[Diagnosis and treatment of retinoblastoma: current strategies for effective tumour control and preservation of vision]. / Diagnose und behandlung des retinoblastoms: aktuelle konzepte zur sicheren tumorkontrolle bei erhalt des sehvermögens.

There are approximately 40 new cases of retinoblastoma in Germany per year. Children in whom the tumour is detected when still intraocular have an excellent overall survival rate (> 95%). However, the prognosis of metastasised retinoblastoma remains poor. About 40% of retinoblastoma patients have tumours in both eyes. For these children in particular it is important to save the eye and visual function as much as possible. There are several options for conservative treatment of localised retinoblastoma including laser coagulation, thermotherapy, cryotherapy, brachytherapy and chemotherapy. In recent years, systemic chemotherapy has become the established standard for primary treatment of intraocular retinoblastoma. In case series, intra-arterial, intravitreal and periocular applications of chemotherapy were also shown to be effective in treating intraocular retinoblastoma. Genetic testing is an integral part of the routine diagnostics of all patients. Mutation analysis of tumour material is invaluable for identification of somatic mutations including mutational mosaicism. Genetic testing also identifies children with heritable retinoblastoma, which represent 50% of cases. These children also have a predisposition for the development of tumours outside of the eye (second primary neoplasm). To adequately address these and other late effects in survivors of retinoblastoma, a multidisciplinary approach is needed that optimises therapy and long-term follow-up. Upcoming multicentre clinical trials will evaluate treatment concepts for localised and metastasised retinoblastoma to improve survival rates and quality of life of children with retinoblastoma. This article was translated and modified and was primarily published in Klin Padiatr 2012; 224: 339-347.

First Report of a Single Exon Deletion in TCOF1 Causing Treacher Collins Syndrome.

Treacher Collins syndrome (TCS) is a rare craniofacial disorder characterized by facial anomalies and ear defects. TCS is caused by mutations in the TCOF1 gene and follows autosomal dominant inheritance. Recently, mutations in the POLR1D and POLR1C genes have also been identified to cause TCS. However, in a subset of patients no causative mutation could be found yet. Inter- and intrafamilial phenotypic variability is high as is the variety of mainly family-specific mutations identified throughout TCOF1. No obvious correlation between pheno- and genotype could be observed. The majority of described point mutations, small insertions and deletions comprising only a few nucleotides within TCOF1 lead to a premature termination codon. We investigated a cohort of 112 patients with a tentative clinical diagnosis of TCS by multiplex ligation-dependent probe amplification (MLPA) to search for larger deletions not detectable with other methods used. All patients were selected after negative screening for mutations in TCOF1, POLR1D and POLR1C. In 1 patient with an unequivocal clinical diagnosis of TCS, we identified a 3.367 kb deletion. This deletion abolishes exon 3 and is the first described single exon deletion within TCOF1. On RNA level we observed loss of this exon which supposedly leads to haploinsufficiency of TREACLE, the nucleolar phosphoprotein encoded by TCOF1.

Prognostic significance of chromosome 3 alterations determined by microsatellite analysis in uveal melanoma: a long-term follow-up study.

BACKGROUND: In uveal melanoma (UM), the most frequent primary intraocular tumour in adults, loss of one entire chromosome 3 (monosomy 3 (M3)) is observed in ~50% of tumours and is significantly associated with metastatic disease. The strong association of metastatic disease with M3 offers the opportunity for molecular prognostic testing of UM patients. METHODS: To re-evaluate M3 as prognostic marker in our clinical and laboratory setting and to determine the metastatic potential of rare tumours with partial M3, we performed a comprehensive study on 374 UM patients treated by enucleation in our clinic within 10 consecutive years, starting in 1998. Genotyping of all tumours was performed by microsatellite analysis. RESULTS: Median follow-up time was 5.2 years. The disease-specific mortality rates (death by UM metastases) for tumours with disomy 3 (D3) and M3 were 13.2% and 75.1%, respectively. The disease-specific survival was worse when M3 was observed together with chromosome 8 alterations (P=0.020). Death of UM metastases was also observed in 12 patients (9%) with D3 tumours. The metastasising D3 tumours showed a larger basal tumour diameter (P=0.007), and were more frequently of mixed or epitheloid cell type (P<0.0001) than D3 tumours that did not metastasise. Mortality rate of tumours showing partial M3 (8.3%) was as low as that for tumours with D3. CONCLUSION: This shows that large tumours with disomy 3 have an increased risk to develop metastases. On the basis of these results, our clinic offers routine prognostic testing of UM patients by chromosome 3 typing.

