Allelic losses on chromosomes 1p, 3p, 11p, 11q in non small cell lung cancers

Recent studies have shown that lung cancer patients frequently suffer inactivation of antioncogenes such as Rb gene (13q14) and p53 gene (17p13). In a study of 48 cases of non-small cell lung cancer (28 squamous-cell carcinomas, 11 adenocarcinomas, 4 large-cell carcinomas, and 5 other types) using restriction fragment length polymorphism analysis, we found DNA sequence deletions from chromosomes 1p32-36, 3p21, 11p15.5, and 11q13. The frequencies of allele loss on chromosome 1p, 3p, 11p and 11q are 31, 57, 20 and 49% of informative cases in this patient group, respectively. Of them, 19 tumors show one allele loss and 10 patients suffer two or more allele losses from different chromosomes.     

11p15.5-specific libraries for identification of potential gene sequences involved in Beckwith-Wiedemann syndrome and tumorigenesis.

Constitutional and somatic chromosomal abnormalities of the chromosome 11p15 region are involved in an overgrowth malformation syndrome, the Beckwith-Wiedemann syndrome (BWS), and in several types of associated tumors. The bias in parental origin for the different etiologic forms of this syndrome and for loss of heterozygosity in the tumors suggests that a gene (or genes) mapping to this region undergoes genomic imprinting. However, the precise localization of the locus (or loci) for the BWS and associated tumors is still unknown and more markers are required. We therefore isolated 11p15 markers from two libraries: the first one obtained by microdissection of the chromosome 11p15.5 region and the second one, a phage library, constructed from a hybrid cell line containing this region as its sole human DNA. Of 19 microclones isolated from the microdissection library, 11 were evolutionarily conserved. Four phage clones were isolated; one (D11S774) detected a highly informative variable number of tandem repeats (VNTR) and another (D11S773) a biallelic polymorphism. These clones were sublocalized using a panel of somatic cell hybrids that defines eight physical intervals in 11p15.5. Twenty-one clones map to the distal interval that harbors the BWS locus.     

Sperm chromosome analysis of two males heterozygous for a t(2;17)(q35;p13) and t(3;8)(p13;p21) reciprocal translocation

Summary Sperm chromosome complements from two males, one heterozygous for the reciprocal translocation t(2;17)(q35;p13) (n = 18) and one for t(3;8) (p13;p21) (n = 73), were analyzed. Only 2:2 segregations were observed with t(2;17): alternate, 56%; adjacent-I, 33%; adjacent-II, 11%. Both 2:2 and 3:1 meiotic segregations occurred in t(3;8): alternate, 34.2%; adjacent-I, 43.8%; adjacent-II, 20.5% and 3:1, 1.4%. A significant excess of chromosomally normal versus balanced sperm complements was observed with both translocation heterozygotes. The frequencies of other chromosome aberrations unrelated to the translocations were 16.7% for t(2;17) and 8.2% for t(3;8). The ratio of X-bearing to Y-bearing sperm was not different from the theoretically expected ratio of 1:1.     

Gene amplification profiling of esophageal squamous cell carcinomas by DNA array CGH

Gene amplification is one of the basic mechanisms that lead to overexpression of oncogenes. DNA array comparative genomic hybridization (CGH) has great potential for comprehensive analysis of both a relative gene-copy number and altered chromosomal regions in cancers, which enables us to identify new amplified genes and unstable chromosomal loci. We examined the amplification status in 32 esophageal squamous cell carcinomas (ESCCs) and 13 ESCC cell lines on 51 frequently amplified loci in a variety of cancers by both DNA array CGH and Southern blot analyses. The 1p34 locus containing MYCL1, 2p24 (MYCN), 7p12 (EGFR), and 12q14 (MDM2) were amplified in one of the 32 cases (3%), and the 17q12 locus (ERBB2) and 8p11 (FGFR1) in two of the 32 cases (6%), while only the 11q13 locus (Cyclin D1, FGF4, and EMS1) was frequently amplified (28%, 9/32), demonstrating this locus to be a major target in ESCCs. One locus, 8q24 (c-MYC) was found to be amplified only in the cell lines. Eight out of 51 loci (15.7%) were found to be amplified in at least one of the 32 primary ESCCs or the 13 ESCC cell lines, suggesting that chromosomal loci frequently amplified in a type of human cancer may also be amplified in other types of cancers. This paper is the first report of an application of DNA array CGH to ESCCs.     

p16(INK4A) immunohistochemical overexpression in premalignant and malignant oral lesions infected with human papillomavirus.

