Live rats resulting from injection of oocytes with spermatozoa freeze-dried and stored for one year

This study was designed to examine whether rat spermatozoa after freeze-drying and 1-year storage can participate in full-term development following intracytoplasmic sperm injection (ICSI). Cauda epididymal spermatozoa from Crlj:Wistar rats were frozen in liquid nitrogen (LN(2)), first dried for 14 hr at 0.37 hPa and then for 3 hr at 0.001 hPa. The dried spermatozoa were stored for 1 year in a desiccator at +25 degrees C, or in a refrigerator at +4 degrees C, or in LN(2) at -196 degrees C. Controls consisted of sperm that had only been frozen and stored in LN(2). After being stored, spermatozoa were sonicated to dissociate the sperm tail and were injected into oocytes from superovulated Slc:SD rats. The respective fertilization rates of oocytes injected with frozen sperm, or with freeze-dried sperm stored at +25, +4, and -196 degrees C were 79%, 75%, 70%, and 73%. However, the corresponding cleavage rates of injected oocytes were 63%, 1%, 38%, and 36%. After transfer of >80 zygotes of each group into recipients, the respective percentages of full-term normal offspring resulting from frozen sperm or from freeze-dried sperm stored at +25, +4, and -196 degrees C were 36%, 0%, 7%, and 14%. These results demonstrate that the storage temperature significantly influenced the likelihood of term development of rats produced by injection of oocytes with freeze-dried spermatozoa. Chromosomal analysis of the rat spermatozoa in the ICSI oocytes indicated that chromosomal aberration in freeze-dried spermatozoa stored at +25 degrees C (100%) occurred more frequently than in frozen control spermatozoa (41%) and freeze-dried spermatozoa stored at -196 degrees C (35%), and the frequency of chromosomal aberrations in freeze-dried spermatozoa stored at +4 degrees C (65%) was the intermediate. In conclusion, rat spermatozoa freeze-dried and stored at +4 degrees C for 1 year are capable of participating in full-term development after ICSI.     

Survival of 16-celled and morula stage rabbit embryos frozen to -196 degrees C,.

Preimplantation stage (16-celled and morula) rabbit embryos were successfully frozen to -196 degrees C. The cooling rate (from a room temperature to 0 degrees C), the presence of the mucin layer surrounding embryos, the ice-seeding treatment and the thawing procedure were examined to determine their effects on the survival of the frozen embryos of Japanese white, New Zealand white and Dutch-Belted rabbits. A high proportion (51%; 16-celled, 69%; morula) of Dutch-Belted rabbit embryos developed in vitro, when they were frozen to -196 degrees C, applying the ice-seeding at -4 degrees C in the presence of 12.5% DMSO, after being cooled to 0 degrees C at the rate of 7-9 degrees C/min, and were diluted by a stepwise addition of 4 different strength PBS on thawing. The highest rate of in vitro development (81%; Japanese white, 75%; New Zealand white, 82%; Dutch Belted embryos) was obtained when the morula stage embryos were frozen to -196 degrees C applying seeding at -4 degrees C after being cooled to 0 degrees C at the rate of 1 degrees C/2.5 min and were diluted, on thawing, by stepwise addition of 6, 3 and 1% DMSO solution and a culture medium. No great difference was found in the survival rate between the embryos covered with the mucin layer and those which had not the coat. All the embryos frozen without applying seeding treatment failed to develop in vitro after being thawed and diluted. Nine out of 27 does each of which received 6 reimplantations of the embryos frozen-thawed became pregnant and were found to be carrying 37 normal fetuses on the 12th day of pregnancy.     

The influence of storage temperature on the transition, activation enthalpy, and activity of enzymes associated with inner mitochondrial membranes

The effects of storage at low temperature on the transition in enzyme function, Tf*, and the Arrhenius activation energy, Ea, were determined for several enzymes associated with the inner membrane of rat liver mitochondria. The enzymes studied were succinate:cytochrome c reductase, cytochrome c oxidase, beta-hydroxybutyrate dehydrogenase, and oligomycin-sensitive, Mg2+-activated ATPase. For freshly isolated mitochondria the Tf*, for succinate:cytochrome c reductase and cytochrome c oxidase, occurred at approximately 23 degrees C and was coincident with a transition in structure, Ts*, determined as the change in temperature coefficient of motion for a spin label intercalated with the membrane lipids. This suggest that the change in thermal response of the membrane-associated enzymes is related to a change in molecular ordering of the membrane lipids. When mitochondria were stored at -12 degrees C, the specific activities of succinate:cytochrome c reductase and cytochrome c oxidase decreased. Concomitant with these changes the Ea, above Tf*, increased. After 100 days storage at -12 degrees C, Ea above Tf* approached the value for Ea below Tf* such that the transition in thermal response could no longer be detected. In contrast, for mitochondria stored at -196 degrees C, although the specific activity declined over the 100 days storage, no changes in either Ea or Tf* were evident. The results indicate a need for caution in evaluating comparative studies of Tf and Ea, for membrane-associated enzymes, using mitochondria which have been frozen and stored.     

