Molecular analysis distinguishes metastatic disease from second cancers in patients with retinoblastoma.

The pediatric ocular tumor retinoblastoma readily metastasizes, but these lesions can masquerade as histologically similar pediatric small round blue cell tumors. Since 98% of retinoblastomas have RB1 mutations and a characteristic genomic copy number "signature", genetic analysis is an appealing adjunct to histopathology to distinguish retinoblastoma metastasis from second primary cancer in retinoblastoma patients. Here, we describe such an approach in two retinoblastoma cases. In patient one, allele-specific (AS)-PCR for a somatic nonsense mutation confirmed that a temple mass was metastatic retinoblastoma. In a second patient, a rib mass shared somatic copy number gains and losses with the primary tumor. For definitive diagnosis, however, an RB1 mutation was needed, but heterozygous promoter→exon 11 deletion was the only RB1 mutation detected in the primary tumor. We used a novel application of inverse PCR to identify the deletion breakpoint. Subsequently, AS-PCR designed for the breakpoint confirmed that the rib mass was metastatic retinoblastoma. These cases demonstrate that personalized molecular testing can confirm retinoblastoma metastases and rule out a second primary cancer, thereby helping to direct the clinical management.

Characterisation of retinoblastomas without RB1 mutations: genomic, gene expression, and clinical studies.

BACKGROUND: Retinoblastoma is the childhood retinal cancer that defined tumour-suppressor genes. Previous work shows that mutation of both alleles of the RB1 retinoblastoma suppressor gene initiates disease. We aimed to characterise non-familial retinoblastoma tumours with no detectable RB1 mutations. METHODS: Of 1068 unilateral non-familial retinoblastoma tumours, we compared those with no evidence of RB1 mutations (RB1(+/+)) with tumours carrying a mutation in both alleles (RB1(-/-)). We analysed genomic copy number, RB1 gene expression and protein function, retinal gene expression, histological features, and clinical data. FINDINGS: No RB1 mutations (RB1(+/+)) were reported in 29 (2·7%) of 1068 unilateral retinoblastoma tumours. 15 of the 29 RB1(+/+) tumours had high-level MYCN oncogene amplification (28-121 copies; RB1(+/+)MYCN(A)), whereas none of 93 RB1(-/-) primary tumours tested showed MYCN amplification (p<0·0001). RB1(+/+)MYCN(A) tumours expressed functional RB1 protein, had fewer overall genomic copy-number changes in genes characteristic of retinoblastoma than did RB1(-/-) tumours, and showed distinct aggressive histological features. MYCN amplification was the sole copy-number change in one RB1(+/+)MYCN(A) retinoblastoma. One additional MYCN(A) tumour was discovered after the initial frequencies were determined, and this is included in further analyses. Median age at diagnosis of the 17 children with RB1(+/+)MYCN(A) tumours was 4·5 months (IQR 3·5-10), compared with 24 months (15-37) for 79 children with non-familial unilateral RB1(-/-) retinoblastoma. INTERPRETATION: Amplification of the MYCN oncogene might initiate retinoblastoma in the presence of non-mutated RB1 genes. These unilateral RB1(+/+)MYCN(A) retinoblastomas are characterised by distinct histological features, only a few of the genomic copy-number changes that are characteristic of retinoblastoma, and very early age of diagnosis. FUNDING: National Cancer Institute-National Institutes of Health, Canadian Institutes of Health Research, German Research Foundation, Canadian Retinoblastoma Society, Hyland Foundation, Toronto Netralaya and Doctors Lions Clubs, Ontario Ministry of Health and Long Term Care, UK-Essen, and Foundations Avanti-STR and KiKa.

Needle core biopsies provide ample material for genomic and proteomic studies of kidney cancer: observations on DNA, RNA, protein extractions and VHL mutation detection.

The use of needle biopsies in basic research is increasing, and our study provides a comprehensive analysis of their adequacy in genomic and proteomic studies of kidney cancer. Frozen clear cell renal cell carcinoma (ccRCC) needle core biopsies and sections from core biopsies embedded in optimal cutting temperature (OCT) compound were used to extract DNA, RNA and protein. Their integrity was determined using genomic and proteomic analyses. VHL mutation testing was performed on ccRCC biopsies and corresponding tumors using bulk and laser capture microdissection (LCM) extractions for comparison. Adequate amounts of good quality DNA (5.8-13.3 µg/whole core, 0.6-2.7 µg/20 sections), RNA (2.9-11.9 µg/whole core, 0.5-1.3 µg/20 sections) and protein (137.4-444 µg/whole core, 39.9-74.1 µg/20 sections) were obtained from whole core and frozen sections of ccRCC needle biopsies, respectively. We observed VHL sequence mutations in 75% of ccRCC tumors and, in most cases, the same mutations were detected in both tumors and corresponding biopsies. Mutations observed by bulk extractions from tumors and biopsies were also detected by LCM without significant differences between both methodologies. ccRCC needle biopsies provide ample material for genomic and proteomic studies of kidney cancer. They are good representatives of their corresponding tumors for VHL mutation detection using both bulk and LCM extractions. LCM does not increase sensitivity of VHL mutation detection.

