Project description:Recurrent somatic hotspot mutations of DICER1 appear to be clustered around each of four critical metal binding residues in the RNase IIIB domain of DICER1. This domain is responsible for cleavage of the 3’ end of the 5p-miRNA strand of a pre-mRNA hairpin. To investigate the effects of these cancer-associated “hotspot” mutations we engineered mouse Dicer1-deficient ES cells to express wild-type and an allelic series of the mutant human DICER1 variants. Global miRNA and mRNA profiles from cells carrying the metal binding site mutations were compared to each other and wild-type human DICER1. The miRNA and mRNA profiles generated through the expression of the hotspot mutations were virtually identical, and the DICER1 hotspot mutation carrying cells were distinct from both wild-type and Dicer1-deficient cells. Further, miRNA profiles showed mutant DICER1 results in a dramatic loss in processing of mature 5p-miRNA strands but were still able to create 3p-strand miRNAs. Messenger-RNA profile changes were consistent with the loss of 5p-strand miRNAs and showed enriched expression for predicted targets of the lost 5p derived miRNAs. We therefore conclude that cancer-associated somatic hotspot mutations of DICER1, affecting any one of four metal binding residues in the RNase IIIB domain, are functionally equivalent with respect to miRNA-processing and are hypomorphic alleles, yielding a global loss in processing of mature 5p-strand miRNA. We further propose that this resulting 3p-strand bias in mature miRNA expression likely underpins the oncogenic potential of these hotspot mutations. A total of 28 Affymetrix Mouse Gene ST arrays were done for mRNA expression profiling of various DICER1 mutants (n=14), wildtype controls (n=6), vector only (n=3) and parental cell lines (n=5).

Project description:Recurrent somatic hotspot mutations of DICER1 appear to be clustered around each of four critical metal binding residues in the RNase IIIB domain of DICER1. This domain is responsible for cleavage of the 3’ end of the 5p-miRNA strand of a pre-mRNA hairpin. To investigate the effects of these cancer-associated “hotspot” mutations we engineered mouse Dicer1-deficient ES cells to express wild-type and an allelic series of the mutant human DICER1 variants. Global miRNA and mRNA profiles from cells carrying the metal binding site mutations were compared to each other and wild-type human DICER1. The miRNA and mRNA profiles generated through the expression of the hotspot mutations were virtually identical, and the DICER1 hotspot mutation carrying cells were distinct from both wild-type and Dicer1-deficient cells. Further, miRNA profiles showed mutant DICER1 results in a dramatic loss in processing of mature 5p-miRNA strands but were still able to create 3p-strand miRNAs. Messenger-RNA profile changes were consistent with the loss of 5p-strand miRNAs and showed enriched expression for predicted targets of the lost 5p derived miRNAs. We therefore conclude that cancer-associated somatic hotspot mutations of DICER1, affecting any one of four metal binding residues in the RNase IIIB domain, are functionally equivalent with respect to miRNA-processing and are hypomorphic alleles, yielding a global loss in processing of mature 5p-strand miRNA. We further propose that this resulting 3p-strand bias in mature miRNA expression likely underpins the oncogenic potential of these hotspot mutations.

Project description:Dicer is an essential enzyme in microRNA biogenesis. Mutations in the DICER1 gene are linked to various cancers, notably through the DICER1 syndrome. To investigate the impact of the pathogenic hotspot mutations in DICER1-associated tumors, we introduced a hotspot mutation into the endogenous Dicer1 locus of a mouse embryonic carcinoma cell line using CRISPR. Our findings not only confirm the loss of 5p-miRNAs, as previously reported, but also uncover an unexpected upregulation of specific 3p-miRNAs. These upregulated 3p-miRNAs, usually considered as passenger strands in the wild-type cells, are selectively loaded into the Argonaute protein in mutant cells based on their 5' end characteristics, resulting in a "strand-switch" phenomenon. Functional assays and transcriptome analyses demonstrate the passenger 3p-miRNAs’ activity. This study suggests that the Dicer hotspot mutation is not merely a loss-of-function mutation for 5p-miRNAs but also a gain-of-function mutation for passenger 3p-miRNA, potentially contributing to DICER1-associated tumorigenesis.

Project description:Dicer is an essential enzyme in microRNA biogenesis. Mutations in the DICER1 gene are linked to various cancers, notably through the DICER1 syndrome. To investigate the impact of the pathogenic hotspot mutations in DICER1-associated tumors, we introduced a hotspot mutation into the endogenous Dicer1 locus of a mouse embryonic carcinoma cell line using CRISPR. Our findings not only confirm the loss of 5p-miRNAs, as previously reported, but also uncover an unexpected upregulation of specific 3p-miRNAs. These upregulated 3p-miRNAs, usually considered as passenger strands in the wild-type cells, are selectively loaded into the Argonaute protein in mutant cells based on their 5' end characteristics, resulting in a "strand-switch" phenomenon. Functional assays and transcriptome analyses demonstrate the passenger 3p-miRNAs’ activity. This study suggests that the Dicer hotspot mutation is not merely a loss-of-function mutation for 5p-miRNAs but also a gain-of-function mutation for passenger 3p-miRNA, potentially contributing to DICER1-associated tumorigenesis.

