Management of upper urinary tract calculi with ureteroscopic techniques

Frequent loss of heterozygosity on chromosome 8p in a variety of human malignancies, including head and neck cancers, has suggested the presence of a tumor suppressor gene (or genes) associated with the pathogenesis of these cancers. To test the role of genetic alterations at 8p23 in oral carcinogenesis, we studied 51 squamous cell carcinomas of the head and neck and 29 oral squamous cell carcinoma cell lines for allelic loss using 7 microsatellite markers spanning approximately 5 cM of chromosome band 8p23. Twenty-three of 51 tumors (45%) and 23 of 29 cell lines (79%) showed allelic loss at 1 or more loci. Three cell lines showed homozygous deletion of loci within a 3 cM region defined by the markers D8S1781 and D8S262. Our results suggest that a tumor suppressor gene (or genes) is located in 8p23 and is associated with the development and/or progression of oral carcinomas.     

Localization and characterization of a chromosome 11 tumor suppressor gene using organotypic raft cultures

The development and progression of human cancer often involves the inactivation of tumor suppressor gene function. Alterations in human chromosome 11 during the development of human cutaneous squamous cell carcinoma suggest the presence of a tumor suppressor gene on this chromosome. Moreover, previous studies in our laboratory demonstrated the presence of a functional tumor suppressor gene on chromosome 11 for the human cutaneous squamous cell carcinoma cell line A388.6TG.c2. In this investigation, we have used organotypic culturing of epithelial cells as a novel in vitro assay for tumor suppression. A388.6TG.c2 and control cells form an abnormal stratified epithelium of 8-12 layers when cultivated on organotypic rafts. In contrast, the chromosome 11 microcell hybrids, HMC 100p4B and HMC 100p5A, form an epithelium of only two to three cell layers. This in vitro growth suppression of the chromosome 11 microcell hybrids in the organotypic rafts correlates well with our previous in vivo skin graft experiments. Comparison of the proliferation and apoptotic indices of cell lines grown on the organotypic rafts suggests that the tumor suppressor gene on chromosome 11 has restricted the ability of the microcell hybrids to stratify but has not significantly altered their ability to undergo cell division or programmed cell death. Furthermore, flow cytometric analysis of cells grown on organotypic raft cultures suggests that the chromosome 11 microcell hybrids are actively progressing through the cell cycle rather than arrested in a particular stage. We have used this novel application of organotypic raft cultures to further localize the chromosome 11 tumor suppressor gene. Introduction of a single der(11)t(X;11) chromosome lacking most of the long arm of chromosome 11 into A388.6TG.c2 does not affect growth on organotypic raft cultures. These data suggest the tumor suppressor gene maps to the long arm of chromosome 11 in the region of 11q13-qter.     

Frequent somatic mutation of the MTS1/CDK4I (multiple tumor suppressor/cyclin-dependent kinase 4 inhibitor) gene in esophageal squamous cell carcinoma

We previously reported frequent loss of heterozygosity on chromosome 9p in esophageal carcinomas and suggested that a tumor suppressor gene located on this chromosomal arm might be involved in development of these cancers. Since recently published studies have shown that a gene mapped on chromosome 9p21, MTS1/CDK4I (multiple tumor suppressor 1/cyclin-dependent kinase 4 inhibitor), is frequently mutated in various types of tumors, we chose to examine esophageal squamous cell carcinomas for mutations in this candidate gene. DNA sequence analyses revealed somatic mutations of MTS1/CDK4I in 14 of 27 tumors examined; 8 were frame-shift mutations and 6 were missense mutations. These results suggested that the MTS1/CDK4I gene is a tumor suppressor the inactivation of which plays an important role during carcinogenesis of the squamous cell type of esophageal carcinoma.     

