vitro survivability and development 24 h post-thaw. On Day 6 of culture (Day 0 = IVF), in vitro produced bovine embryos were divided into three developmental stages: 32-cell (n = 78), compact morula (CM n = 223), and blastocyst (n =56). Embryos within each stage were allocated to the following treatments prior to cryopreservation in 1.5M ethylene glycol: no treatment (Control), 7.5 μg/mL Cytochalasin B for 20 min (CB), or CB with centrifugation (16,000 × g) for 20 min (CBCF). All CB treatments were extended to include embryo freezing. Immediately post-thaw, one-half of the CBCF and Control groups were subjected to zona pellucida drilling (LAH), using the XY Clone® system, creating groups CBCFLAH and LAH, respectively. All thawed embryos were cultured for 24 h and evaluated. No treatment differences were observed for either post-thaw survival or 24 h development. Within the CM stage, CBCFLAH and LAH exhibited a greater number of both total and live cells than Control (total: 69.4, 69.3, 53.0, live: 56.4, 54.7, 39.3 respectively; P < 0.05). In conclusion, LAH post-thaw alone or in combination with CBCF improved embryo viability following cryopreservation.     

Cryopreservation of bovine in vitro produced embryos using ethylene glycol in controlled freezing or vitrification

In this study, the cryoprotectant ethylene glycol (EG) was tested for its ability to improve and facilitate the cryopreservation of in vitro produced (IVP) bovine embryos. Embryos were cryopreserved in EG solutions supplemented with either newborn calf serum (NBCS) or polyvinyl alcohol (PVA). To assess EG toxicity, the embryos were equilibrated in EG concentrations from 1.8 to 8.9 M at room temperature for 10 min and then cultured for 72 h on a cumulus cell monolayer. The hatching rate was highest for day 7 blastocysts frozen in 3.6 M EG (98%) and was not different from the control group (85%). The controlled freezing (0.3 degrees C/min to -35 degrees C) of expanded day 7 blastocysts resulted in a hatching rate of 81%, which was similar to that of the nonfrozen controls (76%). Differential staining revealed only very few degenerate blastomeres attributed to freezing and thawing. Upon direct nonsurgical transfer of day 7 expanded blastocysts frozen in 3.6 M EG, a pregnancy rate of 43% was achieved, while the pregnancy rate after transfer of other developmental stages was significantly lower (22% with expanded day 8 blastocysts). When bovine IVP embryos were incubated at room temperature in 7.2 M EG preceded by preequilibration in 3.6 M EG, the hatching rate of day 7 expanded blastocysts reached 93%. Upon vitrification of IVP day 7 and day 8 blastocysts and expanded blastocysts in 7.2 M EG, the latter showed a higher hatching rate (42%) than blastocysts (12%). Overall, PVA as supplement to the basic freezing solution instead of NBCS had deleterious effects on survival after controlled freezing or vitrification. The simple cryopreservation protocol employed in this study and the low toxicity of ethylene glycol highlight the usefulness of this approach for controlled freezing of IVP embryos. However, further experiments are needed to improve the pregnancy rate following embryo transfer and to enhance survival after vitrification.     

Ultrasound enhanced methanol penetration of zebrafish (<Emphasis Type="Italic">Danio rerio</Emphasis>) embryos measured by permittivity changes using impedance spectroscopy

Studies on permittivity changes in fish embryos measured by impedance spectroscopy after ultrasound treatment during exposure to cryoprotectant is reported here for the first time. The permittivity changes of zebrafish embryos in cryoprotectant solutions before and after ultrasound treatment were measured using impedance spectroscopy. Zebrafish (Danio rerio) embryos at 50% epiboly stage were exposed to 2 M methanol for 25 min before ultrasound treatment for 5 min at 22 degrees C. Embryos were treated with ultrasound in different frequencies (24 and 48 kHz) and voltages (50, 100, 150 and 175 V) combinations. The results showed a clear increasing trend of permittivity from voltage 50 to 175 V over lower impedance frequency range of 10-10(3) Hz indicating increased methanol penetration into the embryos after ultrasound treatment. The embryo survival was not compromised after ultrasound treatment under conditions used in the present study. The use of impedance spectroscopy technique provides a useful none-invasive tool for detecting changes of cryoprotectant penetration in fish embryos after ultrasound treatment. The technique is especially useful for the selection of the suitable cryoprotectants in embryo cryopreservation and may also allow quantitative measurements in embryo membrane permeability studies.     