Spectrum of gross deletions and insertions in the RB1 gene in patients with retinoblastoma and association with phenotypic expression.

Quantitative multiplex PCR and genomic real-time PCR were used to complete an RB1 mutation analysis in 57 of 433 and 72 of 262 patients with hereditary and isolated unilateral retinoblastoma, respectively. These patients were selected because in previous analyses, which focused mainly on the identification of point mutations, no RB1 mutation was found. We identified gross deletions and insertions in peripheral blood DNA from 26 of 57 patients (46%) with hereditary retinoblastoma, and in six of 72 patients (8.3%) with isolated unilateral disease. In addition, we identified 32 somatic mutations in tumor DNA from 31 of 72 patients (43%) with isolated unilateral retinoblastoma. Together with our previous results, we found that gross RB1 alterations were present in the peripheral blood DNA from 65 of 433 (15%) and 17 of 262 (6.5%) patients with bilateral or familial and isolated unilateral retinoblastoma, respectively. Including reported gross deletions, an analysis of the frequency of breakpoints per intron length shows higher densities in introns 13, 16, 23, and 24. Genotype-phenotype analyses showed that on the whole, carriers of gross deletions develop fewer retinoblastomas compared to patients who are heterozygous for other types of RB1 null mutations. Specifically, carriers of cytogenetic and submicroscopic whole gene deletions often have unilateral tumors only. By contrast, almost all patients with gross deletions with one breakpoint in RB1 have bilateral retinoblastoma.

Age at diagnosis of isolated unilateral retinoblastoma does not distinguish patients with and without a constitutional RB1 gene mutation but is influenced by a parent-of-origin effect.

Patients with hereditary cancer are usually diagnosed earlier than patients with non-hereditary tumours. In children with isolated unilateral retinoblastoma, some of whom have a hereditary predisposition, this rule has been subject to debate. We have analysed the clinical manifestation of disease in 188 children with completely resolved mutational status. In 24 (13%) of these patients, testing of blood DNA showed a constitutional RB1 mutation. The distribution of age at diagnosis was not different between patients with and without a constitutional mutation. However, patients with loss of the maternally inherited RB1 allele had an earlier age at diagnosis than patients with loss of the paternally inherited RB1 allele. Our data show that early age at diagnosis does not identify patients with isolated unilateral retinoblastoma that have a higher risk of being carriers of a RB1 gene mutation. Our findings suggest that, at least in some patients, age at diagnosis is modified by a parent-of-origin effect.

Multiple lipomas linked to an RB1 gene mutation in a large pedigree with low penetrance retinoblastoma.

Hereditary predisposition to lipomas is observed in familial multiple lipomatosis (OMIM 151900) and benign cervical lipomatosis (OMIM 151800) and can also be associated with mutations in the MEN1 and PTEN genes (OMIM 131100 and 153480, respectively). In addition, a recent report indicates that a few patients with hereditary retinoblastoma also have lipomas. Here we report on an extended family segregating a splice site mutation in the RB1 gene. Almost all adult carriers of this mutation had multiple lipomas while penetrance for retinoblastoma was incomplete. In an unrelated pedigree, which was reported previously, the identical mutation was only associated with low-penetrance retinoblastoma but not lipomas. Our data indicate that lipoma predisposition in hereditary retinoblastoma is not associated with specific RB1 gene mutations but is influenced by modifying factors linked to this gene.

