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     

Large numbers of mice established by in vitro fertilization with cryopreserved spermatozoa: implications and applications for genetic resource banks, mutagenesis screens, and mouse backcrosses

Recent advances in the methodologies for cryopreservation of mouse spermatozoa have opened up a number of opportunities for mouse geneticists. We have investigated various applications for this relatively new technology and have explored the potential of sperm freezing coupled with IVF for archiving, stock building, and the rapid establishment of backcrosses. Firstly, we investigated the use of sperm freezing for the archiving of (C3H/HeH × BALB/c)F₁ progeny from a large-scale mutagenesis program. We have demonstrated that it is possible to establish efficient, comprehensive, and deep archives and that potentially thousands of offspring can be derived from the frozen spermatozoa of a single mutant male mouse. Secondly, we examined the efficacy of sperm freezing for a number of other genotypes. For at least some genotypes, frozen spermatozoa can be utilized to rapidly build stock far more quickly than by conventional methods. Finally, we demonstrated that it is feasible to use frozen spermatozoa from the mouse mutant archive for the rapid generation of mutant backcross progeny. Received: 8 February 1999 / Accepted: 5 May 1999     

Cryoconservation—archiving for the future

Mouse genetics is set to play a pivotal role in the key post-genome challenge—the study of mammalian gene function. Addressing this challenge will involve the development and application of systematic mutagenesis approaches. The expanding mouse mutant resource that will result threatens to overwhelm the currently available animal facility space. Cryopreservation of both mouse embryos and spermatozoa is currently widely employed for the efficient archiving of mouse stocks. Distribution and dissemination of new and existing mouse strains is simplified by the availability of extensive frozen archives. Also, the availability of archives of frozen spermatozoa provides a potential powerful route for the production of backcross progeny for rapid genetic mapping. Moreover, frozen oocytes and ovaries may offer a valuable addition to the current cryopreservation approaches. Comprehensive mouse mutant archives will provide an essential resource for mammalian genetics throughout the 21^st century. Received: 16 December 1999 / Accepted: 17 December 1999     

Birth of mice after in vitro fertilization using C57BL/6 sperm transported within epididymides at refrigerated temperatures

The transportation of cryopreserved spermatozoa is an economical, efficient, and safe method for the distribution of mouse strains from one facility to another. However, spermatozoa from some strains, including C57BL/6 (B6), are very sensitive to freezing and thawing and frequently fail to fertilize eggs by conventional in vitro fertilization methods at the recipient mouse facility. Since many genetically engineered mice have the B6 genetic background, this sensitivity poses a major obstacle to studies of mouse genetics. We investigated the feasibility of transporting spermatozoa within epididymides under non-freezing conditions. First, we examined the interval that B6 and B6D2F1 (BDF1) spermatozoa retained their ability to fertilize when stored within epididymides at low temperatures (5 degrees C or 7 degrees C). Fertilization rates were >50%, irrespective of the spermatozoa used, when epididymides were stored for 3d at 7 degrees C. B6 spermatozoa, but not BDF1 sperm, had better retention of fertilizing ability at 7 degrees C versus 5 degrees C. We then transported freshly collected B6 and BDF1 epididymides from a sender colony to a recipient colony using a common package delivery service, during which the temperature was maintained at 5 degrees C or 7 degrees C for 2d. Sufficiently high fertilization rates (68.0-77.5%) were obtained for all experimental groups, except for B6 spermatozoa transported at 5 degrees C. These spermatozoa were successfully cryopreserved at the recipient facility and, yielded post-thaw fertilization rates of 27.6-66.4%. When embryos derived from the B6 spermatozoa that were transported at 7 degrees C were transferred into recipient females, 52.7% (38/72) developed to term. In conclusion, transportation of epididymides at refrigerated temperatures is a practical method for the exchange of mouse genetic resources between facilities, especially when these facilities do not specialize in sperm cryopreservation. For the B6 mouse strain, the transportation of epididymides at 7 degrees C rather than 5 degrees C, is recommended.     

