Cryopreservation of mouse spermatozoa]

The spermatozoa of cauda epididymis of mature mice were suspended in 3% skim milk in distilled water supplemented with 12, 15, 18 or 21% (W/V) raffinose. The suspension of spermatozoa were frozen in liquid nitrogen gas for 10 min, then stored in liquid nitrogen (-196 degrees C). The frozen suspensions of spermatozoa were thawed by rapid warming in water bath at room temperature. For removing the cryopreservative solution, a pair of syringes connected with a three stop cock and a filter unit (pore size 0.45 mu) were used. Highest sperm motility was obtained after 1 hr of thawing from the cryopreservative solution containing 18% raffinose and 3% skim milk. These cryopreserved spermatozoa were used for fertilization in vitro. The proportion of pronuclear oocytes was 35.9% (74/206) 6 hr after insemination, and the proportion of 2-cell embryos was 33.6% (42/125) 28 hr after insemination. All 2-cell embryos were transferred to the oviducts of pseudopregnant recipients and 45.2% (19/42) developed to normal young.     

Cryopreservation of mouse spermatozoa

Recently, it has become possible to freeze a large number of mouse spermatozoa immediately after collection from the epididymides of a small number of males. The cryopreservation of spermatozoa is simpler, less time-consuming, and less costly than that of embryos for maintaining various strains of mice with induced mutations. This chapter attempts to provide a realistic overview of the cryopreservation of mouse spermatozoa and to describe a detailed procedure for mouse sperm freezing. Received: 16 December 1999 / Accepted: 17 December 1999     

Cryopreservation of wild mouse spermatozoa

Spermatozoa of wild mice from China, Czechoslovakia, Denmark, India, Japan and Switzerland were frozen and stored at -196 degrees C. After thawing, intact oocytes were inseminated in vitro with relatively high motility frozen-thawed mouse spermatozoa from Czechoslovakia, Denmark and India, while oocytes with a partially dissected zona were inseminated with low motility frozen-thawed spermatozoa from China, Japan and Switzerland. Embryos developing to the 2-cell stage from oocytes fertilized with frozen-thawed spermatozoa were transferred to the oviducts of female recipients on the first day of pseudopregnancy (day when a vaginal plug was confirmed). Successful embryo development to the 2-cell stage was 46 to 67%. Offspring resulted from 17 to 51% of these transferred 2-cell embryos.     

Cryopreservation of mouse spermatozoa: double your mouse space

Cryopreservation of mouse germplasm is an important tool to secure, archive and distribute mouse lines of different origin. While embryo freezing has been standard procedure for many years, major advantages in freezing spermatozoa have been made recently that open new opportunities for management of mouse colonies.     

Cryopreservation of mouse spermatozoa in the presence of raffinose and glycerol

When mouse epididymal spermatozoa were rapidly frozen in two steps (37 to -70 degrees C for solid CO2 and -70 to -196 degrees C for liquid nitrogen) as pellets, 18% raffinose provided the greatest protection to ICR mouse spermatozoa against cold-shock; sperm motility and fertilizing ability were 43% and 22.4%, respectively. A small proportion of spermatozoa frozen with 10% sucrose was motile but incapable of fertilizing ovulated oocytes. Glycerol and dimethylsulphoxide were less effective at any concentration examined. However, the fertilizing ability of frozen-thawed ICR spermatozoa was significantly improved (35.5%) by addition of glycerol (1.75% final concentration) to medium containing 18% raffinose. Spermatozoa from one outbred (ddY) and 5 inbred (C57BL/6N, C3H/HeN, DBA/2N, BALB/c and kk) strains of mice were successfully frozen in the presence of 18% raffinose and 1.75% glycerol, although the fertilization rates of frozen-thawed spermatozoa varied among strains (13% for C57BL/6N to 64% for DBA/2N). A small fraction of mouse eggs resulting from fertilization by frozen-thawed spermatozoa developed normally in vitro (37% in C57BL/6N to 71% in ICR) to the blastocyst stage and in vivo (19% for C57BL/6N spermatozoa and ddY oocytes) to Day 18 of gestation.     

