Molecular genetic investigation of sporadic renal cell carcinoma: analysis of allele loss on chromosomes 3p, 5q, 11p, 17 and 22.

To investigate the role of tumour-suppressor genes on the short arm of chromosome 3 in the mechanism of tumorigenesis in non-familial renal cell carcinoma, we analysed 55 paired blood-tumour DNA samples for allele loss on chromosome 3p and in the region of known or putative tumour-suppressor genes on chromosomes 5, 11, 17 and 22. Sixty-four per cent (35/55) of informative tumours showed loss of heterozygosity (LOH) of at least one locus on the short arm of chromosome 3, compared with only 13% at the p53 tumour-suppressor gene and 6% at 17q21. LOH at chromosome 5q21 and 22q was uncommon (2-3%). Detailed analysis of the regions of LOH on chromosome 3p suggested that, in addition to the VHL gene in chromosome 3p25-p26, mutations in one or more tumour-suppressor genes in chromosome 3p13-p24 may be involved in the pathogenesis of sporadic renal cell carcinoma (RCC). We also confirmed previous suggestions that chromosome 3p allele loss is not a feature of papillary RCC (P < 0.05).     

Molecular and cellular characterization of human renal cell carcinoma cell lines.

Recent studies have suggested that a tumor suppressor gene located in the region 3p21-26 of chromosome 3 is essential to the genesis of sporadic renal cell carcinoma (RCC) and that other tumor suppressor genes located on other chromosomes may be involved with progression of this malignancy. The cellular heterogeneity of solid tumors complicates their analysis. In order to analyze a homogeneous population of tumor cells and identify genetic changes associated with histology in renal cortical tumors, we have established and characterized 35 RCC lines derived from tumor tissue from 31 patients with renal cell carcinomas. The overall success rate in establishing these cell lines from fresh or frozen specimens was 75% (18 of 24) and 35% (17 of 48), respectively. These lines differed in their morphology, growth rates, and tumorigenicity in athymic nude mice. Molecular characterization utilizing DNA fingerprinting and restriction fragment length polymorphism deletion analysis was performed to detect somatic mutations and loss of heterozygosity on the short arm of chromosome 3. Analysis revealed loss of heterozygosity on chromosome 3p in 25 cell lines derived from 28 informative nonpapillary forms of RCC (89%). Deletion-mapping analysis showed the retention of the distal locus, D3S18, in one of the RCC cell lines, which further localized the position of the putative tumor suppressor gene to the region proximal to D3S18. Although deletions on chromosome 3 have been recently suggested to be specific to the clear cell-type phenotype, our results revealed no correlation between loss of heterozygosity and clear or granular cell types.     

Allelic losses from chromosome 17 in human osteosarcomas

Genetic alterations of chromosome 17 have been reported to occur frequently both in human sporadic and familial malignancies. The present study was undertaken to explore the possible involvement of chromosome 17 genes including TP53 and the breast cancer susceptibility BRCA1 tumor suppressor genes in the development of sporadic osteogenic sarcoma. Fifteen patients were screened by polymerase chain reaction (PCR) for loss of heterozygosity (LOH) using four highly polymorphic markers. Loss of heterozygosity at the TP53 locus was detected in 40% (6/15) of informative cases while it was 14% (2/14) at the locus of thyroid hormone receptor alpha (THRA1), 21% (3/14) at the D17S855 locus intragenic to BRCA1 and 27% (4/15) at the D17S579 locus. In 53% of the cases studied at least one locus on chromosome 17 was affected by LOH. In our panel, the overall LOH frequency on 17p and 17q was observed to be 40% (6/15) and 27% (4/15), respectively. Comparison of LOH frequencies with clinical and prognostic features revealed significant correlation only with tumor recurrence. Our results confirm that the role of the TP53 tumor suppressor gene is important in the pathogenesis of sporadic osteosarcoma and suggest that 17ql2-21 region abnormalities may be involved in the development and/or progression of this tumor. This work has been supported by OTKA T-19037 and ETT Grants given to E.O.     