Vitrification of turbot embryos: preliminary assays

Successful fish embryo cryopreservation is still far from being achieved. Vitrification is considered the most promising option. Many factors are involved in the success of the process. The choice of a proper vitrification solution, the enzymatic permeabilization of embryos to increase cryoprotectant permeability, the adequate container for embryo loading, and the temperature for thawing, were the parameters considered at different developmental stages in the present study. After vitrification, embryo morphology was evaluated under stereoscopic microscopy, establishing the percentage of intact embryos. Two of the studied parameters yielded differences in this percentage, the volume of straw used for embryo loading (1 ml straws were significantly better than 0.5 ml straws, with regard to post-thawed embryo morphologies), and the thawing temperature, achieving 49% of embryos with intact morphology after thawing at 0 degrees C. After thawing, the intact embryos were incubated and periodically observed to detect morphological changes. Changes in the perivitelline space, shrinkage of the yolk and chorion ruptures as well as a progressive whitening of the embryo and yolk were observed. After 8 h all embryos showed clear signs of degradation and during this incubation period no embryo showed any developmental ability.     

Cathepsin L involved in the freezing resistance of murine normal hatching embryos and dormant embryos

The cryopreservation of mammalian embryos is an important technology in embryo engineering. The discovery and application of the embryo's own high freezing resistance factors are the main methods to improve the utilization of mammalian embryos in cryopreservation. Cathepsin L gene expression in the frozen and thawed dormant embryos displayed a significant difference from those normal hatched ones. The aim of the present study was to dig out the potential role of Cathepsin L in anti-freezing capacity of murine blastocysts by investigating the location and expression of Cathepsin L in frozen and thawed both activated and dormant hatching blastocysts. Different concentrations of Cathepsin L recombinant protein and E-64d were then respectively added into the embryo cryoprotectant and pre-cryo culture medium. Our results found that down-regulation of Cathepsin L improves the freezing resistance of murine normal hatching embryos by reducing apoptosis. Cathepsin L inhibitors can be used to improve the efficiency of cryopreservation and recovery of blastocysts in vitro. Our study provides a theoretical basis for the further development and application of Cathepsin L.     

Structural and ultrastructural characteristics of the yolk syncytial layer in Prochilodus lineatus (Valenciennes, 1836) (Teleostei; Prochilodontidae)

The yolk syncytial layer (YSL) has been regarded as one of the main obstacles for a successful cryopreservation of fish embryos. The purpose of this study was to identify and characterize the YSL in Prochilodus lineatus, a fish species found in southeastern Brazil and considered a very important fishery resource. Embryos were obtained through artificial breeding by hormonal induction. After fertilization, the eggs were incubated in vertical incubators with a controlled temperature (28 degrees C). Embryos were collected in several periods of development up to hatching and then fixed with 2% glutaraldehyde and 4% paraformaldehyde in 0.1 M sodium phosphate buffer (pH 7.3). Morphological analyses were carried out under either light, transmission or scanning electron microscopy. The formation of the YSL in P. lineatus embryos starts at the end of the cleavage stage (morula), mainly at the margin of the blastoderm, and develops along the embryo finally covering the entire yolk mass (late gastrula) and producing a distinct intermediate zone between the yolk and the endodermal cells. The YSL was characterized by the presence of microvilli on the contact region with the yolk endoderm. A cytoplasmic mass, full of mitochondria, vacuoles, ribosomes, endomembrane nets and euchromatic nuclei, indicated a high metabolic activity. This layer is shown as an interface between the yolk and the embryo cells that, besides sustaining and separating the yolk, acts as a structure that makes it available for the embryo. The structural analyses identified no possible barriers to cryoprotectant penetration.     