Cryopreservation of murine spermatozoa

Cryopreservation of mouse sperm provides an economic option for preserving the large number of mouse strains now being generated by transgenic and targeted mutation methodologies. The ability of a spermatozoan cell to survive cryobiological preservation depends on general biophysical constraints that apply to all cells, such as the avoidance or minimization of the formation of intracellular ice during cooling. This action is typically achieved by use of cryoprotectant substances and by controlled, slow rates of cooling. Superimposed on those general constraints may be special characteristics of mouse spermatozoa, such as more narrow, osmotically driven volume tolerance limits and the fact that relatively successful freezing can be obtained without the use of a permeating cryoprotective agent. The lack of important information regarding sperm cells fundamental cryobiological properties, including their osmotic and membrane permeability characteristics, has hindered progress in developing anything but empirically derived methods. Genetic differences between inbred mouse strains are reflected in motility and fertility characteristics of mouse sperm and contribute to the difficulty of developing successful cryopreservation methods. Recovery of live young from frozen sperm has been much more successful with sperm from hybrid mice than from most inbred strains. There have been no published reports of successful cryopreservation of rat sperm. Nevertheless, in mice, success in deriving live young from intracytoplasmic sperm injection using sperm frozen under suboptimal conditions raises the possibility of using this technique for the ultimate rescue of sperm regardless of the success of cryopreservation. This technique, however, requires additional development and verification of its efficacy before it will be suitable for general laboratory use. Although cryopreservation of mouse sperm is not yet universally successful, it can be used reliably to supplement cryopreservation of embryos and other germline cells or tissues for preserving biomedically important strains of mice for research.     

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 flow-sorted bovine spermatozoa

Experiments were designed to maximize sperm viability after sorting by flow cytometry and cryopreservation. Experiments concerned staining sperm with Hoechst 33342 dye, subsequent dilution, interrogation with laser light, and postsort concentration of sperm. Concentrating sorted sperm by centrifugation to 10 to 20 x 10(6) sperm/ml reduced adverse effects of dilution. Exposing sperm to 150 mW of laser light resulted in lower percentages of progressively motile sperm after thawing than did 100 mW. Sorted sperm extended in a TRIS-based medium had higher postthaw sperm motility after incubation for 1 or 2 h than sperm extended in egg-yolk citrate (EYC) or TEST media, and equilibrating sperm at 5 degrees C for 3 or 6 h prior to freezing was superior to an equilibration time of 18 h. For sorting sperm 4 to 7 h postcollection, it was best to hold semen at 22 degrees C neat instead of at 400 x 10(6)/ml in a TALP buffer with Hoechst 33342. Current procedures for sexing sperm using flow cytometry result in slightly lower postthaw motility and acrosomal integrity compared to control sperm. However, this damage is minor compared to that caused by routine cryopreservation. Fertilizing capacity of flow-sorted sperm is quite acceptable as predicted by simple laboratory assays, and sexed bovine sperm for commercial AI may be available within 2 years.     

淡水鱼类精子的冷冻与保存

养殖鱼类精子的保存具有深刻的研究意义和良好的应用前景,关于鱼类精子的冷冻保存国内外已经有开展了不少研究。对淡水鱼类精子的冷冻保存,特别是淡水鱼类精子的超低温冷冻保存研究进展进行综述。     

Cryopreservation of transgenic mice

Advances in cryopreservation enable one to freeze embryos without the use of a programmable freezing machine or complex protocols. These methods achieve high rates of survival when mouse embryos are frozen. Understanding the factors that influence the survival of cryopreserved embryos can aid troubleshooting and in adapting freezing strategies from mice to other species. Frozen stocks of transgenics can be maintained indefinitely in liquid nitrogen. Cryopreservation of these valuable animals not only protects them from environmental catastrophes, but also is an economical method of storing lines for future detailed analysis.     

