Cysteine analogs with a free thiol group promote fertilization by reducing disulfide bonds in the zona pellucida of mice.

Archives of cryopreserved sperm harvested from genetically engineered mice, in mouse resource centers, are a readily accessible genetic resource for the scientific community. We previously reported that exposure of oocytes to reduced glutathione (GSH) greatly improves the fertilization rate of frozen-thawed mouse sperm. Application of GSH to in vitro fertilization techniques is widely accepted as a standard protocol to produce sufficient numbers of mice from cryopreserved sperm. However, the detailed mechanism of the enhancement of fertilization mediated by GSH in vitro is not fully understood. Here we focused on the chemical by determining the effects of its amino acid constituents and cysteine analogs on the fertilization of oocytes by frozen-thawed sperm. Furthermore, we determined the stability of these compounds in aqueous solution. We show here that l-cysteine (l-Cys), d-cysteine (d-Cys), or N-acetyl-l-cysteine (NAC) increased the rate of fertilization when added to the medium but did not adversely affect embryo development in vitro or in vivo. The levels of thiol groups of proteins in the zona pellucida (ZP) and the expansion of the ZP were increased by l-Cys, d-Cys, and NAC. These effects were abrogated by the methylation of the thiol group of l-Cys. NAC was the most stable of these compounds in the fertilization medium at 4°C. These results suggest that the thiol groups of cysteine analogs markedly enhance the fertilization rate of mouse oocytes.

Rescue in vitro fertilization method for legacy stock of frozen mouse sperm.

Sperm cryopreservation has been widely adopted for maintenance of the genetically engineered mouse (GEM). The cryopreserved sperm are being exchanged among many institutes worldwide. However, the recipients are not always able to obtain high fertilization rates with the frozen sperm shipped from senders. In this study, we cryopreserved mouse sperm via various methods and performed in vitro fertilization (IVF) in which the combination of methyl-beta-cyclodextrin for sperm preincubation and reduced glutathione for insemination was used (the MBCD-GSH IVF). In addition, frozen sperm sent from the Jackson Laboratory (USA) were thawed and used for IVF in the same manner. The fertilization rates of both the sperm cryopreserved via the methods applied in some countries and the cryopreserved GEM sperm improved when used with the MBCD-GSH IVF method. Therefore, we strongly believe that the MBCD-GSH IVF method brings about relatively high fertilization rates with any strain of frozen mouse sperm.

Investigations of motility and fertilization potential in thawed cryopreserved mouse sperm from cold-stored epididymides.

Cold transport of epididymides from genetically modified mice is an efficient alternative to the shipment of live animals between research facilities. Mouse sperm from epididymides cold-stored for short periods can maintain viability. We previously reported that cold storage of mouse epididymides in Lifor® perfusion medium prolonged sperm motility and fertilization potential and that the sperm efficiently fertilized oocytes when reduced glutathione was added to the fertilization medium. Cryopreservation usually results in decreased sperm viability; an optimized protocol for cold storage of epididymides plus sperm cryopreservation has yet to be established. Here, we examined the motility and fertilization potential of cryopreserved, thawed (frozen-thawed) sperm from previously cold-stored mouse epididymides. We also examined the protective effect of sphingosine-1-phosphate (S1P) on sperm viability when S1P was added to the preservation medium during cold storage. We assessed viability of frozen-thawed sperm from mouse epididymides that had been cold-transported domestically or internationally and investigated whether embryos fertilized in vitro with these sperm developed normally when implanted in pseudo-pregnant mice. Our results indicate that frozen-thawed sperm from epididymides cold-stored for up to 48 h maintained high fertilization potential. Fertilization potential was reduced after cold storage for 72 h, but not if S1P was included in the cold storage medium. Live pups were born normally to recipients after in vitro fertilization using frozen-thawed sperm from cold-transported epididymides. In summary, we demonstrate an improved protocol for cold-storage of epididymides that can facilitate transport of genetically engineered-mice and preserve sperm viability after cryopreservation.

Applications of cryopreserved unfertilized mouse oocytes for in vitro fertilization.

Since the first successful reports into oocyte freezing, many papers concerning the cryopreservation of mouse oocytes have been published. However, a simple and practical cryopreservation method for unfertilized C57BL/6 mouse oocytes, and an IVF system using these cryopreserved oocytes have yet to be established, in spite of the fact that C57BL/6 is the prevalent inbred strain and is used for large-scale knockout programs. In this study, unfertilized C57BL/6 mouse oocytes were cryopreserved via a simple vitrification method. After warming, IVF was performed using cryopreserved unfertilized oocytes and fresh sperm, cryopreserved unfertilized oocytes and cold-stored sperm, cryopreserved unfertilized oocytes and frozen sperm (C57BL/6 strain sperm), and cryopreserved unfertilized oocytes and frozen sperm derived from GEM strains (C57BL/6 background GEM strains). Nearly all of the cryopreserved oocytes were recovered, of which over 90% were morphologically normal. Those oocytes were then used for in vitro fertilization, resulting in 72-97% of oocytes developing into 2-cell embryos. A portion of the 2-cell embryos were transferred to recipients, resulting in live young being produced from 32-49% of the embryos. In summary, we established the simple and practical method of mouse oocyte vitrification with high survivability and developmental ability and the IVF using the vitrified-warmed oocytes with fresh, cold-stored or cryopreserved sperm with high fertility.

