High frequency of loss of heterozygosity for 1p35-p36 (D1S247) in Wilms tumor

Genetic variation frequencies in Wilms' tumor: A meta-analysis and systematic review

Over the last few decades, numerous biomarkers in Wilms' tumor have been confirmed and shown variations in prevalence. Most of these studies were based on small sample sizes. We carried out a meta-analysis of the research published from 1992 to 2015 to obtain more precise and comprehensive outcomes for genetic tests. In the present study, 70 out of 5175 published reports were eligible for the meta-analysis, which was carried out using Stata 12.0 software. Pooled prevalence for gene mutations WT1, WTX, CTNNB1, TP53, MYCN, DROSHA, and DGCR8 was 0.141 (0.104, 0.178), 0.147 (0.110, 0.184), 0.140 (0.100, 0.190), 0.410 (0.214, 0.605), 0.071 (0.041, 0.100), 0.082 (0.048, 0.116), and 0.036 (0.026, 0.046), respectively. Pooled prevalence of loss of heterozygosity at 1p, 11p, 11q, 16q, and 22q was 0.109 (0.084, 0.133), 0.334 (0.295, 0.373), 0.199 (0.146, 0.252), 0.151 (0.129, 0.172), and 0.148 (0.108, 0.189), respectively. Pooled prevalence of 1q and chromosome 12 gain was 0.218 (0.161, 0.275) and 0.273 (0.195, 0.350), respectively. The limited prevalence of currently known genetic alterations in Wilms' tumors indicates that significant drivers of initiation and progression remain to be discovered. Subgroup analyses indicated that ethnicity may be one of the sources of heterogeneity. However, in meta-regression analyses, no study-level characteristics of indicators were found to be significant. In addition, the findings of our sensitivity analysis and possible publication bias remind us to interpret results with caution.

Allele loss at 16q defines poorer prognosis Wilms tumour irrespective of treatment approach in the UKW1-3 clinical trials: a Children's Cancer and Leukaemia Group (CCLG) Study

Survival from Wilms tumour is excellent. Hence, better markers are required to restrict treatments causing late sequelae to those at highest risk of relapse. We investigated the prognostic significance of loss of heterozygosity (LOH) on 1p and 16q in 426 favourable histology Wilms tumours treated with either immediate nephrectomy (63%) or preoperative chemotherapy (37%). Four years RFS and OS were 84.6% and 92.0%, respectively. 10.3% tumours had LOH 1p, 14.6% LOH 16q, with 2.6% at both loci. In multivariate analysis, LOH 16q was associated with an increased risk of relapse (hazard ratio (HR) 2.69, 95%CI: 1.47-4.92) and death (HR 2.67, 95%CI: 1.17-6.06). LOH 1p showed no significant associations. These results were not influenced by treatment approach. LOH 16q is an adverse risk factor in favourable histology Wilms tumour, regardless of initial approach to therapy. Its relationship with histological risk groups defined after neo-adjuvant chemotherapy requires analysis in a larger series, and is the subject of the current SIOP WT 2001 trial.

Wilms' tumour: a complex enigma to decipher

Wilms' tumour (WT) is the most common solid tumour of childhood. The molecular signalling pathways determining the origin and behaviour of WT are very complex and several genes in several loci may participate. This review tries to briefly compile recent works on the histology and on the molecular alterations that promote the genesis, development and behaviour of WT. Some molecular alterations seem to be associated with specific histological types and particular clinical outcomes, suggesting that they might be utilised to determine the prognosis and to identify poor prognostic subgroups that can be targeted for more individualised treatments.