Dimethyl sulfoxide influx in turbot embryos exposed to a vitrification protocol

The particular characteristics of fish embryos require the development of specific methods for cryopreservation. One of the main obstacles is related to the presence of membranes and compartments with different water and cryoprotectant permeability. To assess dimethyl sulfoxide (Me2SO4) permeability, we exposed turbot embryos (Scophthalmus maximus) at F stage (tail bud) to the cryoprotectant solutions used in a vitrification protocol and then evaluated the Me2SO4 content inside the embryo using high-performance liquid chromatography (HPLC). The Me2SO4 influx was analyzed in normal embryos and in embryos treated with pronase (2mg/ml) in order to increase chorion permeability. The evaluation was made after each step of cryoprotectant incorporation and removal. Three embryo compartments were distinguished: the perivitelline space (PVS), the yolk sac (YS) and the cellular compartment (CC), and the relative volumes of each, estimated using stereoscopic microscopy imaging, were 11.37, 81.23 and 7.40%, respectively. The Me2SO4 concentration inside the embryos was calculated based on their entrance into one, two or three compartments. Results suggest high entrance of Me2SO4 into the PVS and a low concentration of this cryoprotectant inside the other compartments. Pronase did not significantly increase Me2SO4 influx, but facilitated its elimination during the washing steps.     

Efficiency of osmotic and chemical treatments to improve the permeation of the cryoprotectant dimethyl sulfoxide to Japanese whiting (Sillago japonica) embryos

Insufficient cryoprotectant permeation is one of the major obstacles for successful fish embryo cryopreservation. The purpose of this study was to test the effectiveness of osmotic and chemical treatments to enhance cryoprotectant uptake by fish embryos. Japanese whiting Sillago japonica embryos at the somites and tail elongation stages were treated with hyperosmotic sugar solutions (1 M trehalose and sucrose) for 2-6 min, or a permeating agent (2-6 mg/mL pronase) for 30-120 min, and then impregnated with 10-15% DMSO in artificial sea water or aqueous solutions containing inorganic salts (0.125-0.25 M MgCl₂ and CaCl₂). The viability of the embryos after the treatments was estimated from hatching rates and the internal DMSO concentration was measured by HPLC. Treatment with trehalose for 3 min prior to impregnation with DMSO enhanced the uptake of the cryoprotectant by 45% without significantly affecting embryo viability, whereas pronase had no noticeable effect on cryoprotectant permeation. Incorporation of DMSO into the embryos was enhanced by 143-170% in the presence of 0.25 M MgCl₂ and 0.125 M CaCl₂ compared to sea water. A combination of treatments with trehalose and MgCl₂ was even more effective in promoting DMSO permeation (191% compared to untreated embryos). Tail elongation embryos were less tolerant of the treatments, but had higher DMSO impregnation. In conclusion, the use of trehalose (as dehydrating agent) and MgCl₂/CaCl₂ (as a vehicle during impregnation) greatly promoted cryoprotectant uptake and may be a promising aid for the successful cryopreservation of fish embryos.     

Successful direct transfer of vitrified sheep embryos

The use of a simple cryopreservation method, adapted to direct transfer of thawed embryos may help to reduce the costs of embryo transfer in sheep and increase the use of this technique genetic improvement of this species. Two experiments were made to test a vitrification method that is easy to apply in field conditions. All embryos were collected at Day 7 of the estrous cycle of FSH-stimulated donor ewes and were assessed morphologically, washed in modified PBS and incubated for 5 min in 10% glycerol, for 5 min in 10% glycerol and 20% ethylene glycol and were transferred into the vitrification solution (25% glycerol and 25% ethylene glycol). All solutions were based on mPBS. Embryos were loaded in straws (1 cm central part, the remaining parts being filled with 0.8 M galactose in mPBS) and plunged into liquid N2 within 30 sec of contact with the vitrification solution. The straws were thawed (10 sec at 20 degrees C) and the embryos were either transferred directly or after 5 min of incubation in the content of the straw (followed by washing in PBS) into the uterus of a recipient ewe. In Trial 1, the pregnancy rates at term (72 vs. 72%) as well as the embryo survival rates (60 vs 50% respectively) were not different between fresh (n = 48 embryos) and vitrified (n = 50) embryos. In a second trial no difference was observed between vitrified embryos transferred after in vitro removal of the cryoprotectant (n = 86 embryos) or directly after thawing (n = 72) both in terms of lambing rate (67 vs. 75%, respectively) and embryo survival rate (lambs born/embryos transferred; 49 vs. 53%). This method of sheep embryo cryopreservation provided high pregnancy and embryo survival, even after direct transfer of the embryos.     