Hot spots for molecular genetic alterations in lung cancer

Lung cancers are a heterogeneous group of tumors broadly classified as small cell or non-small cell lung cancers. In each case, numerous DNA mutations precede tumor formation, resulting in the activation of growth stimulatory genes and the loss of tumor suppressor genes. The known cellular functions of the tumor suppressor genes most commonly affected in lung cancer are reviewed herein, including the retinoblastoma (Rb) gene on chromosome 13q14, the p53 gene on 17p13, and the cyclin-dependent kinase inhibitor (CDKN2) gene on 9p21. The chromosomal locations for other potential tumor suppressor genes are on chromosomes 3p, 9p, and 11p. Candidate genes in these regions include the von Hippel-Lindau (VHL) gene at 3p25, the ubiquitin-activating enzyme homologue (UBE1L at 3p21, the genes for the dinucleoside polyphosphate hydrolase FHIT and receptor protein-tyrosine phosphatase gamma PTPRG at 3p14.2, the genes for tropomyosin beta (TM1) and a talin homologue (talin) at 9p21, and the H-ras gene at 11p15.     

Chromosomal abnormalities in glioblastoma multiforme tumors and glioma cell lines detected by comparative genomic hybridization

Comparative genomic hybridization (CGH) is a recent molecular cytogenetic method that detects and localizes gains or losses in DNA copy number across the entire tumor genome. We used CGH to examine 9 glioma cell lines and 20 primary and 10 recurrent glioblastoma tumors. More than 25% of the primary tumors had gains on chromosome 7; they also had frequent losses on 9p, 10, 13 and Y. The losses on chromosome 13 included several interstitial deletions, with a common area of loss of 13q21. The recurrent tumors not only had gains on chromosome 7 and losses on 9p, 10, 13 and Y but also frequent losses on 6 and 14. One recurrent tumor had a deletion of 10q22-26. Cell lines showed gains of 5p, 7 and Xp; frequent amplifications at 8q22-24.2, 7q21-32 and 3q26.2-29 and frequent losses on 4, 10, 13, 14 and Y. Because primary and recurrent tumors and cell lines showed abnormalities of DNA copy number on chromosomes 7, 10, 13 and Y, these regions may play a fundamental role in tumor initiation and/or progression. The propensity for losses on chromosomes 6 and 14 to occur in recurrent tumors suggests that these aberrations play a role in tumor recurrence, the development of resistance to therapy or both. Analysis of common areas of loss and gain in these tumors and cell lines provides a basis for future attempts to more finely map these genetic changes.     

Characterization of cyanobacteria by SDS-PAGE of whole-cell proteins and PCR/RFLP of the 16S rRNA gene

Childhood neuroblastoma, an embryonal neoplasm of sympathetic nervous system progenitors, occurs in a familial form with an autosomal dominant mode of inheritance. Genetic susceptibility to this disorder is thought to arise via a germline mutation affecting a tumor suppressor gene, in accord with the two-hit model established for familial and sporadic retinoblastoma. Surprisingly, the familial neuroblastoma predisposition locus does not map to chromosome band 1p36, a genomic region likely to contain one or more neuroblastoma suppressor genes. We reasoned that inherited point mutations affecting one allele would be unmasked in many cases by somatically acquired deletions of the second allele that included the target gene in the tumor cells from these patients. Thus, to identify chromosomal regions that might contain suppressor genes important in hereditary neuroblastoma, we analyzed six familial tumors by comparative genomic hybridization. Recurrent losses of genetic material were detected on chromosome arms 3p (consensus region, 3p24-pter), 10p (consensus, 10p12-p13), 10q (consensus, 10q25-qter), 16q (consensus, 16q12-q22), and 20q (consensus, 20q13.3-qter), in addition to the regions commonly deleted in sporadic neuroblastomas (1p36 and 11q). These chromosomal sites may harbor novel tumor suppressor genes that could aid in our understanding of the predisposition to and pathogenesis of familial neuroblastoma and potentially sporadic tumors as well.     

