Molecular cytogenetic analysis of a human breast metastasis model: identification of phenotype-specific chromosomal rearrangements.

We have previously characterized an experimental system in which the role of candidate metastasis-related genes can be screened and tested. Monoclonal cell lines M4A4 and NM2C5 originated from the MDA-MB-435 breast tumor cell line but have opposite metastatic capabilities in vivo. To investigate gross genetic changes present in this model, we performed a detailed molecular cytogenetic evaluation of the parental cell line, the M4A4 and NM2C5 cell lines, and related clones of metastatic phenotype. Using a combination of spectral karyotyping (SKY), G-banding, and fluorescence in situ hybridization (FISH), we were able to resolve the identity of all common marker chromosomes present in MDA-MB-435 cells, and to define several chromosomal changes, which were specific to each monoclonal cell line. Twenty identical structural and numerical chromosomal aberrations, including trisomies of chromosomes 2 and 5 as well as t(1;7), t(1;10), t(8;11), t(8;15), and t(20;21), were present in all cell lines. The majority of translocations were relatively simple non-reciprocal rearrangements, most frequently involving chromosomes 19, 1, 6, and 20. Chromosomal gains of 1, 7q, 8q, and 20q are common alterations in breast cancer. The metastatic M4A4 cell line contained numerous unique chromosomal aberrations, of which an abnormal banding region on chromosome 22, abr(22), was the best clone-specific identifier. Conversely, the t(12;15)(q22;q26.1) was found exclusively in the non-metastatic NM2C5 cell line. The integration of these karyotypic data with other cytogenetic and genomic databases will enhance our ability to identify genes that play critical roles in cancer development and progression.

The interrelationship between DRIM gene expression and cytogenetic and phenotypic characteristics in human breast tumor cell lines.

BACKGROUND: In order to facilitate the identification of genes involved in the metastatic phenotype we have previously developed a pair of cell lines from the human breast carcinoma cell line MDA-MB-435, which have diametrically opposite metastatic potential in athymic mice. Differential display analysis of this model previously identified a novel gene, DRIM (down regulated in metastasis), the decreased expression of which correlated with metastatic capability. DRIM encodes a protein comprising 2785 amino acids with significant homology to a protein in yeast and C. elegans, but little else is currently known about its function or pattern of expression. In a detailed analysis of the DRIM gene locus we quantitatively evaluated gene dosage and the expression of DRIM transcripts in a panel of breast cell lines of known metastatic phenotype. RESULTS: Fluorescent in situ hybridization (FISH) analyses mapped a single DRIM gene locus to human chromosome 12q23~24, a region of conserved synteny to mouse chromosome 10. We confirmed higher expression of DRIM mRNA in the non-metastatic MDA-MB-435 clone NM2C5, relative to its metastatic counterpart M4A4, but this appeared to be due to the presence of an extra copy of the DRIM gene in the cell line's genome. The other non-metastatic cell lines in the series (T47D MCF-7, SK-BR-3 and ZR-75-1) contained either 3 or 4 chromosomal copies of DRIM gene. However, the expression level of DRIM mRNA in M4A4 was found to be 2-4 fold higher than in unrelated breast cells of non-metastatic phenotype. CONCLUSIONS: Whilst DRIM expression is decreased in metastatic M4A4 cells relative to its non-metastatic isogenic counterpart, neither DRIM gene dosage nor DRIM mRNA levels correlated with metastatic propensity in a series of human breast tumor cell lines examined. Collectively, these findings indicate that the expression pattern of the DRIM gene in relation to the pathogenesis of breast tumor metastasis is more complex than previously recognized.

Functional genomic comparison of lineage-related human bladder cancer cell lines with differing tumorigenic and metastatic potentials by spectral karyotyping, comparative genomic hybridization, and a novel method of positional expression profiling.

