Elucidation of the mechanism of homozygous deletion of 3p12-13 in the U2020 cell line reveals the unexpected involvement of other chromosomes.

Homozygous deletions in tumor cells have been useful in the localization and validation of tumor suppressor genes. We have described a homozygous deletion in a lung cancer cell line (U2020) which is located within the most proximal of the three regions on the short arm of chromosome 3 believed to be lost in lung cancer development. Construction of a YAC contig map indicates that the deletion spans around 8 Mb, but no large deletion was apparent on conventional cytogenetic analysis of the cell line. To investigate this paradox, whole chromosome, arm-specific, and regional paints have been used. This analysis has revealed that genetic loss has occurred by complex rearrangements of chromosomes 3, rather than simple interstitial deletion. These studies emphasize the power of molecular cytogenetics to disclose unsuspected tumor-specific translocations within the extremely complex karyotypes characteristic of solid tumors.

A combined approach of conventional and molecular cytogenetics for detailed karyotypic analysis of the small cell lung carcinoma cell line U2020.

Until recently the ability to analyze complex karyotypic rearrangements was totally dependent upon light microscopy of G-banded chromosomes. Developments in the area of molecular cytogenetics have revolutionized such analysis, making it possible to determine the nature of complex rearrangements. An extensive analysis has been made of the small cell lung carcinoma (SCLC) cell line U2020, using a combined approach of conventional and molecular cytogenetics, enabling a highly detailed karyotype to be constructed revealing rearrangements previously undetected by G-banding alone. This approach offers the opportunity to reassess other tumor karyotypes, particularly those of high complexity found in solid tumors, for tumor-specific consistent rearrangements indecipherable by conventional karyotyping.

Homozygous deletions at 3p12 in breast and lung cancer.

We have constructed a physical map of the region homozygously deleted in the U2020 cell line at 3p12, including the location of putative CpG islands. Adjacent to one of these islands, we have identified and cloned a new gene (DUTT1) and used probes from this gene to detect two other homozygous deletions occurring in lung and breast carcinomas: the smallest deletion is within the gene itself and would result in a truncated protein. The DUTT1 gene is a member of the neural cell adhesion molecule family, although its widespread expression suggests it plays a less specialized role compared to other members of the family.

Chromosome specific paints from a high resolution flow karyotype of the mouse.

Chromosomes from antigen stimulated B-cells from spleens of inbred mice have been separated using flow cytometry into 18 distinguishable peaks. Using locus-specific oligonucleotides and fluorescence in situ hybridization to banded metaphase spreads, 15 individual chromosomes were identified: 1, 2, 3, 6, 7, 8, 9, 11, 12, 16, 17, 18, 19, X and Y. The remaining six chromosomes, occurring as pairs in three peaks, 4 with 5, 10 with 13, and 14 with 15, were resolved by flow sorting chromosomes from mice carrying an appropriate homozygous translocation and 4, 5 and 14 have been isolated in this way. This is the first demonstration of how a complete set of mouse chromosome paints can be produced.

A site-directed chromosomal translocation induced in embryonic stem cells by Cre-loxP recombination.

We have developed a strategy for chromosome engineering in embryonic stem (ES) cells that relies on sequential gene targeting and Cre-loxP site-specific recombination. Gene targeting was first used to integrate loxP sites at the desired positions in the genome. Transient expression of Cre recombinase was then used to mediate the chromosomal rearrangement. A genetic selection relying on reconstruction of a selectable marker from sequences co-integrated with the loxP sites allowed detection of cells containing the Cre-mediated rearrangement. A programmed translocation between the c-myc and immunoglobulin heavy chain genes on chromosomes 15 and 12 was created by this method. This strategy will allow the design of a variety of chromosome rearrangements that can be selected and verified in ES cells or activated in ES cell-derived mice.

Thioredoxin, a mediator of growth inhibition, maps to 9q31.

The human thioredoxin gene has been provisionally mapped to 3p11-p12. Recently thioredoxin cDNA has been isolated in a procedure that detects transcripts coding for growth-suppressing proteins, and thus the chromosomal location of the gene is of particular interest. Chromosome 3 is believed to harbor several tumor suppressor genes important in the development of lung and other common epithelial tumors. To establish more firmly the chromosomal location of the human thioredoxin gene, a somatic hybrid panel was used; it identified chromosome 9 as the location of the transcribed thioredoxin gene. Fluorescence in situ hybridization of a YAC encoding the transcribed thioredoxin gene refined the localization to 9q31.