Genome-wide loss of heterozygosity analysis of WT1-wild-type and WT1-mutant Wilms tumors

Wilms tumor (WT) is genetically heterogeneous, and the one known WT gene, WT1 at 11p13, is altered in only a subset of WTs. Previous loss of heterozygosity (LOH) analyses have revealed the existence of additional putative WT genes at 11p15, 16q, and 1p, but these analyses examined only one or a handful of chromosomes or looked at LOH at only a few markers per chromosome. We conducted a genome-wide scan for LOH in WT by using 420 markers spaced at an average of 10 cM throughout the genome and analyzed the data for two genetically defined subsets of WTs: those with mutations in WT1 and those with no detectable WT1 alteration. Our findings indicated that the incidence of LOH throughout the genome was significantly lower in our group of WTs with WT1 mutations. In WT1-wild-type tumors, we observed the expected LOH at 11p, 16q, and 1p, and, in addition, we localized a previously unobserved region of LOH at 9q. Using additional 9q markers within this region of interest, we sublocalized the region of 9q LOH to the 12.2 Mb between D9S283 and a simple tandem repeat in BAC RP11-177I8, a region containing several potential tumor-suppressor genes. As a result, we have established for the first time that WT1-mutant and WT1-wild-type WTs differ significantly in their patterns of LOH throughout the genome, suggesting that the genomic regions showing LOH in WT1-wild-type tumors harbor genes whose expression is regulated by the pleiotropic effects of WT1. Our results implicate 9q22.2-q31.1 as a region containing such a gene.

A novel 1p36.2 located gene, APITD1, with tumour-suppressive properties and a putative p53-binding domain, shows low expression in neuroblastoma tumours

Neuroblastoma is characterised by a lack of TP53 mutations and no other tumour suppressor gene consistently inactivated has yet been identified in this childhood cancer form. Characterisation of a new gene, denoted APITD1, in the neuroblastoma tumour suppressor candidate region in chromosome 1p36.22 reveals that APITD1 contains a predicted TFIID-31 domain, representing the TATA box-binding protein-associated factor, TAF_II31, which is required for p53-mediated transcription activation. Two different transcripts of this gene were shown to be ubiquitously expressed, one of them with an elevated expression in foetal tissues. Primary neuroblastoma tumours of all different stages showed either very weak or no measurable APITD1 expression, contrary to the level of expression observed in neuroblastoma cell lines. A reduced pattern of expression was also observed in a set of various tumour types. APITD1 was functionally tested by adding APITD1 mRNA to neuroblastoma cells, leading to the cell growth to be reduced up to 90% compared to control cells, suggesting APITD1 to have a role in a cell death pathway. Furthermore, we determined the genomic organisation of APITD1. Automated genomic DNA sequencing of the coding region of the gene as well as the promoter sequence in 44 neuroblastoma tumours did not reveal any loss-of-function mutations, indicating that mutations in APITD1 is not a common abnormality of neuroblastoma tumours. We suggest that low expression of this gene might interfere with the ability for apoptosis through the p53 pathway.

High frequency of genomic instability in Ewing family of tumors

We tested Ewing sarcoma tumors for microsatellite instability (MSI) and loss of heterozygosity (LOH) to investigate the role of genomic instability (GI) in this sarcoma. We detected a high frequency of GI (57%), mostly on 1p and 11p, 35% and 30%, respectively. Patients with GI compared to those with stable genome had a median progression-free survival (PFS) and overall survival (OS) of 24 months and 70 months, compared with 39 and 84 months, respectively. MSI was observed in 48% (11/23) of the tumor samples. Low-MSI (L-MSI) patients (with MSI presented at only one locus) tended to have a better prognosis, 70% PFS, compared with 25% in the high-MSI (H-MSI) group (P=0.13). LOH without MSI did not correlate with progression. H-GI (MSI and/or LOH in > or =30% of tested markers) tended to associate with an adverse prognosis (P=0.28), and correlated significantly with the pelvic site of the primary tumor (P=0.02). The instability of 1p was not associated with progression, while alterations at the 11p locus tended to correlate with a more aggressive disease (P=0.18). Our data suggest that GI may play a role in Ewing sarcoma clinical behavior and outcome.

