Spermatogonial transplantation in fish: A novel method for the preservation of genetic resources

Recent progress in genome-based breeding has created various fish strains carrying desirable genetic traits; however, methods for the long-term preservation of their genetic resources have not yet been developed, mainly due to the lack of cryopreservation techniques for fish eggs and embryos. Recently, we established an alternative cryopreservation technique for fish spermatogonia using a slow-freezing method. Furthermore, we developed a transplantation system to produce functional eggs and sperm derived from spermatogonia. Spermatogonia isolated from the testes of vasa-green fluorescent protein (Gfp) transgenic rainbow trout (Oncorhynchus mykiss) were transplanted into the peritoneal cavity of triploid masu salmon (Oncorhynchus masou) hatchlings of both genders. The transplanted trout spermatogonia migrated towards the gonadal anlagen of the recipient salmon, into which they were subsequently incorporated. We confirmed that the donor-derived spermatogonia resumed gametogenesis, and produced sperm and eggs in male and female recipient salmon, respectively. Fertilization of the resultant eggs and sperm produced only rainbow trout in the first filial (F₁) generation, suggesting that the sterile triploid recipient salmon produced functional eggs and sperm derived from the trout donors. A combination of spermatogonial transplantation and cryopreservation could be a powerful tool for preserving valuable fish strains with desirable genetic traits and endangered species.     

Systematic factor optimization for cryopreservation of shipped sperm samples of diploid Pacific Oysters, Crassostrea gigas

Despite some 26 published reports addressing oyster sperm cryopreservation, systematic factor optimization is lacking, and sperm cryopreservation has not yet found application in aquaculture on a commercial scale. In this study, the effects of cooling rate, single or combined cryoprotectants at various concentrations, equilibration time (exposure to cryoprotectant), straw size, and cooling method were evaluated for protocol optimization of shipped sperm samples from diploid oysters. Evaluation of cooling rates revealed an optimal rate of 5 degrees C/min to -30 degrees C followed by cooling at 45 degrees C/min to -80 degrees C before plunging into liquid nitrogen. Screening of single or combined cryoprotectants at various concentrations suggested that a low concentration (2%) of polyethylene glycol (FW 200) was effective in retaining post-thaw motility and fertilizing capability when combined with permeating cryoprotetcants such as dimethyl sulfoxide (DMSO), methanol (MeOH), and propylene glycol (P-glycol). However, polyethylene glycol alone was not as effective as MeOH, DMSO, and P-glycol when using the same methods. The highest post-thaw motility (70%) and percent fertilization (98%) were obtained for samples cryopreserved with 6% MeOH. However, this does not exclude other cryoprotectants such as DMSO or P-glycol identified as effective agents in other studies. There was no significant difference in post-thaw motility between straw sizes of 0.25- and 0.5-ml. Equilibration time (exposure to cryoprotectant) of 60 min could be beneficial when the cryoprotectant concentration is low and solution is added in a step-wise fashion at low temperature. Differences in post-thaw sperm quality (e.g., motility or percent fertilization) among individual males were evident in this research. As a consequence, a generalized classification describing males with different tolerances (broad, intermediate, and narrow) to cryopreservation was developed. This classification could be applied to strain or species differences in tolerances to the cryopreservation process. The present study demonstrated that oyster sperm could be collected and shipped chilled to another facility for cryopreservation, and that it could be shipped back to the hatchery for fertilization performed at a production scale yielding live larvae with >90% fertilization. Given the existence of facilities for commercial-scale cryopreservation of dairy bull sperm, the methods developed in the present study for oysters provide a template for the potential commercialization of cryopreserved sperm in aquatic species.     

Adding cholesterol to the stallion sperm plasma membrane improves cryosurvival

Cryopreservation induces partially irreversible damage to equine sperm membranes. Part of this damage occurs due to membrane alterations induced by the membrane changing from the fluid to the gel-state as the temperature is reduced lower than the membrane transition temperature. One way to prevent this damage is to increase the membrane fluidity at low temperatures by adding cholesterol to the membrane. Different concentrations of cholesterol-loaded-cyclodextrins (CLC) were added to stallion sperm to determine the CLC concentration that optimizes cryosurvival. Higher percentages of motile sperm were maintained after thawing when 1.5 mg CLC was added to sperm from stallions whose sperm do not survive freezing well, compared to control sperm from those same stallions (67% vs. 50%; P<0.05). Addition of CLCs increased the percentages of membrane intact sperm surviving cryopreservation compared to untreated sperm for all stallions (P<0.05). The amount of cholesterol that incorporated into the membranes of the sperm cells increased in a polynomial fashion (R2=0.9978) and incorporated into all sperm membranes. In addition, there was a significant loss of cholesterol from sperm membranes after cryopreservation; however, addition of CLCs to sperm prior to cryopreservation maintained higher cholesterol levels in the sperm after freezing and thawing than untreated sperm (P<0.05). Addition of CLCs also resulted in more sperm binding to the zona pellucida of bovine oocytes after cryopreservation than control sperm (48 vs. 15; P<0.05). In conclusion, CLCs improved the percentage of post-thaw viability in equine sperm as well as increased the number of sperm that bind to zona pellucida. Addition of CLCs to stallion sperm prior to cryopreservation is a simple procedure that increases the cryosurvival of cells.     

