Quality assessment of genetic markers used for therapy stratification.

PURPOSE: Therapy stratification based on genetic markers is becoming increasingly important, which makes commitment to the highest possible reliability of the involved markers mandatory. In neuroblastic tumors, amplification of the MYCN gene is an unequivocal marker that indicates aggressive tumor behavior and is consequently used for therapy stratification. To guarantee reliable and standardized quality of genetic features, a quality-assessment study was initiated by the European Neuroblastoma Quality Assessment (ENQUA; connected to International Society of Pediatric Oncology) Group. MATERIALS AND METHODS: One hundred thirty-seven coded specimens from 17 tumors were analyzed in 11 European national/regional reference laboratories using molecular techniques, in situ hybridization, and flow and image cytometry. Tumor samples with divergent results were re-evaluated. RESULTS: Three hundred fifty-two investigations were performed, which resulted in 23 divergent findings, 17 of which were judged as errors after re-evaluation. MYCN analyses determined by Southern blot and in situ hybridization led to 3.7% and 4% of errors, respectively. Tumor cell content was not indicated in 32% of the samples, and 11% of seemingly correct MYCN results were based on the investigation of normal cells (eg, Schwann cells). Thirty-eight investigations were considered nonassessable. CONCLUSION: This study demonstrated the importance of revealing the difficulties and limitations for each technique and problems in interpreting results, which are crucial for therapeutic decisions. Moreover, it led to the formulation of guidelines that are applicable to all kinds of tumors and that contain the standardization of techniques, including the exact determination of the tumor cell content. Finally, the group has developed a common terminology for molecular-genetic results.

Fine-mapping of cytogenetically undetectable EWS/ERG fusions on DNA fibers of Ewing tumors.

In contrast to the EWS/FLI1 fusion which is represented by a t(11;22)(q24;q12), EWS/ERG fusions are frequently cytogenetically not detectable. Three Ewing tumors (ET), two with apparently normal chromosomes 21 and 22, and one ET with a t(2;22)(p25;q12), were studied by FISH on interphase nuclei, metaphase chromosomes and on DNA fibers. EWS/ERG transcripts were detected by RT-PCR in all cases. FISH, using cosmids located proximally (F10, G9) and distally (F7) to the EWS breakpoint region, revealed no detectable separation of these probes in two cases. In contrast, co-hybridization of probe PT1526 containing the ERG breakpoint region with G9 revealed the juxtaposition of two signals per interphase nucleus in all three cases indicating the EWS/ERG fusions. Chromosome preparations displayed the juxtaposed signals on the der(22), and hybridization signals of the probes PT1526 and G9 on the non-rearranged chromosomes 21 and 22 in all cases, respectively. The PT1526 signal on the der(21) was seen only in cases 1 and 2. These results were confirmed by triple-target FISH on tumor DNA fibers. In all three cases, the hybridization pattern F10 - G9 - PT1526 indicates a centromere to telomere orientation. This finding suggests that EWS/ERG fusions in ETs may be generated by an inversion of the ERG gene or a part thereof followed by an insertion into the EWS gene on the der(22). Double-target FISH on interphase nuclei using probes flanking the EWS breakpoint region and probe PT1526 enables the detection of virtually all 22q12 rearrangements in ETs, thus providing a reliable diagnostic assay.

Intratumoural heterogeneity of 1p deletions and MYCN amplification in neuroblastomas.

BACKGROUND: At least three genetic hallmarks identify aggressive tumour behaviour in neuroblastomas; amplification of the oncogene MYCN; deletion (loss of heterozygosity [LOH]) at the short arm of chromosome 1 (del1p36), seen in approximately 28% of the cases; and di-tetraploidy. The MYCN oncogene is amplified in approximately 23% of all neuroblastomas and becomes important for the stratification of therapy in localised and 4s tumours. Up to now, it has been believed that the genetic constellation of neuroblastic tumours is stable and does not alter during tumour evolution or during tumour progression. PROCEDURE: Using fluorescence in situ hybridisation techniques (FISH) to investigate different tumour areas on touch preparations and histological sections, we show that genetic heterogeneity can be detected in neuroblastomas, especially in tumours detected by urinary mass screening. CONCLUSION: The identification of such cell clones is important, because the MYCN amplification and/or the deletion at 1p36 appear to be responsible for aggressive local growth and development of metastases.

Neuroblastoma cells provoke Schwann cell proliferation in vitro.