Effects of hyaluronic acid in culture and cytochalasin B treatment before freezing on survival of cryopreserved bovine embryos produced in vitro

Summary One limitation to the widespread use of in vitro-produced embryos in cattle is their poor survival following cryopreservation. Two approaches for enhancing survival of in vitro-produced bovine embryos following cryopreservation were evaluated: culture in the presence of hyaluronic acid and alterations in the cytoskeleton through cytochalasin B treatment. The experiment was a 2×2 factorial design to test main effects of hyaluronic acid added to culture at day 5 after insemination (+or−) and cryopreservation treatment (control or cytochalasin B). Embryos used for cryopreservation were blastocysts and expanded blastocysts harvested on day 7 after insemination. Cytochalasin B increased the percent of embryos that re-expanded (P<0.0001) and that hatched following thawing (P<0.05). The hatching percent was 29.6% for embryos treated with cytochalasin B versus 9.1% for control embryos. There was no significant effect of hyaluronic acid on survival although there was a tendency for embryos cultured with hyaluronic acid to have higher percent hatching if not treated with cytochalasin B (12.7% for hyaluronic acid versus 4.5% for control; hyaluronic acid x cytochalasin B interaction; P=0.09). In conclusion, cytochalasin B treatment before freezing improved cryosurvival of bovine embryos produced in vitro. Such a treatment could be incorporated into methods for cryopreservation of bovine embryos provided post-transfer survival is adequate. In contrast, culture with hyaluronic acid was of minimal benefit—the increased cryosurvival in the absence of cytochalasin B was not sufficient to allow an adequate number of embryos to survive.     

Permeability of intact and dechorionated zebra fish embryos to glycerol and dimethyl sulfoxide

Intact developing embryos of the zebra fish Brachydanio rerio were exposed to [¹⁴C]DMSO and [³H]glycerol (1 M in Fish Ringer) to assess the degree of permeation of these cryoprotectants. Glycerol enters the embryo more easily, although reaching only about 8% of the expected equilibrium level after 2 hr at room temperature; DMSO reaches only about 2.5% of this level. In an attempt to identify the barrier to permeation, dechorionated embryos were similarly exposed to isotopic DMSO. Permeation increased severalfold, indicating that the chorion retards the free exchange of solute. Embryos are unaffected by exposure to 1 M DMSO in Fish Ringer at 23 °C for up to 1 hr. The number of embryos hatching after 1-hr exposure to DMSO at varying concentrations was significantly reduced at 1.5 and 2 M. Embryos exposed to 1 M glycerol for 1 hr at 23 °C showed disruption of periblast cells and separation of the blastoderm; it was impossible to remove glycerol either by abrupt or very slow dilution.     

应用乙二醇冷冻小鼠胚胎：优化和简化程序的探索

提高解冻胚胎的发育能力和简化冷冻解冻程序是胚胎冷冻研究的两大永恒的主题。尽管乙二醇（EG）广泛用于家畜胚胎冷冻,但很少用于冷冻小鼠和人胚胎。为数很少的以EG慢冻小鼠或人胚胎的研究均采用较为复杂的人胚冷冻程序,未见简化程序和用EG冷冻小鼠桑椹胚的报道。采用简单的牛胚胎冷冻程序研究了发育时期、EG浓度、平衡方法、添加蔗糖以及解冻后脱除EG等对小鼠胚胎冻后发育能力的影响。结果显示：（1）致密晚期桑椹胚冻后体外培养囊胚发育率（81.92%±2.24%）和孵出率（68.56％±2.43%）显著（P＜0.05)高于4-细胞、8-细胞胚胎和致密早期桑椹胚胎;（2）1.8mol/L EG冷冻小鼠致密晚期桑椹胚的囊胚发育和孵出率显著高于其它浓度;（3）在EG中平衡10min的冻后囊胚发育显著好于平衡5、20或30min;（4）两步平衡冷冻胚胎的囊胚发育率和孵出率显著高于一步平衡;（5）用EG冷冻小鼠胚胎无需添加蔗糖;（6）解冻后可不脱除EG;（7）冻后发育的早期囊胚和囊胚细胞数明显少于体内发育胚胎。因此,用EG冷冻小鼠胚胎的最佳方案为：致密晚期桑椹胚用1.8mol/L EG不添加蔗糖、两步平衡15min、以简单的牛胚胎冷冻程序冷冻解冻、解冻后不脱除EG直接培养或移植。     

