Sperm aging in the male and cytogenetic anomalies. An animal model

Summary Superovulated females, outbred ICR Swiss, were inseminated naturally with spermatozoa aged 6–20 days in the male genital tract by bilateral ligation of the corpus epididymis. Females inseminated by the males (also ICR Swiss) mating at 3-day intervals prior to ligation and those mated to sham-operated males served as controls. A total of 1167 fertilized one-cell zygotes of which 868 were at metaphase first cleavage were recovered 33–35 h post-HCG. First-cleavage divisions were analyzed in 631, or 72%, of all zygotes at metaphase and late prophase. The gametic origin of chromosome anomalies was determined on the basis of differential condensation of the chromosomes. The sex ratio of the zygotes was unaffected by aging sperm. In 321 zygotes from the controls the frequency of trisomy was 3.1%, monosomy 2.2%, triploidy 0.93%, and structural rearrangements 0.31%. Aging of sperm for 6 days did not significantly alter the number of heteroploid zygotes recovered. For the periods beyond day 6 and in the combined experimental series there was a highly significant increase in the number of all chromosome anomalies compared with controls. In the experimental zygotes, the incidence of trisomy was 9.7%, monosomy 7.4%, triploidy 3.9%, and structural anomalies 2.6%. There were also significant differences between control and experimental in the origin of the anomalies. The male genome was implicated significantly more often than the female in the origin of trisomies in the experimental series compared with the controls. It was also the direct source of all the structural anomalies and the majority of the triploids in the experimentals, where 8 of 9 were a result of diploid sperm. Therefore, the over-riding mechanism involved in the production of chromosomally anomalous offspring from aging sperm seems to be altered conditions of competition between chromosomally balanced and unbalanced sperm. Additionally, chromosomally normal sperm in an aging population may be affected in some aspects of their physiology so that they create preferential loss of maternally derived chromosomes leading to monosomy or nuclear fragmentation. The implications of these findings for the etiology of human chromosome anomalies are discussed.