BACKGROUND: A subset of human neuroblastomas (NBs) has the capacity to mature completely, imitating sympathetic ganglia. Previously, we showed that the neuronal population in spontaneously maturing NBs usually has a near-triploid DNA content without 1p deletions, and we concluded that the constantly diploid Schwann cells (SCs) do not belong to the neoplastic component of these tumours. We therefore hypothesised that NB cells are able to stimulate SC proliferation, and that SCs trigger NB differentiation. PROCEDURE: We performed in vitro experiments to test this model and to test whether SCs can also influence the growth of aggressive NBs. Human SCs were co-cultivated with NB tumours and cell lines, and were harvested after defined time intervals. Proliferative activity of the SCs and the NB cells was determined by visualisation of 5-bromo-2'-deoxyuridine (BrdU) incorporation or Ki-67 staining. Neurite outgrowth and neurofilament (NF) expression were analysed immunocytochemically and apoptotic rate was determined by a terminal deoxynucleotidyl transferase-mediated dUTP-X fluorescein nick end labelling (TUNEL) assay. RESULTS: Human NB tumours or cell lines unequivocally increased the proliferation of SCs in vitro. In cocultivated NB cells, the proliferative activity was not altered in the first days of cocultivation, although neurite outgrowth and NF expression were enhanced. However, after 10 days, the mitotic rate of neuroblastic cells decreased and the apoptotic rate showed a marked increase. CONCLUSIONS: The results of the cocultivation experiments provide an experimental hint that the in vivo growth of SCs in NBs is caused by the neoplastic neuroblasts, and they also indicate that cells from peripheral nerves can influence the growth of aggressive NB cells if cocultivated.

Prognostic impact of deletions at 1p36 and numerical aberrations in Ewing tumors.

Ewing's sarcoma, peripheral primitive neuroectodermal tumors, and Askin tumors are referred to as Ewing tumors (ETs), and are characterized by high MIC2 expression and a t(11;22)(q24;q12) or other rearrangements involving 22q12. In addition to these constant aberrations, facultative numerical and structural aberrations have been reported: gains of chromosomes 8 and 12, the unbalanced translocation t(1;16), and deletions at the short arm of chromosome 1. To evaluate the frequency and to study the biological impact of these facultative aberrations, we analyzed tumor specimens from 58 ET patients by classical cytogenetics and/or in situ hybridization techniques and compared these data with clinical parameters. Gains of chromosomes 8 and 12 were detected in 55% (32/58) and 24% (14/58) of the cases, respectively. Loss of chromosome 16 or der (16)t(1;16) chromosomes were found in 20% (10/51); deletions at 1p36 were observed in 18% (9/51) of the cases evaluated. The presence of these aberrations did not correlate with age and sex of the patients, with the location of the primary tumor or with the extent of disease at diagnosis by chi-square analysis and Fisher's exact test. Patients with tumors harboring gains of chromosome 8 showed a slightly better clinical outcome (n = 14/30, P = 0.17), whereas gains of chromosome 12 did not influence the clinical outcome (n = 7/30, P = 0.63). However, Kaplan and Meier analysis revealed that deletions at the short arm of chromosome 1 were associated with an unfavorable outcome in patients with localized disease (n = 6/22; P = 0.004).

Neuroblastoma cells can actively eliminate supernumerary MYCN gene copies by micronucleus formation--sign of tumour cell revertance?

Human neuroblastoma cell lines frequently exhibit MYCN amplification and many are characterised by the presence of morphologically distinct cell types. The neuronal cells (N-cells) and the so-called flat cells (F-cells) are thought to represent manifestations of different neural crest cell lineages and are considered to be the consequence of neuroblastoma cell pluripotency. In this study, various neuroblastoma cell lines were examined for micronuclei. In F-cells of neuroblastoma cell lines with extrachromosomally amplified MYCN, we observed the frequent occurrence of micronuclei. Using fluorescence in situ hybridisation (FISH) with a MYCN specific probe, we demonstrated that these micronuclei were packed with MYCN hybridisation signals. In addition, in a minor percentage of cells, MYCN signals occurred in clusters, adhered to the nuclear membrane and aggregated in nuclear protrusions. In F-cells, a substantial reduction or lack of amplified MYCN copies was observed. These observations let us conclude that extrachromosomally amplified genes can be actively eliminated from the nucleus resulting in a dramatic loss of amplified sequences in the F-cells. Moreover, reduction or loss of amplified sequences in F-cells was shown to be accompanied by downregulation of MYCN expression, by a decrease in proliferative activity and by upregulation of molecules of the major histocompatibility complex class I (MHC I). Interestingly, F-cells are not restricted to neuroblastoma cell cultures, but also occur in cell lines of other tissue origin. All F-cells share important biological features, interpreted as cell revertance, i.e. loss of the malignant phenotype and properties. This fact, together with the demonstration that neuroblastoma cells do not differentiate into Schwann cells in vivo [1] Ambros et al. NEJM 1996, 334, 1505-1511, do not support the hypothesis that F-cells represent Schwannian/glial differentiation in vitro. We therefore postulate that the elimination of amplified MYCN gene copies in cultivated neuroblastoma cells is in line with the phenomenon of tumour cell revertance.