Project description:Dicer is an essential enzyme in microRNA biogenesis. Mutations in the DICER1 gene are linked to various cancers, notably through the DICER1 syndrome. To investigate the impact of the pathogenic hotspot mutations in DICER1-associated tumors, we introduced a hotspot mutation into the endogenous Dicer1 locus of a mouse embryonic carcinoma cell line using CRISPR. Our findings not only confirm the loss of 5p-miRNAs, as previously reported, but also uncover an unexpected upregulation of specific 3p-miRNAs. These upregulated 3p-miRNAs, usually considered as passenger strands in the wild-type cells, are selectively loaded into the Argonaute protein in mutant cells based on their 5' end characteristics, resulting in a "strand-switch" phenomenon. Functional assays and transcriptome analyses demonstrate the passenger 3p-miRNAs’ activity. This study suggests that the Dicer hotspot mutation is not merely a loss-of-function mutation for 5p-miRNAs but also a gain-of-function mutation for passenger 3p-miRNA, potentially contributing to DICER1-associated tumorigenesis.

Project description:DICER1 plays a critical role in microRNA (miRNA) biogenesis. Recurrent somatic “hotspot” mutations at four mental binding sites within the RNase IIIb domain of DICER1, were identified in ovarian sex cord-stromal tumors and have since been described in other pediatric tumors. In this study, we identified and characterized DICER1 hotspot mutations in endometrial cancers derived from The Cancer Genome Atlas (TCGA) and our local tumor bank. DICER1 hotspot mutations are found in ~2% of endometrial tumors. Using Illumina and Sanger targeted resequencing we observed biallelic DICER1 mutations in more than 50% of cases with hotspot mutations and identified an additional recurrent mutation G1809R in 2 cases. Through small RNA deep sequencing and real-time PCR, we demonstrated mutations that add a positively charged side chain to residue 1809 have similar detrimental effects on 5p miRNA production as mutations at metal binding sites. In one case G1809R was compound heterozygous with a germline S839F mutation, which contributes to loss of DICER1 expression by promoting protein degradation. As expected, 5p miRNAs are globally reduced in tumors and cell lines with hotspot mutations. Pathway analysis of gene expression profiles indicated that genes derepressed due to loss of 5p miRNAs are strongly associated with cell cycle related pathways. Using a Dicer null cell line model, we demonstrated that DICER1 hotspot mutants abolished the inhibitory effects of wildtype DICER1 on cell proliferation upon re-expression. Furthermore, targets of let-7 family miRNAs are enriched among the upregulated genes, suggesting loss of let-7 may be impacting downstream pathways.

Project description:Analysis of the global gene expression in ovarian Sertoli-Leydig cell tumor samples with or without DICER1 RNase IIIb domain mutation

Project description:Background: Germline truncating mutations in DICER1, an RNase III-type endoribonuclease essential for processing of microRNAs, are seen in families with the pleuropulmonary blastoma-family tumor and dysplasia syndrome; these individuals have a propensity to develop non-epithelial ovarian tumors (i.e. sex-cord stromal and germ cell tumors). Methods: We sequenced the whole transcriptomes or exomes of 14 non-epithelial ovarian tumors and noted closely clustered mutations in the RNase IIIb domain of DICER1 in four cases. Using Sanger sequencing, we then analyzed additional ovarian tumors for mutations in this region. The impact of the mutations on the enzymatic activity of Dicer1 was determined using in vitro RNA cleavage assays. Results: RNase IIIb domain DICER1 mutations were found in 30/102 non-epithelial ovarian tumors (29%), predominantly Sertoli-Leydig cell tumors (26/43, 60%), including 4/4 from individuals with germline DICER1 mutations. The mutations were restricted to metal binding sites within the RNase IIIb catalytic centres critical for miRNA interaction and cleavage, and were somatic in all 14 cases where germline DNA was available for testing. Of 266 epithelial ovarian and endometrial cancers tested, one case, an ovarian carcinosarcoma, had a hotspot mutation. In vitro, the mutant DICER proteins showed reduced RNase IIIb activity but retained RNase IIIa activity. Conclusions: Somatic missense mutations of the RNase IIIb domain of DICER1 are common in non-epithelial ovarian tumors. Genetic, pathologic, and functional evidence suggest that these mutations do not obliterate DICER1 function, rather, they alter it in specific cell types, a novel mechanism through which perturbed microRNA expression is oncogenic.

Project description:Pleuropulmonary blastoma (PPB) is an extremely rare pediatric malignancy in the lung, whose pathogenesis is poorly understood, except for recent reports of frequent germline heterozygous DICER1 mutations. To investigate the genetic basis of PPB, we performed whole-exome sequencing in 7 representative PPB cases, followed by targeted deep sequencing in 12 cases with PPB. DICER1 mutations were found in 11/12 cases. Biallelic DICER1 mutations were common in PPB, in which RNase IIIb domain mutations were found in all cases with or without nonsense/frameshift mutations and were somatic in all evaluable cases. A majority of cases had mutated DICER1 alleles in germline with or without an additional somatic mutation in the remaining allele, while other cases had exclusively somatic mutations involving the RNase IIIb domain. TP53 deletions/mutations were detected in 8/12 cases. Our results highlight a unique role of the RNase IIIb domain mutations and TP53 inactivation in PPB pathogenesis.

Project description:mRNA and microRNA transcriptomes of pediatric thyroid cancers harboring DICER1 RNase IIIb domain mutation