We have recently characterized T24T, an invasive and metastatic variant of the T24 human bladder cell line, resulting in a model for bladder cancer progression. To gain additional insight into the repertoire of genetic changes that may be responsible for the invasive and metastatic phenotype, we used spectral karyotyping (SKY) in combination with comparative genomic hybridization (CGH) in these cells. To assess the functional significance of the genetic differences found between the two cell lines, we have developed a positional expression profiling (PEP) method for comparing gene expression data obtained from oligonucleotide microarrays based upon chromosomal position. Using SKY and CGH, we were able to define the genetic changes in the cell lines, and in addition, resolve the identity of all marker chromosomes from our initial karyotyping and G-band analysis. PEP analysis revealed important similarities and differences when compared with the cytogenetic data, allowing insights of how genomic structural changes affect gene expression on a regional scale. The shape of the expression profiles for chromosomes 8, 12, and X correlated well with the numerical imbalances revealed by CGH and SKY, whereas regions like 10q, gained in T24T compared with T24, was not associated with changes in gene expression. Furthermore, we have shown that 12p, a region of agreement between CGH and PEP harbors RhoGDI2, a candidate gene, the expression of which inversely correlates with bladder tumor progression, demonstrating the usefulness of this multimodal approach in identifying promising genetic changes that may be responsible for the invasive phenotype.

Analysis of the regulation of the A33 antigen gene reveals intestine-specific mechanisms of gene expression.

The A33 antigen is a transmembrane protein expressed almost exclusively by intestinal epithelial cells. The level of its expression is robust and uniform throughout the rostrocaudal axis of the human and mouse intestines. In the colon, strong expression is found in the basolateral membranes of both the proliferating cells in the lower regions of the crypts and the differentiating cells in the upper regions of crypts. Similarly, in the small intestine, the protein is highly expressed by all the epithelial cells in the crypts and by the differentiated cells migrating over the villi. Thus, the A33 antigen has emerged as a definitive marker for all intestinal epithelial cells, irrespective of cell lineage and differentiation status. To understand the molecular mechanisms mediating this rare tissue-specific expression pattern, we undertook a comprehensive analysis of the 5'-regulatory region of the human A33 antigen gene. This allowed us to point to positive cis-regulatory elements incorporating consensus Krüppel-like factor and caudal-related homeobox (CDX)-binding sites, located just upstream from the human A33 antigen transcription start site, as being important for the intestine-specific expression pattern of this gene. Further analysis provided evidence that the A33 antigen gene may be one of only a few target genes to be described thus far for the intestine-specific homeobox transcription factor, CDX1. Taken together, our data lead us to propose that the activity of CDX1 is pivotal in mediating the exquisite, intestine-specific expression pattern of the A33 antigen gene.

Comprehensive karyotyping of the HT-29 colon adenocarcinoma cell line.

The tumor cell line HT-29 was derived from a primary adenocarcinoma of the rectosigmoid colon. HT-29 is hypertriploid (3n+) and has accumulated numerous chromosomal structural aberrations. To identify material involved in chromosome rearrangements, we performed a comprehensive cytogenetic analysis using G-banding, spectral karyotyping (SKY), and fluorescence in situ hybridization (FISH). The combination of molecular cytogenetic techniques enabled us to define the first comprehensive karyotype for HT-29. Seventeen marker chromosomes were found in 75-100% of metaphase cells, generally in a single copy per cell. We confirmed the composition of eight previously described markers, refined the classification of seven others, and identified two novel marker chromosomes. Notable aberrations included a reciprocal translocation between chromosomes 6 and 14 and an unusual, large derivative chromosome 8 composed entirely of 8q material. The telomere status, evaluated by FISH, revealed telomeric signals at the termini of all chromosomes. No interstitial telomeric sequences were observed in any cell. Although numerous chromosomal aberrations are present in HT-29, the cell line appears to have retained a high level of genomic stability during passage in culture since undergoing transformation. The excellent resolving power of SKY, coupled with additional information obtained from molecular cytogenetic analyses, will improve our ability to identify genetic lesions characteristic of cancer.