Dinucleotide repeats flanking the renal carcinoma breakpoint at 3p14.2

Molecular evidence for derivation of metastatic cells from minor subclones of primary clear renal cell carcinomas

The production of metastases depends on changes in a large number of genes. It is also connected with the interaction of tumor cells with the environment. It has been reported that primary tumor clone domination is also an important factor in metastasizing, and in many neoplasms dominating clones are the metastatic forerunners. Up to now it is unknown whether domination of a given clone in a primary renal cell carcinoma is a crucial factor in forming metastases or rather presence or absence of specific genes imposes the major advantage in the metastatic process. To study the presence or absence of the duplication and mitotic nondisjunction event as one of the phenomenon in the creation of metastases, as well as possible derivation of metastatic cells from the minor subclone of primary tumor, we examined three metastatic renal clear-cell carcinomas in which by comparative genomic hybridization we detected the loss of 3p in the primary tumor and two copies of 3p in the corresponding metastasis. Loss of heterozygosity analyses using markers for 3p25 (D3S1038), 3p21.1 (D3S1295), and 3p14.2 (D3S1481) proved heterozygosity of at least two 3p loci in all metastatic tumors, which indicates the absence of mitotic nondisjunction event as a cause of occurrence of two copies of 3p in metastases. Our results suggest that in some of the clear-cell renal carcinomas metastatic cells may derive from minor subclones of primary tumors.

Molecular alterations to human chromosome 3p loci in neuroendocrine lung tumors

BACKGROUND

The origins of and interrelations between low grade and high grade neuroendocrine lung tumors, typical and atypical carcinoids, and small cell lung carcinoma (SCLC) have not been elucidated. Karyotypic and molecular genetic studies have demonstrated deletions in 3p in 100% of SCLCs and the candidate lung tumor suppressor gene, FHIT, at 3p14.2 is not expressed in the majority of SCLCs. Similar studies of typical and atypical carcinoids could clarify the interrelations among these tumors.

METHODS

For molecular genetic analyses, archival carcinoids and paired normal cells were microdissected from paraffin sections, deparaffinized, and DNA prepared. Oligonucleotide primer pairs for 12 microsatellite markers mapping between 3p14.2 and 3p21.3 were used to amplify allelic DNA fragments from 13 typical and 6 atypical carcinoids. In addition, an independent series of archival sections of carcinoids and SCLCs was tested by immunohistochemistry for expression of Fhit protein.

RESULTS

Of the six atypical carcinoids examined, three had lost an allele at all informative markers, whereas one had lost alleles in two distinct regions and two showed allele loss in a subregion of the chromosome region tested. Of the 13 typical carcinoids, 3 showed allele loss at only 1 or 2 loci each. Typical carcinoids, similar to normal lung epithelia, were strongly positive for the cytoplasmic Fhit protein, SCLCs were uniformly negative, and atypical carcinoids appeared to express an intermediate level of Fhit protein.

CONCLUSIONS

Loss of heterozygosity at 3p14.2-p21.3 is significantly more extensive in all atypical carcinoids. Atypical carcinoids, which exhibit clinicopathologic features intermediate between typical carcinoids and small cell carcinomas and have been considered well differentiated neuroendocrine carcinomas, also are intermediate between typical carcinoids and SCLC on the basis of extent of loss of 3p alleles and reduced expression of Fhit protein.

Inactivation of the von Hippel-Lindau (VHL) tumour suppressor gene and allelic losses at chromosome arm 3p in primary renal cell carcinoma: evidence for a VHL-independent pathway in clear cell renal tumourigenesis

