Chromosome 17/17q gain and unaltered profiles in high resolution array-CGH are prognostically informative in neuroblastoma.

The prognostic relevance of chromosome 17 gain in neuroblastoma is still discussed. This investigation specifies the frequency, type, size, and transcriptional relevance in a large patient cohort. Primary tumor material of 202 patients was analyzed using high-resolution oligonucleotide array-based comparative genomic hybridization (aCGH) and correlated with clinical and survival data. A subset (n = 145) was correlated for differentially expressed genes (DEG) by microarray analysis. Chromosome 17 aCGH analysis showed numerical gain in 94/202 patients (47%), partial gain in 93/202 patients (46%), and no gain in 15/202 patients (7%). The frequency of partial gain was higher in stage 4 neuroblastoma (stage 1 15%; stage 2 12%; stage 3 16%; stage 4S 7%; and stage 4 50%). Overall survival (OS) was superior in patients with numerical gain compared with patients with partial gain or no gain (5-y-OS: 0.95 ± 0.02 vs. 0.63 ± 0.05 vs. 0.60 ± 0.13; P < 0.001). Gene expression analysis demonstrated 95/130 DEGs between tumors with numerical or partial chromosome/no gain. Only one DEG (CCKBR) was detected comparing tumors with partial gain and those with no gain. In patients with partial gain, the distribution of breakpoints did not correlate with stage and 11q status, but with MYCN amplification and 1p status. The "best" breakpoints in cases with partial 17q gain were at 42.5 Mb for event-free and 26.6 Mb for OS. Numerical gain of chromosome 17 is associated with a better prognosis than partial and no gain. The group of tumors with partial gain was similar to the group without gain with respect to stage distribution, outcome, and gene expression profile.

Heterogeneity of the MYCN oncogene in neuroblastoma.

PURPOSE: MYCN amplification is an important therapy-stratifying marker in neuroblastoma. Fluorescence in situ hybridization with signal detection on the single-cell level allows a critical judgement of MYCN intratumoral heterogeneity. EXPERIMENTAL DESIGN: The MYCN status was investigated by fluorescence in situ hybridization at diagnosis and relapse. Heterogeneity was defined as the simultaneous presence of amplified cells (>/=5 cells per slide) and nonamplified cells within one tumor or sequential change of the amplification status during the course of the disease. Likewise, heterogeneity can be detected between primary tumor and metastasis. RESULTS: From 1,341 patients analyzed, 1,071 showed no amplification, 250 showed homogeneous amplification, and 20 patients showed MYCN heterogeneity. Of the patients with heterogeneity, 12 of 20 had clusters of MYCN amplifications, 3 of 20 had amplified single cells, 3 of 20 showed MYCN amplifications in the bone marrow but not in the primary tumor, and 2 of 20 acquired MYCN amplification during the course of the disease. All stage 4 patients were treated according to high-risk protocols; 7 of 8 later progressed. Four patients with localized disease were treated according to high-risk protocol because of MYCN-amplified clusters; 1 of 4 later progressed. One patient treated with mild chemotherapy experienced progression. Seven patients with localized/4S disease underwent no chemotherapy: 4 of 5 patients with MYCN heterogeneity at diagnosis remained disease-free, and 1 of 5 experienced local progression. Two patients had normal MYCN status at diagnosis but acquired MYCN amplification during the course of the disease. CONCLUSION: MYCN heterogeneity is rare. Our results suggest that small amounts of MYCN-amplified cells are not correlated to adverse outcomes. More patients with heterogeneity are warranted to clarify the role of MYCN heterogeneity for risk classification.

Localized infant neuroblastomas often show spontaneous regression: results of the prospective trials NB95-S and NB97.

PURPOSE: The excellent prognosis of localized neuroblastoma in infants, the overdiagnosis observed in neuroblastoma screening studies, and several case reports of regression of localized neuroblastoma prompted us to initiate a prospective cooperative trial on observation of localized neuroblastoma without cytotoxic treatment. PATIENTS AND METHODS: For infants with localized neuroblastoma without MYCN amplification, chemotherapy was scheduled only in cases with threatening symptoms; otherwise, the tumor was either resected or observed by ultrasound and magnetic resonance imaging (MRI). RESULTS: Of 340 eligible participants, 190 underwent resection, 57 were treated with chemotherapy, and 93 were observed with gross residual tumor. Of those 93 patients with unresected tumors, spontaneous regression was seen in 44, local progression in 28, progression to stage 4S in seven, and progression to stage 4 in four. Time to regression was quite variable, with first signs of regression noted 1 to 18 months after diagnosis and in 15 of 44 patients even after the first year of life. So far, complete regression was observed in 17 of 44 patients 4 to 20 months after diagnosis. Known clinical risk factors were not able to differentiate between patients with regression and regional or metastatic progression. Overall survival (OS; 3-year OS, 0.99 +/- 0.01) and metastases-free survival (rate at 3 years, 0.94 +/- 0.03) for patients with unresected tumors was excellent and was not different from patients treated with surgery or chemotherapy. CONCLUSION: Spontaneous regression is regularly seen in infants with localized neuroblastoma and is not limited to the first year of life. A wait-and-see strategy is justified in those patients.