Frequent loss of heterozygosity on chromosomes 16 and 4 in human hepatocellular carcinoma

By restriction fragment length polymorphism analysis, we examined loss of heterozygosity at 34 loci on 23 chromosomes in 35 surgically resected human hepatocellular carcinomas. Allele losses at the HP locus on chromosome 16q22 and at the MT2P1 locus on chromosome 4p11-q21 were detected in 57% (8/14) and 50% (8/16) of cases, respectively. Loss of heterozygosity on chromosomes 16q and 4 occurred simultaneously in 4 of 7 informative cases for both loci, and seemed to be important in the development of human hepatocellular carcinoma irrespective of the presence of hepatitis B virus infection. In contrast, the incidence of allele loss was low at the other loci, e.g., chromosome 1p, 3p, 11p, 13q or 17p, where one allele is frequently lost in other cancers.     

Frequent Loss of Heterozygosity on Chromosomes 16 and 4 in Human Hepatocellular Carcinoma

By restriction fragment length polymorphism analysis, we examined loss of heterozygosity at 34 loci on 23 chromosomes in 35 surgically resected human hepatocellular carcinomas. Allele losses at the HP locus on chromosome 16q22 and at the MT2P1 locus on chromosome 4p11-q21 were detected in 57% (8/14) and 50% (8/16) of cases, respectively. Loss of heterozygosity on chromosomes 16q and 4 occurred simultaneously in 4 of 7 informative cases for both loci, and seemed to be important in the development of human hepatocellular carcinoma irrespective of the presence of hepatitis B virus infection. In contrast, the incidence of allele loss was low at the other loci, e.g., chromosome 1p, 3p, 11p, 13q or 17p, where one allele is frequently lost in other cancers.     

Analysis of the TSC1 and TSC2 genes in sporadic renal cell carcinomas.

The genetic events involved in the aetiology of non-clear-cell renal cell carcinoma (RCC) and a proportion of clear cell RCC remain to be defined. Germline mutations of the TSC1 and TSC2 genes cause tuberous sclerosis (TSC), a multi-system hamartoma syndrome that is also associated with RCC. We assessed 17 sporadic clear cell RCCs with a previously identified VHL mutation, 15 clear-cell RCCs without an identified VHL mutation and 15 non-clear-cell RCCs for loss of heterozygosity (LOH) at chromosomes 9q34 and 16p13.3, the chromosomal locations of TSC1 and TSC2. LOH was detected in 4/9, 1/11 and 3/13 cases informative at both loci. SSCP analysis of the whole coding region of the retained allele did not reveal any cases with a detectable intragenic second somatic mutation. Furthermore, RT-PCR analysis of TSC1 and TSC2 on total RNA from 8 clear-cell RCC cell lines confirmed expression of both TSC genes. These data indicate that biallelic inactivation of TSC1 or TSC2 is not frequent in sporadic RCC and suggests that the molecular mechanisms of renal carcinogenesis in TSC are likely to be distinct.     

Clonal allele loss in gastrointestinal cancers

Using a panel of DNA probes for hypervariable DNA regions we screened 52 gastrointestinal carcinomas for clonal allele losses on chromosomes 1, 5, 7, 12, 16 and 17. A total of 24/35 informative cases of colorectal cancers showed loss of constitutional heterozygosity at a locus on chromosome 17p, while 9/31 cases informative for a locus on 5q showed allele loss. Loss of sequences at 5q was linked to allele loss at 17p with a single exception. In gastric cancers loss of heterozygosity most frequently occurred at 1q (5/10 tumours) and at 12q (6/11 tumours). Gastrointestinal tumours show consistent chromosomal losses and the loci involved are different in gastric and colorectal cancers.     

Allelic loss at chromosome 3p characterizes clear cell phenotype of renal cell carcinoma.