Preservation of ejaculated mouse spermatozoa from fertile C57BL/6 and infertile Hook1/Hook1 mice collected from the uteri of mated females

Methods routinely used to preserve mouse spermatozoa require that the male be killed to recover spermatozoa from the epididymides. Here we obtained multiple samples of ejaculated spermatozoa from normal fertile C57BL/6 and infertile Hook1/Hook1 (formerly known as azh/azh) mutant males from uteri after mating, thus avoiding termination of the males. Ejaculated sperm were preserved by conventional cryopreservation or by rapid freezing without cryoprotection, and were injected into the oocytes by intracytoplasmic sperm injection (ICSI). The proportions of oocytes that survived, became activated, and developed into two-cell embryos were similar when comparing the two preservation methods in wild-type versus Hook1/Hook1 mice and tested mice versus controls (fresh and rapid-frozen epididymal and fresh ejaculated sperm). Two-cell embryos were transferred into the oviducts of pseudopregnant females, and fetal development was examined at Day 15 of gestation. A total of 39%-54% of transferred embryos produced with preserved ejaculated sperm implanted. Live, normal fetuses (11%-17%) were obtained in all examined groups and from all males included in the study. More implants (71%-82%) and fetuses (28%-31%) were noted in controls. Lower developmental potentials of embryos produced with preserved ejaculated sperm might be due to their capacitation status; the majority of sperm retrieved from the uterus were capacitated. This study bears significance for the maintenance and distribution of novel mouse strains. The method is applicable for all types of mice, including those with male infertility syndromes. The sole requirement is that the male of interest is able to copulate and its ejaculate contains spermatozoa.     

Fertilization in vitro with spermatozoa from different mice increased variation in the developmental potential of embryos compared to artificial parthenogenetic activation

Although successful embryo development is dependent upon genetic and epigenetic contributions from both the male and female, the male potential to adversely affect embryo development has been scarcely studied. It is unclear whether the sperm variation among different males would affect the outcome of oocyte evaluation by embryo development following fertilization. In the present study, variation in the developmental potential of mouse embryos was first compared between in vitro fertilization with epididymal spermatozoa from different males and Sr(2+) parthenogenetic activation using oocytes of different qualities, and then the effect of male on fertilization and embryo development was examined using randomly chosen oocytes and spermatozoa from cauda epididymidis, vas deferens or electro-ejaculates. Rates of fertilization and blastocyst formation were significantly higher with spermatozoa from cauda epididymidis or vas deferens than with ejaculated spermatozoa. Rates of embryonic development differed significantly between different males, but not between different ejaculates of the same male. Analysis of standard errors of means and coefficients of variance indicated that as long as multiple males were involved, the variation in oocyte fertilization/activation and blastocyst formation was always higher after fertilization than after Sr(2+) parthenogenetic activation whether spermatozoa were collected from epididymidis, vas deferens or ejaculates and regardless of oocyte qualities. It is concluded that (1) epididymal mouse spermatozoa fertilize more oocytes than ejaculated spermatozoa under identical experimental conditions; (2) like farm animals, the mice also show a remarkable male effect on the developmental potential of in vitro produced embryos although they are supposed to be less genetically diverse; (3) parthenogenetic activation is recommended for assessment of oocyte quality to exclude the effect of male.     

Genetic and reproductive potential of spermatozoa of diploid and triploid males obtained from interspecific hybridization of Misgurnus anguillicaudatus female with M. mizolepis male