Oligonucleotide array-based comparative genomic hybridization (aCGH) of 90 neuroblastomas reveals aberration patterns closely associated with relapse pattern and outcome.

The study of genomic alterations in neuroblastoma is of particular importance since several cytogenetic markers proved to be closely associated with the clinical phenotype. To disclose patterns of gains and losses, we performed high-resolution oligonucleotide array-based comparative genomic hybridization (aCGH). A total cohort of 90 patients was classified into 6 subsets according to tumor stage and outcome: Stages 1-3+ (with event), Stage 1-3- (no event), Stage 4+/-, and Stage 4S+/-. The aberration patterns in Stages 1-3- and 4S- tumors differed from all other groups as they were predominantly characterized by losses (3, 4, 14, X) and gains (7, 17) of whole chromosomes. However, 59/65 (91%) tumors of Stages 1-3+ or Stage 4 revealed numerous structural copy number alterations (sCNA). While deletions in chromosomes 1, 3, and 11 discriminated outcome in Stage 4, there were no specific sCNA that distinguished tumor stage within the subgroup of unfavorable tumors. sCNA in 1p, 3p, 11q, 17q, or MYCN amplification (MNA) was seen among 22/24 patients who died, 10/12 with metastatic relapses, and 5/9 with local recurrences. Detailed breakpoint analyses on chromosomes 1, 3, 11, and 17 disclosed preferred breaking areas, although breakpoints were not identical. Amplifications were found in 18 patients and involved 2p24 (MYCN) and other segments of chromosome 2, as well as regions on chromosome arms 6q, 12q, and 17q. One single feature in 21q21.1 (BU678720, without known function yet) attracted particular attention since five patients showed a homozygous loss of this sequence.

Loss in chromosome 11q identifies tumors with increased risk for metastatic relapses in localized and 4S neuroblastoma.

PURPOSE: To improve risk prediction in neuroblastoma and to specify the type of a possible relapse, alterations in the long arm of chromosome 11 were analyzed. EXPERIMENTAL DESIGN: A representative cohort of 611 neuroblastomas was investigated for deletion events in distal chromosome 11q using interphase fluorescence in situ hybridization. RESULTS: Alterations in 11q were found in 159 of 611 tumors in the whole cohort (26%) and were associated with stage 4 disease (P < 0.001) and age at diagnosis of >2.5 years (P < 0.001). Event-free survival and overall survival were significantly poorer for patients with 11q loss in the whole cohort (event-free survival and overall survival, P < 0.001) and in different subsets: neuroblastoma without MYCN amplification (MNA) (event-free survival and overall survival, P < 0.001), with MNA (event-free survival, P = 0.03; overall survival, P = 0.02), and MYCN-nonamplified stage 1, 2, 3, and 4S tumors with and without del 1p (event-free survival and overall survival, P < 0.001). In stage 4, the 11q status did not discriminate outcome. By multivariate analysis, the 11q status proved prognostic for event-free survival in the whole cohort (P = 0.008; hazard ratio, 1.573) and in the subgroup of stages 1, 2, 3, and 4S without MNA (P < 0.001; hazard ratio, 3.534). Moreover, 11q alterations were strongly correlated with the occurrence of metastatic relapses (P < 0.001). CONCLUSION: In addition to the current risk stratification, the status of 11q enables the identification of patients with an increased risk for relapses in general and metastatic relapses in particular.

Favorable outcome of triploid neuroblastomas: a contribution to the special oncogenesis of neuroblastoma.