Cryopreservation of sperm from the marine shrimp Sicyonia ingentis

Sperm from a marine shrimp, Sicyonia ingentis, were frozen to -196 degrees C using a variety of cooling rates and cryoprotectants. A cooling rate of 1 degree C/min resulted in minimal cell breakage. Sperm samples were frozen in solutions of known membrane stabilizers--trehalose, sucrose, proline, and glycerol. These compounds were somewhat effective but a dramatic increase in sperm viability was seen when DMSO was present in the freezing medium. Sperm viability was assessed using the in vitro acrosome reaction technique of Griffin et al. (1987). The highest sperm survival (56%) was obtained with samples frozen at 1 degrees C/min in a 5% (v/v) DMSO solution. No decrease in viability was seen in sperm samples stored in liquid nitrogen (-196 degrees C) for 1 month.     

Lipid and protein changes due to freezing in Dunning AT-1 cells

Defining the process of cellular injury during freezing, at the molecular level, is important for cryosurgical applications. This work shows changes to both membrane lipids and protein structures within AT-1 Dunning prostate tumor cells after a freezing stress which induced extreme injury and cell death. Cells were frozen in an uncontrolled fashion to -20 or -80 degrees C. Freezing resulted in an increase in the gel to liquid crystalline phase transition temperature (T(m)) of the cellular membranes and an increase in the temperature range over which the transition occurred, as determined by Fourier transform infrared spectroscopy (FTIR). Thin layer chromatography (TLC) analysis of total lipid extracts showed free fatty acids (FFA) in the frozen samples, indicating a change in the lipid composition. The final freezing temperature had no effect on the thermotropic response of the membranes or on the FFA content of the lipid fraction. The overall protein secondary structure as determined by FTIR showed only slight changes after freezing to -20 degrees C, in contrast to a strong and apparently irreversible denaturation after freezing to -80 degrees C. Taken together, these results suggest that the decrease in viability between control and frozen cells can be correlated with small changes in the membrane lipid composition and membrane fluidity. In addition, loss of cell viability is associated with massive protein denaturation as observed in cells frozen to -80 degrees C, which was not observed in samples frozen to -20 degrees C.     

Fertilizing capacity and ultrastructure of fowl and turkey spermatozoa before and after freezing.

The fertilizing capacity, motility and ultrastructure of fowl and turkey spermatozoa were examined at various stages of the freezing process. For both species, fertility and motility were depressed after equilibration with dimethyl-sulphoxide at 5 degrees C. After freezing, motility was maintained at 55% for fowl spermatozoa and 40% for turkey spermatozoa; however, fertility was 55% for the fowl and 0% for the turkey. Qualitatively, the damage to the spermatozoa of both species was nearly identical, as revealed by scanning and transmission electron microscopy. The plasmalemma was the primary site of damage. 'Bent' spermatozoa, coiled tails and swollen mitochondria were also present. Damage to the acrosome was only observed in spermatozoa which had been frozen to -180 degrees or -196 degrees C. These changes were attributed to adverse osmotic conditions. Binding of cationic ferritin to the plasmalemma of spermatozoa from both species remained unaltered.     

Cryopreservation and transport of mouse spermatozoa at -79 degrees C.

In the present study, 2 experiments were carried out. In experiment 1, mouse spermatozoa were frozen and stored in an ultra-low temperature freezer maintained at -79 degrees C, from 1 week to 8 months. In vitro fertilization rates of the frozen-thawed sperm after 1 week and 4 months of storage were high at 71 and 71%, respectively. These values did not differ significantly from the value (73%) of the control stored at -196 degrees C. In contrast, the 8-month storage rate was significantly lower at 51%. In experiment 2, frozen spermatozoa were transported in a Styrofoam box packed in dry ice from Hokkaido to Tokyo. In vitro fertilization rate of frozen-thawed sperm after transport at -79 degrees C was high at 88%, which was not significantly different from that (84%) of the transported control at -190 degrees C. After transferring two-cell embryos derived from frozen spermatozoa to recipients, 37-62% of the embryos developed into offspring in both experiments. These results indicate that mouse spermatozoa can survive cryopreservation in an ultra-low temperature freezer (-79 degrees C) for up to 4 months and transport at -79 degrees C.     