Localization of putative tumor suppressor loci by genome-wide allelotyping in human pancreatic endocrine tumors

Only two tumor suppressor gene loci, one on 3p25 and the MEN1 gene on 11q13, have thus far been implicated in the pathogenesis of sporadic human pancreatic endocrine tumors (PETs). A genome-wide allelotyping study of 28 human PETs was undertaken to identify other potential tumor suppressor gene loci. In addition to those on chromosomes 3p and 11q, frequent allelic deletions were identified on 3q (32%), 11p (36%), 16p (36%), and 22q (29%). Finer deletion mapping studies localized the smallest regions of common deletion to 3q27, 11p13, and 16p12.3-13.11. Potential candidate genes at these loci include WT1 (11p13), TSC2 (16p13), and NF2 (22q12), but no known tumor suppressor gene localizes to 3q27. The mean fractional allelic loss among these human PETs is 0.126, and no correlation was observed between allelic loss and clinical parameters, including age, sex, hormonal subtype, and disease stage. These findings highlight novel locations of tumor suppressor gene loci that contribute to the pathogenesis of human PETs, and several of these on 3p, 3q, and 22q are syntenic with loci on mouse chromosomes 9 and 16 that are implicated in a murine transgenic model of PETs.     

Homozygous deletions at chromosome 9p21 and mutation analysis of p16 and p15 in microdissected primary non-small cell lung cancers

Loss of heterozygosity on chromosome 9p has been detected in many primary human tumors and cell lines, suggesting that this chromosomal arm harbors one or more tumor suppressor genes. The recently cloned p16 and p15 genes, mapped to 9p21, are likely candidates for such tumor suppressors. To map the deletion at chromosome 9p21 in non-small cell lung tumors, we analyzed DNA from 25 tumors and matching normal DNAs at six microsatellite markers that flank the region occupied by the p16 and p15 genes. Loss of heterozygosity of at least one microsatellite marker on chromosome 9p21 was detected in 13 (52%) of 25 tumors, including one tumor that exhibited homozygous deletion of both human IFNalpha and D9S171. Six tumors analyzed by a comparative multiplex PCR technique showed homozygous deletions of the sequence tag site marker c5.1 (within p16). Screening for mutations in p16 and p15 revealed one tumor with a non-sense mutation in exon 2 of p16, but no mutations were detected in p15 in any of the tumors. Thus, in these analyses approximately one-half of the non-small cell lung tumors had loss of heterozygosity at chromosome 9p21, and of these tumors, one-half had homozygous deletions of the region that includes p16. This appears to confirm the importance of a locus in this region critical to growth control in lung. The apparent lack of other mutations in p16 and p15 in the tumors with loss of heterozygosity leaves open the possibility of an unidentified gene in this region that may function as a tumor suppressor.     

Waist to hip ratio and psychosocial factors in adults with insulin-dependent diabetes mellitus: the Pittsburgh Epidemiology of Diabetes Complications study

Loss of heterozygosity (LOH) at several chromosomal loci is a common feature of the malignant progression of human tumors. In the case of chromosome 11, LOH has been well documented in several types of solid neoplasms, including gastric carcinoma, suggesting the presence of suppressor gene(s) at 11p15 and 11q22-23. Little is currently known about the molecular events occurring during the development of gastric cancer. To define the regions of chromosome 11 involved in gastric cancer progression, we used high-density polymorphic markers to screen for LOH in matched normal and tumor tissue DNA from 60 primary gastric carcinomas. We found that 21% of the tumors showed LOH simultaneously at 11p15 and 11q22-23, 41% had LOH at 11p15, and 30% had LOH at 11q22-23. We confirm that the minimal critical area of LOH for 11p15.5 is the approximately 2-Mb region between loci D11S1318 and D11S988. However, when we analyzed the pattern of LOH according to the country of origin of the patient, LOH for 11q22-23 alone was found only in cases from Italy. The minimal critical region of LOH at 11q22-23 is identical to that identified for other solid tumors, suggesting that the same putative tumor suppressor gene(s) contained within this region is involved in the pathogenesis of several common human tumors.     