Marked differences in unilateral isolated retinoblastomas from young and older children studied by comparative genomic hybridization.

Although it is established that the loss of function of both alleles of the RB1 gene is a prerequisite for the development of retinoblastoma, little is known about the genetic events that are required for tumor progression. We used comparative genomic hybridization (CGH) to search for DNA copy number changes in isolated unilateral retinoblastomas. From a series of 66 patients with retinoblastomas with somatic mutations in both RB1 alleles, tumor samples from 13 children with the youngest (2.0-9.8 months) and 13 with the oldest (36.2-84.1 months) age at operation were studied. Loss at 13q14, the location of RB1, was demonstrated in two tumors only. Recurring chromosome imbalances included gains at 6p (11/26), 1q (10/26), 2p (4/26), and 17q (4/26), gains of the entire chromosome 19 (3/26), and losses at 16q (9/26). A commonly gained region at 1q32 was identified. Increased dosage of GAC1, a candidate oncogene located in 1q32, was found in two of four tumors by Southern blot analysis. Comparison of the CGH findings revealed that retinoblastomas from children with an older age at operation showed significantly more frequent (13/13 cases vs 4/13 cases; P = 0.0005) and more complex genetic abnormalities (median, 5 changes/abnormal tumor vs median, 1.5 changes/abnormal tumor; P = 0.003) than retinoblastomas from children with a young age at operation. Gains at 1q, 2p, 17q, of the entire chromosome 19 and losses of 16q were restricted to the older age group. Our results suggest that the progression of retinoblastomas from older patients follows mutational pathways different from those of younger patients.

Partial deletions of the long and short arm of chromosome 3 point to two tumor suppressor genes in uveal melanoma.

Uveal melanoma is the most common form of primary eye cancer. Monosomy 3, which is an unusual finding in tumors but is present in approximately 50% of uveal melanomas, is significantly correlated with metastatic disease. To obtain positional information on putative tumor suppressor genes on this chromosome, we have investigated tumors from 333 patients by comparative genomic hybridization, microsatellite analysis, or conventional karyotype analysis. A partial deletion of the long arm was found in eight tumors, and the smallest region of deletion overlap (SRO) spans 3q24-q26. We found six tumors with a partial deletion of the short arm and were able to define a second SRO of about 2.5 Mb in 3p25. This SRO does not overlap with the VHL gene. Our finding suggests a role for two tumor suppressor genes in metastasizing uveal melanoma and may explain the loss of an entire chromosome 3 in these tumors.

Identification of chromosomes 3, 6, and 8 aberrations in uveal melanoma by microsatellite analysis in comparison to comparative genomic hybridization.

In uveal melanoma, monosomy 3 is strongly associated with metastic disease and poor prognosis. Cytogenetic analysis and comparative genomic hybridization (CGH) have been used to identify chromosomal aberrations in uveal melanoma. As these methods are costly and time consuming in routine diagnostic settings, we evaluated whether tumors with monosomy 3 can be reliably identified by microsatellite analysis (MSA). In addition, we also tested if aberrations of chromosomes 6 and 8, which have also been associated with the course of the disease, can be detected by MSA. We established a protocol for MSA of 23 markers, 3-4 on each arm of chromosomes 3, 6, and 8. Twenty tumors were analyzed by CGH and MSA, and 10 tumors were analyzed by MSA only. For chromosome 3, the results of CGH and MSA were concordant, thus indicating that the dosage of this chromosome can reliably be determined by MSA. However, MSA failed to detect copy number gains at 6p in some tumors. Moreover, despite quantitative evaluation of allele ratios, it was not possible to discern 8p losses and gains reliably. We thus conclude that while MSA can be used to determine monosomy 3 in uveal melanoma, careful interpretation of results for chromosomes 6 and 8 is recommended.

