Evolutionary mode and timing of dissemination of high-grade serous carcinomas.

Dissemination within the peritoneal cavity is a main determinant of poor patient outcomes from high-grade serous carcinomas (HGSCs). The dissemination process is poorly understood from a cancer evolutionary perspective. We reconstructed the evolutionary trajectories across a median of 5 tumor sites and regions from each of 23 patients based on deep whole-exome sequencing. Polyclonal cancer origin was detected in 1 patient. Ovarian tumors had more complex subclonal architectures than other intraperitoneal tumors in each patient, which indicated that tumors developed earlier in the ovaries. Three common modes of dissemination were identified, including monoclonal or polyclonal dissemination of monophyletic (linear) or polyphyletic (branched) subclones. Mutation profiles of initial or disseminated clones varied greatly among cancers, but recurrent mutations were found in 7 cancer-critical genes, including TP53, BRCA1, BRCA2, and DNMT3A, and in the PI3K/AKT1 pathway. Disseminated clones developed late in the evolutionary trajectory models of most cancers, in particular in cancers with DNA damage repair deficiency. Polyclonal dissemination was predicted to occur predominantly as a single and rapid wave, but chemotherapy exposure was associated with higher genomic diversity of disseminated clones. In conclusion, we described three common evolutionary dissemination modes across HGSCs and proposed factors associated with dissemination diversity.

Frequent copy number gains of SLC2A3 and ETV1 in testicular embryonal carcinomas.

Testicular germ cell tumours (TGCTs) appear as different histological subtypes or mixtures of these. They show similar, multiple DNA copy number changes, where gain of 12p is pathognomonic. However, few high-resolution analyses have been performed and focal DNA copy number changes with corresponding candidate target genes remain poorly described for individual subtypes. We present the first high-resolution DNA copy number aberration (CNA) analysis on the subtype embryonal carcinomas (ECs), including 13 primary ECs and 5 EC cell lines. We identified recurrent gains and losses and allele-specific CNAs. Within these regions, we nominate 30 genes that may be of interest to the EC subtype. By in silico analysis of data from 150 TGCTs from The Cancer Genome Atlas (TCGA), we further investigated CNAs, RNA expression, somatic mutations and fusion transcripts of these genes. Among primary ECs, ploidy ranged between 2.3 and 5.0, and the most common aberrations were DNA copy number gains at chromosome (arm) 7, 8, 12p, and 17, losses at 4, 10, 11, and 18, replicating known TGCT genome characteristics. Gain of whole or parts of 12p was found in all samples, including a highly amplified 100 kbp segment at 12p13.31, containing SLC2A3. Gain at 7p21, encompassing ETV1, was the second most frequent aberration. In conclusion, we present novel CNAs and the genes located within these regions, where the copy number gain of SLC2A3 and ETV1 are of interest, and which copy number levels also correlate with expression in TGCTs.

C77G in PTPRC (CD45) is no risk allele for ovarian cancer, but associated with less aggressive disease.

The pan lymphocyte marker CD45 exists in various isoforms arising from alternative splicing of the exons 4, 5 and 6. While naïve T cells express CD45RA translated from an mRNA containing exon 4, exons 4-6 are spliced out to encode the shorter CD45R0 in antigen-experienced effector/memory T cells. The SNP C77G (rs17612648) is located in exon 4 and blocks the exon's differential splicing from the pre-mRNA, enforcing expression of CD45RA. Several studies have linked C77G to autoimmune diseases but lack of validation in other cohorts has left its role elusive. An incidental finding in an ovarian cancer patient cohort from West Norway (Bergen region, n = 312), suggested that the frequency of C77G was higher among ovarian cancer patients than in healthy Norwegians (n = 1,357) (3.0% vs. 1.8% allele frequency). However, this finding could not be validated in a larger patient cohort from South-East Norway (Oslo region, n = 1,198) with 1.2% allele frequency. Hence, C77G is not associated with ovarian cancer in the Norwegian population. However, its frequency was increased in patients with FIGO stage II, endometrioid histology or an age at diagnosis of 60 years or older indicating a possible association with a less aggressive cancer type.

Exome sequencing of bilateral testicular germ cell tumors suggests independent development lineages.

