No CDKN2 mutations in neuroblastomas.

Mutations of CDKN2 have been found recently in melanoma and many other tumor types. Neuroblastoma shares with melanoma a neuroectodermal origin and a high incidence of deletions of the short arm of chromosome 1. Therefore, we analyzed 18 primary neuroblastomas and 9 tumor-derived cell lines for mutations in CDKN2. We used PCR-single-strand conformation polymorphism to examine exons 1 and 2 of the CDKN2 gene for mutations, but none were detected. Furthermore, no homozygous deletions were detected and there was no loss of heterozygosity at the closely linked IFNA locus. We conclude that disruption of the CDKN2 gene is not required for malignant transformation of human neuroblastomas.

Significance of chromosome 1p loss of heterozygosity in neuroblastoma.

We analyzed 156 primary neuroblastoma tumor samples for loss of heterozygosity at the distal short arm of chromosome 1 (1p LOH). We also compared 1p LOH with known clinical and genetic prognostic variables as well as patient outcome. 1p LOH was detected in 30 of 156 tumors (19%) and was strongly associated with adverse clinical and biological features. 1p LOH was also strongly predictive of a poor outcome in univariate analyses (estimated 4-year survival, 32 +/- 10% SE versus 76 +/- 5% SE; P < 0.001). However, the prognostic value of 1p LOH was equivocal when stratified for amplification of the MYCN oncogene (P = 0.16). We conclude that 1p LOH is an important component of a pattern of genetic abnormalities in neuroblastoma associated with an aggressive clinical course.

Human Krüppel-related 3 (HKR3): a candidate for the 1p36 neuroblastoma tumour suppressor gene?

Human Krüppel-related 3 (HKR3) is a zinc finger gene that maps within chromosome subbands 1p36.2-.3, a region postulated to contain a tumour suppressor gene associated with advanced neuroblastomas. Genomic clones of HKR3 were isolated from a P1 library and physically mapped to within 40 kb of D1S214 at 1p36.3. The gene is ubiquitously expressed in human tissues, but especially high levels are present in human fetal and adult nervous tissues. Hemizygous deletion of HKR3 in a lymphoblastoid cell line derived from a neuroblastoma patient with a constitutional 1p36 interstitial deletion and in the neuroblastoma cell line SK-N-AS, which also has a small interstitial 1p36 deletion, has been observed. Allelic loss at D1S214 in 15/15 informative primary neuroblastoma specimens with 1p36 deletions has also been observed. In a panel of 16 neuroblastoma cell lines, no gross genomic DNA rearrangements were noted, the gene was always expressed (albeit at variable levels) and there was no evidence for truncating mutations. Furthermore, there were no mutations detected in the zinc finger coding region in four neuroblastoma cell lines with 1p deletions analysed by direct sequence analysis. We conclude that HKR3 is a novel zinc finger gene that maps to a region of the genome commonly rearranged or deleted in neuroblastoma and other human cancers.

Molecular analysis of the region of distal 1p commonly deleted in neuroblastoma.

Cellular, cytogenetic, and molecular evidence indicates that chromosome band 1p36 is often deleted in neuroblastoma cell lines and tumours, suggesting the presence of one or more tumour suppressor genes in this region. We used a multifaceted approach to analyse the commonly deleted region, 28 distal 1p-specific polymorphic loci were used to detect loss of heterozygosity (LOH) in a panel of primary neuroblastoma tumours. Thirty-two of 122 tumours (26%) demonstrated LOH at three or more loci. In addition, a patient with a constitutional deletion of 1p36.2-.3 and two neuroblastoma cell lines with 1p36 abnormalities were characterised by FISH. When combined with the LOH data, a single consensus region of deletion was defined proximally by PLOD and distally by D1S80, a region spanning approximately five megabases. Several proposed candidate tumour suppressor genes, including ID3, CDC2L1, DAN, PAX7, E2F2, TNFR2 and TCEB3, map outside of this region; however, the transcription factor HKR3 cannot be excluded. LOH for 1p is correlated with adverse clinical and biological features and a poor prognosis, but 1p LOH is not an independent predictor of overall survival. To identify additional candidate genes, an integrated physical map of 1p35-36 is being constructed. The current map includes 445 polymerase chain reaction (PCR)-formatted markers and 608 YACs. This map will help identify region-specific transcripts by direct selection and sequencing.

A simple combined microdissection and aspiration device for the rapid procurement of single cells from clinical peripheral blood smears.