Multiple subcutaneous granular-cell tumours in a patient with Noonan syndrome.

A boy with Noonan syndrome and multiple subcutaneous granular-cell tumours is described and the association discussed.

RB1 gene mutations in retinoblastoma.

Mutations in both alleles of the RB1 gene are causal for the development of retinoblastoma, a childhood tumor of the eye. The spectrum of somatic and germline mutations in this gene is dominated by small mutations. Data on small mutations are listed in a locus specific database available at http://www.d-lohmann.de/Rb/mutations.html. Analysis of 368 reported small mutations reveals considerable heterogeneity. A notable recurrence of transitions is observed at 13 CpG-dinucleotides that are part of CGA codons or splice donor sites. Most mutations create a premature termination codon. With few exceptions, patients heterozygous for mutations of this kind develop bilateral retinoblastoma. Missense mutations and inframe deletions are rare. Some of these mutations are associated with a distinct phenotype marked by incomplete penetrance and reduced expressivity.

Twelve novel RB1 gene mutations in patients with hereditary retinoblastoma. Mutations in brief no. 206. Online.

Hereditary predisposition to retinoblastoma is caused by germline mutations in the RB1 gene. Mutation analysis in this gene is important because knowledge of the causative mutation is often required for accurate risk prediction in relatives. We have performed RB1 gene mutation analysis in 45 patients with hereditary retinoblastoma. Screening by heteroduplex and SSCP analysis resulted in the identification of small mutations in 28 (62%) patients. Recurrent mutations, mostly CpG-transitions, were found in 16 patients. Two patients with isolated bilateral retinoblastoma showed missense mutations, S567L and C712R, which have previously been reported in a patient with bilateral tumors and in a family with low penetrance, respectively. Twelve of the mutations identified here have not been reported to date. These include a novel missense mutation, L662P, which was identified in two bilaterally affected siblings and their mother with unilateral retinoma.

Constitutional RB1-gene mutations in patients with isolated unilateral retinoblastoma.

In most patients with isolated unilateral retinoblastoma, tumor development is initiated by somatic inactivation of both alleles of the RB1 gene. However, some of these patients can transmit retinoblastoma predisposition to their offspring. To determine the frequency and nature of constitutional RB1-gene mutations in patients with isolated unilateral retinoblastoma, we analyzed DNA from peripheral blood and from tumor tissue. The analysis of tumors from 54 (71%) of 76 informative patients showed loss of constitutional heterozygosity (LOH) at intragenic loci. Three of 13 uninformative patients had constitutional deletions. For 39 randomly selected tumors, SSCP, hetero-duplex analysis, sequencing, and Southern blot analysis were used to identify mutations. Mutations were detected in 21 (91%) of 23 tumors with LOH. In 6 (38%) of 16 tumors without LOH, one mutation was detected, and in 9 (56%) of the tumors without LOH, both mutations were found. Thus, a total of 45 mutations were identified in tumors of 36 patients. Thirty-nine of the mutations-including 34 small mutations, 2 large structural alterations, and hypermethylation in 3 tumors-were not detected in the corresponding peripheral blood DNA. In 6 (17%) of the 36 patients, a mutation was detected in constitutional DNA, and 1 of these mutations is known to be associated with reduced expressivity. The presence of a constitutional mutation was not associated with an early age at treatment. In 1 patient, somatic mosaicism was demonstrated by molecular analysis of DNA and RNA from peripheral blood. In 2 patients without a detectable mutation in peripheral blood, mosaicism was suggested because 1 of the patients showed multifocal tumors and the other later developed bilateral retinoblastoma. In conclusion, our results emphasize that the manifestation and transmissibility of retinoblastoma depend on the nature of the first mutation, its time in development, and the number and types of cells that are affected.

[Molecular genetics and diagnosis of retinoblastoma. Significance for ophthalmologic practice]. / Molekulare Genetik und Diagnostik des Retinoblastoms. Bedeutung für die Ophthalmologische Praxis.

