The role of the paternal genome in the development of the mouse germ line

Abstract

The mouse germ line originates at 6.5 days post coitum (dpc) in the proximal epiblast, apparently in response to signals from the primitive endoderm or the extraembryonic mesoderm [1], [2]. Some studies have implied a significant role for imprinted genes in germ-line development [3], [4]. These genes, whose expression is determined by their parental origin [5], serve complementary functions during mammalian development [6], [7], [8], [9] and exert striking reciprocal phenotypic effects on androgenetic (AG: two paternal genomes) and parthenogenetic (GG/PG: two maternal genomes) cells [3], [4], [10]. This may include a fundamental effect on germ-cell development because PG but not AG cells can differentiate into viable gametes [3], [4], [11], suggesting that the maternal genome is obligatory for development of the mammalian germ line. Here we show unequivocally that AG cells can differentiate into germ cells, and that in chimeras with normal cells they produce functional sperm. These studies establish that the paternal and maternal genomes can individually provide both the signal and the response required for the specification of germ cells in mammals.