Molecular analysis of cells from cytology specimens can help to establish a diagnosis in ambiguous cases. However, mutations in heterogeneous samples might not be detected because of the diluting effect of DNA from normal background cells. Even if a mutation were detected, it could not be traced back to a specific cell type. Molecular analysis of single cells circumvents this problem. Both mechanical and laser assisted methods have been described for the selective procurement of cells from histology slides; however, they have the drawback of either being technically demanding or expensive. Furthermore, it is nuclear whether they can be applied to cytology specimens. Finally, few of these techniques are able to procure single cells. Therefore, we developed a simplified combined microdissection and aspiration device for the rapid procurement of single cells from clinical cytology specimens. The principle of this device, called the cytopicker, is the combination of the microdissection tool, a steel cannula, with the aspiration tool, a glass capillary connected to a vacuum, into one device. Steel cannulae are optimal for microdissection of cells from the hard matrix of cytology specimens but aspirate poorly. On the other hand, glass capillaries are suboptimal for dissecting but aspirate very well. Combining both tools into one by inserting the capillary into the cannula allows optimal dissection using the cannula (with the glass capillary with-drawn and thus protected), followed by optimal aspiration using the capillary (after being advanced through the cannula). All movements of the device are controlled by just one micromanipulator, making the cytopicker inexpensive to manufacture. The cytopicker can rapidly and simply procure single cells, such as lymphoblasts, from cytology specimens, such as peripheral blood smears. DNA from these cells can be amplified by PCR. However, precautions have to be taken to avoid contamination. Once improved further, the cytopicker might facilitate molecular analysis in the routine cytology laboratory.

Whole genome amplification of single cells from clinical peripheral blood smears.

Molecular analysis of clinical samples has been hampered by the lack of fresh or frozen specimens and the presence of contaminating background cells within samples obscuring the molecular analysis of the pathological cells of interest. Routine cytology specimens are a ubiquitous and abundant, yet largely untapped, source of clinical samples for molecular analysis. Morphologically defined single cells from peripheral blood smears can be microdissected from contaminating background cells and their whole genome amplified by primer extension preamplification, followed by polymerase chain reaction analysis of the specific DNA of interest. Thus, molecular information can be traced back to the cell of origin in these clinical specimens. This should allow studies on clonality, loss of heterozygosity, mutation, or amplification of multiple loci from one single cell in haematological smears and possibly other clinical cytology specimens.

Cloning, chromosomal localization, physical mapping, and genomic characterization of HKR3.

The Krüppel-type zinc finger proteins are members of a conserved family of transcription factors that are important in developmental regulation. Altered expression of several of these proteins has been implicated in human diseases, including cancer. We report the cloning, mapping, and characterization of the zinc finger gene Human Krüppel-Related 3 (HKR3). Genomic clones of HKR3 were isolated from a P1 library and localized to human chromosome subband 1p36.3 by human-rodent somatic cell hybrid mapping and fluorescence in situ hybridization. The gene was physically mapped to within 40 kb of D1S214 by YAC content and long-range restriction mapping. HKR3 spans 9.5 kb of genomic DNA and is contained in 11 exons. Sequencing defined each of the exon/intron splice site junctions and identified a CpG island in the 5' region of the gene. HKR3 is ubiquitously expressed in human tissues as at least two major transcripts, the shorter of which excludes a conserved finger-associated box and a putative acidic activation domain contained in the full-length transcript. HKR3 is a novel zinc finger gene that maps to a region of the genome commonly rearranged or deleted in human cancers.

Physical mapping and genomic structure of the human TNFR2 gene.

The tumor necrosis factor receptor 2 (TNFR2) gene localizes to 1p36. 2, a genomic region characteristically deleted in neuroblastomas and other malignancies. In addition, TNFR2 is the principal mediator of the effects of TNF on cellular immunity, and it may cooperate with TNFR1 in the killing of nonlymphoid cells. Therefore, we undertook an analysis of the genomic structure and precise physical mapping of this gene. The TNFR2 gene is contained on 10 exons that span 26 kb. Most of the functional domains of TNFR2 are encoded by separate exons, and each of the repeats of the extracellular cysteine-rich domain is interrupted by an intron. The genomic structure reveals a close relationship to TNFR1, another member of the TNFR superfamily. Based on electrophoretic analysis of yeast artificial chromosomes, TNFR2 maps within 400 kb of the genetic marker D1S434. In addition, we have identified a new polymorphic dinucleotide repeat within intron 4 of TNFR2. The genetic sequence information and exon-intron boundaries we have determined will facilitate mutational analysis of this gene to determine its potential role in neuroblastoma, as well as in other cancers with characteristic deletions or rearrangements of 1p36.