Identification of clinically relevant mosaicism in type I hereditary haemorrhagic telangiectasia.

BACKGROUND: Hereditary haemorrhagic telangiectasia (HHT) is an autosomal dominant genetic disorder affecting the vascular system, characterised by epistaxis, arteriovenous malformations and mucocutaneous and gastrointestinal telangiectases. Mutations in two genes, ENG and ACVRL1, account for the majority of cases. Almost all cases of HHT show a family history of HHT-associated symptoms; few cases are de novo. Mutational mosaicism is the presence of two populations of cells, with both mutant and normal genotypes in one individual and generally occurs through de novo mutation events in embryogenesis. Some isolated cases of HHT with no detectable ENG or ACVRL1 mutation may be caused by a mosaic ENG or ACVRL1 mutation that is present at levels below the limit of detection of current molecular screening methods. OBJECTIVE: To identify clinically relevant mosaicism in type I HHT. METHODS: Sequencing, quantitative multiplex-PCR and marker analysis were used to identify three HHT families with founders who showed mosaicism for endoglin mutations. Where available, mosaicism was verified by testing different sampling sites, including blood, hair and buccal swabs. RESULTS: All three mosaic samples exhibited the mutation in an estimated ≤ 25% of the DNA. Two of the mosaic patients had clinically confirmed HHT by the Curaçao criteria and the other showed symptoms of HHT. In each case the heterozygous mutation had already been identified in another family member before detection in the mosaic founder. CONCLUSIONS: The results show the importance of investigating patients without prior family history for the presence of mutational mosaicism, as detecting this would enable appropriate genetic screening and targeted medical care for at-risk children of mosaic patients.

Using RB1 mutations to assess minimal residual disease in metastatic retinoblastoma.

To assess complete remission before subjecting nongermline metastatic retinoblastoma patients to an autologous peripheral stem cell transplant, we tested for patient-specific retinoblastoma tumor suppressor gene (RB1) mutant alleles in cerebrospinal fluid (CSF) and bone marrow. In 1 child with CSF and 1 with bone marrow metastases, allele-specific polymerase chain reaction (AS-PCR) detected the biallelic RB1 mutations specific to their tumors. The tumor of Child A was homozygous for R251X, and in Child B, it was homozygous for R358X. In Child A, the R251X mutation was detected in mutant controls diluted to 1:12,800 but not in CSF samples, corroborating clinical remission after chemotherapy. In Child B's bone marrow, AS-PCR for R358X was strongly positive at the detection of relapse, and subsequent bone marrow samples corroborated clinical remission after chemotherapy. No mutant tumor RB1 alleles were detected in their harvested peripheral blood stem cells. Both children were deemed suitable candidates for supralethal-dosage consolidation chemotherapy followed by autologous peripheral stem cell rescue of the bone marrow aimed at curing their metastatic retinoblastoma. When Child A recurred, the mutant tumor RB1 allele was detected 3.5 months before conventional pathology detected retinoblastoma tumor cells in the CSF. Assaying tumor-specific RB1 mutations complements cytological and immunohistochemical assessment of retinoblastoma involvement of CSF and bone marrow. Tumor cells can be detected in numbers lower than possible by conventional methods. An early diagnosis of relapse may allow an early institution of new therapy. A prospective international multicenter trial of the rare patients with metastatic retinoblastoma would assess the role of molecular monitoring in surveillance for minimal residual disease and recurrence.

Detection of mosaic RB1 mutations in families with retinoblastoma.

The RB1 gene mutation detection rate in 1,020 retinoblastoma families was increased by the use of highly sensitive allele specific-PCR (AS-PCR) to detect low-level mosaicism for 11 recurrent RB1 CGA>TGA nonsense mutations. For bilaterally affected probands, AS-PCR increased the RB1 mutation detection sensitivity from 92.6% to 94.8%. Both RB1 oncogenic changes were detected in 92.7% of sporadic unilateral tumors (357/385); 14.6% (52/357) of unilateral probands with both tumor mutations identified carried one of the tumor mutations in blood. Mosaicism was evident in 5.5% of bilateral probands (23 of 421), in 3.8% of unilateral probands (22 of 572), and in one unaffected mother of a unilateral proband. Half of the mosaic mutations were only detectable by AS-PCR for the 11 recurrent CGA>TGA mutations, and not by standard sequencing. This suggests that significant numbers of low-level mosaics with other classes of RB1 mutations remain unidentified by current technology. We show that the use of linkage analysis in a two-generation retinoblastoma family resulted in the erroneous conclusion that a child carried the parental mutation, because the founder parent was mosaic for the RB1 mutation. Of 142 unaffected parental pairs tested, only one unaffected parent of a proband (0.7%) showed somatic mosaicism for the proband's mutation, in contrast to an overall 4.5% somatic mosaicism rate for retinoblastoma probands, suggesting that mosaicism for an RB1 mutation is highly likely to manifest as retinoblastoma.

Identification of a mutation in exon 27 of the RB1 gene associated with incomplete penetrance retinoblastoma.

