Screening for germline DND1 mutations in testicular cancer patients

The Role of DND1 in Cancers

The Ter mutation in Dead-End 1 (Dnd1), Dnd1^Ter, which leads to a premature stop codon, has been determined to be the cause for primordial germ cell deficiency, accompanied with a high incidence of congenital testicular germ cell tumors (TGCTs) or teratomas in the 129/Sv-Ter mice. As an RNA-binding protein, DND1 can bind the 3'-untranslated region (3'-UTR) of mRNAs and function in translational regulation. DND1 can block microRNA (miRNA) access to the 3'-UTR of target mRNAs, thus inhibiting miRNA-mediated mRNA degradation and up-regulating translation or can also function to degrade or repress mRNAs. Other mechanisms of DND1 activity include promoting translation initiation and modifying target protein activity. Although Dnd1^Ter mutation causes spontaneous TGCT only in male 129 mice, it can also cause ovarian teratomas in mice when combined with other genetic defects or cause germ cell teratomas in both genders in the WKY/Ztm rat strain. Furthermore, studies on human cell lines, patient cancer tissues, and the use of human cancer genome analysis indicate that DND1 may possess either tumor-suppressive or -promoting functions in a variety of somatic cancers. Here we review the involvement of DND1 in cancers, including what appears to be its emerging role in somatic cancers.

Human DND1-RRM2 forms a non-canonical domain swapped dimer

RNA recognition motif (RRM) being the most abundant RNA binding domain in eukaryotes, is a major player in cellular regulation. Several variations in the canonical βαββαβ topology have been observed. We have determined the 2.3 Å crystal structure of the human DND1-RRM2 domain. The structure revealed an interesting non-canonical RRM fold, which is maintained by the formation of a 3D domain swapped dimer between β1 and β4 strands across protomers. We have delineated the structural basis of the stable domain swapped dimer formation using the residue level dynamics of protein explored by NMR spectroscopy and MD simulations. Our structural and dynamics studies substantiate major determinants and molecular basis for domain swapped dimerization observed in the RRM domain.

Contrasting effects of Deadend1 (Dnd1) gain and loss of function mutations on allelic inheritance, testicular cancer, and intestinal polyposis

Background

Certain mutations in the Deadend1 (Dnd1) gene are the most potent modifiers of testicular germ cell tumor (TGCT) susceptibility in mice and rats. In the 129 family of mice, the Dnd1^Ter mutation significantly increases occurrence of TGCT-affected males. To test the hypothesis that he Dnd1^Ter allele is a loss-of-function mutation; we characterized the consequences of a genetically-engineered loss-of-function mutation in mice, and compared these results with those for Dnd1^Ter.

Results

We found that intercrossing Dnd1^+/KO heterozygotes to generate a complete loss-of-function led to absence of Dnd1^KO/KO homozygotes and significantly reduced numbers of Dnd1^+/KO heterozygotes. Further crosses showed that Dnd1^Ter partially rescues loss of Dnd1^KO mice. We also found that loss of a single copy of Dnd1 in Dnd1^KO/+ heterozygotes did not affect baseline occurrence of TGCT-affected males and that Dnd1^Ter increased TGCT risk regardless whether the alternative allele was loss-of-function (Dnd1^KO) or wild-type (Dnd1⁺). Finally, we found that the action of Dnd1^Ter was not limited to testicular cancer, but also significantly increased polyp number and burden in the Apc^+/Min model of intestinal polyposis.

Conclusion

These results show that Dnd1 is essential for normal allelic inheritance and that Dnd1^Ter has a novel combination of functions that significantly increase risk for both testicular and intestinal cancer.