Incidence of the loss of heterozygosity on chromosome 3p was evaluated using 7 polymorphic probes in 35 Japanese patients with sporadic renal cell carcinoma (RCC). Overall frequency of the loss of heterozygosity on 3p was 53%, representing 16 of 30 informative cases. Examination of the relationship between histopathological phenotypes of RCC and incidence of the 3p loss revealed that the loss of heterozygosity in clear cell type tumors (75%, 12 of 16) was significantly (P less than 0.01) more frequent than that in granular cell type tumors (14%, 1 of 7). In addition, three mixed cell type tumors, consisting predominantly of granular cell components, showed no loss of chromosome 3p loci. These findings may support the notion that the loss of heterozygosity on chromosome 3p is a nonrandom event in the tumorigenesis of sporadic RCC, and suggest that this type of chromosomal rearrangement is specific to the clear cell phenotype of RCC.     

Frequent loss of heterozygosity on chromosomes Xp and 13q in human ovarian cancer.

Loss of heterozygosity (LOH) was examined at 27 loci on chromosomes 3p, 6q, 11p, 13q, 17 and X in 42 human ovarian tumors. LOH was detected in 12 of 26 (46%) and 5 of 12 (42%) informative cases at 2 chromosome 13q loci, D13S32 and D13S34 respectively. On chromosome Xp, tumor-specific allele loss was observed in 9 out of 15 informative cases (60%) at the ornithine transcarbamylase (OTC) gene locus. Examination of 12 additional Xp and 13q loci has mapped the common deletion regions to Xp21.1-->p11.4 and 13q33-->q34. The observation of significant LOH on Xp represents a strong indication of genetic changes in the X chromosome in a human malignancy. The allele losses on 13q which have been reported for other cancers suggest that chromosome 13, in addition to the retinoblastoma gene, may contain other growth-regulating gene(s) important in the development of several tumor types, including ovarian malignancies.     

Analysis of the estrogen receptor gene structure in human breast cancer

We studied the structure of the human estrogen receptor (ER) gene by Southern blot analysis in 34 tumor samples and normal breast tissues or peripheral blood samples from the same patients. No rearrangement or amplification of the ER gene was seen in either ER-positive or ER-negative breast tumors. One patient showed an apparent constitutional deletion of a non-allelic ("invariant") restriction fragment in DNAs from both normal leukocytes and bilateral breast tumors. Of 20 patients constitutionally heterozygous for an ER gene RFLP, only one showed tumor-specific loss of heterozygosity. This is consistent with the ER gene change we noted overall. At the c-myb locus on chromosome 6q adjacent to the ER gene, allele loss occurred in 1 out of 15 informative cases. In addition, tumor-specific allelic loss at the c-H-ras1 locus on chromosome 11p occurred in 4 of 22 informative cases, and at the D17S28 locus on chromosome 17p in 2 of 7 informative cases.     

Molecular analysis of genetic changes in the origin and development of renal cell carcinoma.

Renal cell carcinoma has been characterized by an abnormality on the short arm of chromosome 3 which suggests the presence of a tumor suppressor gene at this location. In order to more precisely define the location of the renal cell carcinoma gene and to differentiate molecular changes occurring in early stages of renal neoplasia versus those occurring later in malignant progression, DNA from normal and tumor tissue from 60 patients with various stages of renal cell carcinoma was analyzed for loss of alleles at different chromosomal loci. In tumor tissue from 51 of 58 evaluable patients (88%) there was loss of heterozygosity at one or more of 10 loci tested on chromosome 3 independently of tumor stage. Analysis of the genotypes identified the distal portion of 3p bounded by D3S2 and D3S22 (3p21-26) as the region of the disease gene. In tumor tissue from patients with advanced renal cell carcinoma, we found loss of heterozygosity on chromosome 11p in 5 of 21 (24%), on chromosome 13 in 3 of 9 (33%), and on chromosome 17 in 2 of 19 (11%). We found no loss of heterozygosity at the loci on chromosomes 11, 13, or 17 in tumor tissue from patients with localized renal cell carcinoma (N = 5). These data suggest the existence of a tumor suppressor gene on chromosome 3p which may be essential to the genesis of sporadic renal cell carcinoma and that other tumor suppressor genes are associated with progression of this malignancy.     