Cryopreservation of spermatozoa in cyprinid fishes

The present study investigated semen cryopreservation in cyprinid fish using computer-assisted sperm motility analysis for viability control. Spermatozoa of the bleak, Chalcalbumus chalcoides, were used as a basic model to describe the toxic and cryoprotective effects of internal and external cryoprotectants, their most effective concentrations and combinations, the freezing and thawing conditions, and the effects of equilibration. We also used these data to develop a cryopreservation protocol for Barbus barbus, Chondrostoma nasus, Ctenopharyngodon idella, Cyprinus cario, Hypohtalmichthys molitrix, Leuciscus cephalus, Rutilus meidingerii, and Vimba vimba. For all investigated species the optimal extender composition was a buffered physiological sperm motility-inhibiting saline solution containing 10% DMSO and 0.5% glycin. The optimal sperm equilibration period in the extender was < or = 5 min. Freezing was performed in an insulated box in liquid nitrogen vapor and it was optimal at 4 to 5 cm above the surface of the liquid, depending on the species. Thawing was optimal in a 25 degrees C water bath whereby the thawing time ranged depending on species from 15 to 45 sec. This cryopreservation protocol resulted in frozen-thawed semen with 35 to 65% motile and 5 to 25% locally motile spermatozoa depending on the quality of fresh semen.     

Cryopreservation of Xenopus transgenic lines

Xenopus laevis has been widely used for molecular, cellular, and developmental studies. With the development of the sperm-mediated transgenic method, it is now possible to study gene function during vertebrate development by using this popular model. On the other hand, like other animal species, it is labor intensive, and the maintenance of transgenic lines is expensive. In this article, we investigated the possibility of using sperm-cryopreservation as a means to preserve transgenic frog lines. We demonstrated that cryopreserved sperms are viable but not fertile under our in vitro fertilization (IVF) conditions. However, by microinjecting cryopreserved sperm nuclei, we successfully regenerated a transgenic line carrying a double promoter transgene construct, where the marker gene encoding the green fluorescent protein (GFP) is driven by the gamma-crystallin gene promoter and a gene of interest, encoding a fusion protein of GFP with the matrix metalloproteinase stromelysin-3 (ST3-GFP), is driven by a heat shock-inducible promoter. We demonstrated the functional transmission of the ST3-GFP transgene by analyzing the phenotype of the F1 animals after heat-shock to induce its expression. Our method thus provides an inexpensive means to preserve transgenic frog lines and a convenient way for distribution of transgenic lines. Furthermore, the ease with which to microinject nuclei compared to the technically demanding transgenesis procedure with variable outcome should facilitate more laboratories to use transgenic Xenopus laevis for functional studies in vivo. Mol. Reprod. Dev. 67: 65-69, 2004.     

Cryopreservation of spermatozoa from closed colonies, and inbred, spontaneous mutant, and transgenic strains of rats

We attempted to cryopreserve spermatozoa from closed colonies (Jcl:SD and Jcl:Wistar), and inbred (BN/Crj, F3441 DuCrj, LEW/Crj, Long-Evans and WKY/NCrj), mutant (Zitter [WTC.ZI-zi] and Tremor [TRM]), transgenic (human A-transferase [A], and green fluorescent protein [GFP]) strains of rats. Rat epididymal spermatozoa suspended in cryopreservation solution (23% egg yolk, 8% lactose monohydrate, and 0.7% Equex Stm, pH 7.4, adjusted with 10% Tris [hydroxymethy] aminomethane) were frozen and stored at -196 degrees C. After thawing at 37 degrees C, the spermatozoa were instilled into the tip of each uterine horn of the recipients. A total of five recipient females for each strain were inseminated with cryopreserved spermatozoa, and normal live offspring of all strains (Jcl:SD: 11, Jcl:Wistar: 13, BN/Crj: 9, F344/DuCrj: 28, LEW/Crj: 4, Long-Evans: 6, WKY/NCrj: 8, TRM: 24, WTC.ZI-zi: 27, A: 30 and GFP: 20) were obtained.     

