Azusa Yamato

Transforming mutations of RAC guanosine triphosphatases in human cancers

Members of the RAS superfamily of small guanosine triphosphatases (GTPases) transition between GDP-bound, inactive and GTP-bound, active states and thereby function as binary switches in the regulation of various cellular activities. Whereas HRAS, NRAS, and KRAS frequently acquire transforming missense mutations in human cancer, little is known of the oncogenic roles of other small GTPases, including Ras-related C3 botulinum toxin substrate (RAC) proteins. We show that the human sarcoma cell line HT1080 harbors both NRAS(Q61K) and RAC1(N92I) mutant proteins. Whereas both of these mutants were able to transform fibroblasts, knockdown experiments indicated that RAC1(N92I) may be the essential growth driver for this cell line. Screening for RAC1, RAC2, or RAC3 mutations in cell lines and public databases identified several missense mutations for RAC1 and RAC2, with some of the mutant proteins, including RAC1(P29S), RAC1(C157Y), RAC2(P29L), and RAC2(P29Q), being found to be activated and transforming. P29S, N92I, and C157Y mutants of RAC1 were shown to exist preferentially in the GTP-bound state as a result of a rapid transition from the GDP-bound state, rather than as a result of a reduced intrinsic GTPase activity. Activating mutations of RAC GTPases were thus found in a wide variety of human cancers at a low frequency; however, given their marked transforming ability, the mutant proteins are potential targets for the development of new therapeutic agents.

Leukemic evolution of donor-derived cells harboring IDH2 and DNMT3A mutations after allogeneic stem cell transplantation.

Leukemic evolution of donor-derived cells harboring IDH2 and DNMT3A mutations after allogeneic stem cell transplantation

Cancer‐associated missense mutations of caspase‐8 activate nuclear factor‐κB signaling

Head and neck squamous cell carcinoma (HNSCC) is an aggressive cancer with a 5‐year survival rate of ~50%. With the use of a custom cDNA‐capture system coupled with massively parallel sequencing, we have now investigated transforming mechanisms for this malignancy. The cDNAs of cancer‐related genes (n = 906) were purified from a human HNSCC cell line (T3M‐1 Cl‐10) and subjected to high‐throughput resequencing, and the clinical relevance of non‐synonymous mutations thus identified was evaluated with luciferase‐based reporter assays. A CASP8 (procaspase‐8) cDNA with a novel G‐to‐C point mutation that results in the substitution of alanine for glycine at codon 325 was identified, and the mutant protein, CASP8 (G325A), was found to activate nuclear factor‐κB (NF‐κB) signaling to an extent far greater than that achieved with the wild‐type protein. Moreover, forced expression of wild‐type CASP8 suppressed the growth of T3M‐1 Cl‐10 cells without notable effects on apoptosis. We further found that most CASP8 mutations previously detected in various epithelial tumors also increase the ability of the protein to activate NF‐κB signaling. Such NF‐κB activation was shown to be mediated through the COOH‐terminal region of the second death effector domain of CASP8. Although CASP8 mutations associated with cancer have been thought to promote tumorigenesis as a result of attenuation of the proapoptotic function of the protein, our results now show that most such mutations, including the novel G325A identified here, separately confer a gain of function with regard to activation of NF‐κB signaling, indicating another role of CASP8 in the transformation of human malignancies including HNSCC.

Oncogenic MAP2K1 mutations in human epithelial tumors

The scirrhous subtype of gastric cancer is a highly infiltrative tumor with a poor outcome. To identify a transforming gene in this intractable disorder, we constructed a retroviral complementary DNA (cDNA) expression library from a cell line (OCUM-1) of scirrhous gastric cancer. A focus formation assay with the library and mouse 3T3 fibroblasts led to the discovery of a transforming cDNA, encoding for MAP2K1 with a glutamine-to-proline substitution at amino acid position 56. Interestingly, treatment with a MAP2K1-specific inhibitor clearly induced cell death of OCUM-1 but not of other two cells lines of scirrhous gastric cancer that do not carry MAP2K1 mutations, revealing the essential role of MAP2K1(Q56P) in the transformation mechanism of OCUM-1 cells. By using a next-generation sequencer, we further conducted deep sequencing of the MAP2K1 cDNA among 171 human cancer specimens or cell lines, resulting in the identification of one known (D67N) and four novel (R47Q, R49L, I204T and P306H) mutations within MAP2K1. The latter four changes were further shown to confer transforming potential to MAP2K1. In our experiments, a total of six (3.5%) activating mutations in MAP2K1 were thus identified among 172 of specimens or cell lines for human epithelial tumors. Given the addiction of cancer cells to the elevated MAP2K1 activity for proliferation, human cancers with such MAP2K1 mutations are suitable targets for the treatment with MAP2K1 inhibitors.

High-throughput resequencing of target-captured cDNA in cancer cells.

