Proacrosin-deficient mice and zona pellucida modifications in an experimental model of multifactorial infertility.

In humans, male and female partners contribute more or less equally to the infertility problem. In approximately 20% of infertile couples, the concurrence of male and female factors is suggested to be responsible for infertility. Neither of these factors are known nor is there a model system to prove this assumption. We present such a model system in the mouse, in which the lack of acrosin in the male and modifications of the zona pellucida (ZP) in the female result in a significant reduction of the fertilization rate in vitro. We generated mice carrying a deletion in the proline-rich region (PRR) of the proacrosin gene, resulting in the absence of proacrosin in the homozygous PRR(-/-) male mouse. Under normal conditions, sperm from the proacrosin-deficient mice are still capable of ZP penetration and fertilization. In this study, modifications of the ZP of oocytes after superovulation were achieved by treatment with dimethylsulphoxide or aroclor-1254 or by in-vitro ageing. It is known that under these conditions, a time-dependent hardening of the ZP occurs. The rates of fertilization in vitro of treated and aged oocytes using sperm from PRR(-/-) mice were found to be significantly reduced when compared with those reached with wild-type sperm. The relevance of the acrosin status and ZP condition for fertilization success were further substantiated by the finding that the fertilization rate with PRR(-/-) sperm is affected by the thickness of the ZP. Our results demonstrate that the lack of acrosin in sperm in combination with modifications to the ZP can affect fertility and can be an experimental model for the study of unexplained infertility in human couples in which both male- and female-derived factors are suggested to be the underlying causes.

Difference of acrosomal serine protease system between mouse and other rodent sperm.

A fraction of acrosomal proteins dispersed during calcium ionophore A23187-induced acrosome reaction was prepared from cauda epididymal sperm of wild-type and acrosin-deficient mice, rat, and hamster. The acrosome-reacted sperm were further extracted by Nonidet P-40 to obtain the detergent-soluble protein fraction. Activities of serine proteases in the two protein fractions were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of gelatin. A mixture of 42- and 41-kDa gelatin-hydrolyzing proteases was found in both fractions of the wild-type mouse sperm, whereas the acrosin-deficient mouse sperm contained the active 42-kDa protease and apparently lacked the activity of the 41-kDa protease. However, exogenous bovine pancreatic trypsin compensated for the absence of acrosin in the protein fractions of the mutant mouse sperm; the gelatin-hydrolyzing activity of the 41-kDa protease appeared when the sperm proteins of the mutant mice were treated with pancreatic trypsin. Two-dimensional polyacrylamide gel electrophoresis revealed that the 42- and 41-kDa proteases were distinguished from acrosin by the isoelectric point and immunoreactivity with affinity-purified antibody against an oligopeptide corresponding to the N-terminal amino acid sequence of mouse proacrosin. Moreover, the gelatin-hydrolyzing proteins corresponding to these two proteases were not detected in rat and hamster sperm, in spite of the treatment of the sperm extracts with pancreatic trypsin, and the total amount of gelatin-hydrolyzing activities in mouse was much smaller than those in rat and hamster. These results may reflect the difference of the serine protease system for the sperm penetration through the egg zona pellucida between mouse and other rodent animals, possibly explaining why the acrosin-deficient mouse sperm are capable of penetrating the zona pellucida.

Spermatozoa lacking acrosin protein show delayed fertilization.

Acrosin (ACR), a serine proteinase located in the acrosome of the sperm, has been presumed to be involved in the recognition and binding of the sperm to the zona pellucida of the ovum and the sperm penetration through the zona pellucida. To examine the function of acrosin in vivo, we have generated mice carrying a mutation at the acrosin locus (Acr) through targeted disruption in embryonic stem (ES) cells. One chimeric male and female transmitted the targeted gene through their germ line. Homozygous Acr-/- mice are fertile and yield litters comparable in number and size to those of Acr+/+ mice. These data show that sperm of the homozygous Acr-/- mice are able to penetrate the zona pellucida, fertilize the ovum, and produce viable offspring. However, spermatozoa lacking acrosin protein show a delayed fertilization. One chimeric male which contained the targeted gene in 20% of its sperm transmitted only the Acr+ allele to its progeny. Furthermore, in vitro fertilization with equally mixed sperm cells of Acr+/+ and Acr-/- mice resulted in fertilization only with the Acr+ sperm cells. Incubation of oocytes with Acr+ or Acr- sperm show that the Acr+ sperm are faster to fertilize the oocytes than the Acr- sperm cells. These results suggest that Acr- sperm have a selective disadvantage when they are in competition with Acr+ sperm.