Cryopreservation of bull spermatozoa alters the perinuclear theca

The perinuclear theca (PT) is involved in several important sperm functions leading to fertilization. The objective of this study was to investigate the effect of cryopreservation of bull spermatozoa on the integrity of the PT and the relationship between PT integrity and semen characteristics. Semen from seven bulls was evaluated before and after cryopreservation, comparing the integrity of the plasma membrane (hypo-osmotic test), percentage of live and dead spermatozoa (triple stain), acrosome integrity (triple stain) and the integrity of the PT (negative stain by electron microscopy). Cryopreservation of bull semen caused substantial damage to the PT; the proportion of spermatozoa with a damaged PT was 15.2% versus 52.5% (P<0.05) in fresh versus frozen-thawed spermatozoa, respectively. Furthermore, on average, 67.4% (range, 64-72%) of fresh spermatozoa were live, compared to 53.1% (range, 49-58%) for frozen-thawed spermatozoa; there was an inverse correlation between the percentage of live spermatozoa and the percentage with damage to the PT. Although 59.1% of frozen-thawed spermatozoa had an intact acrosome, only 43.7% of them still remained alive. In frozen-thawed semen, there was a high correlation (r=0.69) between live spermatozoa with an intact acrosome and spermatozoa that maintained an intact PT. In conclusion, freezing/thawing of bull spermatozoa altered the PT and maintaining PT integrity may be necessary to maintain acrosome integrity.     

Cryopreservation of seabream (Sparus aurata) spermatozoa

The aim of this research was to optimize protocols for freezing spermatozoa of seabream (Sparus aurata). All the phases of the cryopreservation procedure (sampling, choosing the cryoprotective extender, cooling, freezing, and thawing) were studied in relation to the species of spermatozoa under examination, so as to be able to restore on thawing the morphological and physiological characteristics of fresh semen. Seabream spermatozoa were collected by stripping and transported to the laboratory chilled (0-2 degrees C). Five cryoprotectants, dimethyl sulfoxide (Me(2)SO), ethylene glycol (EG), 1,2-propylene glycol (PG), glycerol, and methanol, were tested at concentrations between 5 and 15% by volume to evaluate their effect on the motility of semen exposed for up to 30 min at 26 degrees C. The less toxic cryoprotectants, 10% EG, 10% PG, and 5% Me(2)SO, respectively, were added to 1% NaCl to formulate the extenders for freezing. The semen was diluted 1:6 with the extender, inserted into 0.25-ml plastic straws by Pasteur pipette, and frozen using a cooling rate of either 10 or 15 degrees C/min to -150 degrees C followed by transfer and storage in liquid nitrogen (-196 degrees C). The straws were thawed at 15 degrees C/s. On thawing, the best motility was obtained with 5% Me(2)SO, although both 10% PG and EG showed good results; no differences were found between the two freezing gradients, although semen frozen with the 10 degrees C/min gradient showed a slightly higher and more prolonged motility.     

Cryopreservation of turbot (Scophthalmus maximus) spermatozoa

The aim of this study was to develop a method for cryopreserving turbot semen and to compare sperm motility characteristics, metabolic status and fertilization capacity of frozenthawed and fresh semen. The best results were obtained when spermatozoa were diluted at a 1:2 ratio with a modified Mounib extender, supplemented with 10% BSA and 10% DMSO. For freezing sperm samples, straws were placed at 6.5 cm above the surface of liquid nitrogen (LN) and plunged in LN. The straws were thawed in water bath at 30 degrees C for 5 sec. Use of this simple method resulted in a 60 to 80% reactivation rate of the thawed spermatozoa. Although the percentage of motile spermatozoa in the frozen-thawed semen samples was significantly lower than in fresh semen, spermatozoa velocity and respiratory rate remained unchanged. The process of cryopreservation significantly decreased intracellular ATP content. The fertilization rate of frozen-thawed spermatozoa was significantly lower than that of fresh spermatozoa, but it increased with sperm concentration.     