Frequent loss of heterozygosity on chromosomes 1q, 5q, and 17p in human gastric carcinomas

Recently, loss or inactivation of genes at specific chromosomal loci has been considered to be one of the important mechanisms during the development of human tumors. In order to identify tumor suppressor genes for gastric carcinoma, we performed restriction fragment length polymorphism analysis on 48 human gastric carcinomas. Allele losses were investigated for 14 specific loci on chromosomes 1, 5, 6, 7, 10, 11, 12, and 17. Loss of heterozygosity on chromosome 17p13.1 (p53 locus) was detected in 13 (68%) of 19 informative cases. Well-differentiated adenocarcinoma showed high frequencies of allele losses on chromosomes 5q (60%) and 17p (67%) in early cancers and on chromosomes 1q (67%), 5q (36%), 7p (33%), 7q (39%), and 17p (73%) in advanced cancers. In poorly differentiated adenocarcinomas, loss of heterozygosity was detected on chromosomes 1p (38%), 12q (31%), and 17p (60%). Allele losses on chromosomes 1q, 5q, and 7p were not detected in poorly differentiated adenocarcinoma, their frequencies being significantly different between the two histological types. These results suggest that allele loss on chromosome 17p is a common event in gastric carcinoma, regardless of histological type, and that allele loss on chromosome 5q may play a role in the carcinogenesis of well-differentiated adenocarcinoma. Additionally, allele losses on chromosomes 1q and 7p may be involved in the progression of well-differentiated adenocarcinoma.     

A third Wilms' tumor locus on chromosome 16q.

Loss of heterozygosity studies have been used to identify chromosomal regions which are frequently deleted and thus indicate areas which may harbor tumor suppressor genes. As a result, both the WT1 gene located in chromosome 11p13 and an unidentified gene(s) within chromosome 11p15 have been implicated in Wilms' tumorigenesis. Cytogenetic and linkage studies suggest that additional non-chromosome 11 sites are involved in Wilms' tumor. Because these sites may also involve loss of heterozygosity, loci on 33 autosomal arms were screened for allele loss in a series of Wilms' tumors. We found that in addition to loss on chromosome 11p (11 of 25 informative tumors) there was significant loss on chromosome 16q (9 of 45 informative tumors), while the total frequency of allele loss excluding these loci was low (9 of 426 total informative loci). These data indicate that losses of both chromosome 11p and 16q alleles are nonrandom events and suggest that 16q is the location of a third tumor suppressor gene underlying Wilms' tumorigenesis. The parental origin of the lost chromosome 16q allele was determined in eight sporadic tumors. Alleles of paternal and of maternal origin were each lost in four sporadic tumors indicating that, unlike chromosome 11p, alleles of either parental origin are lost on 16q.     

The genetic locus NRC-1 within chromosome 3p12 mediates tumor suppression in renal cell carcinoma independently of histological type, tumor microenvironment, and VHL mutation

Human chromosome 3p cytogenetic abnormalities and loss of heterozygosity have been observed at high frequency in the nonpapillary form of sporadic renal cell carcinoma (RCC). The von Hippel-Lindau (VHL) gene has been identified as a tumor suppressor gene for RCC at 3p25, and functional studies as well as molecular genetic and cytogenetic analyses have suggested as many as two or three additional regions of 3p that could harbor tumor suppressor genes for sporadic RCC. We have previously functionally defined a novel genetic locus nonpapillary renal carcinoma-1 (NRC-1) within chromosome 3p12, distinct from the VHL gene, that mediates tumor suppression and rapid cell death of RCC cells in vivo. We now report the suppression of tumorigenicity of RCC cells in vivo after the transfer of a defined centric 3p fragment into different histological types of RCC. Results document the functional involvement of NRC-1 in not only different cell types of RCC (i.e., clear cell, mixed granular cell/clear cell, and sarcomatoid types) but also in papillary RCC, a less frequent histological type of RCC for which chromosome 3p LOH and genetic aberrations have only rarely been observed. We also report that the tumor suppression observed in functional genetic screens was independent of the microenvironment of the tumor, further supporting a role for NRC-1 as a more general mediator of in vivo growth control. Furthermore, this report demonstrates the first functional evidence for a VHL-independent pathway to tumorigenesis in the kidney via the genetic locus NRC-1.     