Intratubular germ cell neoplasia, the precursor of testicular germ cell tumors (TGCTs), is hypothesized to arise during embryogenesis from developmentally arrested primordial germ cells (PGCs) or gonocytes. In early embryonal life, the PGCs migrate from the yolk sac to the dorsal body wall where the cell population separates before colonizing the genital ridges. However, whether the malignant transformation takes place before or after this separation is controversial. We have explored the somatic exome-wide mutational spectra of bilateral TGCT to provide novel insight into the in utero critical time frame of malignant transformation and TGCT pathogenesis. Exome sequencing was performed in five patients with bilateral TGCT (eight tumors), of these three patients in whom both tumors were available (six tumors) and two patients each with only one available tumor (two tumors). Selected loci were explored by Sanger sequencing in 71 patients with bilateral TGCT. From the exome-wide mutational spectra, no identical mutations in any of the three bilateral tumor pairs were identified. Exome sequencing of all eight tumors revealed 87 somatic non-synonymous mutations (median 10 per tumor; range 5-21), some in already known cancer genes such as CIITA, NEB, platelet-derived growth factor receptor α (PDGFRA), and WHSC1. SUPT6H was found recurrently mutated in two tumors. We suggest independent development lineages of bilateral TGCT. Thus, malignant transformation into intratubular germ cell neoplasia is likely to occur after the migration of PGCs. We reveal possible drivers of TGCT pathogenesis, such as mutated PDGFRA, potentially with therapeutic implications for TGCT patients.

Meta-analysis identifies four new loci associated with testicular germ cell tumor.

We conducted a meta-analysis to identify new susceptibility loci for testicular germ cell tumor (TGCT). In the discovery phase, we analyzed 931 affected individuals and 1,975 controls from 3 genome-wide association studies (GWAS). We conducted replication in 6 independent sample sets comprising 3,211 affected individuals and 7,591 controls. In the combined analysis, risk of TGCT was significantly associated with markers at four previously unreported loci: 4q22.2 in HPGDS (per-allele odds ratio (OR) = 1.19, 95% confidence interval (CI) = 1.12-1.26; P = 1.11 × 10(-8)), 7p22.3 in MAD1L1 (OR = 1.21, 95% CI = 1.14-1.29; P = 5.59 × 10(-9)), 16q22.3 in RFWD3 (OR = 1.26, 95% CI = 1.18-1.34; P = 5.15 × 10(-12)) and 17q22 (rs9905704: OR = 1.27, 95% CI = 1.18-1.33; P = 4.32 × 10(-13) and rs7221274: OR = 1.20, 95% CI = 1.12-1.28; P = 4.04 × 10(-9)), a locus that includes TEX14, RAD51C and PPM1E. These new TGCT susceptibility loci contain biologically plausible genes encoding proteins important for male germ cell development, chromosomal segregation and the DNA damage response.

Functional glutathione S-transferase genotypes among testicular germ cell tumor survivors: associations with primary and post-chemotherapy tumor histology.

PURPOSE: The pathogenesis of testicular germ cell tumor (TGCT) remains unknown. The aim of this study was to evaluate the pathogenic role of functional polymorphisms in detoxification enzymes among TGCT patients, through association studies of constitutive genotypes and medical parameters before and after chemotherapy. EXPERIMENTAL DESIGN: Germline deletion polymorphisms in the glutathione S-transferase mu 1 (GSTM1) and the GST theta 1 (GSTT1), and a functional single nucleotide polymorphism in GST pi 1 (GSTP1, Ile105Val), were analyzed in TGCT survivors (TCSs) (n = 675) and controls (n = 189). Statistical analyses were performed for the genotype distributions between the TCSs and control populations, and between the genotypes and clinicopathological parameters of the TCSs. RESULTS: The GST genotypes showed comparable distributions among the TCSs and the control population. However, the genotype combination GSTT1positive/GSTP1-GG or GSTP1-AG/GSTM1positive was more frequent among the TCSs [P = 0.050, odds ratio (OR): 1.47, 95% confidence interval (CI): 0.998-2.165]. The combined genotype GSTT1positive/GSTP1AA/GSTM1positive was associated with decreased risk of development of pure embryonal carcinoma (P = 0.009, OR: 0.309, 95% CI: 0.122-0.784) and the GSTP1-A-allele (i.e. genotypes GSTP-AA or GSTP-AG) was also associated with decreased risk for development of pure teratoma (P = 0.032, OR: 0.326, 95% CI: 0.122-0.873). Furthermore, the GSTP1-A-allele was overrepresented within the 'good prognosis group' (P = 0.032, OR: 2.407, 95% CI: 1.060-5.469), whereas the GSTM1nulltype was associated with the extent of TC qualifying as 'poor prognosis group' (P = 0.025, OR: 2.839, 95% CI: 1.104-7.301). The GSTP1-AG genotype was associated with necrosis in the tumor's post-chemotherapy histology (P = 0.001, OR: 16.087, 95% CI: 1.930-134.087). Failure, after platinum-based chemotherapy, was associated with the GSTT1positive/GSTP-AA or GSTP-GG/GSTM1-positive genotype (P = 0.019, OR: 2.168, 95% CI: 1.130-4.160). CONCLUSION: This study confirms an association between the GSTP1-G-allele and TGCT. Combinations of GST genotypes were associated with primary and post-chemotherapy tumor histology, and prognostic group presentation.

