Testicular tumors, the most common cancer in young men, arise from abnormalities in germ cells during fetal development. Unconventional inheritance for testicular germ cell tumor (TGCT) risk both in humans and mice implicates epigenetic mechanisms. Apolipoprotein B mRNA-editing enzyme complex 1 (APOBEC1) cytidine deaminase and Deadend-1, which are involved in C-to-U RNA editing and microRNA-dependent mRNA silencing, respectively, are potent epigenetic modifiers of TGCT susceptibility in the genetically predisposed 129/Sv inbred mouse strain. Here, we show that partial loss of either APOBEC1 complementation factor (A1CF), the RNA-binding cofactor of APOBEC1 in RNA editing, or Argonaute 2 (AGO2), a key factor in the biogenesis of certain noncoding RNAs, modulates risk for TGCTs and testicular abnormalities in both parent-of-origin and conventional genetic manners. In addition, non-Mendelian inheritance was found among progeny of A1cf and Ago2 mutant intercrosses but not in backcrosses and without fetal loss. Together these findings suggest nonrandom union of gametes rather than meiotic drive or preferential lethality. Finally, this survey also suggested that A1CF contributes to long-term reproductive performance. These results directly implicate the RNA-binding proteins A1CF and AGO2 in the epigenetic control of germ-cell fate, urogenital development, and gamete functions.he germline is the only cell lineage that transmits genetic and epigenetic information across generations. Early in mammalian development, primordial germ cells (PGCs) escape a somatic fate to become unipotent precursors of gametes, the highly specialized cells that give rise to the totipotent zygote upon fertilization (1). Various molecular mechanisms regulate pluripotency by modulating gene expression and protein activity throughout development (2). Failure of pluripotency control can lead to infertility, carcinoma in situ, gamete dysfunctions, and unusual modes of inheritance. Carcinoma in situ anomalously express markers of pluripotency and can give rise to testicular germ cell tumors (TGCTs) (3-7). Studying the genetics, epigenetics, and biology of germ cells (GCs) and TGCTs can provide unique insights about GC development, pluripotency control, tumorigenesis, and unconventional inheritance.TGCTs are the third most heritable cancer and are the most common cancers in young men 15-35 y old (8). Genome-wide association studies (GWAS) in humans identified susceptibility loci such as KIT ligand (KITL), Sprouty 4 (SPRY4), Bcl2 antagonist killer (BAK1), Doublesex-and Mab3-related transcription factor (DMRT1), Deleted in azoospermia RNA-binding protein (DAZL), PRDM transcriptional regulator (PRDM14), the telomerase reverse transcriptase TERT, and its cofactor AFT7IP (9-15). Individually and collectively, however, these susceptibility genes account for only a modest portion of inherited risk. Many genes and inherited factors remain to be discovered, their functions in normal development characterized, and the ways that dysfunction leads to TGCTs inve...
