Loss of heterozygosity for chromosome 14q in neuroblastoma.

BACKGROUND: Neuroblastoma is a genetically heterogeneous disease, with subsets of tumors demonstrating rearrangements of several genomic regions. Preliminary studies from several groups have identified loss of heterozygosity (LOH) for the long arm of chromosome 14 (14q) in 20-25% of primary neuroblastomas. PROCEDURE: To determine precisely the frequency and extent of 14q deletions, we performed LOH analysis for a large series of primary neuroblastomas using a panel of 11 highly polymorphic markers. RESULTS: LOH was detected in 83 of 372 tumors (22%). Although the majority of tumors with allelic loss demonstrated allelic loss for all informative markers, 13 cases showed LOH for only a portion of 14q. A single consensus region of deletion, which was shared by all tumors with 14q LOH, was defined within 14q23-q32 between D14S588 and the 14q telomere. Allelic loss for 14q was strongly correlated with the presence of 11q LOH (P < 0.001 ) and inversely correlated with MYCN amplification (P= 0.04). CONCLUSIONS: LOH for 14q was evident in all clinical risk groups, indicating that this abnormality may be a universal feature of neuroblastoma tumor development. These findings suggest that a tumor suppressor gene involved in the initiation or progression of neuroblastoma is located within distal 14q.

Detailed molecular analysis of 1p36 in neuroblastoma.

BACKGROUND: Several lines of evidence es tablish that chromosome band 1p36 is frequently deleted in neuroblastoma primary tumors and cell lines, suggesting that a tumor suppressor gene within this region is involved in the development of this tumor. PROCEDURE: We analyzed the status of 1p36 in primary neuroblastomas and cell lines to define the region of consistent rearrangement. RESULTS: Loss of heterozygosity (LOH) studies of primary neuro blastomas identified allelic loss in 135 of 503 tumors (27%), with the smallest region of overlap (SRO) defined distal to D15214 (1p36.3). No homozygous deletions were detected at 120 loci mapping to 1p36.1-p36.3 in a panel of 46 neuroblastoma cell lines. A recently identified patient with neuroblastoma was found to have a constitutional deletion within 1p36.2-p36.3, and this deletion, when combined with the LOH results, defined a smaller SRO of one megabase within 1p36.3. We constructed a comprehensive integrated map of chromosome 1 containing 11,000 markers and large-insert clones, a high-resolution radiation hybrid (RH) map of 1p36, and a P1-artificial chromosome (PAC) contig spanning the SRO, to further characterize the region of interest. Over 768 kb (75%) of the SRO has been sequenced to completion. Further analysis of distal 1p identified 113 transcripts localizing to 1p36, 21 of which were mapped within the SRO. CONCLUSION: This analysis will identify suitable positional candidate transcripts for mutational screening and subsequent identification of the 1p36.3 neuroblastoma suppressor gene.

Molecular evolution of the CMT1A-REP region: a human- and chimpanzee-specific repeat.

The CMT1A-REP repeat consists of two copies of a 24-kb sequence on human chromosome 17p11.2-12 that flank a 1.5-Mb region containing a dosage-sensitive gene, peripheral nerve protein-22 (PMP22). Unequal meiotic crossover mediated by misalignment of proximal and distal copies of the CMT1A-REP in humans leads to a 1.5-Mb duplication or deletion associated with two common peripheral nerve diseases, Charcot-Marie-Tooth disease type 1A (CMT1A) and hereditary neuropathy with liability to pressure palsies (HNPP). Previous molecular hybridization studies with CMT1A-REP sequences suggested that two copies of the repeat are also found in the chimpanzee, raising the possibility that this unique repeat arose during primate evolution. To further characterize the structure and evolutionary synthesis of the CMT1A-REP repeat, fluorescent in situ hybridization (FISH) analysis and heterologous PCR-based assays were carried out for a series of primates. Genomic DNA was analyzed with primers selected to differentially amplify the centromeric and telomeric ends of the human proximal and distal CMT1A-REP elements and an associated mariner (MLE) sequence. All primate species examined (common chimpanzee, pygmy chimpanzee, gorilla, orangutan, gibbon, baboon, rhesus monkey, green monkey, owl monkey, and galago) tested positive for a copy of the distal element. In addition to humans, only the chimpanzee was found to have a copy of the proximal CMT1A-REP element. All but one primate species (galago) tested positive for the MLE located within the CMT1A-REP sequence. These observations confirm the hypothesis that the distal CMT1A-REP element is the ancestral sequence which was duplicated during primate evolution, provide support for a human-chimpanzee clade, and suggest that insertion of the MLE into the CMT1A-REP sequence occurred in the ancestor of anthropoid primates.

Mapping of the kinesin-related gene ATSV to chromosome 2q37.

The human ATSV (axonal transporter of synaptic vesicles) gene encodes an anterograde axonal motor transport protein and demonstrates homology to the kinesin gene family in several species. The human ATSV gene was mapped to chromosome 2q37 by screening of a human/rodent somatic cell hybrid panel by the polymerase chain reaction and by fluorescent in situ hybridization analysis using genomic and cDNA clones.