Association between long-term neuro-toxicities in testicular cancer survivors and polymorphisms in glutathione-s-transferase-P1 and -M1, a retrospective cross sectional study.

BACKGROUND: To assess the impact of polymorphisms in Glutathione S-transferase (GST) -P1, -M1, and -T1 on self-reported chemotherapy-induced long-term toxicities in testicular cancer survivors (TCSs). METHODS: A total of 238 TCSs, who had received cisplatin-based chemotherapy at median twelve years earlier, had participated in a long-term follow-up survey which assessed the prevalence of self-reported paresthesias in fingers/toes, Raynaud-like phenomena in fingers/toes, tinnitus, and hearing impairment. From all TCSs lymphocyte-derived DNA was analyzed for the functional A-->G polymorphism at bp 304 in GSTP1, and deletions in GST-M1 and GST-T1. Evaluation of associations between GST polymorphisms and self-reported toxicities included adjustment for prior treatment. RESULTS: All six evaluated toxicities were significantly associated with the cumulative dose of cisplatin and/or bleomycin. Compared to TCSs with either GSTP1-AG or GSTP1-AA, the 37 TCSs with the genotype GSTP1-GG, were significantly less bothered by paresthesias in fingers and toes (p = 0.039, OR 0.46 [0.22-0.96] and p = 0.023, OR 0.42 [0.20-0.88], respectively), and tinnitus (p = 0.008, OR 0.33 [0.14-0.74]). Furthermore, absence of functional GSTM1 protected against hearing impairment (p = 0.025, OR 1.81 [1.08-3.03]). CONCLUSION: In TCSs long-term self-reported chemotherapy-induced toxicities are associated with functional polymorphisms in GSTP1 and GSTM1. Hypothetically, absence of GST-M1 leaves more glutathione as substrate for the co-expressed GST-P1. Also intracellular inactivation of pro-apoptotic mediators represents a possible explanation of our findings. Genotyping of these GSTs might be a welcomed step towards a more individualized treatment of patients with metastatic testicular cancer.

Ovarian dysgerminomas are characterised by frequent KIT mutations and abundant expression of pluripotency markers.