There is a well-known association between patient outcome and tumor ploidy in neuroblastoma. To date, however, most clinical trials have not used this parameter for therapy stratification. Using conventional cytogenetics and fluorescence in situ hybridization (FISH), we investigated 36 tumors in terms of ploidy and chromosome 1 copy number (polysomy). In addition, interphase FISH for polysomy was performed on a second cohort of 440 neuroblastomas, together with the status of 1p, MYCN, and 11q. The main goals were as follows: (1) to assess the reliability of FISH to determine ploidy; (2) to illustrate associations between somy 1 and clinical/biologic factors; and (3) to investigate the role of somy 1 for predicting outcome. The comparison between karyotyping and FISH in the smaller cohort revealed 86% consistency between ploidy and polysomy (31/36). According to FISH, trisomic tumors in the second cohort showed structural chromosomal aberrations less frequently compared to di-/tetrasomic tumors (15 vs. 60%, P < 0.001). The portion of trisomic neuroblastomas was higher in stages 1, 2, and 4S versus stages 3 and 4 (55 vs. 24%, P < 0.001) and in children 18 months or younger versus those older than 18 months (55 vs. 19%, P < 0.001). Prognosis was significantly better for trisomic tumors versus di-/tetrasomic in the whole cohort [event-free (EFS) and overall survival (OS), P < 0.001]. In the subgroup without abnormalities of other molecular markers, EFS of trisomic neuroblastomas was better (P = 0.048), but was most likely due to an unequal stage distribution. In further subgroups, in terms of age and stage, significance between the somy groups was not reached, neither for EFS nor OS. The multivariate analyses including age, stage, chromosomal markers, and somy 1 confirmed the lack of independent prognostic power for the copy number of chromosome 1. This study demonstrates the following: (1) FISH is a practical alternative to other more labor-intensive techniques for determining ploidy; (2) trisomic tumors correlate with younger age at diagnosis, localized stage, and the lack of structural alterations; and (3) polysomy is not an independent prognostic marker. The sharp decline of trisomic tumors after the age of 18 months supports the idea of different genetic tumor entities.

Quantitative real-time PCR for quick simultaneous determination of therapy-stratifying markers MYCN amplification, deletion 1p and 11q.

Amplification of the oncogene MYCN as well as deletions in 1p and 11q are important prognostic and in part therapy-stratifying factors in human neuroblastoma. Due to the increasing clinical relevance of these molecular markers, accurate and fast assessment of the status of MYCN, 1p, and 11q is essential. As 2 techniques are recommended to avoid artefacts and to circumvent technical limitations, we developed a real-time q-PCR assay using genomic DNA from frozen and paraffin-embedded tissue as template as an alternative to LOH analyses and Southern blot (SB) and in addition to fluorescence in situ hybridization (FISH). Determination of deletion or amplification was achieved by comparing the copy number of a target gene (TG from the region of interest) to an unaffected reference gene (RG) within the same chromosome. PCR raw data were normalized to a serial dilution standard curve and a ratio TG/RG was created. The ratio to define a deletion was set as 0.5 (= expected ratio 1 TG copy/2 RG copies), the amplification threshold was set as >10.0. Data were compared to results obtained by FISH and were consistent in 10 of 13 (77%) tumors with deletion 1p, 18 of 20 (90%) with deletion 11q, 12 of 12 (100%) with MYCN amplification, and 146 of 151 (97%) samples without any aberration. Three tumors with aberrations in 1p and 2 tumors with aberrations in 11q were detectable by FISH but not by PCR. Three cases indicated a deletion 11q, 1 tumor a deletion 1p by PCR only. Specificity was 98% for 1p and MYCN each and 92% for 11q. Sensitivity was 77% for 1p, 90% for 11q, and 100% for MYCN. The discrepant results were mostly caused by heterogeneous cell populations of the investigated tissue; the use of real-time q-PCR for the detection of chromosomal aberrances in NB enables a fast and reliable assessment of the 3 most relevant chromosomal aberrations simultaneously. As the assay does not require reference tissue, can be performed with small amounts of DNA, and allows the investigation of paraffin-embedded material for the MYCN-status, it can be regarded alternative to LOH or SB analyses and in addition to FISH.

MYCN-status in neuroblastoma: characteristics of tumours showing amplification, gain, and non-amplification.