Cryopreservation of mouse oocytes using a medium with low sodium content: effect of plunge temperature

The effect of various combinations of plunge temperature and thawing protocol on the survival and viability of mouse oocytes was examined. The oocytes were frozen either in a standard freezing medium (ETFM, embryo transfer freezing medium) or in a low-sodium, choline-based freezing medium (CJ2), with 1.5 M 1,2-propanediol and 0.1 M sucrose, and using a conventional slow cooling method. The criteria used to assess survival were morphological state after thawing (intact or lysed), ability to become fertilized, and ability to develop to the two-cell, morula, and blastocyst stage in vitro. Oocytes frozen in CJ2 and plunged into liquid nitrogen (LN(2)) from -10, -20, or -33 degrees C remained intact and developed to the blastocyst stage at significantly higher rates than oocytes frozen in ETFM. For oocytes plunged into LN(2) from -33 degrees C, very rapid thawing (10 s in 30 degrees C water) was more detrimental than rapid or slow thawing (holding in air at room temperature for 10 or 30 s, respectively, prior to submersion in water at 30 degrees C for 10 s). By contrast, oocytes plunged into LN(2) from -10 or -20 degrees C survived better when thawing was very rapid or rapid than when thawing was slow. With the current protocol CJ2 was very effective over a wide range of plunge temperatures (-20 to -33 degrees C), although the optimal thawing protocol depended on the particular plunge temperature. Over 90% of oocytes surviving after slow cooling in CJ2 to -33 degrees C could be plunged to -196 degrees C with little or no further damage.     

Inactivation of mitochondrial 2-oxoglutarate dehydrogenase complex as a result of phospholipid degradation induced by freeze-thawing.

The inactivation of 2-oxoglutarate dehydrogenase complex by freeze-thawing was examined along with alterations of membrane phospholipids, in order to elucidate the mechanism of freezing injury in mitochondria. The dehydrogenase complex activity in slowly frozen and thawed mitochondria decreased to 70% as compared to intact mitochondria and further decreased during incubation. This inactivation during incubation was temperature dependent, i.e., at temperatures up to 25 degrees C there was a slight decrease, while at higher temperatures there was a marked decrease in the dehydrogenase complex activity. Simultaneously, there was a significant accumulation of free fatty acids, generated from mitochondrial phospholipids, which inhibited 2-oxoglutarate dehydrogenase and subsequently enzyme complex activity. Oxoglutarate dehydrogenase activity in mitochondria was markedly inhibited by exogenous phospholipase A, and this inhibition was partially prevented with bovine serum albumin. Furthermore, when intrinsic phospholipase A was either inhibited or stimulated, there was a respective decrease or increase in the enzyme complex inactivation. The activity of the purified enzyme complex decreased slightly after slow freezing, but remained constant even when incubated at temperatures up to 32 degrees C. However, the activity of this enzyme complex was markedly reduced when incubated either in the presence of venom phospholipase A or with exogenous fatty acid. The relationship between inactivation of the 2-oxoglutarate dehydrogenase complex, phospholipase A activation and production of free fatty acids in frozen and thawed mitochondria is discussed.     

Ultrastructural changes in the MP3 neuron of the mollusk Lymnaea stagnalis after cryopreservation of the isolated brain

Investigation of a possibility of long-term storage of frozen (-196 degrees C) viable neurons and nervous tissue is one of the central present day problems. In this study ultrastructural changes in neurons of frozen-thawed snail brain were examined as a function of time. We studied the influence of cryopreservation, cryoprotectant (Me2SO), cooling to 4-6 degrees C, and a prolonged incubation in physiological solution at 4-6 degrees C on dictyosomes of Golgi apparatus, endoplasmic reticulum (ER) cisternae and mitochondria. It has been found that responses of these intracellular structures of cryopreserved neurons to the above influences are similar: dissociation of Golgi dictyosomes, swelling of endoplasmic reticulum cisternae and mitochondrial cristae. Both freezing-thawing and cryoprotectant were seen to cause an increase in the number of lysosomes, liposomes, myelin-like structures, and to form large vacuoles. The structural changes in molluscan neurons caused by cryopreservation with Me2SO (2 M) were reversible.     