BACKGROUND: Ovarian germ cell tumours (OGCTs) typically arise in young females and their pathogenesis remains poorly understood. We investigated the origin of malignant OGCTs and underlying molecular events in the development of the various histological subtypes of this neoplasia. RESULTS: We examined in situ expression of stem cell-related (NANOG, OCT-3/4, KIT, AP-2gamma) and germ cell-specific proteins (MAGE-A4, NY-ESO-1, TSPY) using a tissue microarray consisting of 60 OGCT tissue samples and eight ovarian small cell carcinoma samples. Developmental pattern of expression of NANOG, TSPY, NY-ESO-1 and MAGE-A4 was determined in foetal ovaries (gestational weeks 13-40). The molecular genetic part of our study included search for the presence of Y-chromosome material by fluorescence in situ hybridisation (FISH), and mutational analysis of the KIT oncogene (exon 17, codon 816), which is often mutated in testicular GCTs, in a subset of tumour DNA samples. We detected a high expression of transcription factors related to the embryonic stem cell-like pluripotency and undifferentiated state in OGCTs, but not in small cell carcinomas, supporting the view that the latter do not arise from a germ cell progenitor. Bilateral OGCTs expressed more stem cell markers than unilateral cases. However, KIT was mutated in 5/13 unilateral dysgerminomas, whereas all bilateral dysgerminomas (n = 4) and all other histological types (n = 22) showed a wild type sequence. Furthermore, tissue from five phenotypic female patients harbouring combined dysgerminoma/gonadoblastoma expressed TSPY and contained Y-chromosome material as confirmed by FISH. CONCLUSION: This study provides new data supporting two distinct but overlapping pathways in OGCT development; one involving spontaneous KIT mutation(s) leading to increased survival and proliferation of undifferentiated oogonia, the other related to presence of Y chromosome material and ensuing gonadal dysgenesis in phenotypic females.

Cisplatin-induced long-term hearing impairment is associated with specific glutathione s-transferase genotypes in testicular cancer survivors.

PURPOSE: Cisplatin, a cornerstone of combination chemotherapy in the treatment of testicular cancer, induces hearing impairment with considerable interindividual variations. These differences might be a result of functional polymorphisms in cisplatin-detoxifying enzymes like glutathione S-transferases (GSTs). PATIENTS AND METHODS: We identified 173 cisplatin-treated testicular cancer survivors (TCSs) who had participated in a long-term survey that included audiometric testing and lymphocyte sampling. The hearing decibel thresholds at 4,000 Hz were categorized into leveled scales by normative decibel percentiles. Known functional polymorphisms (positive or negative) in GSTT1 and GSTM1 and codon 105 A/G (Ile/Val) in GSTP1 were analyzed by multiplex polymerase chain reaction, followed by restriction enzyme cutting, and separated by gel electrophoresis. RESULTS: The risk of having an inferior audiometric result was more than four times higher in TCSs with 105Ile/105Ile-GSTP1 or 105Val/105Ile-GSTP1 compared with 105Val/105Val-GSTP1 (odds ratio [OR] = 4.21; 95% CI, 1.99 to 8.88; P < .001 when modeled by ordinal logistic regression [OLR]). GSTM1 positivity was detrimental for hearing ability. Two combined genotypes were associated with hearing ability. The presence of pattern 1 (GSTT1 positive, GSTM1 positive, and 105Ile/105Ile-GSTP1) was associated with hearing impairment (OR = 2.76; 95% CI, 1.35 to 5.64; P = .005, OLR). TCSs with pattern 2 (GSTT1 positive, GSTM1 positive, and 105Val/105Val-GSTP1) had better hearing ability than TCSs without this pattern (OR = 5.35; 95% CI, 2.25 to 12.76; P < .001, OLR). CONCLUSION: The presence of both alleles of 105Val-GSTP1 offered protection against cisplatin-induced hearing impairment. Two genotype patterns with good and poor protection against cisplatin-induced ototoxicity were identified.

Novel genomic aberrations in testicular germ cell tumors by array-CGH, and associated gene expression changes.

INTRODUCTION: Testicular germ cell tumors of adolescent and young adult men (TGCTs) generally have near triploid and complex karyotypes. The actual genes driving the tumorigenesis remain essentially to be identified. MATERIALS AND METHODS: To determine the detailed DNA copy number changes, and investigate their impact on gene expression levels, we performed an integrated microarray profiling of TGCT genomes and transcriptomes. We analyzed 17 TGCTs, three precursor lesions, and the embryonal carcinoma cell lines, NTERA2 and 2102Ep, by comparative genomic hybridization microarrays (array-CGH), and integrated the data with transcriptome profiles of the same samples. RESULTS: The gain of chromosome arm 12p was, as expected, the most common aberration, and we found CCND2, CD9, GAPD, GDF3, NANOG, and TEAD4 to be the therein most highly over-expressed genes. Additional frequent genomic aberrations revealed some shorter chromosomal segments, which are novel to TGCT, as well as known aberrations for which we here refined boundaries. These include gains from 7p15.2 and 21q22.2, and losses of 4p16.3 and 22q13.3. Integration of DNA copy number information to gene expression profiles identified that BRCC3, FOS, MLLT11, NES, and RAC1 may act as novel oncogenes in TGCT. Similarly, DDX26, ERCC5, FZD4, NME4, OPTN, and RB1 were both lost and under-expressed genes, and are thus putative TGCT suppressor genes. CONCLUSION: This first genome-wide integrated array-CGH and gene expression profiling of TGCT provides novel insights into the genome biology underlying testicular tumorigenesis.