Identification of TDE2 gene and its expression in non-small cell lung cancer

TDE2, a gene with sequence similarity to the mouse testicular tumor-differentially-expressed (Tde1/MUSTETU) gene, was identified by serial analysis of gene expression (SAGE) in nonsmall cell lung cancers (NSCLC). Here we characterized the TDE2 gene and determined its transcript levels in a panel of lung tumors, adjacent nonmalignant lung tissues and a variety of normal human tissues. In addition, we show that TDE2 is a potential transmembrane protein with 11 putative transmembrane helices. Using real-time quantitative PCR, we showed that TDE2 transcript levels were higher in NSCLC compared to nonmalignant samples. In nonpulmonary normal tissues, the level of TDE2 was the highest in bladder, kidney and muscle; moderate to low in stomach, liver, skin, placenta and ovary tissues; and undetectable in brain, spleen and heart. By in situ hybridization, we showed that 10 of 18 lung tumors and only 1 of 14 adjacent nonmalignant regions had high levels of TDE2 transcripts. Alternatively, only 2 of 18 tumors and 8 of 14 adjacent nonmalignant bronchiole epithelium regions demonstrated negative to low levels of TDE2 signals.

The Wnt signaling pathway in solid childhood tumors

The Wnt signaling pathway has long been known to direct growth and patterning during embryonic development. Recent evidence also implicates this pathway in the development of childhood tumors of the liver, the kidney, the brain, and the pancreas. Here, we review the current evidence on how constitutive activation of the Wnt signaling pathway may occur in hepato-, nephro-, medullo- and pancreatoblastomas. With particular emphasis the mutational activation of CTNNB1, an emerging major oncogene in solid childhood tumors, is discussed.

Molecular analysis of region t(5;6)(q21;q21) in Wilms tumor

We have previously described the physical localization of a constitutional t(5;6)(q21;q21) in a patient (tumor cell sample designated as MA214) with bilateral Wilms tumor (WT). We have now physically refined the breakpoints and identified putative gene targets within this region. The translocation breakpoints are contained within a 2.5-Mbp region on 5q21 containing four candidate genes and a 1.3-Mbp region on 6q21 that contains three candidate genes. To explore the role of this region in WT genesis, we have performed loss of heterozygosity (LOH) analysis with markers flanking the translocation breakpoints in tumor from MA214 and a panel of sporadic WT. Alleles were retained for all informative markers used in the MA214 tumor. In sporadic tumors LOH was found in 6 of 63 (9.5%) and 5 of 62 (8%) informative cases for flanking markers D6S301 and D6S1592 on 6q21. LOH was found in 3 of 58 (5.2%) and 2 of 54 (3.6%) for flanking markers D5S495 and D5S409 on 5q21. These preliminary data suggest LOH at the t(5;6)(q21;q21) region is unlikely to be a mechanism for tumor development in MA214, but may be important for a subgroup of sporadic WT.

Renal cancer: cytogenetic and molecular genetic aspects

To date, much progress has been made in the fields of cytogenetics and molecular genetics of renal tumors. The previous and recent findings have delineated the characteristics of the various tumors, particularly the cytogenetic and molecular differences that exist between papillary and nonpapillary clear cell renal cell carcinomas (RCCs). At the same time, new cytogenetic subtypes have emerged [e.g., t(X;1)] in subtypes of RCC, while in others (e.g., Wilms tumors) several new cytogenetic abnormalities and consequent molecular involvement have been found. In addition to Wilms tumor, papillary RCC, and clear-cell RCC, cytogenetic and fluorescence in situ hybridization analyses have been performed on several other tumors of the kidney, including chromophobic carcinoma, metanephric adenoma, collecting duct carcinoma, transitional cell carcinoma, congenital mesoblastic nephroma, and malignant rhabdoid tumors of the kidney. This review is therefore intended to present a concise update on the cytogenetic and molecular data on renal tumors, focusing mainly on the clinical usefulness of the findings reported in the literature.