Regeneration of cryoresistance of in vitro rumen ciliate cultures

The purpose of this study was to investigate factors affecting mechanical- and cryo-resistance of the rumen ciliates Entodinium caudatum (E.c.), Entodinium furca monolobum (E.f.m.), Entodinium simplex (E.s.), Diplodinium denticulatum (two clones, D.d.01 and D.d.02), Diploplastron affine (D.a.) and Epidinium ecaudatum forma caudatum (E.e.c.) after long-term in vitro cultivation. Following prolonged in vitro cultivation (more than six months), the ciliates were very sensitive to both centrifugation and 5% (v/v) dimethylsulphoxide, with motility decreased to: 39 and 23% for E.c., 66 and 32% for E.f.m., 46 and 27% for D.d. 01, 64 and 41% for D.a., and 44 and 28% for E.e.c., respectively. Thus, cryopreservation was unsuccessful. The effect of supplementing the ciliate growth medium with rumen fluid, glycine-betaine, proline, myo-inositol, linoleic acid, Sel-Plex or insulin, together with the effect of the source of rumen fluid on ciliate resistance to centrifugation, dimethylsulphoxide and freezing was also tested. The omission of rumen fluid from the growth medium resulted in the loss of cryoresistance after one-month cultivation. Supplementing the growth environment with a combination of glycine-betaine, proline, linoleic acid, Sel-Plex, insulin plus improved quality rumen fluid significantly enhanced survival of the ciliates after the freezing-thawing procedure (from 1 to 33% survival in un-supplemented vs. supplemented for E.c., P < 0.01; 4-40% E.f.m., P < 0.01; 0-17% D.d., P < 0.05; 5-7% D.a. and 4-36% E.e.c., P < 0.01).     

Osteoblast viability and differentiation with Me2SO as cryoprotectant compared to osteoblasts from fresh human iliac cancellous bone

The aim of this study was to compare the viability of human osteoblasts cryopreserved with Me2SO to that of fresh human iliac cancellous bone using cell culture techniques. Osteoblasts were obtained by spontaneous outgrowth of human iliac cancellous bone specimens in experiment I. In experiment II, human iliac cancellous bone was frozen with 10% Me2SO at -80 degrees C for 2 weeks and osteoblasts grew spontaneously after thawing at 37 degrees C by removing Me2SO with sucrose. The cells were grown in culture flasks containing DMEM as a culture medium, supplemented with 10% fetal calf serum. They were kept at 37 degrees C in a humidified atmosphere of 95% air and 5% CO2. Cells from the second passage were plated at a density of 5 times 10(3) cells/cm2 in 24-well plates. For detection of viability and differentiation, WST-1 assay, determination of alkaline phosphatase activity, concentration of procollagen I peptide, concentration of osteocalcin, and indirect immunofluorescence for osteopontin, collagen type I, integrin beta1, and fibronectin were applied. Experiments were conducted at four stages of confluence (days 4, 7, 14, and 21 after plating the cells). Based on the results of this study, we conclude that osteoblast-like cells survived cryopreservation and synthesized a range of markers that were consistent with this cell type.     

Rapid cryopreservation of five mammalian and one mosquito cell line at −80°C while attached to flasks in a serum free cryopreservative

Cell culturing, and the requisite storage of cell lines at ultra-low temperatures, is used in most laboratories studying or using eukaryotic proteomics, genomics, microarray, and RNA technologies. In this study we have observed that A72(dog), CRFK(cat), NB324K(human), MCF7(human), WI38(human), and C636(mosquito) cells were effectively cryopreserved at −80°C while attached to the substratum of 25cm² tissue culture flasks. This was accomplished using a serum free crypreservative recently developed by Corsini and co-workers. The technique allows for significant savings of time and money in laboratories that rapidly process numerous cell lines.     

Cryopreservation of spermatozoa of the terrestrial Puerto Rican frog, Eleutherodactylus coqui

World-wide reports of amphibian population declines have led to increased interest in the reproductive biology of anurans. As a model system, here we present evidence for the effective cryoprotection of sperm from the Puerto Rican frog, Eleutherodactylus coqui, using mixtures of fetal bovine serum (FBS) and dimethylsulfoxide (Me(2)SO), glycerol or sucrose extenders. Using a fluorescent dye exclusion assay, we found that 53.9 and 50.4% of all sperm with intact membranes prior to freezing maintained membrane integrity after rapid freezing and thawing when protected with either a FBS/glycerol or FBS/sucrose solution, respectively. The methods reported here may be useful for similar work with many of the more than 700 other species in this genus.     