The recent advent of whole exon (exome)‐capture technology, coupled with second‐generation sequencers, has made it possible to readily detect genomic alterations that affect encoded proteins in cancer cells. Such target resequencing of the cancer genome, however, fails to detect most clinically‐relevant gene fusions, given that such oncogenic fusion genes are often generated through intron‐to‐intron ligation. To develop a resequencing platform that simultaneously captures point mutations, insertions–deletions (indels), and gene fusions in the cancer genome, we chose cDNA as the input for target capture and extensive resequencing, and we describe the versatility of such a cDNA‐capture system. As a test case, we constructed a custom target‐capture system for 913 cancer‐related genes, and we purified cDNA fragments for the target gene set from five cell lines of CML. Our target gene set included Abelson murine leukemia viral oncogene homolog 1 (ABL1), but it did not include breakpoint cluster region (BCR); however, the sequence output faithfully detected reads spanning the fusion points of these two genes in all cell lines, confirming the ability of cDNA capture to detect gene fusions. Furthermore, computational analysis of the sequence dataset successfully identified non‐synonymous mutations and indels, including those of tumor protein p53 (TP53). Our data might thus support the feasibility of a cDNA‐capture system coupled with massively parallel sequencing as a simple platform for the detection of a variety of anomalies in protein‐coding genes among hundreds of cancer specimens. (Cancer Sci 2012; 103: 131–135)

Oncogenic activity of BIRC2 and BIRC3 mutants independent of nuclear factor-κB-activating potential.

BIRC2 and BIRC3 are closely related members of the inhibitor of apoptosis (IAP) family of proteins and play pivotal roles in regulation of nuclear factor‐κB (NF‐κB) signaling and apoptosis. Copy number loss for and somatic mutation of BIRC2 and BIRC3 have been frequently detected in lymphoid malignancies, with such genetic alterations being thought to contribute to carcinogenesis through activation of the noncanonical NF‐κB signaling pathway. Here we show that BIRC2 and BIRC3 mutations are also present in a wide range of epithelial tumors and that most such nonsense or frameshift mutations confer direct transforming potential. This oncogenic function of BIRC2/3 mutants is largely independent of their ability to activate NF‐κB signaling. Rather, all of the transforming mutants lack an intact RING finger domain, with loss of ubiquitin ligase activity being essential for transformation irrespective of NF‐κB regulation. The serine‐threonine kinase NIK was found to be an important, but not exclusive, mediator of BIRC2/3‐driven carcinogenesis, although this function was independent of NF‐κB activation. Our data thus suggest that, in addition to the BIRC2/3–NIK–NF‐κB signaling pathway, BIRC2/3–NIK signaling targets effectors other than NF‐κB and thereby contributes directly to carcinogenesis. Identification of these effectors may provide a basis for the development of targeted agents for the treatment of lymphoid malignancies and other cancers with BIRC2/3 alterations.

Mutational Landscape and Antiproliferative Functions of ELF Transcription Factors in Human Cancer

ELF4 (also known as MEF) is a member of the ETS family of transcription factors. An oncogenic role for ELF4 has been demonstrated in hematopoietic malignancies, but its function in epithelial tumors remains unclear. Here, we show that ELF4 can function as a tumor suppressor and is somatically inactivated in a wide range of human tumors. We identified a missense mutation affecting the transactivation potential of ELF4 in oral squamous cell carcinoma cells. Restoration of the transactivation activity through introduction of wild-type ELF4 significantly inhibited cell proliferation in vitro and tumor xenograft growth. Furthermore, we found that ELF1 and ELF2, closely related transcription factors to ELF4, also exerted antiproliferative effects in multiple cancer cell lines. Mutations in ELF1 and ELF2, as in ELF4, were widespread across human cancers, but were almost all mutually exclusive. Moreover, chromatin immunoprecipitation coupled with high-throughput sequencing revealed ELF4-binding sites in genomic regions adjacent to genes related to cell-cycle regulation and apoptosis. Finally, we provide mechanistic evidence that the antiproliferative effects of ELF4 were mediated through the induction of HRK, an activator of apoptosis, and DLX3, an inhibitor of cell growth. Collectively, our findings reveal a novel subtype of human cancer characterized by inactivating mutations in the ELF subfamily of proteins, and warrant further investigation of the specific settings where ELF restoration may be therapeutically beneficial. Cancer Res; 76(7); 1814-24. ©2016 AACR.

p53-inducible DPYSL4 associates with mitochondrial supercomplexes and regulates energy metabolism in adipocytes and cancer cells