MEN1 gene analysis in sporadic adrenocortical neoplasms

Adrenocortical tumors occur as sporadic tumors, as part of the multiple endocrine neoplasia type 1 (MEN1) syndrome or as part of other hereditary disorders. We recently cloned the MEN1 gene, a tumor-suppressor gene located on chromosome 11q13. Subsequently, we showed that sequential somatic inactivation of both alleles of the MEN1 gene contributes to the development of some sporadic endocrine neoplasms (parathyroid, enteropancreatic neuroendocrine, bronchial carcinoid, and pituitary tumors). We now studied whether somatic inactivation of the MEN1 gene contributes to the pathogenesis of sporadic adrenocortical neoplasms. Seven adrenocortical carcinomas, 2 adrenocortical carcinoma cell lines, and 11 aldosterone-secreting, 8 cortisol-secreting, and 5 nonsecreting benign adrenocortical tumors were studied. Seven tumors (5 of 5 carcinomas, 2 of 21 nonsecreting benign adenomas; P < 0.001) exhibited loss of heterozygosity on 11q13. All 33 tumors and cell lines were screened for mutation throughout the MEN1 open-reading frame and adjacent splice junctions. None exhibited a mutation within the MEN1-coding region. We conclude that somatic MEN1 mutation within the MEN1-coding region does not occur commonly in sporadic adrenocortical tumors, although the majority of adrenocortical carcinomas exhibit 11q13 loss of heterozygosity.     

Loss of heterozygosity at 11q23 in squamous cell carcinoma of the head and neck is associated with recurrent disease

Loss of heterozygosity (LOH) at chromosome 11q23 has been found in a variety of epithelial human neoplasms, suggesting that this region contains a tumor suppressor gene(s) important to tumorigenesis. We investigated whether LOH at 11q23 could be detected in squamous cell carcinoma of the head and neck (SCCHN), and whether loss at this site was associated with specific clinical parameters. Fifty-six matched blood and SCCHN tumor samples taken at the time of diagnosis were evaluated for LOH at three microsatellite markers at 11q23. Multiplex PCRs with [alpha-32P]dCTP labeling of the amplified DNA strands were performed. Clinical data were obtained from medical record review. LOH at 11q23 was found in 13 of 52 (25%) evaluable tumors. There was no association between LOH at 11q23 and amplification of the CCND1 (cyclin D1) oncogene or inactivation of the p53 gene, which had been determined previously. With a mean follow-up of 24 months, an association independent of tumor size or stage was found between LOH at 11q23 and recurrent disease (P = 0.04). Among subjects who received radiotherapy (RT) as a component of their treatment, LOH at 11q23 was associated with persistent or recurrent locoregional disease (P = 0.05). LOH at 11q23 occurs in a subset of SCCHN. It is associated with a higher likelihood of recurrent disease, perhaps related to resistance to RT. The specific gene(s) and mechanism(s) responsible remain to be identified. Until then, LOH at 11q23 might become a marker identifying patients likely to do poorly with conventional therapy.     

Somatic deletion mapping on chromosome 10 and sequence analysis of PTEN/MMAC1 point to the 10q25-26 region as the primary target in low-grade and high-grade gliomas

The 10q25-26 region between the dinucleotide markers D10S587 and D10S216 is deleted in glioblastomas and, as we have recently shown, in low-grade oligodendrogliomas. We further refined somatic mapping on 10q23-tel and simultaneously assessed the role of the candidate tumor suppressor gene PTEN/MMAC1 in glial neoplasms by sequence analysis of eight low-grade and 24 high-grade gliomas. These tumors were selected for partial or complete loss of chromosome 10 based on deletion mapping with increased microsatellite marker density at 10q23-tel. Three out of eight (38%) low-grade and 3/24 (13%) high-grade gliomas exclusively target 10q25-26. We did not find a tumor only targeting 10q23.3, and most tumors (23/32, 72%) showed large deletions on 10q including both regions. The sequence analysis of PTEN/MMAC1 revealed nucleotide alterations in 1/8 (12.5%) low-grade gliomas in a tumor with LOH at l0q21-qtel and in 5/21 (24%) high-grade gliomas displaying LOH that always included 10q23-26. Our refined mapping data point to the 10q25-26 region as the primary target on 10q, an area that also harbors the DMBT1 candidate tumor suppressor gene. The fact that we find hemizygous deletions at 10q25-qtel in low-grade astrocytomas and oligodendrogliomas - two histologically distinct entities of gliomas - suggests the existence of a putative suppressor gene involved early in glial tumorigenesis.     