Lack of parental origin specificity of altered alleles at 11p15 in testicular germ cell tumors.

Allelic imbalance (AI) at loci on chromosome 11 has been shown in several types of human solid tumors, including testicular germ cell tumors (TGCTs). In this study we have focused on the 11p15 region, which is known for its high density of imprinted genes. Highly polymorphic microsatellite markers were analyzed in a series of 71 TGCTs, and AI was observed in 28 of the tumors (39%) at one or more of the loci analyzed. The AI data were evaluated against the chromosome 11 copy number, determined by fluorescence in situ hybridization with a centromere-specific probe. To evaluate preferential parental allele alterations, the patients' normal and tumor genotypes were compared with the parental genotypes. Both losses and gains of both paternal and maternal alleles were found, and this lack of parental origin specificity of the altered allele suggests that the remaining allele is not inactivated by imprinting. A smallest region of overlapping changes was identified between the markers D11S2351 and D11S2347. In summary, our results support the theory that a nonimprinted 11p15 tumor suppressor gene is involved in the development of a subgroup of TGCTs.

Distinct epigenetic phenotypes in seminomatous and nonseminomatous testicular germ cell tumors.

The genetic nature of testicular germ cell tumors and the molecular mechanisms underlying the morphological and clinical differences between the two subtypes, seminomas and nonseminomas, remains unclear. Genetic studies show that both subtypes exhibit many of the same regional genomic disruptions, although the frequencies vary and few clear differences are found. We demonstrate significant epigenetic differences between seminomas and nonseminomas by restriction landmark genomic scanning. Seminomas show almost no CpG island methylation, in contrast to nonseminomas that show CpG island methylation at a level similar to other solid tumors. We find an average of 1.11% of CpG islands methylation in nonseminomas, but only 0.08% methylated in seminomas. Furthermore, we demonstrate that seminomas are more highly hypomethylated than nonseminomas throughout their genome. Since both subtypes are thought to arise from primordial germ cells, the epigenetic differences seen between these subtypes may reflect the normal developmental switch in primordial germ cells from an undermethylated genome to a normally methylated genome. We discuss these findings in relation to different developmental models for seminomatous and nonseminomatous testicular germ cell tumors.

Genome profiling of breast cancer cells selected against in vitro shows copy number changes.

About 20% of breast carcinomas show no clonal chromosome abnormalities when analyzed after short-term culturing. An interesting question is whether this subset of breast carcinomas really is karyotypically normal or if selection for normal cells occurred in vitro. To address this issue, 26 breast carcinomas that had shown no cytogenetic changes by chromosome banding analysis were examined by comparative genomic hybridization (CGH), a technique that does not require culturing or tumor metaphase cells. All but one case showed copy number changes by CGH (median, four). A comparison of these findings with those of a karyotypically abnormal series analyzed using the same CGH protocol found that the cytogenetically "normal" cases were typically genetically less complex (median, four and eight, respectively; P = 0.0058). Although largely the same alterations were found in both series, some differences with respect to the frequencies of specific imbalances were seen. Gains of 3p and 6q and losses of 10q, 14q, and 17p more often were found in the cytogenetically abnormal series than in the normal tumors. We conclude that in most instances cells found to be normal by chromosome banding analysis after short-term culture do not belong to the tumor parenchyma. Furthermore, when we compared the distribution of the number of imbalances detected by CGH in the total data set according to the mitotic index in vivo (scored from 1 to 3), the median values were three, seven, and 18, respectively (P < 0.001). These data indicate not only that karyotypically normal breast carcinomas may represent a genetically simpler subgroup that grows poorly in vitro but also that this subset of tumors already has a slow growth rate in vivo.