Loss of heterozygosity of chromosome 16q in gallbladder carcinoma

BACKGROUND

The present study was planned to investigate cumulative genetic changes during development and progression of gallbladder carcinoma (GBC) in clinical patients.

MATERIALS AND METHODS

We examined GBC DNA from resected tissue isolated from 56 cases of GBC for loss of heterozygosity (LOH) at six loci on five chromosomal arms (1p36, 9p21, 13q14, 16q24, 17p13), using highly polymorphic microsatellite markers.

RESULTS

High incidences of LOH at 1p36 (19/36: 53%), 9p21 (12/32: 38%), 13q14 (20/36: 56%), 16q24 (31/54: 61%), and 17p13 (15/36: 42%) were detected. When comparing genetic features with clinicopathological stages of these tumors, it appeared that only LOH at 16q24 had a high incidence (5/6: 83%) at an early stage (T1a: tumor invades lamina propria) of the disease, although large numbers of LOH were found on all chromosomal arms in tumors of more advanced stages (T1b, T2, T3, and T4).

CONCLUSION

These results suggested that the putative tumor suppressor gene on 16q24 may be strongly related to an early step of carcinogenesis in GBC and that GBC acquires a high malignant potential when the tumor invades the muscle layer.

Cytogenetic abnormalities and clinical outcome in Wilms tumor: a study by the U.K. cancer cytogenetics group and the U.K. Children's Cancer Study Group

BACKGROUND

Tumor genetic features reported to correlate with adverse outcome in Wilms tumor include karyotype complexity, losses of material from the short arm of chromosome 1 and from the long arms of chromosomes 11, 16 and 22 and gain of material from the long arm of chromosome 1. This study sought to test these associations in a large series of tumors studied by cytogenetic analysis. Identification of markers associated with elevated risk of relapse and fatal outcome could allow more effective treatment stratification at presentation.

PROCEDURE

Thirteen member laboratories of the U.K. Cancer Cytogenetics Group provided results from a 12-year period. Karyotype abnormalities were correlated with clinical data (age, tumor stage, and histology) and outcome data provided by the central register of the U.K. Children's Cancer Study Group.

RESULTS

Of 127 abnormal karyotypes, 78 included a reputedly "poor prognosis" feature. Univariate survival analysis showed no significant adverse effect for karyotype complexity, 1p loss or 11q loss. The poor outcome of cases with 16q loss was of borderline significance, but this effect was restricted to those tumors with unbalanced translocation der(16)t(1q;16q). The association between relapse risk and gain of 1q material was not significant. Only monosomy 22 was a significant marker of poor outcome in univariate analysis (13 cases showing 50% relapse free survival at 5 years compared to 79% survival for the remaining 114 cases, P = 0.02). In multivariate analysis, significant independent predictors of poor outcome were 1q gain (Hazard Ratio 3.4), stage IV disease (HR 5.0), and monosomy 22 (HR 5.9).

CONCLUSIONS

Loss of chromosome 22 identifies high risk Wilms tumors. The prognostic significance of 1q gain, 16q loss and unbalanced translocation der(16)t(1q;16q) is unresolved and warrants further investigation.

p29, a novel GCIP-interacting protein, localizes in the nucleus

GCIP, a newly identified cyclin D-interacting protein, was found to reduce the phosphorylation of retinoblastoma protein and inhibit E2F1-mediated transcriptional activity. To explore more GCIP interacting proteins, the yeast two-hybrid screening using GCIP as a bait protein was performed. One novel gene, p29, was demonstrated to associate with GCIP in the yeast two-hybrid method and in vitro GST pull-down assay. Multiple tissue Northern blot analysis showed that p29 was abundantly expressed in the heart, skeletal muscle, and kidney relative to other tissues. The transient expression of HA-tagged p29 in HeLa cells localized in the nucleus. Taken together, we have isolated a novel protein, p29, which may be involved in the functional regulation of GCIP.