Human papillomavirus (HPV) is believed to promote the oncogenic process, and the correlation between viral oncoproteins and dysfunction of p16(INK4A) tumor suppressor protein in oral lesions is controversial. To test the hypothesis that anogenital HPV types participate in disruption of the regulation of p16(INK4A) suppressor protein in oral lesions, we analyzed 46 oral biopsy specimens for the presence of HPV 6/11 and 16/18 by in situ hybridization (ISH) and for p16(INK4A) expression by immunohistochemistry (IHC). Eighteen (39%) of the 46 oral lesions were HPV-positive and 28 (61%) were HPV-negative. HPV 6/11 DNA was found in 5 (11%) and HPV 16/18 in 13 (28%) of 46 biopsies. Nine of the 18 HPV-positive oral lesions (50%), assessed by catalyzed signal amplification coupled to ISH (CSA-ISH), gave high-intensity p16(INK4A) immunostaining. Focal and diffuse patterns were observed in 11/13 (77%) lesions with HPV 16/18, focal immunopositivity in 3/5 (80%) with HPV 6/11, and negative or sporadic p16-labeling in 18/28 (64%) without the presence of HPV DNA. These results showed a strong association between overexpression of p16 protein and malignant oral lesions, mainly those infected by HPV 16/18. We can conclude that high-risk HPV types are associated with p16 overexpression, and p16 may serve as a biomarker in oral cancer related to high-risk HPV infection.     

Loss of heterozygosity on chromosome 11p13 in primary bladder carcinoma

Although the occurrence of bladder cancer is common, the molecular events underlying the pathogenesis of this cancer remain ill-defined. A loss of heterozygosity (LOH) at specific chromosomal loci may predispose individuals to the development of bladder cancer but this has not been examined in detail. Furthermore, the role that deletion or inactivation of putative tumour suppressor genes might play in the genesis of bladder cancer has not been established. In this study, allelic deletion analysis on the short arm of chromosome 17 of patients with primary bladder tumours failed to show deletion at 17p13 (0/7), a region known to contain the p53 tumour suppressor gene. Chromosome 11p15 showed allelic deletion at the IGF2 locus (2/7: 29%) and the PTH locus (1/11: 9%). However, no deletion was observed at the CALCA locus (0/6). LOH at 11p13, a region containing the Wilm's tumour suppressor gene (WT1), was also studied. Analysis of LOH at 11p13 showed deletion at the CAT locus (13/18: 72%), the J/D11S414 locus (5/15: 33%), the WT1 locus (7/14: 50%) and the FSHB locus (6/16: 38%). The significance of these findings is discussed.     

Alterations in p16 and p53 genes and chromosomal findings in patients with lung cancer: Fluorescence in situ hybridization and cytogenetic studies

Background: Chromosomal aberrations and instability of gene(s) are two factors related to the genetic instability of cancer cells. A loss of the tumor-suppressor function of the genes p16 and p53 is the most common event leading to the development of human cancers. Carcinoma of the lung is the leading cause of cancer deaths in the world. Chromosomal abnormalities in lung cancer may provide a valuable clue to the identification of target loci and culminate in a successful search for the major genes. The aim of this study was to investigate (i) alterations of the p16 and p53 genes and (ii) chromosomal aberrations in patients with small cell and non-small cell lung cancer by fluorescence in situ hybridization (FISH) and cytogenetic studies. Methods: We carried out cytogenetic analysis by Giemsa-banding in 18 cases. FISH probes for the p16 and p53 genes were also used on interphase nuclei to screen the alterations in these genes in lung cancer (LC).Results: We observed a high frequency of losses of the p16 – in 8/18 (44%) – and p53 – in 7/18 (39%) – genes in the cases with LC. A total of 18 patients showed predominantly numerical and structural aberrations. Among these two types, structural aberrations predominated and usually consisted of deletions, breaks, and fragilities in various chromosomes. Both structural and numerical changes were observed in almost all patients. Chromosomes 3 and 1 were found to be most frequently involved in structural abnormalities, followed by chromosomes 6, 9, and 8. Autosomal aneuploidies were also observed to be the most frequent (chromosomes 22, 19, 18, 20, 9, and 17), followed by those of the X and Y chromosomes. The expression of fragile sites was also found to be significantly higher in seven chromosomal regions: 3p14, 1q21, 1q12, 6q26, 9q13, 8q22, and 8q24. Conclusion: Our data confirmed that DNA damage and genomic instability may be factors contributing to the mutation profile and development of lung cancer. The patients who developed lung cancer showed a high frequency of loss of both p16 and p53, in addition to chromosomal aberrations. Tobacco could be a major carcinogenic factor in lung-cancer progression. The loss of p16 and p53, and increased incidence of autosomal aneuploidy and chromatid breaks, along with other chromosomal alterations, can contribute to the progression of the disease.     