CDKN2A mutation and deletion status in thin and thick primary melanoma.

Human melanoma cell lines and tumor tissue from familial and sporadic melanomas have frequent, nonrandom chromosomal breaks and deletions on chromosome 9p21, a region that includes the tumor suppressor gene CDKN2A/p16INK4A. Germ-line mutations within this gene have been observed in some familial melanoma kindreds, but somatic mutation in sporadic primary melanoma is infrequent. Thirty-nine archival, paraffin-embedded, sporadic, primary cutaneous malignant melanomas (20 >3-mm-thick and 19 <0.75-mm-thick cases) were examined for mutations of the CDKN2A gene using single-strand conformational polymorphism analysis and direct sequencing. No mutations were detected. Loss of heterozygosity for the 9p21 microsatellite marker D9S942 was detected in 6 of 17 informative thick lesions (35%) but 0 of 18 thin lesions (P = 0.006). These results support other studies indicating that intragenic mutation is an infrequent mechanism of CDKN2A inactivation in primary melanoma. The finding of loss of heterozygosity for the 9p21 microsatellite D9S942 in thick but not thin primary melanoma suggests that deletion or inactivation of CDKN2A or other tumor suppressor gene(s) at this locus is involved in the progression rather than initiation of sporadic malignant melanoma.     

Allelic losses of chromosomes 9, 11, and 17 in human bladder cancer

Twenty-five human bladder tumors were examined for loss of heterozygosity of markers on chromosomes 6p, 9q, 11p, 14q, and 17p. These studies show that all of the markers were reduced to homozygosity in at least some of the tumors. They also confirmed earlier studies by Fearon et al. [Nature (Lond.), 318: 377-380, 1985] that approximately 40% of bladder tumors were reduced to homozygosity for markers on chromosome 11p. However, the greatest frequency of allelic loss was seen for chromosomes 9q (67% of informative cases) and 17p (63% of informative cases) with both chromosomes being lost concordantly in 10 out of 20 informative tumors. Allelic loss of chromosome 9q has not been previously observed with other human cancers; however, deletions of 17p have been reported in breast, lung, and colorectal carcinomas. The data raise the interesting possibility that allelic losses of specific chromosomes might be a feature of cancer in a particular differentiated cell type whereas loss of other chromosomes harboring more generally acting tumor suppressor genes might be a common feature of human cancers.     

Detection of frequent allelic loss on proximal chromosome 17q in sporadic breast carcinoma using microsatellite length polymorphisms.

Analyses of losses of heterozygosity and linkage studies have implicated a gene(s) on chromosome 17q in the genesis of sporadic and early-onset familial breast carcinomas, respectively. To define the critical region of 17q, we examined DNAs from a series of 20 sporadic breast carcinomas and corresponding blood samples for allelic losses of chromosome 17q using microsatellite length polymorphisms. With these highly informative markers (average heterozygosity, 0.73), we observed frequent deletions of 17q at several loci. We found that D17S250 was deleted in 50% (7 of 14), THRA1 in 79% (11 of 14), D17S579 in 59% (11 of 19), NME1 in 29% (5 of 17), MPO in 36% (4 of 11), and GH in 25% (4 of 16) in the tumor set examined. A common region of deletion was found that was flanked by D17S250 to D15S579. These markers have recently been localized to a 6-cM interval of proximal chromosome 17q in bands 17q11.2-q21 and map within the region of the early-onset familial breast cancer locus, implying that the same gene or genes may be involved in both sporadic and familial breast tumors. Thyroid hormone receptor alpha and retinoic acid receptor alpha are two potential candidate genes in this region.     