Mutation of the MENIN gene in sporadic pancreatic endocrine tumors

Pancreatic endocrine tumors occur both sporadically and as part of the multiple endocrine neoplasia type 1 (MEN1) syndrome. MEN1 is an autosomal dominant disease characterized by parathyroid hyperplasia, pancreatic endocrine tumors, and pituitary adenomas. The MEN1 gene called MENIN maps to chromosome 11q13 and is thought to function as a tumor suppressor gene. We previously demonstrated loss of heterozygosity (LOH) at 11q13 in approximately 40% of sporadic pancreatic endocrine tumors and hypothesize that MENIN is involved in the development of these tumors. Thirty-one sporadic pancreatic endocrine tumors were analyzed for mutation of MENIN by nonradioactive single-stranded conformation polymorphism. Twelve mutations were detected in 31 sporadic pancreatic endocrine tumors (34%). Twelve of these 31 tumors previously demonstrated loss of heterozygosity at 11q13. Of the tumors with LOH, seven contained mutations of the MENIN gene (58%). The majority of the MENIN mutations occurred within exon 2. Two independent mutations in MENIN were detected in a gastrinoma that also revealed LOH, leading to the possibility of another tumor suppressor gene locus at 11q13. Mutations were present in both benign and malignant pancreatic endocrine tumors, suggesting that a MENIN gene mutation is a frequent and early event in the tumorigenesis. The high incidence of truncating mutations in tumors with LOH at 11q13 support the hypothesis that MENIN is a tumor suppressor gene.     

Mutual influence of plasmid profile and growth temperature on the lipid composition of Yersinia pseudotuberculosis bacteria

Glioblastoma multiforme (GBM) is the most malignant glial brain tumor in humans. The fact that deleted copies of chromosome 10 are observed frequently in primary GBM tumors supports the hypothesis that one or more tumor suppressor genes located on chromosome 10 occupy crucial growth control checkpoints for glial cells. Deletion mapping in primary GBM tumors using the loss of heterozygosity (LOH) test has implicated the 10q24-10qter region as one possible site for a gene. We report here on the molecular cytogenetic analysis of chromosome 10 abnormalities in a human GBM cell line, JBSA. LOH testing showed that JBSA cells were hemizygous for chromosome 10. Molecular cytogenetic analysis showed that the undeleted homologue was involved in a reciprocal translocation t(7;10)(p21;q22). The translocation breakpoint on chromosome 10 lay within band q22 between D10S19 and D10S4. The fact that JBSA cells lack one homologue of chromosome 10 and carry a translocation breakpoint on the remaining one, proximal to the smallest region of overlap reported in primary tumor deletions, suggests that 10q22 may be another possible site for a tumor suppressor gene involved in GBM.     