Energy transfer from photosystem II to photosystem I in Porphyridium cruentum

Rates of photooxidation of P-700 by green (560 nm) or blue (438 nm) light were measured in whole cells of porphyridium cruentum which had been frozen to -196 degrees C under conditions in which the Photosystem II reaction centers were either all open (dark adapted cells) or all closed (preilluminated cells). The rate of photooxidation of P-700 at -196 degrees C by green actinic light was approx. 80% faster in the preilluminated cells than in the dark-adapted cells. With blue actinic light, the rates of P-700 photooxidation in the dark-adapted and preilluminated cells were not significantly different. These results are in excellent agreement with predictions based on our previous estimates of energy distribution in the photosynthetic apparatus of Porphyridium cruentum including the yield of energy transfer from Photosystem II to Photosystem I determined from low temperature fluorescence measurements.     

Changes in morphology and cell number of inner cell mass of porcine blastocysts during freezing

Changes in the morphology and cell number of the inner cell mass (ICM) of porcine blastocysts at the expanded and hatched stages during freezing (-6.8 degrees C, -35 degrees C and -196 degrees C) were studied by differential fluorochrome staining. The shape of each ICM cell from fresh blastocysts at the expanded and hatched stages was sharply delineated but that of ICM cells from frozen blastocysts was partially distorted. The cell-to-cell contact of the ICM from fresh blastocysts was tight, while that from frozen blastocysts was loose or scattered. The percentages (18 to 38%) of expanded and hatched blastocysts with tight-contact ICM cells from frozen groups at each step were significantly lower (P<0.05) than that (100%) from fresh blastocysts. The number of live ICM cells and their proportion from frozen expanded blastocysts (10.9, 12,4% at -36 degrees C) were significantly lower (P<0.05) than those from fresh embryos (18.4, 19.1%) and at -196 degrees C (20.6, 18.4%). At the hatched stage, the number of live ICM cells and their proportion were not significantly different between each freezing step. These results show that the ICM of porcine embryos at both the expanded- and hatched-blastocysts stages survived even after freezing at -196 degrees C and that the degree of ICM damage was lower at the hatched stage than at the expanded stage.     

Cryopreservation of Leucocytozoon caulleryi sporozoites

Leucocytozoon caulleryi sporozoites that had been stored at -196 degrees C or -80 degrees C for 6 or 12 months in Eagle's minimum essential medium or Medium 199 supplemented with 5% glycerol and 10% chicken serum showed infectivity to chickens. Glycerol at a concentration of 10% and dimethyl sulfoxide at 10% and 5% were found to be ineffective cryoprotective agents for the low temperature preservation of sporozoites. Sporozoites isolated from the intact females of Culicoides arakawae, which had been stored at -80 degrees C for 6 or 12 months without cryoprotective agents, retained their infectivity. No differences were observed in the prepatent period, duration of parasitemia, and presence of serum-soluble antigens between chickens infected with frozen sporozoites and those infected with fresh sporozoites.     

Changes in phospholipid composition of mitochondria after freezing-warming in the presence of Na2S204

The phospholipid composition of mitochondria membranes subjected to rapid freezing (300-400 degrees C per 1 min) to -196 degrees C and subsequent slow warning (at 20 degrees C) was determined by the method of chromatography in the thin layer of silicagel. Under such conditions of freezing and warming a significant decrease in lecithin and ethanolamine phosphatide content is observed in the mitochondria membranes. When freezing the suspension of mitochondria in the medium containing Na2S2O4 in a concentration of 0.05 M only the lipid component changes slightly.     

The mitochondria of higher mushrooms: the cytochromes beta of the mitochondria of Agaricus campestris (F.) var. bisporus]

Kinetic studies of cytochrome reduction show that only two beta-type cytochromes reducible in the presence of succinate are present in A. campestris mitochondria. At 25 degrees C, the difference spectrum reduced in the presence of antimycin minus oxidized shows the two beta-type cytochrome have a common, asymetric alpha-band at 560 nm which splits into two peaks at 559 and 562 nm at liquid nitrogen temperature (-196 degrees C).     

The role of freezing in trypsin activity oscillations.

