Functions of genes related to testicular germ cell tumour development.

OBJECTIVE: Testicular germ cell tumour (TGCT) is a malignancy with a high heritable component. The inherited risk is polygenic, and around 50 susceptibility genes are identified. The functional role of the gene products for TGCT development is not well understood. The focus of this review is functional studies of genetic risk factors for TGCT derived from GCNIS and the signalling pathways involved in the pathogenesis. RECENT DEVELOPMENTS: Genome-wide association studies have identified new risk loci for TGCT and confirmed previously identified susceptibility genes. Many of these risk genes are related to male germ cell development, sex determination and genomic integrity. Gain- and loss-of-function studies in animal models and TGCT cell lines, as well as gene and protein expression studies in TGCT patient samples, have contributed to the understanding of TGCT development. KITLG-KIT signalling is of crucial importance, but several other signal transduction pathways may also play a role. Many of the risk loci are in non-coding regions, and studies have revealed that non-coding RNAs may act as oncogenes or tumour suppressors in TGCT development. CONCLUSIONS: The risk of TGCT is polygenic, and the underlying molecular mechanisms are complex. Several signalling pathways are related to TGCT development, and both proteins and non-coding RNAs may act as oncogenes or tumour suppressors. Epigenetic studies are of importance to get further knowledge about how the signalling pathways are regulated.

A novel splice site mutation in the Cockayne syndrome group A gene in two siblings with Cockayne syndrome.

Cockayne syndrome (CS) is mainly caused by mutations in the Cockayne syndrome group A or B (CSA or CSB) genes which are required for a sub-pathway of nucleotide excision repair entitled transcription coupled repair. Approximately 20% of the CS patients have mutations in CSA, which encodes a 44 kDa tryptophane (Trp, W) and aspartic acid (Asp, D) amino acids (WD) repeat protein. Up to now, nine different CSA mutations have been identified. We examined two Somali siblings 9 and 12 years old with clinical features typical of CS including skin photosensitivity, progressive ataxia, spasticity, hearing loss, central and peripheral demyelination and intracranial calcifications. Molecular analysis showed a novel splice acceptor site mutation, a G to A transition in the -1 position of intervening sequence 6 (g.IVS6-1G>A), in the CSA (excision repair cross-complementing 8 (ERCC8)) gene. IVS6-1G>A results in a new 28 amino acid C-terminus and premature termination of the CSA protein (G184DFs28X). A review of the CSA protein and the 10 known CSA mutations is also presented.