Linkage and Association Studies of Prostate Cancer Susceptibility: Evidence for Linkage at 8p22-23

Multiple lines of evidence have implicated the short arm of chromosome 8 as harboring genes important in prostate carcinogenesis. Although most of this evidence comes from the identification of frequent somatic alterations of 8p loci in prostate cancer cells (e.g., loss of heterozygosity), studies have also suggested a role for 8p genes in mediation of inherited susceptibility to prostate cancer. To further examine this latter possibility, we performed linkage analyses, in 159 pedigrees affected by hereditary prostate cancer (HPC), using 24 markers on the short arm of chromosome 8. In the complete set of families, evidence for prostate cancer linkage was found at 8p22-23, with a peak HLOD of 1.84 (P=.004), and an estimate of the proportion of families linked (alpha) of 0.14, at D8S1130. In the 79 families with average age at diagnosis >65 years, an allele-sharing LOD score of 2.64 (P=.0005) was observed, and six markers spanning a distance of 10 cM had LOD scores >2.0. Interestingly, the small number of Ashkenazi Jewish pedigrees (n=11) analyzed in this study contributed disproportionately to this linkage. Mutation screening in HPC probands and association analyses in case subjects (a group that includes HPC probands and unrelated case subjects) and unaffected control subjects were carried out for the putative prostate cancer-susceptibility gene, PG1, previously localized to the 8p22-23 region. No statistical differences in the allele, genotype, or haplotype frequencies of the SNPs or other sequence variants in the PG1 gene were observed between case and control subjects. However, case subjects demonstrated a trend toward higher homozygous rates of less-frequent alleles in all three PG1 SNPs, and overtransmission of a PG1 variant to case subjects was observed. In summary, these results provide evidence for the existence of a prostate cancer-susceptibility gene at 8p22-23. Evaluation of the PG1 gene and other candidate genes in this area appears warranted.     

Cellular protein alterations in colorectal cancer: p28, p53 and p65 studies

The expression and intracellular distribution of the p28 protein (MW 28 kD), which is electrophoretically specific for tumour cells, the p53 protein (MW 53 kD), one of the most frequently mutated in cancer, and the oncofoetal p65 protein (MW 65 kD), were investigated in colorectal cancer and normal colonic mucosa. The correlation between the expression of these proteins and the stage of the cancer, was evaluated. Neoplastic and normal tissues were fractionated by differential centrifugation, and protein analysis was performed by means of the Western blot technique in the presence of polyclonal (anti-p28 and anti-p65) or monoclonal (anti-p53) antibodies. Among the colorectal cancer cases examined 69% (11/16), 53% (10/19) and 77% (17/22) were positive for p28, p53 and p65, respectively. Immunoblot analysis revealed that the tumour specific p28 protein expression was mainly evident in the nuclear fraction, while the p53 and p65 proteins accumulated in the cell nuclei and the cytoplasm, although to different extents. The p65 protein appeared to be specifically expressed in the early stages of colorectal cancer, while a high level of p53 protein was typical for more invasive colorectal cancer stages.     

