Uterine serous carcinoma (USC) is a biologically aggressive subtype of endometrial cancer. We analyzed the mutational landscape of USC by whole-exome sequencing of 57 cancers, most of which were matched to normal DNA from the same patients. The distribution of the number of protein-altering somatic mutations revealed that 52 USC tumors had fewer than 100 (median 36), whereas 5 had more than 3,000 somatic mutations. The mutations in these latter tumors showed hallmarks of defects in DNA mismatch repair. Among the remainder, we found a significantly increased burden of mutation in 14 genes. In addition to well-known cancer genes (i.e., TP53, PIK3CA, PPP2R1A, KRAS, FBXW7), there were frequent mutations in CHD4/ Mi2b, a member of the NuRD-chromatin-remodeling complex, and TAF1, an element of the core TFIID transcriptional machinery. Additionally, somatic copy-number variation was found to play an important role in USC, with 13 copy-number gains and 12 copy-number losses that occurred more often than expected by chance. In addition to loss of TP53, we found frequent deletion of a small segment of chromosome 19 containing MBD3, also a member of the NuRDchromatin-modification complex, and frequent amplification of chromosome segments containing PIK3CA, ERBB2 (an upstream activator of PIK3CA), and CCNE1 (a target of FBXW7-mediated ubiquitination). These findings identify frequent mutation of DNA damage, chromatin remodeling, cell cycle, and cell proliferation pathways in USC and suggest potential targets for treatment of this lethal variant of endometrial cancer.endometrial carcinoma | uterine serous papillary cancer | cancer genomics E ndometrial cancer is the most prevalent gynecologic tumor in women, with an annual incidence of 47,130 new cases and 8,010 deaths in 2012 in the United States (1). On the basis of clinical and histopathological features, endometrial cancer is classified into type I and type II disease groups (2). Type I tumors, which constitute the majority of cases, are generally diagnosed at an early stage, are low grade and endometrioid in histology, are associated with a history of hyperestrogenism, and typically have a good prognosis. In contrast, type II cancers are poorly differentiated, often with serous papillary [uterine serous carcinoma (USC)] or clear cell histology. Although these tumors account for a minority of endometrial cancers, the majority of relapses and deaths occur in this group of patients (2).Among type II cancers, USC represents the most biologically aggressive subtype (3, 4). Classically, the neoplastic epithelium is characterized by serous differentiation with psammoma bodies and a predominantly papillary architecture (3). Pleomorphic cytology with nuclear atypia, prominent nucleoli, a vescicular chromatin pattern, and high mitotic activity are seen. Clinically, USC has a propensity for early intra-abdominal and lymphatic spread (3) and is more commonly diagnosed in women of African ancestry (3-5). The overall 5-y survival of USC is only 30 ± 9% for all stages, and the recurre...
Carcinosarcomas (CSs) of the uterus and ovary are highly aggressive neoplasms containing both carcinomatous and sarcomatous elements. We analyzed the mutational landscape of 68 uterine and ovarian CSs by whole-exome sequencing. We also performed multiregion whole-exome sequencing comprising two carcinoma and sarcoma samples from six tumors to resolve their evolutionary histories. The results demonstrated that carcinomatous and sarcomatous elements derive from a common precursor having mutations typical of carcinomas. In addition to mutations in cancer genes previously identified in uterine and ovarian carcinomas such as TP53, PIK3CA, PPP2R1A, KRAS, PTEN, CHD4, and BCOR, we found an excess of mutations in genes encoding histone H2A and H2B, as well as significant amplification of the segment of chromosome 6p harboring the histone gene cluster containing these genes. We also found frequent deletions of the genes TP53 and MBD3 (a member with CHD4 of the nucleosome remodeling deacetylase complex) and frequent amplification of chromosome segments containing the genes PIK3CA, TERT, and MYC. Stable transgenic expression of H2A and H2B in a uterine serous carcinoma cell line demonstrated that mutant, but not wild-type, histones increased expression of markers of epithelial-mesenchymal transition (EMT) as well as tumor migratory and invasive properties, suggesting a role in sarcomatous transformation. Comparison of the phylogenetic relationships of carcinomatous and sarcomatous elements of the same tumors demonstrated separate lineages leading to these two components. These findings define the genetic landscape of CSs and suggest therapeutic targets for these highly aggressive neoplasms.uterine carcinosarcoma | ovarian carcinosarcoma | exome sequencing C arcinosarcomas (CSs) of the female genital tract, also known as mixed malignant Müllerian tumors, are rare but highly aggressive tumors characterized by a biphasic histology. These cancers most commonly arise in the uterus, followed by the ovaries, fallopian tubes, and vagina (1-3). The diagnosis of CS requires the presence of both sarcomatous and carcinomatous components. Although the pathogenesis of CSs remains under debate, an increasing body of evidence supports the origin of both elements from a common epithelial cell that undergoes sarcomatous dedifferentiation, rather than two independent progenitors (2-5).The overall 5-y survival is only 30 ± 9% for all stages, and the recurrence rate after surgery is extremely high (50-80%) (3-5). The uncertain origin and poor prognosis of uterine and ovarian CSs motivate determination of the molecular basis of CS aggressive behavior in the hope of developing novel and effective treatment modalities. ResultsThe Genetic Landscape of CS. A total of 68 patients with stage I-IV uterine (n = 44) and ovarian (n = 24) CSs were studied. Their clinical and histological features are presented in SI Appendix, Table S1. Upon surgical removal of tumors, primary cell lines were prepared (five tumors) or tumors were frozen (63 tumors). Among t...
Most neuropsychiatric disease risk variants are in noncoding sequences and lack functional interpretation. Because regulatory sequences often reside in open chromatin, we reasoned that neuropsychiatric disease risk variants may affect chromatin accessibility during neurodevelopment. Using human induced pluripotent stem cell (iPSC)–derived neurons that model developing brains, we identified thousands of genetic variants exhibiting allele-specific open chromatin (ASoC). These neuronal ASoCs were partially driven by altered transcription factor binding, overrepresented in brain gene enhancers and expression quantitative trait loci, and frequently associated with distal genes through chromatin contacts. ASoCs were enriched for genetic variants associated with brain disorders, enabling identification of functional schizophrenia risk variants and their cis-target genes. This study highlights ASoC as a functional mechanism of noncoding neuropsychiatric risk variants, providing a powerful framework for identifying disease causal variants and genes.
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