Retinoblastoma (RB) is initiated by loss of function of both copies of the retinoblastoma susceptibility gene (RB 1). Hereditary predisposition to RB is caused by germline mutations in the RB 1 gene. Tumor formation is initiated by the somatic loss of the second allele. Most patients with hereditary RB develop multiple tumors that usually affect both eyes. In nonhereditary disease, however, both RB 1 mutations are somatic events that cause the formation of a single tumor focus. Knowledge of the germline mutation is often essential for accurate risk prediction. Applying strategies for efficient mutation detection, germline mutations can be identified in most individuals with hereditary RB. The vast majority of mutant alleles cause premature termination of translation owing to frameshift or nonsense mutations. In patients carrying these mutant alleles, penetrance is almost complete (> 95%) and numerous tumor foci are observed. However, some 5% of the mutations result in comparatively mild alterations at the protein level. Patients with mutations of this kind often show a lower mean number of tumor foci (reduced expressivity) or no tumor at all (incomplete penetrance). Reduced expressivity and incomplete penetrance are also observed in patients with large cytogenetic deletions. By mutation analysis in DNA from fresh frozen tumor samples and peripheral blood, we have detected RB 1 germline mutations in some 20% of patients with unilateral RB. These results emphasize the importance of molecular analysis in patients with isolated unilateral RB.

The murine Ext1 gene shows a high level of sequence similarity with its human homologue and is part of a conserved linkage group on chromosome 15.

We have cloned and sequenced the murine homologue of the human EXT1 gene. At the protein level, these genes show almost complete identity as divergence is limited to only 5 amino acid positions that are scattered about the whole sequence. In addition, similarity searches identified a protein from chromosome III of C. elegans that shows significant similarity to the human and murine EXT/Ext genes. Using high resolution backcross mapping, the murine Ext1 was mapped at 26.55 cM between D15Mit143 and D15Mit153 on mouse chromosome 15. Therefore, Ext1 is part of an evolutionarily conserved linkage group including SDC2/Hspg1, TRHR/Trhr, EXT1/Ext1, MYC/Myc, and TG/Tgn.

The spectrum of RB1 germ-line mutations in hereditary retinoblastoma.

We have searched for germ-line RB1 mutations in 119 patients with hereditary retinoblastoma. Previous investigations by Southern blot hybridization and PCR fragment-length analysis had revealed mutations in 48 patients. Here we report on the analysis of the remaining 71 patients. By applying heteroduplex analysis, nonisotopic SSCP, and direct sequencing, we detected germ-line mutations resulting in premature termination codons or disruption of splice signals in 51 (72%) of the 71 patients. Four patients also showed rare sequence variants. No region of the RB1 gene was preferentially involved in single base substitutions. Recurrent transitions were observed at most of the 14 codons within the RB1. No mutation was observed in exons 25-27, although this region contains two CGA codons. This suggests that mutations within the 3'-terminal region of the RB1 gene may not be oncogenic. When these data were combined with the results of our previous investigations, mutations were identified in a total of 99 (83%) of 119 patients. The spectrum comprises 15% large deletions, 26% small length alterations, and 42 % base substitutions. No correlation between the location of frameshift or nonsense mutations and phenotypic features, including age at diagnosis, the number of tumor foci, and manifestation of nonocular tumors was observed.

Molecular analysis and predictive testing in retinoblastoma.

Predictive testing using molecular analysis is an integral part of contemporary retinoblastoma management. We have made extensive use of segregation analysis for risk assessment in both familial and sporadic disease. Investigation of loss of heterozygosity in tumor samples proved to be invaluable for the identification of linkage phase. In many families, however, accurate carrier risk assessment depends on direct identification of the causative R B I mutation. Consequently, we have developed methods for rapid mutation screening. Using these techniques, mutation analysis can now be offered to an increasing number of individuals.