6041

RNASEL

PRCA1|RNS4;ribonuclease L (2',5'-oligoisoadenylate synthetase-dependent);RNASEL;ribonuclease L (2',5'-oligoisoadenylate synthetase-dependent)

2',5'-oligoisoadenylate synthetase-dependent|2-5A-dependent RNase|2-5A-dependent ribonuclease|RNase L|interferon-induced 2-5A-dependent RNase|ribonuclease 4

1q25

protein-coding

Recently, the interferon (IFN) antiviral pathways and prostate cancer genetics and have surprisingly converged on a single-strand specific, regulated endoribonuclease. genetics studies from several laboratories in the U.S., Finland, and Israel, support the recent identification of the RNase L gene, RNASEL, as a strong candidate for the long sought after hereditary prostate cancer 1 (HPC1) allele. Results from these studies suggest that mutations in RNASEL predispose men to an increased incidence of prostate cancer, which in some cases reflect more aggressive disease and/or decreased age of onset compared with non-RNASEL linked cases. RNase L is a uniquely regulated endoribonuclease that requires 5-triphosphorylated, 2,5-linked oligoadenylates (2-5A) for its activity. The presence of both germline mutations in RNASEL segregating with disease within HPC-affected families and loss of heterozygosity (LOH) in tumor tissues suggest a novel role for the regulated endoribonuclease in the pathogenesis of prostate cancer. The association of mutations in RNASEL with prostate cancer cases further suggests a relationship between innate immunity and tumor suppression. It is proposed here that RNase L functions in counteracting prostate cancer by virtue of its ability to degrade RNA, thus initiating a cellular stress response that leads to apoptosis. This monograph reviews the biochemistry and genetics of RNase L as it relates to the pathobiology of prostate cancer and considers implications for future screening and therapy of this disease.

Three putative prostate cancer-susceptibility genes, RNASEL/HPC1 at 1q24, MSR1 at 8p22, and ELAC2/HPC2 at 17p11, have recently been identified. Our objective was to investigate somatic mutations in these genes in sporadic prostate cancer. We analyzed 39 clinical prostate cancer specimens, 10 prostate cancer xenografts (LuCaP series), and 4 prostate cancer cell lines (LNCaP, DU145, PC-3, and MPC-3) for genetic changes using denaturing high-performance liquid chromatography and direct sequencing in order to screen the whole coding regions of RNASEL and MSR1, as well as exons 7 and 17 of ELAC2. The known 471delAAAG truncating mutation was found in the RNASEL gene in cell line LNCaP. The only new missense variation in RNASEL, Gly296Val, was found in cell line DU145, but not in any other samples. RNASEL and ELAC2 also showed the common missense polymorphic changes. A previously reported truncating mutation (Arg293X) was found in MSR1 in the germ line of one individual. Our results indicate that inactivation of the RNASEL, ELAC2, or MSR1 genes by somatic mutation is a rare phenomenon in sporadic prostate cancer.

The endoribonuclease L (RNase L) is the effector of the 2-5A system, a major enzymatic pathway involved in the molecular mechanism of interferons (IFNs). RNase L is a very unusual nuclease with a complex mechanism of regulation. It is a latent enzyme, expressed in nearly every mammalian cell type. Its activation requires its binding to a small oligonucleotide, 2-5A. 2-5A is a series of unique 5-triphosphorylated oligoadenylates with 2-5 phosphodiester bonds. By regulating viral and cellular RNA expression, RNase L plays an important role in the antiviral and antiproliferative activities of IFN and contributes to innate immunity and cell metabolism. The 2-5A/RNase L pathway is implicated in mediating apoptosis in response to viral infections and to several types of external stimuli. Several recent studies have suggested that RNase L could have a role in cancer biology and evidence of a tumor suppressor function of RNase L has emerged from studies on the genetics of hereditary prostate cancer.

The endoribonuclease RNase-L requires 2,5-linked oligoadenylates for activation, and mediates antiviral and antiproliferative activities. We previously determined that RNase-L activation induces senescence; to determine potential mechanisms underlying this activity, we used microarrays to identify RNase-L-regulated mRNAs. RNase-L activation affected affected a finite number of transcripts, and thus does not lead to a global change in mRNA turnover. The largest classes of downregulated transcripts, that represent candidate RNase-L substrates, function in protein biosynthesis, metabolism and proliferation. Among these, mRNAs encoding ribosomal proteins (RPs) were particularly enriched. The reduced levels of four RP mRNAs corresponded with a decrease in their half lives and a physical association with an RNase-L-ribonucleoprotein (RNP) complex in cells, suggesting that they represent authentic RNase-L substrates. Sequence and structural analysis of the downregulated mRNAs identified a putative RNase-L target motif that was used for the in silico identification of a novel RNase-L-RNP-interacting transcript. The downregulation of RP mRNAs corresponded with a marked reduction in protein translation, consistent with the roles of RP proteins in ribosome function. Our data support a model in which the RNase-L-mediated degradation of RP mRNAs inhibits translation, and may contribute to its antiproliferative, senescence inducing and tumor suppressor activities.