While the role of MYCN-amplification (MNA) for risk assessment in neuroblastoma is undisputed, the phenomenon of gene copy excess below the amplification threshold is rarely described. To discuss biological characteristics and the clinical impact of the so-called MYCN-gain versus amplified or non-amplified cases, we investigated the MYCN status of 659 patients uniformly analysed by fluorescence in situ hybridisation. The number of MYCN-amplified tumours in our cohort was 18% (116/659); an additional 38 tumours (6%) displayed MYCN-gain. Both alterations were associated with an advanced stage disease, an increased patient age and further chromosomal alterations. Most of the amplified neuroblastomas displayed 1p aberrations, whereas MYCN-gain tumours correlated with 11q alterations. In contrast to the amplified cases, tumours with gain displayed no increased MYCN RNA levels. MNA versus non-amplification discriminated between good and poor outcomes, independent of stage, age and the degree of amplification. However, patients with amplified tumours showed a significantly better outcome when this was combined with non-stage 4 disease and age <1 year versus stage 4 and age < 1 year. Although MYCN-gain was associated with poor event-free-survival (EFS) in stages 1-3, 4S (P=0.005), this might be related to associated genetic aberrations and not to the MYCN-gain itself. A survival difference between neuroblastomas with gain and single copy MYCN could not be delineated. In conclusion, MNA predicts a poor outcome for neuroblastoma patients of all stages and age. MYCN-gain is also a characteristic feature of advanced stage tumours and older patients, but is not associated with higher MYCN expression and appears not to be discriminative in predicting patient outcome.

Gain of distal chromosome arm 17q is not associated with poor prognosis in neuroblastoma.

PURPOSE: In several studies, gain of the distal long arm of chromosome 17 was shown to be a frequent and prognostically relevant factor in neuroblastoma, in addition to MYCN amplification (MNA) or 1p deletion. We asked whether this observation could be confirmed in a German cohort. EXPERIMENTAL DESIGN: To evaluate the frequency and prognostic impact of 17q gain, we investigated tissue samples from 193 neuroblastoma patients by the use of fluorescence in situ hybridization. The DNA probe (MPO) was located in distal 17q in the region of interest as used by several groups. To analyze the association of patients' outcome with the breakpoint position within 17q, we used the more proximal DNA probe ERBB2 in 17q21 on a selected number of cases. Gain was defined as an excess of 17q material compared with the chromosome 17 centromere in at least 50% of the analyzed tumor cells. In addition, alterations in chromosomes 1p, 3p, and 11q, as well as MYCN status, were determined to describe the interrelationship between the different parameters and to evaluate an independent prognostic influence. RESULTS: Gain of 17q was found in 61% of the investigated tumors. An additional 23% displayed an excess of 17q in less than half of all cells. Gain correlated with stage 4 disease (P = 0.003) and with other chromosomal alterations, such as 1p (P < 0.001), 3p (P = 0.01), 11q (P = 0.001), and MNA (P = 0.016), as well as with increased patient age (P = 0.01). Outcome was not different between patients with 17q gain compared with those without, however. A prognostic influence could not be delineated in all stages or in localized or in stage 4 subgroups or in the MYCN nonamplified patient cohort. Outcome did not differ between patients with additional 17q material in <10% of the cells or in >70%. Patients showing a breakpoint in the more proximal part of 17q could not be described as having a more favorable outcome compared with patients with a more distal breakpoint. Prognosis was poor in patients with MNA and/or 11q loss either with or without 17q gain. A multivariate analysis including the chromosomal parameters 17q, 11q, and MYCN status, as well as stage, showed MYCN and 11q status (P < 0.001), but not 17q or stage as significant prognostic factors. CONCLUSION: Although the most frequent aberration in neuroblastoma to date, we found no association between 17q gain and an inferior prognosis in our cohort; the status of MYCN and 11q, however, allowed reliable prediction of patients' outcomes.

FISH analyses for alterations in chromosomes 1, 2, 3, and 11 define high-risk groups in neuroblastoma.

BACKGROUND: The prognostic chromosomal markers 1p loss and MYCN amplification (MNA) are only present in a subgroup of approximately 30% of neuroblastomas. To further characterize high and low risk subsets we investigated alterations in chromosome arms 3p and 11q, additional changes in 1p and MYCN as well as the somy-status of chromosome 1 in the same sample. PROCEDURE: Fluorescence in situ hybridization (FISH) was used as an alternative technique to PCR/LOH- or comparative genomic hybridization (CGH) analyses. Alterations in chromosomes 3p and 11q were investigated in 182 unselected tumors, 1p loss and MNA in 174 and 179 of these, respectively. The somy-status of chromosome 1 was determined in 165 tumors as it highly correlates with the tumor ploidy. RESULTS: Alterations in the four chromosomal regions were found in the following frequencies: 3p26: 19%, 11q23: 29%, 1p36: 29%, MNA: 19%. Fifty-two percent of all cases displayed structural aberrations in at least one chromosomal region, 83% in stage 4 and 30% in stages 1-3, 4s. All aberrations were thus correlated with stage 4 disease but were also present in a substantial subset of localized and 4s tumors. Trisomy of chromosome 1 was found in 38% of the tumors, disomy or tetrasomy in 62%. Patients with alterations in any of the four chromosomes and di/tetrasomy 1 showed a significantly increased age at diagnosis. Loss in 1p and MNA were closely associated with each other, as well as 3p and 11q aberrations but not the groups 1p/MNA versus 3p/11q. Only a small portion of trisomic tumors showed aberrations in at least one of the four chromosomal regions (14%) in contrast to the majority of the di/tetrasomic cases (74%). As already known the MYCN status discriminated between good and poor outcome in localized and metastatic stage 4 tumors. In addition alterations in 1p or 11q, deletion in 3p and di/tetrasomy 1 were associated with an unfavorable prognosis in MYCN single copy tumors of stages 1-3, 4s. Multivariate analysis revealed 11q alterations and MNA as the most important chromosomal prognostic factors in all stages. CONCLUSION: FISH analyses for chromosomal alterations in 3p and 11q as well as in 1p and MYCN allows to define different groups with an increased risk for disease progression.