Cryopreservation of Musca domestica (Diptera: Muscidae) embryos

Prior studies on cryopreserving embryos of several non-drosophilid flies established that two Drosophila melanogaster embryo cryopreservation protocols were not directly suitable for use with these species. This paper describes our work on developing a protocol for cryopreservation of embryos of the housefly, Musca domestica. Significant progress was made when permeabilization of the vitelline membrane was optimized, a vitrification solution containing ethylene glycol, polyethylene glycol, and trehalose was formulated, and when cooling and recovery of the cryopreservation protocol included a step which passed the embryos through liquid nitrogen vapor. More than 70% of housefly embryos withstand treatments of dechorionation, permeabilization, loading with cryoprotectant, and dehydration in vitrification solution, but the cooling, warming, and poststorage rearing steps still cause a considerable reduction in survival. About 53% of the vitrified M. domestica embryos hatched into larvae. Relative to the percentage of the control adult emergence, about 13% of the embryos stored in liquid nitrogen developed into fertile adults. Hatching of the F(1) progeny of adults having been cryopreserved as embryos was similar to control levels.     

Analysis of cryoprotectant, cooling rate and in situ dilution using conventional freezing or vitrification for cryopreserving sheep embryos

Two studies were conducted to evaluate the influence of cryoprotectant, cooling rate, container and cryopreservation procedure on the post-thaw viability of sheep embryos. In Study 1, late morula- to blastocyst-stage embryos were exposed to 1 of 10 cryoprotectant (1.5 M, glycerol vs propylene glycol)-plunge temperature treatments. Embryos were placed in glass ampules and cooled at 1 degrees C/min to -5 degrees C, seeded and further cooled at 0.3 degrees C/min to -15, -20, -25, -30 and -35 degrees C before rapid cooling by direct placement in liquid nitrogen (LN(2)). Post-thaw embryo viability was improved (P<0.01) when embryos were cooled to at least -30 degrees C before LN(2) plunging. Although there were no overt differences in embryo viability between cryoprotectant treatments (each resulted in live offspring after embryo transfer), there was a lower (P<0.01) incidence of zona pellucida damage using propylene glycol (4%) compared to glycerol (40%). In Study 2, embryos were equilibrated in 1.5 M propylene glycol or glycerol or a vitrification solution (VS3a). Embryos treated in propylene glycol or glycerol were divided into ampule or one-step((R)) straw treatments, cooled to -6 degrees C at 1 degrees C/min, seeded, cooled at 0.5 degrees C/min to -35 degrees C, held for 15 minutes and then transferred to LN(2). Embryos vitrified in the highly concentrated VS3a (6.5 M glycerol + 6% bovine serum albumin) were transferred from room air to LN(2) vapor, and then stored in LN(2). Propylene glycol- and glycerol-treated embryos in straws experienced lower (P<0.05) degeneration rates (27%) and yielded more (P<0.05) hatched blastocysts (73 and 60%, respectively) at 48 hours of culture and more (P<0.05) trophoblastic outgrowths (67 and 53%, respectively) after 1 week than vitrified embryos (47, 40 and 20%, respectively). In vitro development rate for VS3a-treated embryos was similar (P>0.10) to that of ampule controls, which had fewer (P<0.05) expanded blastocysts compared to similar straw treatments. Live offspring were produced from embryos cryopreserved by each straw treatment (propylene glycol, 3 of 7; glycerol, 1 of 7; VS3a, 2 of 7). In summary, freeze-preservation of sheep embryos was more effective in one-step straws than glass ampules and propylene glycol tended to be the optimum cryoprotectant. Furthermore, these findings demonstrate, for the first time, the biological competence of sheep embryos cryopreserved using the simple and rapid procedure of vitrification.     