Inactivation of tumour suppressor gene(s) (TSGs) on 3p appears to be a critical event in the pathogenesis of clear cell renal cell carcinoma (CC-RCC). Analysis of loss of heterozygosity (LOH) in sporadic RCC samples has implicated roles for TSGs in three specific regions of 3p in RCC development: (1) 3p12-p14, which includes the breakpoint of the familial t(3;8) constitutional translocation involved in hereditary RCC development and a recently cloned putative TSG, the FHIT gene: (2) 3p21.2-p21.3, a common region of deletion in many cancers including lung; and (3) 3p25-p26, which contains the von Hippel-Lindau (VHL) disease TSG. We and others have shown that most primary sporadic CC-RCCs contain somatic VHL gene mutations, clearly implicating inactivation of the VHL gene in the pathogenesis of CC-RCC. It is not known if CC-RCC without VHL gene mutations have alternative mechanisms of VHL gene inactivation or result from an alternative non-VHL pathway to RCC, e.g., inactivation of TSGs in 3p12-p21. We and others have reported hypermethylation and silencing of the VHL TSG in RCC from patients with VHL disease and in CC-RCC cell lines. However, the incidence and specificity of VHL methylation in primary sporadic RCC has not been defined. Therefore, we analysed methylation of the VHL, CDKN2, MYC, and H19 genes in primary RCC samples. Hypermethylation of the VHL promoter region was detected in 11% (11/99) of the primary RCCs analysed. In 10 of these tumours, there was no evidence of concomitant VHL gene mutation. VHL methylation was specific to CC-RCC (15%, 7/45) but was not detected in any non-CC tumours (n = 16). None of the 11 RCCs methylated at VHL had evidence of methylation at either CDKN2 or MYC (methylation at CDKN2 was, however, detected in 3%, or 1/33, of RCCs without VHL methylation). A normal methylation pattern at H19 was demonstrated in the three RCCs with methylated VHL analysed. Previous studies have suggested that, in addition to VHL, other 3p TSGs at 3p12-p14 and 3p21 may be involved in CC-RCC tumourigenesis. However, the interpretation of these studies has been difficult because information on VHL gene status has not been available for these data sets. Therefore, we investigated a subset of 55 sporadic RCCs (of known VHL gene methylation and mutation status) for LOH at polymorphic markers close to candidate TSG loci in the 3p14.2 and 3p21.2-p21.3 regions. Among tumours with LOH at one or more 3p markers, the incidence of 3p25 allele loss was higher in tumours with VHL alterations (mutation or methylation) than in those without. For tumours without detectable VHL alterations, the frequency of 3p14-p21 LOH was significantly higher than the frequency of 3p25-p26 LOH (93%, 13/14 vs. 43%, 6/14; P = 0.013), whereas, in RCC samples with VHL methylation or mutation, the frequency of 3p14-p21 LOH did not differ from that of sp25-p26 (72%, 18/25 vs. 59%, 13/22; P = 0.376). None of the 11 RCCs with 3p25 allele loss that were informative at 3p21 and 3p14 showed LOH at 3p25 only. These findings suggest that (1) VHL methylation is a specific and important event in the pathogenesis of CC-RCC; (2) in CC-RCC with 3p LOH but without VHL inactivation, mutations in TSGs at 3p14-p21 appear to have a primary role in tumourigenesis; and (3) inactivation of other 3p TSGs in addition to VHL may also be required for malignant transformation in tumours with VHL gene inactivation.

Normal FHIT transcripts in renal cell cancer- and lung cancer-derived cell lines, including a cell line with a homozygous deletion in the FRA3B region

The recently identified FHIT gene encompasses the FRA3B region and the breakpoint of a constitutive t(3;8) occurring in a family with hereditary renal cell cancer. Occurrence of aberrant transcripts in different types of tumours has led to the suggestion that FHIT might play a critical role in the development of various types of cancer. We have analyzed the gene and its transcripts in lung cancers and renal cell cancer-derived cell lines. A lung adenocarcinoma cell line, GLC-A2, appeared to have a homozygous deletion in intron 5 of FHIT. RT-PCR analysis revealed a normal-sized PCR product in all of the cell lines: Including GLC-A2. A number of them had an additional aberrant product. Analysis of a great number of control cell lines and tissues showed that the majority of these also had aberrant PCR products in addition to a normal-sized PCR product. Different specimens of the same cell type showed variable additional RT-PCR products. Normal-sized PCR products had a sequence identical to the FHIT sequence. PCR products longer than normal had insertions of different sizes at different positions. With three exceptions, PCR products shorter than normal represented FHIT sequences missing one or more entire exons. Thus, the presence of aberrant transcripts is not cancer-specific. Conceivably, sequence responsible for the instability of the FRA3B region are being transcribed into FHIT pre-mRNA and may cause the abnormal splicing and processing of the transcripts.