Diploid and triploid interspecific hybrid male progeny obtained from mating Misgurnus anguillicaudatus with M. mizoleis were reported to have histologically fertile and sterile testes, respectively. However, their reproductive capacity is still unclear because mating tests have not been examined using mature hybrids. Here, we examined physiological and genetic characteristics of spermatozoa of diploid and triploid hybrids. In diploid hybrid males, 1n, 2n and 4n spermatozoa showing low motility were detected. However, spermatozoa of three diploid hybrid males could generate 2n larvae. Therefore, only 1n spermatozoa of diploid hybrid males was fertile to produce larva. The chromosomes of diploid hybrid males were transmitted to spermatozoa by random segregation between the homologous chromosomes because most larvae had one allele derived from both M. anguillicaudatus and M. mizolepis at all loci examined. In triploid hybrid males, spermatozoa could be categorized to three different types based on their ploidy status. Type 1: In the first and second males, sperm samples mainly comprised 6n spermatozoa. Motility and fertility were not recorded. Type 2: The third male gave a large proportion of 6n spermatozoa as well as a small proportion of 1n spermatozoa. Although no motility was observed, larvae arose from eggs inseminated with such spermatozoa. Type 3: In the fourth male, only 1n spermatozoa were detected and their motility was vigorous. When eggs were fertilized with such 1n spermatozoa, normal larvae hatched. 1n spermatozoa of the triploid hybrid male only included the M. anguillicaudatus genome. In Misgurnus fishes, diploid hybrid males exhibited semi-sterility or slight fertility. On the contrary, triploid hybrid males were sometime fertile due to the production of 1n spermatozoa by a kind of transformation of meiosis like meiotic hybridogenesis.     

Inactivation of the mouse adenylyl cyclase 3 gene disrupts male fertility and spermatozoon function

Mammalian spermatids and spermatozoa express functional G protein-coupled receptors. However, bicarbonate-regulated soluble adenylyl cyclase (AC), the major AC present in these cells, is not directly coupled to G proteins. To understand how G protein-coupled receptors signal in spermatozoa, we investigated whether a conventional transmembrane cyclase is present and biologically active in these cells. Here, we provide evidence for expression of type 3 AC (AC3) in male germ cells and describe the effects of disruption of the AC3 gene on fertility and function of mouse spermatozoa. As previously reported in rat, AC3 mRNA is expressed in mouse testes and localized, together with soluble AC mRNA, mainly in postmeiotic germ cells. AC3 protein was detected by immunolocalization in round and elongating spermatids in a region corresponding to the developing acrosome and was retained in the mature spermatozoa of the epididymis. Forskolin caused a small increase in cAMP production in mouse spermatozoa, but this increase could not be detected in the AC3(-/-) mice. Inactivation of the AC3 gene did not have overt effects on spermatogenesis; however, AC3(-/-) males were subfertile with only three litters generated by 11 males over a period of 6 months. When used in in vitro fertilization, spermatozoa from these AC3(-/-) mice produced few embryos, but their fertilizing ability was restored after removal of the zona pellucida. Despite an apparently normal structure, these spermatozoa had decreased motility and showed an increase in spontaneous acrosome reactions. These data support the hypothesis that AC3 is required for normal spermatid or spermatozoa function and male fertility.     

Live mice from cryopreserved embryos derived in vitro with cryopreserved ejaculated spermatozoa

This study was undertaken to try to reduce the number of animals required to maintain mouse strains by banking of embryos or spermatozoa. The principal objective was to cryopreserve ejaculated mouse spermatozoa, using a method recently developed for epididymal spermatozoa. Within 30 min after mating, ejaculated spermatozoa were flushed from the uterus of mated females; shortly afterwards, epididymal spermatozoa were also collected from the same males that had mated with the females. The average values for spermatozoal motility and viability of ejaculated specimens of nine males were 43 and 46%, respectively, and for epididymal specimens, the corresponding values were 60 and 52%. In experiment 1, ejaculated or epididymal spermatozoa were incubated with oocytes for 0.5 to 4 h. As evidenced by development into two-cell embryos within 24 h, kinetics of fertilization of the two spermatozoa types were similar. In experiment 2, ejaculated and epididymal spermatozoa of three males were separately cryopreserved in medium containing raffinose, glycerol, and egg yolk. Samples were cooled and seeded at -4 degrees C, cooled to -70 degrees C at 20 degrees C/min, and then were placed into liquid nitrogen for storage. When cryopreserved epididymal or ejaculated spermatozoa were thawed at > 1,000 degrees C/min and used for in vitro fertilization, > 60% of oocytes cleaved, and approximately 95% of cleaved embryos developed into morulae or blastocysts. When embryos produced with cryopreserved spermatozoa were transferred into recipients, 18 and 22 live pups were obtained from 62 and 54 embryos resulting from ejaculated or epididymal spermatozoa, respectively. This study documented the feasibility of cryopreserving ejaculated spermatozoa as an effective alternative to preserving germ plasm from genetically valuable mice.     