Somatic genetic changes in lung cancer and precancerous lesions.

BACKGROUND: Morphological abnormalities of the bronchial epithelium are associated with lung cancer development and are considered likely to represent the preneoplastic stage of the disease. The association of these lesions with different histological types of lung cancer was reviewed in a series of 97 samples. Lesions associated with squamous cell carcinomas provided the best samples for further study. The objective of this study was to describe the somatic genetic changes which occur in these preinvasive lesions. Among the various candidate somatic genetic changes, loss of heterozygosity on chromosome 3 and changes to the p53 gene were selected as being the most informative. It was demonstrated that these genetic changes, characteristic of fully invasive lung tumours, also occur at the premalignant stage of the disease. In an attempt to take a less directed approach to the comparison of invasive and preinvasive lesions, karyotype analysis was performed on short-term cultures of bronchial cells adjacent to the bronchial margin obtained from patients undergoing lung tumour resection. One such karyotype had a deletion to chromosome 3 (del 3p13-14) as the single abnormality. CONCLUSION: It was concluded that genetic damage to p53 and chromosome 3 is involved in the preinvasive stage of lung cancer, and that damage to chromosome 3 is a particularly early event.

Multicolour fluorescence in situ hybridisation to order small, single-copy probes on metaphase chromosomes.

In constructing complete human chromosome maps, the relative order of markers and their precise chromosomal location will be combined. Multicolour in situ hybridisation, in which two probes are simultaneously hybridised to chromosomes and subsequently distinguished, potentially will provide both types of information. Using this technique, we have produced an ordered map of eight human chromosome 3 DNA markers, using small, single-copy probes that can detect target sequences ranging in size from 4 kb to as little as 500 bp.

A 190-kilodalton protein overexpressed in non-P-glycoprotein-containing multidrug-resistant cells and its relationship to the MRP gene.

BACKGROUND: A 190k (190-kilodalton) membrane protein has been identified in several multidrug-resistant (MDR) cell lines that show decreased drug accumulation without expression of P-glycoprotein. It is not clear whether this 190k protein is involved directly in drug efflux. Recently, a gene for a putative transporter protein, MRP (multidrug resistance-associated protein) has been sequenced and localized to chromosome 16. The protein encoded by this gene contains a 7-amino-acid sequence present in the synthetic peptide used to generate the antiserum recognizing the 190k protein. PURPOSE: The study was undertaken to clarify the relationship of the 190k protein to MRP gene expression in non-P-glycoprotein-containing MDR cells of the large-cell and adenocarcinoma lung cancer lines, COR-L23 and MOR. METHODS: Expression of the 190k protein was determined by Western blot analysis and that of the MRP gene by polymerase chain reaction amplification of complementary DNA reverse transcribed from RNA. Abnormalities of chromosome 16 were investigated in chromosome spreads by fluorescence in situ hybridization. RESULTS: The amount of detectable 190k protein is closely associated with degree of drug resistance. Cell lines surviving in higher drug concentrations have greater amounts of protein, and revertant lines grown without drug for up to 28 weeks show reduced expression of the protein together with enhanced drug sensitivity. The 190k protein appears to be one of the major proteins differentially expressed in membranes of drug-resistant cells. The amount of MRP messenger RNA correlates closely with that of the 190k protein. The MDR cells contain amplified chromosome 16 material with many double minutes in the large-cell lung tumor lines and an enlarged chromosome 16 in the adenocarcinoma lines. CONCLUSION: The 190k protein detected immunologically is likely to be the protein, encoded by the MRP gene, which becomes overexpressed in these cells as a consequence of chromosomal amplification and fragmentation. IMPLICATION: Though associated with drug resistance, enhanced drug efflux, and decreased drug accumulation in cell lines, the role of this protein in clinical resistance has yet to be determined.

The probe BMS1271 identifies a new polymorphic locus (D3S1207) and maps to 3p26-pter.

We report here the characterization of a new polymorphic locus (D3S1207), shown by fluorescence in situ hybridization to map to 3p26-pter. The distal region of chromosome 3 has been implicated in both von Hippel-Lindau and 3p deletion syndrome, lung, uterine, breast, testicular, and ovarian cancers, renal cell and nasopharyngeal carcinomas, mesotheliomas, and various haematological malignancies, yet relatively few polymorphic marker probes are well mapped within this region. The identification of this new probe will therefore be particularly useful for the study of these diseases.

Molecular and genetic characterization and physical mapping of 11 new markers detecting multiallele restriction fragment length polymorphisms on the short arm of human chromosome 3.