At least four different chromosomal regions are involved in loss of heterozygosity in human breast carcinoma

Three chromosome regions, i.e., 11p15, 13q, and 17p, were previously reported by three independent groups to be specifically reduced to hemizygosity in human primary breast cancer. We examined the DNA of 64 mammary tumors for loss of heterozygosity (LOH) with 28 polymorphic DNA markers dispersed on 10 arms of 8 different chromosomes. Complete or near-complete absence of LOH was observed on 5 arms (5 chromosomes). LOH at all three previously invoked regions was confirmed, and the highest frequency was found on 17p (67% of heterozygous patients). Allele loss of a marker from chromosome 3 (region p14-p21) was found in 7 of 15 informative cases. Concurrent LOH at 2 to 4 loci was noted in 20 of the 43 tumors showing LOH. Allele losses did not correlate with any of the six clinico-histopathological variables investigated, but in a group of patients in which we were unable to demonstrate LOH, the absence of distant metastases was statistically significant (P less than 0.05). These results suggest that some of the observed allele losses reflect random events, possibly as a result of genetic instability, but are not without biological significance for the progression of particular subclasses of breast tumors.     

Chromosome 11p15 deletions in human malignant astrocytomas and primitive neuroectodermal tumors.

Chromosome 11p15 deletions occur frequently in several types of human cancer, both sporadic and familial, suggesting that a tumor suppressor gene is present within the deleted chromosome region. We carried out a restriction fragment length polymorphism analysis of chromosome 11p in two types of human brain tumors: malignant astrocytoma, the most common glial tumor in adults; and primitive neuroectodermal tumor (PNET), a malignant embryonic tumor that afflicts children. Loss of heterozygosity was found in 11/43 malignant astrocytomas (26%) and in 3/11 PNETs (27%). Deletion mapping revealed a region of loss on chromosome 11p (p15.4-pter) that was common to both tumor types. To determine whether the c-H-ras gene, located on chromosome 11p in the common region of deletion, was a candidate gene, we analyzed polymerase chain reaction products corresponding to all four c-H-ras coding exons for single-strand conformation polymorphisms. The absence of electrophoretic mobility shifts in tumor DNA compared to leukocyte DNA indicated that c-H-ras gene mutations were most likely not present. These results suggested that loss of a gene on chromosome 11p15 distinct from c-H-ras is an important step in tumorigenesis within the central nervous system in both children and adults.     

Smoking related cancers and loci at chromosomes 15q25, 5p15, 6p22.1 and 6p21.33 in the Polish population

Genetic factors associated with the risk of smoking related cancers have until recently remained elusive. Since the publication of a genome-wide association study (GWAS) on lung cancer new genetic loci have been identified that appear to be associated with disease risk. In this replication study we genotyped 14 single nucleotide polymorphisms (SNPs) located at the 5p12.3-p15.33, 6p21.3-p22.1, 6q23-q27 and 15q25.1 loci in 874 lung, 450 bladder, 418 laryngeal cancer cases and cancer-free controls, matched by year of birth and sex to the cases. Our results revealed that loci in the chromosome region 15q25.1 (rs16969968[A], rs8034191[G]) and 5p15 (rs402710[T]) are associated with lung cancer risk in the Polish population (smoking status adjusted OR = 1.45, 1.35, 0.77; p ≤ 0.0001, 0.0005, 0.002; 95%CI 1.23-1.72, 1.14-1.59, 0.66-0.91 respectively). None of the other regions analyzed herein were implicated in the risk of lung, bladder or laryngeal cancer. This study supports previous findings on lung cancer but fails to show association of SNPs located in 15q25.1 and 5p15 region with other smoking related cancers like bladder and laryngeal cancer.     

Deletions in human chromosome arms 11p and 13q in primary hepatocellular carcinomas

Normal liver and hepatocellular carcinoma (HCC) genotypes were compared at loci on most of the human chromosomes with probes that detect restriction fragment length polymorphisms. Six of fourteen tumors exhibited loss of heterozygosity of one or more markers on 11p. Ten patients were informative for loci on 13q, and 5 of these 10 exhibited loss of heterozygosity for one or more of the 13q markers. Altogether, 9 of the 14 patients showed loss of a polymorphic allele for one or more loci on either 11p or 13q. A survey of loci on 16 additional chromosomes indicated that the deletions were not due to a general loss of heterozygosity in HCCs. Quantitative densitometry showed that each of the 10 deletions resulted in hemizygosity (no reduplication) of the remaining allele in tumor tissue. In contrast to hereditary embryonal tumors, in which reduplication of the remaining chromosome is the rule, simple deletion appears to be the primary mechanism responsible for the loss of heterozygosity in these adult, nonhereditary HCCs. These data show that HCCs arising in hepatitis B virus carriers are a genetically heterogeneous group of tumors, some of which may arise through 13q alterations, some through 11p alterations, some with both chromosomes altered, and some with both intact.     