Effects of breeding season and mating on total number and distribution of spermatozoa in the epididymis of the brown marsupial mouse, Antechinus stuartii

Changes in the number and distribution of spermatozoa in the epididymis of the adult brown marsupial mouse were examined during July/August in mated and unmated males. The effects of mating on epididymal sperm populations were studied in 2 groups of males each mated 3 times and compared with the number and distribution of spermatozoa in the epididymides of 4 unmated control groups. One testis and epididymis were removed from each animal (hemicastration) either before or early in the mating season to provide information on initial sperm content and distribution. The contralateral side was removed later in the mating season to examine the effects of mating or sexual abstinence on epididymal sperm distribution. Epididymal sperm number peaked in both the distal caput and distal corpus/proximal cauda epididymidis in late July. The total number of spermatozoa, including those remaining in the testis, available to each male at the beginning of the mating season in early August was approximately 4.4 x 10(6)/side. Although recruitment of spermatozoa into the epididymis from the testis continued until mid-August, sperm content of the epididymis reached a peak of about 3.5 x 10(6)/epididymis in early August. At this time approximately 0.9 x 10(6) spermatozoa remained in the testis which had ceased spermatogenic activity. Throughout the mating season, epididymal spermatozoa were concentrated in the distal corpus/proximal cauda regions of the epididymis and were replenished by spermatozoa from upper regions of the duct. Relatively few spermatozoa were found in the distal cauda epididymidis, confirming a low sperm storage capacity in this region. A constant loss of spermatozoa from the epididymis, probably via spermatorrhoea, occurred throughout the mating season and very few spermatozoa remained in unmated males in late August before the annual male die-off. Mating studies showed that an average of 0.23 x 10(6) spermatozoa/epididymis were delivered per mating in this species, but the number of spermatozoa released at each ejaculation may be as few as 0.04 x 10(6)/epididymis when sperm loss via spermatorrhoea is taken into account. We suggest that the unusual structure of the cauda epididymidis, which has a very restricted sperm storage capacity, may function to limit the numbers of spermatozoa available at each ejaculation and thus conserve the dwindling epididymal sperm reserves in order to maximize the number of successful matings which are possible during the mating season.     

Polymorphism in hybrid male sterility in wild-derived Mus musculus musculus strains on proximal chromosome 17

The hybrid sterility-1 (Hst1) locus at Chr 17 causes male sterility in crosses between the house mouse subspecies Mus musculus domesticus (Mmd) and M. m. musculus (Mmm). This locus has been defined by its polymorphic variants in two laboratory strains (Mmd genome) when mated to PWD/Ph mice (Mmm genome): C57BL/10 (carrying the sterile allele) and C3H (fertile allele). The occurrence of sterile and/or fertile (wild Mmm × C57BL)F₁ males is evidence that polymorphism for this trait also exists in natural populations of Mmm; however, the nature of this polymorphism remains unclear. Therefore, we derived two wild-origin Mmm strains, STUS and STUF, that produce sterile and fertile males, respectively, in crosses with C57BL mice. To determine the genetic basis underlying male fertility, the (STUS × STUF)F₁ females were mated to C57BL/10 J males. About one-third of resulting hybrid males (33.8%) had a significantly smaller epididymis and testes than parental animals and lacked spermatozoa due to meiotic arrest. A further one-fifth of males (20.3%) also had anomalous reproductive traits but produced some spermatozoa. The remaining fertile males (45.9%) displayed no deviation from values found in parental individuals. QTL analysis of the progeny revealed strong associations of male fitness components with the proximal end of Chr 17, and a significant effect of the central section of Chr X on testes mass. The data suggest that genetic incompatibilities associated with male sterility have evolved independently at the proximal end of Chr 17 and are polymorphic within both Mmd and Mmm genomes.     