Genetic markers with high degrees of polymorphisms are of vital importance in the construction of high resolution (2-4 cM) linkage maps of human chromosomes as specified in the short-term goals of the Human Genome Initiative. In this paper, we report on molecular and genetic characterization and physical localization of 11 new multiallele restriction fragment length polymorphism markers on human chromosome 3p. Ten of these represent three- and four-allele polymorphisms of the base substitution type probably at two adjacent restriction sites. One has been identified as a novel mini-satellite sequence comprising a variable copy number tandem repeat array of a G/T-rich 79-bp sequence. This collection of multiallele polymorphic (PIC values: 0.40-0.60) markers should prove valuable and increase the resolution power of the available chromosome 3p genetic markers.

Molecular characterization of a large homozygous deletion in the small cell lung cancer cell line U2020: a strategy for cloning the putative tumor suppressor gene.

Homozygous deletions are instrumental in the detection and cloning of tumor suppressor genes. We report the isolation and characterization of 39 new single-copy probes saturating a submicroscopic homozygous deletion detected in the DNA of the small cell lung cancer (SCLC) cell line U2020. The probes were selected from a large collection, covering the entire length of chromosome 3 with an estimated average spacing of 100-150 kb. Based on the number of probes in the deletion and the probe density, the size of the U2020 submicroscopic deletion was estimated to be in the range of 4-7 megabases. Among the deleted loci, 17 showed conservation across species, probably representing potential coding gene sequences. By genetic and physical mapping of a large randomly chosen fraction of the deleted probes, we defined the location of the U2020 deletion within chromosome band 3p12. Our cloning strategy is based on narrowing the region of interest by eliminating probes that retain heterozygosity in SCLC samples, thus selecting for probes in the region of common loss.

Ordering of six polymorphic DNA markers important in the delineation of 3p deletions in neoplasia.

Using fluorescence in situ hybridisation (FISH) the chromosomal location and relative order of six human chromosome 3 probes has been determined. The sensitivity of the technique has enabled the relative mapping of probes carrying inserts as small as 500 basepairs (bp), thus allowing the following proximal-distal probe order to be proposed: D3S30 (3p13-14), D3S4 (3p13-14), D3S2 (distal 3p14), D3S32 (3p21), D3S48E (3p21-23), and D3S11 (3p22-23). These data combined with the deletion mapping data of other researchers raise the possibility that the loss of more than one region of the short arm of chromosome 3 may be important in the development of small cell lung cancer.

Robertsonian translocation and an extra microchromosome: independent origin identified by in situ hybridization.

Robertsonian translocation may result in either a monocentric or a dicentric product involving the long arms of the participating chromosomes. In the former case a microchromosome involving the short arms of both acrocentrics would be expected to arise, but in practice is rarely observed. Where such small bisatellited markers are seen in association with Robertsonian translocations, they are assumed to represent such reciprocal products. We present a case, involving a t(14q21q) and a DA/DAPI positive microchromosome, where using in situ hybridization we show that this assumption is incorrect and that the microchromosome has arisen independently.

Characterization of a B-lymphocyte t(2;14) (p11;q32) translocation from an ataxia telangiectasia patient conferring a proliferative advantage on cells in vitro.

Patients with the recessively inherited disorder ataxia telangiectasia (AT) are particularly prone to the development of both B-cell and T-cell tumours. Specific translocations involving T-cell gene rearrangements and an unknown locus 3' of IGH have been described in AT T-cell clone and tumour cells. We describe here a t(2;14)(p11;q32) translocation which was observed in nonmalignant short-term-cultured B lymphocytes from an AT patient. In vivo, the clone of cells grew from 1% to 6% of the total cell population over a period of 2 yr. Clonal translocations may therefore be associated with AT B cells, as well as AT T cells. B lymphocytes were transformed with Epstein-Barr virus, and the t(2;14) translocation cell was cellularly cloned. Using Southern filter analysis and in situ hybridisation to define more clearly the positions of the breakpoints, we show that the translocation at 14q32 involves a deletion within the IGH chain gene of at least J1, J2, DQ52, and sequences 1.5 kb 5' of DQ52 and that the breakpoint is either adjacent to the non-deleted JH sequences or upstream of these sequences, within the D or V regions, but proximal to all members of the VHII family of genes. The breakpoint at 2p11 is outside and proximal to IGK with respect to the centromere in an unknown gene. Sub-lines with an initially low proportion of translocation cells eventually became monoclonal in vitro for these cells. This suggests they have a growth advantage in vitro.