The FHIT gene, spanning the chromosome 3p14.2 fragile site and renal carcinoma-associated t(3;8) breakpoint, is abnormal in digestive tract cancers

A 200-300 kb region of chromosome 3p14.2, including the fragile site locus FRA3B, is homozygously deleted in multiple tumor-derived cell lines. Exon amplification from cosmids covering this deleted region allowed identification of the human FHIT gene, a member of ther histidine triad gene family, which encodes a protein with 69% similarity to an S. pombe enzyme, diadenosine 5', 5''' P1, P4-tetraphosphate asymmetrical hydrolase. The FHIT locus is composed of ten exons distributed over at least 500 kb, with three 5' untranslated exons centromeric to the renal carcinoma-associated 3p14.2 breakpoint, the remaining exons telomeric to this translocation breakpoint, and exon 5 within the homozygously deleted fragile region. Aberrant transcripts of the FHIT locus were found in approximately 50% of esophageal, stomach, and colon carcinomas.

Major role for a 3p21 region and lack of involvement of the t(3;8) breakpoint region in the development of renal cell carcinoma suggested by loss of heterozygosity analysis

In a loss of heterozygosity analysis of 3p, we examined 44 sporadic cases of renal cell carcinoma (RCC) and matched normal tissue with 18 markers distributed over the whole p-arm. The majority of these markers clustered in three regions that have been suggested to be involved in the development of RCC, namely the p25 region, where the von Hippel Lindau (VHL) gene is located; the p21 region, which has been identified as a common region of overlap (SRO) of heterozygous deletions; and the p14 region, which is the location of the constitutional t(3;8) breakpoint occurring in an RCC family. Thirty-one out of these 44 tumors were analyzed with 9 additional markers from the 3p12-14 region to further delimit the SRO in this region. Our analysis shows that when deletions were detected the 3p21 region was always included. The 3p21 markers D3F15S2 and UBEIL were always contained within these 3p21 deletions. The t(3;8) breakpoint region showed the lowest percentage of loss of heterozygosity. Moreover, in three cases the t(3;8) breakpoint region retained heterozygosity, whereas a region more proximal to the breakpoint showed allelic losses. This supports exclusion of the t(3;8) region from a role in the development of sporadic RCC. In a number of tumors, two or three 3p regions with allelic losses were present separated by a region of retention of heterozygosity. In these tumors, deletions at 3p21 occurred in combination with deletions of either the VHL region, or the region proximal to the t(3;8), or both, suggestive of multiple gene involvement in the development of sporadic RCC with a primary role of the 3p21 region.

Integrated YAC contig containing the 3p14.2 hereditary renal carcinoma 3;8 translocation breakpoint and the fragile site FRA3B

An extended YAC contig has been developed for the 3p14 region containing the hereditary renal carcinoma 3;8 translocation breakpoint and the 3p14.2 fragile site FRA3B. This region of chromosome 3 has been implicated by chromosomal translocation, deletion, and loss of heterozygosity in the pathogenesis of several malignant diseases. The contig allows accurate positioning of candidate genes, polymorphic markers, and other 3p rearrangements within this region. The contig, spanning approximately 6 Mb of DNA, contains 51 YACs identified by 27 markers, including a subset of CA repeats located in the 3p14.1-14.2 interval. The order of CA microsatellites, derived from marker content of the YACs, is in agreement with the order previously determined by genetic linkage studies. We find that the protein-tyrosine phosphatase gamma gene, PTPRG, is located minimally 1 Mb proximal to the t(3;8) breakpoint. The more proximal 3p homozygous deletion in the small-cell lung cancer cell line, U2020, is more than 5 Mb from the site of the 3;8 translocation. This integrated physical and genetic map provides a framework for further investigations of malignant diseases associated with proximal 3p loss. In addition, the positioning of separate 3p14.2 aphidicolin-induced breakpoints suggests that FRA3B may represent a region rather than a single site.