Significance We herein performed RNA sequencing to show that DPYSL4 is a p53-inducible regulator of energy metabolism in both cancer cells and normal cells, such as adipocytes. DPYSL4 was found to localize in both cytosol and mitochondria, particularly in associations with mitochondrial supercomplexes, providing a potential mechanism for its regulation of OXPHOS and cellular energy supply. Furthermore, DPYSL4 expression suppressed tumor growth and metastasis in vivo. Together, these results suggest a potential link between p53-inducible DPYSL4 and the pathophysiology of cancer and metabolic disorders, possibly via its energy-regulating function. The tumor suppressor p53 regulates multiple cellular functions, including energy metabolism. Metabolic deregulation is implicated in the pathogenesis of some cancers and in metabolic disorders and may result from the inactivation of p53 functions. Using RNA sequencing and ChIP sequencing of cancer cells and preadipocytes, we demonstrate that p53 modulates several metabolic processes via the transactivation of energy metabolism genes including dihydropyrimidinase-like 4 (DPYSL4). DPYSL4 is a member of the collapsin response mediator protein family, which is involved in cancer invasion and progression. Intriguingly, DPYSL4 overexpression in cancer cells and preadipocytes up-regulated ATP production and oxygen consumption, while DPYSL4 knockdown using siRNA or CRISPR/Cas9 down-regulated energy production. Furthermore, DPYSL4 was associated with mitochondrial supercomplexes, and deletion of its dihydropyrimidinase-like domain abolished its association and its ability to stimulate ATP production and suppress the cancer cell invasion. Mouse-xenograft and lung-metastasis models indicated that DPYSL4 expression compromised tumor growth and metastasis in vivo. Consistently, database analyses demonstrated that low DPYSL4 expression was significantly associated with poor survival of breast and ovarian cancers in accordance with its reduced expression in certain types of cancer tissues. Moreover, immunohistochemical analysis using the adipose tissue of obese patients revealed that DPYSL4 expression was positively correlated with INFg and body mass index in accordance with p53 activation. Together, these results suggest that DPYSL4 plays a key role in the tumor-suppressor function of p53 by regulating oxidative phosphorylation and the cellular energy supply via its association with mitochondrial supercomplexes, possibly linking to the pathophysiology of both cancer and obesity.

Inactivating mutations and hypermethylation of the NKX2-1/TTF-1 gene in non-terminal respiratory unit-type lung adenocarcinomas

The major driver mutations of lung cancer, EGFR mutations and EML4‐ALK fusion, are mainly detected in terminal respiratory unit (TRU)‐type lung adenocarcinomas, which typically show lepidic and/or papillary patterns, but are rarely associated with a solid or invasive mucinous morphology. In order to elucidate the key genetic events in non‐TRU‐type lung cancer, we carried out whole‐exome sequencing on 43 non‐TRU‐type lung adenocarcinomas based on morphology (17 acinar, nine solid, and two enteric adenocarcinomas, and 15 adenocarcinomas with a mucinous morphology). Our analysis identified mutations in TP53 (16/43, 37.2%), KRAS (13/43, 30.2%), and NKX2‐1/TTF‐1 (7/43; 16.3%) as the top three significantly mutated genes, while the EGFR mutation was rare (1/43, 2.3%) in this cohort. Eight NKX2‐1/TTF‐1 mutations (five frameshift, two nonsense, and one missense) were identified, with one case harboring two distinct NKX2‐1/TTF‐1 mutations (one missense and one frameshift). Functional assays with the NK2 homeobox 1 (NKX2‐1)/thyroid transcription factor 1 (TTF‐1) mutants revealed that none of them retain the activity as a transcriptional factor. Histologically, invasive mucinous adenocarcinomas accounted for most of the NKX2‐1/TTF‐1 mutations (five cases), as well as one enteric and one acinar adenocarcinoma. Immunohistochemistry showed that the cohort was largely divided into TTF‐1‐postive/hepatocyte nuclear factor 4‐α (HNF4‐α)‐negative and TTF‐1‐negative/HNF4‐α‐positive groups. NKX2‐1/TTF‐1 mutations were exclusively found in the latter, in which the gastrointestinal markers, mucin 5AC and cytokeratin 20, were frequently expressed. Bisulfite sequencing revealed that the NKX2‐1/TTF‐1 gene body was highly methylated in NKX2‐1/TTF‐1‐negative cases, including those without the NKX2‐1/TTF‐1 mutations. The genetic or epigenetic inactivation of NKX2‐1/TTF‐1 may play an essential role in the development and aberrant differentiation of non‐TRU‐type lung adenocarcinomas.

CONGESTIVE HEART FAILURE SECONDARY TO A TSH-SECRETING PITUITARY ADENOMA AGGRAVATED BY TAKOTSUBO CARDIOMYOPATHY IN AN ELDERLY PATIENT

ABSTRACT Objective: To review a case of congestive heart failure (CHF) due to a thyroid-stimulating hormone (TSH)-secreting pituitary adenoma (TSH-oma) concomitant with Takotsubo cardiomyopathy in an elderly patient. Methods: We describe the clinical course, laboratory data, imaging studies, and management of the patient and provide a brief literature review regarding Takotsubo cardiomyopathy associated with hyperthyroidism. Results: A 76-year-old woman was admitted to our hospital for CHF treatment. Chest X-ray and electrocardiogram (ECG) showed cardiomegaly and broad T-wave inversion, respectively. Furthermore, left ventricular angiogram and subsequent coronary angiogram showed mild hypokinesis of the apex, without signs of obstructive coronary disease. Pulmonary hypertension was determined through right-heart catheterization. Accordingly, we clinically diagnosed this patient with Takotsubo cardiomyopathy complicated with pulmonary hypertension. Administration of β-blockers and angiotensin-receptor bloc...