Phenotypic analysis of C57BL/6J and FVB/NJ mice generated using evaporatively dried spermatozoa

Combination of evaporative drying and frozen storage at -80 degrees C has been used successfully to preserve hybrid B6D2F1 mouse spermatozoa. To determine whether this method can be applied equally well to inbred mice, spermatozoa of C57BL/6J and FVB/ NJ mice were evaporatively dried and stored for 1 mo at -80 degrees C before being used for intracytoplasmic sperm injection (ICSI) to produce live offspring. After weaning, 1 male and 1 female mouse from each litter were randomly selected at 8 wk of age for natural mating to produce live offspring. Results showed that spermatozoa from both inbred strains that had been evaporatively dried and subsequently stored at -80 degrees C could be used successfully to derive live, healthy, and reproductively sound offspring by ICSI. No significant differences were found in embryo transfer rate (number of pups born/number of embryos transferred), litter size, weaning rate, body weight, number of pathologic lesions, and amount of contamination by pathogens of mice produced by ICSI using evaporatively dried spermatozoa compared with mice produced by natural mating or by ICSI using fresh (that is, nonpreserved) spermatozoa. Progeny produced by mating mice generated from ICSI using evaporatively dried spermatozoa were normal. Therefore, spermatozoa from inbred mouse strains C57BL/6J and FVB/NJ can be preserved successfully after evaporative drying and frozen storage at -80 degrees C.     

Horn quality and postmortem sperm parameters in Spanish ibex (Capra pyrenaica hispanica)

The horns are secondary sexual characteristics used by males of many ungulate species for intra-sexual fights during the rut. Thus, the dominant males with most developed horns are naturally selected for reproduction. Several studies have suggested that the quality of the horn, in many wild ruminants, may be correlated with semen quality. The aim of the present study was to determine whether inter-individual differences in levels of horn asymmetry and horn size are related to differences in sperm quality in a wild population of Spanish ibex by the assay of epididymal spermatozoa collected postmortem. In order to test this hypothesis we collected morphometric horns data from a total of 59 mature males (9-15 years of age) that were legally hunted during rutting season. The testicles were recovered, and the collection of epididymal spermatozoa was done at different times after death (2-60 h). The percentage of motile spermatozoa, motility rate, plasma membrane integrity, sperm viability, sperm morphology, and acrosome integrity were evaluated. Our findings showed that viable epididymal spermatozoa may be retrieved from dead animals many hours after death. However, sperm parameters were affected by the elapsed time between the death of the animal and spermatozoa collection. The study revealed that the horn quality was firstly associated with sperm motility.     

Female mice of DDK strain are fully fertile in the intersubspecific crosses with Mus musculus molossinus and M. m. castaneus

The female mice of DDK strain are almost infertile when mated with males from other strains. This phenomenon is caused by the early death of F1 embryos owing to the incompatibility system attributed to the ovum mutant (Om) locus on Chromosome (Chr) 11 and known as DDK syndrome. In the present study, DDK females were found to be fully fertile in the intersubspecific matings with the males of two wild mouse-derived strains, MOM (originated from Japanese wild mice, Mus musculus molossinus) and Cas (originated from Philippine wild mice, M. m. castaneus), indicating that no incompatibility exists between DDK oocytes and spermatozoa of MOM and Cas strains. Furthermore, this compatibility has been confirmed by the following two findings: (1) Normal fertility was shown by the two types of backcrosses, DDK females x F(1) (DDK female x MOM male) males and DDK females x F(1) (DDK female x Cas male) males; and (2) the offspring from these backcrosses segregated equally into the homozygotes and heterozygotes as genotyped by the microsatellite markers closely linked to Om locus. MOM and Cas strains would be useful for further investigations on the Om locus. On the other hand, the litter size of F(1) [C57BL/6Cr (B6) female x Cas male] females mated with B6 males was about half that of the mating with DDK males. It would be interesting to investigate whether this reduction in fertility is related to the Om locus or not.     