The importance of the frozen phase in the formation of cryooscillations of trypsin activity has been shown in experiments conducted at -10 degrees C under frozen and supercooled conditions, respectively. A solution containing trypsin obtained by trypsinogen activation and 0.1 M MnCl2 was distributed in test tubes with or without previous freezing and kept at -10 degrees C and pH 8.4. At given time intervals the frozen and supercooled samples were tested simultaneously for tryptic activity. Although a temporal motion of trypsin activity was produced by the frozen samples, the activity of the supercooled samples began to oscillate only after spontaneous freezing of the solutions. This phenomenon suggests the importance of compartmentalization of the frozen heterogeneous system, which results in an increase in concentration vs a decrease in diffusion rate of the components.     

Real-time evaluation of macromolecular surface modified quartz crystal resonant sensors under cryogenic stress for biological applications

This study presents a novel auto-gain-control based quartz acoustic sensor technology capable of constant quartz crystal operation when cycled between ambient (22 degrees C) and cryogenic temperatures (-196 degrees C), afforded by direct exposure of crystals to bulk liquid nitrogen. The real-time frequency response profiles due to freeze-thaw cycling on crystals of differing surface finish and two model macromolecular surface coatings were studied in order to determine surface events such as water uptake. The quartz crystal surface finishes used were optically polished or lapped to one of two surface finishes. These were used as control native gold electrodes, and these surfaces were further coated with bovine serum albumin or the tri-block copolymer, poloxamer-188 as model macromolecular surface architectures. Crystals were snap frozen in liquid nitrogen and allowed to return to ambient temperature under controlled conditions. The processes of ice formation, thawing and evaporation were followed in real-time and comparisons were made between the test samples in order to assess the capability of this technique for sensing changes in surface characteristics such as the entrapment of water.     

Deep freezing of sheep embryos.

Sheep embryos, collected 1-8 days after oestrus, were placed in Dulbecco's phosphate-buffered saline medium (PBS). After treatment, the viability of the embryos was tested by temporary transfer to ligated rabbit oviducts. In Exp. 1, Days 5-8 embryos survived for at least 15 min at 0 degrees C in the presence of 1-5 M-DMSO. In Exp. 2, 12/14 Days 5-8 embryos survived after being frozen in 1-5 M-DMSO at 0-3 degrees C/min to temperatures ranging between-15 degrees and -60 degrees C and then thawed at 12 degrees C/min. In Exp. 3, Days 5-8 embryos were frozen in 1-5 M-DMSO at 0-3 degrees C/min to below-65 degrees C before being transferred to liquid nitrogen (-196 degrees C), and stored for 12 hr to 1 month. The embryos were thawed at 3 degrees C/min, 12 degrees C/MIN or 360 degrees C/min and, after transfer to rabbit oviducts, 0/4, 10/36 and 1/4, respectively, developed normally. The 11 embryos which were considered normal when recovered from the rabbit oviducts plus 1 slightly retarded embryo were transferred to 7 recipient ewes. Four ewes subsequently lambed, producing 5 lambs. In addition, 8 embryos were transferred to 4 ewes directly after thawing. Three of these ewes subsequently lambed, producing 3 lambs.     

Effects of various conditions of semen storage on the acrosin system of human spermatozoa

Stability of the human sperm acrosin system (major components: non-zymogen acrosin, proacrosin and acrosin inhibitor) was studied under various conditions of semen storage used clinically or in the laboratory. Freezing at -196 degrees C caused a profound decrease in total acrosin content and in the amount of this enzyme present in zymogen form (proacrosin), but resulted in some increase in non-zymogen acrosin. Acrosin inhibitor did not appear to be significantly affected by this treatment. No relationship was present between the decreases in sperm motility induced by freezing to -196 degrees C and the alterations in total acrosin, proacrosin and non-zymogen acrosin. Storage of whole semen at -20 degrees C had deleterious effects on all the components of the acrosin system measured except for non-zymogen acrosin. Major decreases in the total acrosin, proacrosin and acrosin inhibitor occurred after only 1 day at -20 degrees C and continued slowly thereafter. Whole semen kept at room temperature for up to 24 h after ejaculation did not show any significant changes in the sperm acrosin system. Seminal plasma did not have a detrimental or stabilizing effect of acrosin and proacrosin when spermatozoa were kept at room temperature. However, removal of seminal plasma and re-suspension of spermatozoa in 0.9% NaCl resulted n the liberation of a significant amount of the acrosin inhibitor from the spermatozoa and the apparent activation of some of the proacrosin to acrosin.     

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.