Glass-forming property of the system diethyl sulphoxide/water and its cryoprotective action on Escherichia coli survival

In this work the thermal properties of diethyl sulphoxide (Et2SO), as well as its cryoprotective ability are studied and related to other well-known cryoprotectant substances, like dimethyl sulphoxide (Me2SO). We have investigated the thermal properties of Et2SO/water systems using Differential Scanning Calorimetry at a very low heating/cooling rate (2 degrees C/min). Liquid/solid or glassy/crystalline transitions have been observed only for the solutions with content of Et2SO ranging from 5 up to 40% w/w and/or greater than 85%. In the 45-75% w/w Et2SO range we have found a noticeable glass-forming tendency and a great stability of the amorphous state to the reheating. In samples with Et2SO content ranging from 80 to 85%, we observed a great stability of the glass forming by cooling, but a lesser stability to the subsequent reheating. The glass-forming tendency of these solutions is discussed in terms of existing competitive interactions between molecules of Et2SO, on the one hand, and Et2SO and water molecules, on the other hand. The results are well explainable on the basis of the model structure of water/Et2SO solutions, deduced by Raman and infrared studies [J. Mol. Struct. 665 (2003) 285-292]. The cryoprotective ability of Et2SO on Escherichia coli survival has been also investigated, and a comparison among Et2SO and other widely used cryoprotectants, like Me2SO and glycerol has been done. Survival of E. coli, determined after freezing-thawing process, was maximal at 45% w/w Et2SO (more than 85% viability). It should be noted that at the same concentration the survival is only about 35% in the presence of Me2SO and not more than 15% in the presence of glycerol. These features are well consisted with the glass-forming properties of Et2SO.     

High ice nucleation temperature of zebrafish embryos: slow-freezing is not an option

Although fish embryos have been used in a number of slow-freezing cryopreservation experiments, they have never been successfully cryopreserved. In part this is because little is known about whether ice forms within the embryo during the slow-freezing dehydration process. Therefore, we examined the temperature of intraembryonic ice formation (T(IIF)) and the temperature of extraembryonic ice formation (T(EIF)), using a cryomicroscope. We used both unmodified zebrafish embryos and those with water channels (aquaporin-3 or AQP3) inserted into their membranes to increase permeability to water and cryoprotectants, examined at 100% epiboly to the 6-somite stage. In these experiments we examined: (1) the spontaneous freezing of (external) solutions; (2) the spontaneous freezing of solutions containing embryos; (3) the effect of preloading the embryos with cryoprotectants on T(IIF); (4) whether preloading the embryos with cryoprotectant helps in survival after nucleating events in the solution; and (5) the damaging effects of extracellular nucleation events versus solution toxicity on the embryos. The solutes alone (embryo medium--EM, sucrose culture medium, 1 M propylene glycol in EM, and 1 M propylene glycol in a sucrose culture medium) froze at -14.9 +/- 1.1, -17.0 +/- 0.3, -17.8 +/- 1.0, and -17.7 +/- 1.4, respectively. There was no difference amongst these means (P > 0.05), thus adding cryoprotectant did not significantly lower the nucleation point. Adding embryos (preloaded with cryoprotectant or not) did not change the basic freezing characteristics of these solutes. In all these experiments, (T(EIF)) equaled (T(IIF)), and there was no difference in the freezing point of the solutions with or without the embryos (P > 0.05). Additionally, there was no difference in the freezing characteristics of embryos with and without aquaporins (P > 0.05). The formation of intraembryonic ice was lethal to the zebrafish embryos in all cases. But this lethal outcome was not related to solution injury effects, because 88-98% of embryos survived when exposed to a higher solute concentration with no ice present. Taken together, these data suggest that slow-freezing is not a suitable option for zebrafish embryos. The mechanism of this high temperature nucleation event in zebrafish embryos is still unknown.     

The osmotic characteristics of human fetal liver-derived hematopoietic stem cell candidates

Hematopoietic stem cells derived from fetal liver have promising therapeutic potential for allotransplantation but require a specific protocol to minimize the damage produced by cryopreservation procedures. In this study, a fundamental approach was applied for designing a cell preservation protocol. To this end, the biophysical characteristics that describe the osmotic reaction of CD34(+)CD38(-) human fetal liver stem cell candidates were studied using fluorescent microscopy. The osmotically inactive volume of the stem cell candidates was determined as 48% of the isotonic volume. The permeability coefficients for water and Me(2)SO were determined at T = +22 degree C: L(p) = 0.27 +/- 0.03 microm x min(-1)atm(-1), P(Me(2)SO)) = 2.09 +/- 0.85 x 10 (-4) cm x min(-1), sigma (Me(2)SO)) = 0.63 +/- 0.03 and at T = +12 degree C: L(p) = 0.15 +/-0.02 microm x min(-1)atm(-1), P(Me(2)SO)) = 6.44 +/-1.42 x 10 (-5) cm x min(-1), sigma (Me(2)SO)) = 0.46 +/- 0.05. The results obtained suggest that post-hypertonic and hypotonic stress are the possible reasons for damage to a CD34(+)CD38(-) cell during the cryopreservation procedure.