Deletions in chromosome arms 3p and 11q are new prognostic markers in localized and 4s neuroblastoma.

PURPOSE: To find new nonrandom chromosomal changes in neuroblastoma (NB) with a potential to forecast the patient's outcome, alterations in chromosome arms 3p and 11q were investigated. EXPERIMENTAL DESIGN: Frequency and prognostic potential of 3p and 11q alterations in 144 NBs were analyzed using interphase fluorescence in situ hybridization with DNA probes for 3p26 and 11q23. Aberrations were defined as deletion (monosomy of a specific region) or imbalance (at least two intact and additional 3p26- or 11q23-deleted chromosomes). RESULTS: Forty-two of 144 cases (29%) displayed 11q alterations (21% deletions, 8% imbalances). Most aberrations were associated with stage 4 disease (28 of 59, 47%) but were also present in localized and 4s tumors (14 of 85, 16%; P = 0.007). Patients with 11q deletion/imbalance were significantly older at diagnosis (P < 0.001). Changes in 3p were detected in 26 of 144 (18%) samples (15% deletions, 3% imbalances). These alterations were also associated with stage 4 [20 of 59 (34%) versus 6 of 85 (7%) in stages 1-3 and 4s, P = 0.007], and the median age was increased (P < 0.001). Aberrations in both chromosomes were highly associated with each other (P < 0.001). MYCN amplification (MNA) was detected in 10% and 12% of tumors with 11q and 3p alterations, and changes in 1p36 occurred in 13% and 26% of the 3p- and 11q-aberrant tumors. MYCN amplification and 11q deletion/imbalance tended to show an inverse correlation (P = 0.07) as well as 1p and 3p deletion/imbalance (P = 0.07). Patients with 3p and 11q abnormalities in localized/4s tumors showed an inferior outcome compared with those without these alterations (P = 0.002 and P = 0.0027, respectively), in particular in MYCN single copy tumors (P < 0.0001 and P = 0.0006, respectively). CONCLUSION: Alterations in 3p and 11q are frequent nonrandom aberrations in NB and define a new high-risk subgroup in MYCN single copy stage 1-3 and 4s disease.

Fluorescence in situ hybridization analyses of chromosome band 1p36 in neuroblastoma detect two classes of alterations.

Chromosomal alterations in 1p36 were investigated in 196 neuroblastoma tumors using fluorescence in situ hybridization. Additionally, by using the same technique, it was determined whether MYCN was amplified in 149 of these. The most frequent finding was a deletion in 1p36, leading to monosomy of this region (29 cases, 15%). Furthermore, we found tumors with at least two intact copies of chromosome 1 and additional 1p36-deleted copies. Altogether, 21 tumors (11%) displayed this imbalance of 1p36. Similar to the cases with deletion, imbalances were predominantly found in stage 4 tumors (81%), and they were significantly associated with an increased patient age (P = 0.01). Nearly all 1p-deleted tumors showed amplification of MYCN (24/27 analyzed samples, 89%), whereas only 8 of 21 (38%) with imbalance did. Eight cases with imbalance were investigated for loss of heterozygosity (LOH) using microsatellite markers in 1p35-36. Only 4 displayed 1p36 LOH, whereas the remaining 4 were heterozygous. Both patients with deletion of 1p and with imbalance had a poor outcome [3-year rate of event-free-survival (EFS): 33 +/- 15% and 41 +/- 15%], which was significantly worse compared to the outcome of patients without 1p alterations (3-year EFS: 70 +/- 5%; P = 0.01 and P = 0.0059). We conclude that besides monosomic short arm deletions, imbalance of 1p36 is a strong marker of a poor prognosis in neuroblastoma and not necessarily associated with MYCN amplification and LOH.