Increase, Mutations leads to Increase, Heritable mutations in offspring

If a mutation arises in spermatogonial stem cells and does not influence cellular function, the mutation can become fixed and/or propagated within the stem cell population. Mutations that do not affect sperm maturation will persist through the succeeding stages of spermatogenesis and will be found in the mature sperm of the organism throughout its reproductive lifespan. Mutations can also occur in differentiating spermatogonia; however, once the sperm generated by these dividing spermatogonia are ejaculated there will be no ‘record’ of the induced mutation. Mutations that impair spermatogenesis or the viability of the cell will be lost via apoptosis and cell death, potentially contributing to decreased fertility. Mutations that do not impact sperm motility, morphology or ability to penetrate the zona pellucida (or other important sperm parameters), and that are present in mature sperm, may be transmitted to the egg resulting in the development of an offspring with a mutation. Thus, increased incidence of mutations in germ cells leads to increased incidence of mutations in the offspring. There is a great deal of evidence demonstrating that exposure to a variety of DNA alkylating agents induces mutations in male spermatogenic cells.

Mutations conferring a selective disadvantage to sperm or to the embryo will not be measured in live born offspring and will be eliminated. Thus, mutation frequency in sperm should be equal to mutation rate derived by measuring mutations in the offspring for non-selective loci (as is seen in the rodent tandem repeat and transgene mutation examples described above); or, sperm mutation frequency should be greater than mutation rate measured by identifying mutations in the offspring. However, quantitative data to demonstrate this are lacking because of current technical limitations to study this. It is anticipated that improved models will be developed to predict the likely outcome of increased rates of heritable mutation from sperm mutation frequency data when more data are available from studies applying next generation sequencing technologies in sperm and pedigrees.

Mutation is the underlying source of evolution and occurs in every species. Theoretically, any sexually reproducing organism (i.e., producing gametes) can acquire mutations in their gametes and transmit these to descendants. Thus, the present KER is relevant to any species producing sperm.