小鼠精子注入兔卵母细胞受精研究

The methods of intracytoplasmic sperm injection (ICSI) and subzonal injection (SUZI) were used to study heterologous fertilization and embryonic development between the mouse and the rabbit. Results were as follows: 1. The mouse sperm nuclei decondensed and formed pronuclei following microinjection into cytoplasm and perivitelline space (PVS) of rabbit oocytes; 2. The hybrid embryos developed to the stage of 8-cell when cultured in vitro; 3. The karyotype analysis showed a normal complement of rabbit oocyte and mouse sperm chromosomes in the 4-cell hybrid embryos; 4. The ultrastructure of 4-cell hybrid embryos was similar to that of normal 4-cell rabbit embryos; 5. The fertilization rate (32.4%) and cleavage rate (22.2%) when 5-10 mouse spermatozoa were injected were higher than those of injection of a single spermatozoon into PVS of the rabbit oocyte, but the difference was not significant (P > 0.05). The fertilization rate (42.3%) and cleavage rate (30.8%) in rabbit oocytes in vitro matured for 11-12 h were higher than those in the oocytes which were in vitro matured for 24-25 h following microinjection of 1-2 mouse spermatozoa into PVS, but the difference was not significant (P > 0.05).     

Cryopreservation of mouse embryoid bodies

Cryopreservation of embryonic stem (ES) cells is essential to establish them as a resource for regenerative therapy. We evaluated survival adhesion rate, cell structure, gene expression, and multipotency of frozen and thawed embryoid bodies (EBs) derived from mouse ES cells. EBs were cryopreserved using the BICELL and the Program Freezer. After one week the EBs were thawed and cultured. EBs prepared in the Program Freezer had the highest survival adhesion (Program Freezer; 55-69%, BICELL; 30-38%). Though many cells in the thawed EBs were damaged, some were not, especially those prepared in the Program Freezer. RT-PCR analysis showed that genes characteristic of the three embryonic germ layers were expressed in thawed EBs cultured for one week. EBs transplanted into mice formed teratomas consisting of cells derived from the three germ layers. In conclusion, EBs frozen in the Program Freezer had higher survival adhesion rates compared to the BICELL and formed differentiated cells characteristic of the three embryonic germ layers.     

Cryopreservation effects on domestic cat epididymal versus electroejaculated spermatozoa

Frozen-thawed epididymal spermatozoa have already been successfully used in artificial insemination in the domestic cat, proving to be a valuable resource for the reproduction of felid species, which are threatened with extinction. The aim of this study was to compare the effects of freezing and thawing on domestic cat semen collected by electroejaculation (EL) and from the epididymides (EP) and vasa deferentia. Ten adult cats were anesthetized, electroejaculated and immediately thereafter, orchiectomized. Epididymal spermatozoa were collected through the compression of caudae epididymidis and vasa deferentia. Spermatozoa were frozen-thawed following a single protocol. Sperm motility, sperm progressive status (0-5), plasma membrane integrity and morphology (light and transmission electron microscope) were assessed on two occasions, immediately after collection and after freezing and thawing. There were no significant differences between the electroejaculated and epididymal fresh or frozen-thawed spermatozoa for any of the variables. However, the incidence of acrosome defects after freezing and thawing increased by 19% based on light microscopy, whereas ultrastructural images revealed acrosome damages in most sperm cells. Since these acrosomal changes are known to affect sperm fertilising capacity, further studies are needed to optimize cryopreservation techniques for epididymal as well as electroejaculated domestic cat spermatozoa.