Absence or reduction of Fhit expression in most clear cell renal carcinomas

The FHIT gene at human chromosome region 3p14.2 straddles the common fragile site, FRA3B, and numerous homozygous deletions in cancer cell lines and primary tumors. Also, the 3p14.2 chromosome breakpoint of the familial clear cell kidney carcinoma-associated translocation, t(3;8)(p14.2;q24), disrupts one FHIT allele between exons 3 and 4, fulfilling one criterion for a familial tumor suppressor gene: that one allele is constitutionally inactivated. Because the FHIT gene sustains biallelic intragenic deletions rather than mutations, there has not been evidence that the FHIT gene frequently plays a role in kidney cancer, although replacement of Fhit expression in a Fhit-negative renal carcinoma cell line suppressed tumor growth in nude mice. We have now assessed 41 clear cell renal carcinomas for expression of Fhit by immunohistochemistry. Normal renal tubule epithelial cells express Fhit uniformly and strongly, whereas 51% of the tumors are completely negative, 34% of tumors show a mixture of positive and negative cells, and 14% are uniformly positive, although usually less strongly positive than the normal epithelial cells. Most interestingly, there was a correlation between complete absence of Fhit and the G1 morphological grade and early clinical stage. Morphological grades G2 and G3 exhibited a mixture of positive and negative cells with a tendency for a higher fraction of negative cells in G3. Fhit inactivation is likely to be an early event in G1 tumors and may be associated with progression in G2 and G3 tumors.     

Alterations of the PPP2R1B gene in human lung and colon cancer

The PPP2R1B gene, which encodes the beta isoform of the A subunit of the serine/threonine protein phosphatase 2A (PP2A), was identified as a putative human tumor suppressor gene. Sequencing of the PPP2R1B gene, located on human chromosome 11q22-24, revealed somatic alterations in 15% (5 out of 33) of primary lung tumors, 6% (4 out of 70) of lung tumor-derived cell lines, and 15% (2 out of 13) of primary colon tumors. One deletion mutation generated a truncated PP2A-Abeta protein that was unable to bind to the catalytic subunit of the PP2A holoenzyme. The PP2R1B gene product may suppress tumor development through its role in cell cycle regulation and cellular growth control.     

Distinct patterns of chromosomal alterations in high- and low-grade head and neck squamous cell carcinomas

Comparative genomic hybridization was performed on 30 primary head and neck squamous cell carcinomas. Fractional or entire DNA loss of chromosome 3p was a basic finding that occurred in 29 cases (97%). Additional DNA underrepresentations were observed in more than 50% of the cases on chromosomes 1p, 4, 5q, 6q, 8p, 9p, 11q, 13q, 18q, and 21q. Deletions on chromosomes 3p, 13q, and 17p were confirmed by loss of heterozygosity analysis. Entire or partial DNA copy number increases were identified for chromosome 3q in 26 cases (87%) with high-level amplifications at 3q24 and 3q27-qter. Overrepresentations were found in decreasing order of frequency at 11q13 (70%), 8q (57%), 19q (50%), 19p (47%), and 17q (47%). The use of comparative genomic hybridization superkaryograms of the group of well-differentiated carcinomas (G1) indicated that the deletions on chromosomes 3p and 9p along with the overrepresentation of 3q are associated with early tumor development. Accordingly, the undifferentiated tumors (G3) were characterized by additional deletions on chromosomes 4q, 8p, 11q, 13q, 18q, and 21q and overrepresentations on 1pter, 11q13, 19, and 22q, suggesting that these changes are preferentially associated with tumor progression.     

Mutational analysis of CDKN2 (MTS1/p16ink4) in human breast carcinomas

The CDKN2 gene that encodes the cell cycle regulatory protein cyclin-dependent kinase-4 inhibitor (p16) has recently been mapped to chromosome 9p21. Frequent homozygous deletions of this gene have been documented in cell lines derived from different types of tumors, including breast tumors, suggesting that CDKN2 is a tumor suppressor gene involved in a wide variety of human cancers. To determine the frequency of CDKN2 mutations in breast carcinomas, we screened 37 primary tumors and 5 established breast tumor cell lines by single-strand conformation polymorphism analysis. In addition, Southern blot analysis was performed on a set of five primary breast carcinoma samples and five breast tumor cell lines. Two of the five tumor cell lines revealed a homozygous deletion of the CDKN2 gene, but no mutations were observed in any of the primary breast carcinomas. These results suggest that the mutation of the CDKN2 gene may not be a critical genetic change in the formation of primary breast carcinoma.