Retinoblastoma (Rb) is initiated by germline mutations in the RB1 gene. Up to date, no mutation was identified in exons 26 and 27. We have identified a 2 bp frameshift insertion in exon 27 of the RB1 gene (RBg.177008_177009dup) in a boy with unilateral Rb and his healthy father that has occurred de novo on the allele transmitted by the father's father. RT-PCR showed that the mutant +2 bp transcript is present in RNA from peripheral leukocytes after short-term culture. The level of the mutant transcript was low compared to the normal transcript indicating abnormal expression of the variant allele. The mutant transcript was further reduced after puromycin treatment suggesting that NMD is not involved. Although oncogenic mutations in the terminal exons of the RB1 gene are rare molecular testing is important as those terminal mutations can be associated with incomplete penetrance and cause high recurrence risk in family members.

Patterns of missplicing caused by RB1 gene mutations in patients with retinoblastoma and association with phenotypic expression.

We have analyzed RNA from retinoblastoma patients and unaffected carriers with various RB1 gene mutations to determine the patterns of missplicing and associations with phenotypic expression. Most sequence alterations in or in the neighborhood of conserved splice signals that we tested resulted in simple exon skipping (15 mutations) or intron inclusion (new acceptor AG-sites, four mutations) as expected. Two mutations resulted in skipping of a neighboring exon (exon 11), a complex pattern indicating competition for correct lariat formation. We observed no activation of a cryptic splice site but found that a recurrent missense mutation in exon 7 creates a new splice site (two families). RT-PCR analysis enabled us to confirm the presence and to characterize the transcriptional consequences of gross insertions and deletions in the RB1 gene in six patients, including two patients with mutational mosaicism. We also used RT-PCR analysis to search for unknown mutations in 15 patients and identified three oncogenic point mutations deep in introns. Two of these mutations are recurrent thus indicating that, despite the vast extent of the introns of the RB1 gene, few bases are effective targets for oncogenic mutations. When analyzing associations between phenotypic expression (16 families) and mutational consequences we observed no link to the presence or absence of a premature termination codon in the mutant transcript. However, the location of a mutation relative to the splice sequence has a strong and consistent influence on phenotypic expression.

Human retinoblastoma is not caused by known pRb-inactivating human DNA tumor viruses.

Retinoblastomas occur as the consequence of inactivation of the tumor suppressor retinoblastoma protein (pRb), classically upon biallelic inactivation of the RB1 gene locus. Recently, human papillomavirus (HPV) genomic DNA has been detected in retinoblastomas. To investigate the possibility that oncoproteins encoded by pRb-inactivating DNA tumor viruses play a role in the pathogenesis of human retinoblastoma, 40 fresh-frozen tumors were analyzed for the presence of HPV, adenovirus (HAdV) and polyomavirus (BKV, JCV and SV40) genomic DNA sequences by real-time polymerase chain reaction (PCR). Tumors were screened for genetic and epigenetic alterations in all 27 exons of the RB1 gene locus and promoter by exonic copy number detection, sequencing and methylation-specific PCR of the promoter region. Retinoblastoma tumors from children with bilateral familial (n=1), bilateral nonfamilial (n=1) and unilateral nonfamilial (n=38) disease were analyzed. Inactivating modifications to the RB1 gene locus were identified on both the alleles in 27 tumors, one allele in 8, and neither allele in 5 cases. A median of over 107,000 tumor cells were analyzed for viral genomic DNA in each PCR reaction. All tumor samples were negative for 37 HPV types, 51 HAdV types, BKV and JCV genomic sequences. Very low copy number (0.2-260 copies per 100,000 tumor cells) SV40 genomic DNA detected in 8 of 39 samples was demonstrated to be consistent with an artifact of plasmid-derived SV40. In contrast to recent reports, we obtained substantial quantitative evidence indicating that neither HPV nor any other pRb-inactivating human DNA tumor viruses play a role in the development of retinoblastoma, regardless of RB1 genotype.

Novel mutations and polymorphisms in genes causing hereditary hemorrhagic telangiectasia.

Hereditary Hemorrhagic Telangiectasia (HHT) is an autosomal dominant vascular disorder caused by mutations in Endoglin (ENG) or activin receptor-like kinase-1 (ALK1, ACVRL1) genes. We performed molecular characterization in clinically affected probands of 31 HHT families and detected a total of 28 different mutations in the two genes, including four shared by more than one family. Twelve mutations were identified in the ENG gene, six of which were novel and comprised two nonsense mutations in exons 6 and 8, deletions in exons 5 and 11, and splice site mutations in exon 12 and intron 8. Eleven of sixteen mutations identified in the ALK1 gene were novel single base pair substitutions in exons 4, 7, 8, and 9. We also describe the first de novo ALK1 mutation that causes a previously unreported c.1133C>A substitution of a highly conserved residue (p.P378H). The proband and his two daughters, who also carried the familial mutation, all suffered from gastrointestinal (GI) bleeding. In addition, we report seven newly identified polymorphisms and summarize all known ones in both genes.