Frequent loss of heterozygosity on chromosome 14q in neuroblastoma

Using 29 polymorphic DNA markers which detect allelic deletion of genes at specific loci on 19 different chromosomes, we analyzed 14 neuroblastomas for possible loss of chromosomal heterozygosity. The incidence of loss of heterozygosity was high at the D14S1 locus on chromosome 14q, being detected in six of 12 patients (50%). In spite of the cytogenetic finding suggesting high frequency of chromosome 1p deletion, loss of heterozygosity at the MYCL locus on 1p32 was detected only in two of nine patients (22%). It was also found in two of 11 patients (18%) on 13q, but not on chromosomes 2, 3, 5, 6, 7, 8, 9, 10, 11, 12, 15, 16, 17, 18, 19, and 20. The present results indicate that recessive genetic changes involving sequences on chromosome 14q may play an important role in the development of neuroblastoma.     

Frequent loss of heterozygosity on chromosomes 6q, 11, and 17 in human ovarian carcinomas

Recently, tumor-specific allele loss has been shown to be an important characteristic of some tumors. When such loss includes one or more growth-regulatory genes, it may allow the expression of tumorigenicity. Using Southern blots, we analyzed normal and tumor DNA samples from 19 ovarian cancer patients, using a series of polymorphic DNA probes that map to a variety of chromosomal loci. Of 14 informative cases, tumor-specific allelic loss was observed in nine (64%) at the estrogen receptor (ESR) gene locus on chromosome 6q. On chromosome 17p at the D17S28 and D17S30 loci, allelic losses were also detected in 6 of 8 (75%) and 9 of 14 (64%) cases, respectively. Allelic loss at the HRAS1 gene locus on chromosome 11p occurred in 5 of 11 (46%) informative cases. The relatively high incidence of these allelic losses observed on chromosome 6q represents the first implication by molecular genetic analysis of this chromosomal region in a human malignancy, and it thus appears to be a genetic change specific to ovarian carcinoma. DNA sequence losses on 11p and 17p, also reported for other cancers, may reflect the presence of tumor- or growth-suppressor genes on these chromosomes that are important in the genesis of many tumor types, including ovarian malignancies.     

Frequent loss of heterozygosity at the DCC locus in gastric cancer.

We examined 28 cases of surgically resected gastric cancer, excluding the diffuse type, for loss of heterozygosity (LOH) on 12 chromosomal arms using polymorphic DNA markers. LOH on chromosome 18q was detected in 61% (14 of 23) of the cases by the probes OLVIIA8, OLVIIE10, p15-65, SAM 1.1, and OS-4, and a putative common region showing LOH included the locus of the DCC tumor suppressor gene. LOH on chromosome 17p was also frequently found (8 of 19 or 42% of the cases) by the probes p10-3 and pHF12-1, and in 5 of these 6 cases the LOH on chromosome 17p was accompanied by LOH on chromosome 18q. On the other hand, the incidence of LOH was 30% or less using probes pHRnES, pHF12-65, p-c-mybE2.6, NJ3 3.2, pHF12-8, pHINS6.0, p9D11, hp2-alpha, pCMM6, and P1A5 on chromosomes 1q, 5, 6q, 7q, 9, 11p, 13q, 16q, 20, and 22q, respectively. LOH on chromosome 18q was frequent irrespective of the depth of tumor invasion, whereas the incidence of LOH on chromosome 17p was higher in the cases in which the tumor invaded beyond the muscularis propria than in those in which tumor invasion was limited to the submucosa and muscularis propria. These results suggest that LOH on chromosome 18q occurs at an earlier stage than LOH on chromosome 17p and that the inactivation of tumor suppressor genes located on chromosome 17p and 18q (e.g., the p53 and DCC genes) is critically involved in the development of the majority of gastric cancers. While alteration of the p53 gene is observed in various human cancers, that of the DCC gene is considered to occur more selectively in gastrointestinal cancers.