SUMMARY
Sarcomas are a broad family of mesenchymal malignancies exhibiting remarkable histologic diversity. We describe the multi-platform molecular landscape of 206 adult soft tissue sarcomas representing 6 major types. Along with novel insights into the biology of individual sarcoma types, we report three overarching findings: 1) unlike most epithelial malignancies, these sarcomas (excepting synovial sarcoma) are characterized predominantly by copy number changes, with low mutational loads and only a few genes (TP53, ATRX, RB1) highly recurrently mutated across sarcoma types, 2) within sarcoma types, genomic and regulomic diversity of driver pathways defines molecular subtypes associated with patient outcome, and 3) the immune microenvironment, inferred from DNA methylation and mRNA profiles, associates with outcome and may inform clinical trials of immune checkpoint inhibitors. Overall, this large-scale analysis reveals previously unappreciated sarcoma type-specific changes in copy number, methylation, RNA, and protein, providing insights into refining sarcoma therapy and relationships to other cancer types.
The replication of poliovirus RNA genomes containing amber mutations was studied to test whether viral proteins provided in trans could rescue the replication of an RNA genome that could not be completely translated itself. Mutants containing amber codons at different positions in the genome displayed vastly different abilities to be rescued by wild-type proteins provided by a helper genome. Amber-suppressing cell lines were used to ensure that the defects in the amber mutants arose from their failure to be translated, not from defects in RNA sequence or structure. An internal region of the poliovirus genome was identified whose translation is required in cis; failure to translate this region was shown to inhibit RNA replication. This coupling between translation and RNA replication could provide a late proofreading mechanism that enables poliovirus, and possibly many other RNA viruses, to prevent the replication of defective genomes.
We have developed a ribonuclease protection method suitable for sensitive detection of an RNA species in the presence of a large excess of its complementary strand, as for the detection of negative strands of positive-strand RNA viruses. By using this method to probe for poliovirus negative strands in virions, we found that positive strands are present in at least 40,000-fold excess over negative strands. Thus, we have confirmed that poliovirus encapsidation is highly specific for positive strands and have demonstrated that the genome-linked protein VPg, which is covalently attached to the 5' ends of both positive and negative strands, cannot be the sole determinant of RNA packaging. We tested the ratios of viral positive strands to negative strands in cells at different times during infection; this value ranged from approximately 40/1 to 70/1, being highest at 4 h and lower at 2 and 6 h postinfection.
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