Chromosome analysis by spectral karyotyping of spermatozoa from an oligoasthenozoospermic carrier of a 10; 21 reciprocal translocation

Cytogenetic analysis of germ-line cells prior to intracytoplasmic sperm injection (ICSI) treatment is thought to be necessary for infertile males with an identified chromosomal abnormality. We analyzed the chromosomal karyotype of human spermatozoa from an oligoasthenozoospermic carrier of a reciprocal translocation t(10; 21). Cytogenetic analysis of 39 spermatozoa was performed by spectral karyotyping (SKY) and by ICSI into mouse oocytes. The motile morphologically normal spermatozoa were injected into mouse oocytes. Of these spermatozoa, 38 (97.4%) were activated. Twenty-one (53.8%) of the activated oocytes formed two pronuclei. Metaphase chromosome spreads from 13 spermatozoa were analyzed. Only one spermatozoon was normal and 2 spermatozoa exhibited balanced translocation. Nine and one spermatozoa showed abnormalities related and unrelated to the translocation, respectively. The numbers of normal/balanced spermatozoa were lower than those in previous reports analyzing reciprocal translocations using a previously described technique involving penetrated golden hamster oocytes. After genetic counseling with the carrier and his partner, ICSI treatment was performed. Healthy female and male infants were delivered at 37 weeks gestation via a Caesarean section. The female infant was a carrier of the reciprocal translocation and the male infant was confirmed normal on prenatal diagnosis at 16 weeks gestation. For genetic counseling prior to ICSI treatment, the incidence of unbalanced type spermatozoa after swim-up or Percoll gradient treatment should be investigated and discussed with couples having fertility problems related to oligozoospermia autosomal structural abnormalities.     

Efficacious Production of Viable Germ-Line Chimeras between Embryonic Stem (ES) Cells and 8-Cell Stage Embryos

Many embryonic stem (ES) cell lines have been isolated from various mouse strains, but production of germ-line chimeras has been achieved with only strain 129. This report describes the isolation of a new ES cell line, F1/1, from a mouse blastocyst with the C57BL/6 X CBA male genotype and tests on its ability to produce germ-line chimeras by two techniques, blastocyst injection and 8-cell embryo injection. Chimera production using CD-1 blastocysts as a host was low (20%), as reported by others. But by the 8-cell embryo injection method, in which F1/1 cells were injected into the perivitelline space through a slit in the zona pellucida of 8-cell embryos, chimeric mice with extremely high chimerism were obtained at a rate of 80%. Breeding tests showed that 89% of the fertile males were germ-line chimeras and in most case, the majority of the sperms in their testes were derived from F1/1 cells. This F1/1 cell line with a different genotype from the 129 strain shows high ability to produce functional germ cells, moreover, the 8-cell embryo injection method using F1/1 cells seems to be an efficient way to produce viable germ-line chimeras.     

An increased level of sperm abnormalities in mice with a partial deletion of the Y chromosome

Two congenic lines of mice, one with a partial deletion of the Y chromosome, differ in the percentage of spermatozoa with abnormal heads: B10.BR/SgSn males give 22.6% and B10.BR-Ydel/Ms males give 64.2% abnormal sperm. The F1s resulting from crosses of B10.BR/SgSn males with females of five common inbred strains exhibited significantly lower levels of abnormal sperm than the parental strains, as opposed to F1 hybrids sired by B10.BR-Ydel/Ms mutant males, where very high levels of abnormal spermatozoa were found. About 30% of abnormal spermatozoa, produced by males with deletion on the Y chromosome, were characterized by a flat acrosomal cap. This class of abnormality was never observed in non-mutant males, suggesting a mutant-specific defect. These results demonstrate the important role of the Y chromosome in spermatogenesis.     