Establishment of a transport system for mouse epididymal sperm at refrigerated temperatures.

The exchange of genetically engineered mouse strains between research facilities requires transporting fresh mouse sperm under refrigerated temperatures. Although sperm generally maintains fertility for 48 h at cold temperatures, in vitro fertilization rates of C57BL/6 mouse sperm are low after 48-h cold storage. Furthermore, 48 h is often not sufficient for the specimens to reach their destinations. To increase the availability of this technology, we aimed to extend the cold storage period while maintaining sperm fertility. In this study, we determined the optimal medium for sperm preservation and evaluated the effect of reduced glutathione in the fertilization medium on sperm fertility after cold storage. We found that higher fertility levels were maintained after 72-h cold storage in the preservation medium Lifor compared with storage in paraffin oil, M2 medium, or CPS-1 medium. In addition, 1.0 mM glutathione enhanced sperm fertility. After transporting sperm from Asahikawa Medical University to our laboratory, embryos were efficiently produced from the cold-stored sperm. After transfer, these embryos developed normally into live pups. Finally, we tested the transport system using genetically engineered mouse strains and obtained similar high fertilization rates with all specimens. In summary, we demonstrated that cold storage of sperm in Lifor maintains fertility, and glutathione supplementation increased the in vitro fertilization rates of sperm after up to 96 h of cold storage. This improved protocol provides a simple alternative to transporting live animals or cryopreserved samples for the exchange of genetically engineered mouse strains among research facilities.

Short-term storage and transport at cold temperatures of 2-cell mouse embryos produced by cryopreserved sperm.

At refrigerated temperatures, mouse embryos can maintain developmental ability for short periods. Previously, we succeeded in transporting vitrified and warmed 2-cell mouse embryos while maintaining developmental ability at refrigerated temperatures for 50 h. Transport of nonfrozen embryos is an easier and more useful means of exchanging genetically engineered mice between laboratories than is transport of cryopreserved embryos. Here we examined the developmental ability of transported 2-cell embryos that were produced through in vitro fertilization using cryopreserved sperm. Results show that 2-cell embryos produced by cryopreserved sperm can develop into blastocysts after cold storage for 24, 48, and 72 h. Transported 2-cell embryos produced by cryopreserved sperm yielded a favorable number of pups in all of the receiving laboratories after transport lasting 48 to 52 h. In summary, cold storage and transport of 2-cell embryos derived from cryopreserved sperm at refrigerated temperatures provides a novel means of transporting genetically engineered mice as an alternative to the transport of cryopreserved embryos and sperm.

Fertilization of C57BL/6 mouse sperm collected from cauda epididymides after preservation or transportation at 4 degrees C using laser-microdissected oocytes.

The C57BL/6 mouse is commonly used to produce transgenic and knockout strains for biomedical research. However, the motility and fertility of its sperm decrease markedly with freezing. Short-term preservation of sperm without freezing can avoid this. Furthermore, such samples can be transported safety without the special skills or equipment needed for the transportation of live animals or frozen products. We evaluated the motility and fertility of sperm collected from cauda epididymides after preservation or transportation at 4 degrees C. Oocytes with the zona pellucida subjected to laser-microdissection were used to assist fertilization in vitro. Although the motility of sperm gradually decreased with storage (P<0.05), no disruption of the sperm plasma membrane was seen. The proportion of zona-intact oocytes fertilized with sperm preserved for 0, 24, 48 and 72h were 70, 14, 5 and 1%, respectively. On the other hand, 45, 20 and 14% of laser-microdissected oocytes were fertilized by sperm preserved for 24, 48 and 72h, respectively (P<0.05). The fertility of sperm collected from cauda epididymides of two transgenic strains after transportation at 4 degrees C were also significantly increased using laser-microdissected oocytes rather than zona-intact oocytes (57 and 68% vs. 5%, P<0.05). Efficient production of offspring from sperm preserved or transported at 4 degrees C was achieved using laser-microdissected oocytes. Thus the fertility of sperm preserved or transported at 4 degrees C could be maintained, although motility gradually decreased with storage. Laser-microdissected oocytes will contribute to the efficient production of embryos and offspring using such preserved sperm samples.

Birth of mice from vitrified/warmed 2-cell embryos transported at a cold temperature.

Cryopreservation of 2-cell embryos is an effective technology for storage of genetically engineered mouse strains. Transport of genetically engineered mice between laboratories has frequently been performed using such cryopreserved 2-cell embryos. However, the receiving laboratory requires proficient skills and special instruments to obtain live young from cryopreserved and transported embryos. Therefore, in this study, we tried to address the storage and transport of vitrified/warmed 2-cell embryos at a cold temperature. In cold storage experiments, the development rates of 2-cell embryos stored in M2 medium for 24, 48 and 72 h into blastocysts were relatively high (83%, 63% and 43%, respectively). Although, 2-cell embryos stored in PB1 and mWM maintained the developmental potency for 24h, the rates were markedly decreased to low levels after 48 h (PB1: 0%; mWM: 5%). In transport experiments, many pups were obtained from vitrified/warmed 2-cell embryos transported at a cold temperature in all receiving laboratories (incidence of successful development: 49%; 249/511). In summary, short-term storage and transport of vitrified/warmed 2-cell embryos in M2 medium at a cold temperature can maintain their ability to develop into live young.