In vitro reconstitution of mammalian U1 snRNPs active in splicing: the U1-C protein enhances the formation of early (E) spliceosomal complexes.

We have established an in vitro reconstitution/splicing complementation system which has allowed the investigation of the role of mammalian U1 snRNP components both in splicing and at the early stages of spliceosome formation. U1 snRNPs reconstituted from purified, native snRNP proteins and either authentic or in vitro transcribed U1 snRNA restored both early (E) splicing complex formation and splicing-activity to U1-depleted extracts. In vitro reconstituted U1 snRNPs possessing an m3G or ApppG cap were equally active in splicing, demonstrating that a physiological cap structure is not absolutely required for U1 function. However, the presence of an m7GpppG or GpppG cap was deleterious to splicing, most likely due to competition for the m7G cap binding proteins. No significant reduction in splicing or E complex formation was detected with U1 snRNPs reconstituted from U1 snRNA lacking the RNA binding sites of the U1-70K or U1-A protein (i.e., stem-loop I and II, respectively). Complementation studies with purified HeLa U1 snRNPs lacking subsets of the U1-specific proteins demonstrated a role for the U1-C, but not U1-A, protein in the formation and/or stabilization of early splicing complexes. Studies with recombinant U1-C protein mutants indicated that the N-terminal domain of U1-C is necessary and sufficient for the stimulation of E complex formation.

Demonstration of the translocation der(16)t(1;16)(q12;q11.2) in interphase nuclei of Ewing tumors.

The der(16)t(1;16) has been detected cytogenetically in a number of malignancies including Ewing tumors (ETs). To enable fast and reliable analysis of der(16) chromosomes, we established an interphase cytogenetic approach. By using two DNA probes hybridizing to the heterochromatic portions on the long arms of chromosomes 1 and 16, this technique allows the detection of this chromosomal aberration in nonproliferating cells. Formation of the der(16) leads to partial excess of 1q material and partial loss of the long arm of chromosome 16. Double-target fluorescence in situ hybridization (FISH) experiments were performed on cytospin slides of 13 ETs, near-triploid tumor cells and normal cells to assess whether the FISH technique used permits the discrimination of nuclei harboring this aberration from nuclei without a der(16) chromosome. In five ETs, we found evidence for the presence of one or two der(16)t(1;16) chromosomes both by FISH and by conventional cytogenetics. Tumor cells displayed two signals for intact chromosomes 1, one or two additional fused signals for the der(16) chromosomes, and one signal for the intact chromosome 16. In one case without fused signals, the presence of a der(16) was demonstrated by hybridizing a painting probe for chromosome 16 simultaneously with the paracentromeric probe for chromosome 1. Our results suggest that double-target FISH on interphase nuclei offers an ideal tool for analyzing tumors prospectively and retrospectively to assess the biological role and the possible prognostic impact of the der(16) in ETs and in other solid tumors.

[5 years neuroblastoma screening in Austria: rate of participation, results and a comparison with other screening areas]. / Fünf Jahre Neuroblastom-Screening in Osterreich: Beteiligungsrate, Ergebnisse und ein Vergleich mit anderen Screeningregionen.

In late 1990 a screening program for the early detection of neuroblastoma in infants was introduced in Austria. The program is performed on a voluntary basis in collaboration with general pediatricians and practitioners. Filter strips for urine collection are distributed to parents of infants aged seven to nine months on the occasion of a routine check up. The samples are sent to the laboratory by parents and analysed for vanillylmandelic acid (VMA) and homovanillic acid (HVA). Between January 1991 and December 1995 125,201 infants were screened. The compliance rate was 26.8% for Austria, but great differences were seen for different regions (65% in Carinthia, 10% in Vorarlberg). 30 children were admitted to hospital for investigation of repeatedly elevated urine catecholamines. A neuroblastoma was identified in 16 cases. In 12 of these cases at least one unfavorable prognostic factor was present (stage > or = 3, elevated LDH, unfavorable histology, N-myc amplification, di- or tetraploidy). Neuroblastoma screening of infants aged more than six months seems to detect predominantly those tumors which are unlikely to regress spontaneously. The observation of one false negative case, however, demonstrates that neuroblastomas which become clinically manifest at a later date may remain undetected by early screening. Possible advantages of shifting screening to a later age and repeated screening are discussed.