Scrotal heat stress effects on sperm viability, sperm DNA integrity, and the offspring sex ratio in mice

Evidence exists to suggest detrimental effects of heat stress on male fertility. This study was designed to assess the effects of scrotal heat stress on mature and developing sperm in a mouse model. After receiving shock heat treatment (42 degrees C for 30 min), mature spermatozoa were recovered from the epididymis hours (6) or Days (7, 14, 21, 28, 60) later, to determine the variables: number of spermatozoa, sperm viability, motility and progressive motility, sperm DNA integrity as established by the TUNEL method, embryo implantation rate, and sex ratio of the fetuses conceived using the heat-exposed spermatozoa. Our results indicate that transient mild heat treatment does not affect in the same way the different types of male germ cells. Spermatocytes present within the testis at the time of heat stress resulted into a lower concentration of spermatozoa with reduced viability and low motility. Even though, DNA integrity of spermatozoa resulting from spermatocytes was also compromised by heat stress, the higher degree of DNA damage was found among spermatozoa resulting from spermatids present within the testis at the time of heat stress. At last, heat shock effect on spermatozoa present in the epididymis at the time of thermal stress resulted into a sex ratio distortion. These findings point to a higher sensitivity of spermatocytes to heat exposure and also suggest a different response of X and Y chromosome-bearing spermatozoa to heat stress that warrants further investigation.     

H-Y antigen: No evidence for alleles in wild strains of mice

H-Y antigen(s) coded or controlled by the Y chromosome in a variety of wild mouse strains have been compared with those of the inbred laboratory strains C57BL/6 (B6) and C57BL/10 (B10). H-Y antigen(s) were detected by H-2-restricted cytotoxic T cells from B6 and B10 female mice primed in vivo and boosted in vitro with syngeneic male spleen cells: There was no difference in the degree of H-Y specific lysis of male cells from the C57BL strains and of F₁ hybrids or B6 congenic mice carrying the Y chromosome from the wild mouse strains examined. This result indicated that at the level of target cell specificity the H-Y antigen(s) from wild and laboratory strains were indistinguishable. H-Y antigen(s) were also found to be indistinguishable at the level of the in vitro induction of the anti H-Y cytotoxic response: F₁ female mice, primed in vivo and boosted in vitro with homologous F₁ male cells, all made H-Y-specific responses and where it could be examined, the target cell specificity of the anti-H-Y cytotoxic cells showed that B10 male cells as well as the homologous F₁ male cells (where the Y chromosome was derived from the wild strain) were good targets. Finally, possible differences in H-Y transplantation antigens between the wild strains and the B10 laboratory strain were examined by grafting F₁ male mice, the progeny of B10 females, and wild strain males with B10 male skin. These grafts were not rejected during an observation period of more than 9 months. Taken together, neither the cytotoxic data nor the skin graft data provide any evidence for allelism of H-Y even though the mouse strains examined were collected from widely disparate geographical locations.     

Male-to-male differences in post-thaw motility of rhesus spermatozoa after cryopreservation of replicate ejaculates

BACKGROUND: The efficiency of controlled propagation to produce rhesus monkeys of particular genotypes can be maximized by use of cryopreserved spermatozoa collected from specific males to inseminate appropriate females. But this assumes that semen from males with different genotypes can be cryopreserved with equal effectiveness. METHODS: To investigate whether spermatozoa from different Macaca mulatta males can be effectively cryopreserved when frozen under identical conditions, we collected and froze semen specimens from 13 adult, fertile males maintained at three primate research centers. RESULTS: Survival, based on post-thaw motility normalized to the pre-freeze value, was assayed within 30 minutes after thawing; it varied from 50% to 70% but declined thereafter. To examine the response of semen from individual males, we collected and froze three to six ejaculates per male from each of seven males. CONCLUSIONS: In general, semen from a given male responded reproducibly to freezing, but there were significant differences among males. The cause of these differences among M. mulatta males in post-thaw sperm survival remains unidentified.