Effects of Desiccation and Cryopreservation on the In Vitro Viability of Embryos of the Recalcitrant Seed Species Araucaria hunsteinii K. Schum

Embryos excised from fresh seed had a moisture content of about37% (fr. wt.), 7% above that of the whole seed: mainly as aresult of the dryness of the seed coat. When cultured for 14d at 26°C embryo growth ranged from unorganized to fullyorganized. Embryos which had been directly surface-sterilizedexhibited lower fully organized growth than aseptically excisedembryos. During desiccation of the whole seed at 15°C and 15% r.h.moisture loss from the embryo was slow until the embryo reacheda mean critical moisture content for fully organized growthin vitro of about 30%. After this point the rate of moistureloss increased, quickly diminishing the moisture content differentialbetween the embryo and the whole seed. No such shoulder in theembryo desiccation curve was observed when using a low viability(7%) seed batch. When dried below 30% moisture content, suchaseptically excised embryos increasingly exhibited unorganizedgrowth in vitro, with only root meristem survival (46%) at 13%moisture content. In contrast, a much higher level of root meristem survival (84%of control) was observed when aseptically excised embryos wererapidly desiccated to 13% moisture content, using a flow ofsterile air. However, the benefits of rapid drying were lostif the embryos were directly surface-sterilized prior to desiccation.Furthermore, 80% of aseptically excised embryos which survivedrapid desiccation to 20% moisture content exhibited root meristemsurvival following subsequent cryopreservation. These findingshave implications for the in vitro conservation of recalcitrantseed tissue. Key words: Araucaria hunsteinii K. Schum., recalcitrant seed embryo, desiccation, cryopreservation     

Morphology and ultrastructure of the serosal cells (teratocytes) in Cardiochiles nigriceps Viereck (Hymenoptera : Braconidae) embryos

The morphogenetic changes of the serosal membrane during embryonic development of Cardiochiles nigriceps Viereck (Hymenoptera : Braconidae) were investigated. Eggs observed soon after oviposition into the natural host Heliothis virescens (F.) (Lepidoptera, Noctuidae) showed a transparent chorion and a uniform texture. After 5 hr, the embryo exhibited a distinct granular appearance and by 12 hr attained the germ band stage. A serosal membrane originated from the anterior pole of the embryo between 14 and 15 hr after the egg was laid, eventually forming with the cells both in the anterior and posterior pole a continuous envelope around the developing embryo.Ultrastructural observations revealed that the serosal cells in contact with the abdominal region of the embryo, beginning 24–25 hr after oviposition, formed a syncytium. However, the syncytial tissue did not extend to the cells around the head and thorax. The serosal cells at both embryo poles increased in size without losing their structural organization, and developed into teratocytes when the larva hatched. In contrast, the serosal cells surrounding the body of the embryo persisted longer on the head and thorax region of the newly hatched larva, while the syncytial tissue degraded more rapidly after hatching.In vitro rearing experiments showed that C. nigriceps embryos removed from parasitized host larvae just before and just after serosa formation, hatched only when the medium used was formulated with the addition of fetal bovine serum. Embryos did not develop or hatch when placed in a serum-free medium. Once the syncytium deriving from the serosal membrane became evident, embryos readily developed and hatched in serumfree media. The results of this study seem to suggest that the serosal embryonic membrane could have a nutritional role for the developing parasitoid embryo.     

Structure and enzymatic removal of the chorion of embryos of the Nile tilapia

Dechorionation or partial digestion of the egg chorion is necessary for introducing embryonic stem cells into blastulas for chimera production and for harvesting blastulas. Several methods to digest the Nile tilapia Oreochromis niloticus chorion were tried and it was found that the chorions of most clutches of eggs were digested in <3 h using hatching medium [produced by allowing embryos to hatch in Hanks balanced salt solution (HBSS) in an incubator], or 2 mg ml⁻¹ pronase P6911 in 10% Ca/Mg free HBSS. The chorion of Nile tilapia possesses multiple lamellae as found in most teleost species that have been studied. It was found to be thinner than that of medaka Oryzias latipes and thicker than that of zebrafish Danio rerio . During natural hatching the chorion was digested from the inner surface, and tail movements helped to break the remaining chorion; however, chorion digestion has to be complete for experimental dechorionation, because digestion starts at the external surface. The zona radiata externa remained intact after experimental digestion with hatching media but was disrupted by pronase. Embryos dechorionated at the cleavage or blastula stage only survived for 2 or 3 days, but some dechorionated at the gastrula stage or early segmentation stage developed until the natural hatching time. If the chorion was partially digested at the cleavage or blastula stage, some embryos survived to hatch.