Comprehensive profiling of 8p11-12 amplification in breast cancer

In human carcinomas, especially breast cancer, chromosome arm 8p is frequently involved in complex chromosomal rearrangements that combine amplification at 8p11-12, break in the 8p12-21 region, and loss of 8p21-ter. Several studies have identified putative oncogenes in the 8p11-12 amplicon. However, discrepancies and the lack of knowledge on the structure of this amplification lead us to think that the actual identity of the oncogenes is not definitively established. We present here a comprehensive study combining genomic, expression, and chromosome break analyses of the 8p11-12 region in breast cell lines and primary breast tumors. We show the existence of four amplicons at 8p11-12 using array comparative genomic hybridization. Gene expression analysis of 123 samples using DNA microarrays identified 14 genes significantly overexpressed in relation to amplification. Using fluorescence in situ hybridization analysis on tissue microarrays, we show the existence of a cluster of breakpoints spanning a region just telomeric to and associated with the amplification. Finally, we show that 8p11-12 amplification has a pejorative effect on survival in breast cancer.     

The D4 dopamine receptor (DRD4) maps to distal 11p close to HRAS.

Dopaminergic pathophysiology is important in several psychiatric illnesses. The recently cloned D4 dopamine receptor gene (DRD4) shows considerable homology to the D2 and D3 dopamine receptors (DRD2 and DRD3); pharmacologically, its affinity for the atypical antipsychotic clozapine is much higher than that of these other dopamine receptors. Probe pB28 for this locus recognizes an informative HincII polymorphism. We typed this polymorphism on several large reference families (a total of about 271 individuals) to place DRD4 in the genetic linkage map. Pairwise linkage analysis (using ILINK) provided evidence for close linkage to the distal 11p loci tyrosine hydroxylase (TH) and the Harvey ras oncogene (HRAS). We used our version of LINKMAP adapted to run under distributed parallel processing (Linda-LINKMAP) for an analysis moving DRD4 across a fixed map with HRAS set 3.8 cM distal to TH. This localized DRD4 close to HRAS, with no crossovers observed between those loci and a maximum lod score of 19.9 (2 cM distal to HRAS). The one LOD unit support interval extends from about 1 cM proximal to HRAS to 8 cM distal to HRAS. Crossovers identified in one kindred place DRD4 distal to TH, providing further evidence for its location close to HRAS, making DRD4 one of the most telomeric of 11p markers. (This also places DRD4 in band 11p15.5.)     

Six loci mapped on to human chromosome 2p are assigned to sheep chromosome 3p

Six loci, apoliproprotein B (including Ag(x) antigen), immunoglobulin kappa constant region (IGKC), luteinizing hormone/choriogonadotrophin receptor, avian myelocytomatosis viral related oncogene, neuroblastoma derived, ornithine decarboxylase, and proopiomelanocortin (adrenocorticotropin/beta-lipotropin) (POMC), were newly assigned to sheep chromosome 3p using a chromosomally characterized minipanel of sheep-hamster cell hybrids. Isotopic in situ hybridization of IGKC to sheep chromosome 3p22–p17 is reported, confirming the cell hybrid assignment. As these loci are all known to map to human chromosome 2p, this study demonstrates that this chromosomal segment is extensively conserved in sheep. Only POMC has been previously assigned to cattle chromosome 11, which is the equivalent of sheep chromosome 3p. Therefore, we predict that the other loci assigned in this study to sheep 3p are likely to be located on cattle 11. The provisional assignment of an additional locus, annexin-like to sheep chromosome 3p is also reported.     

Chromosome 17p12-q11 harbors susceptibility loci for systemic lupus erythematosus

Systemic lupus erythematosus (SLE) is an autoimmune disease characterized by the presence of autoantibodies against intracellular components, the formation of immune complexes, and inflammation in various organs, typically the skin and kidney glomeruli. The etiology of the disease is not well understood but is most likely the result of the interaction between genetic and environmental factors. In order to identify susceptibility loci for SLE, we have performed genome scans with microsatellite markers covering the whole genome in families from Argentina, Italy, and Europe. The results reveal a heterogeneous disease with different susceptibility loci in different family sets. We have found significant linkage to chromosome 17p12-q11 in the Argentine set of families. The maximum LOD score was given by marker D17S1294 in combination with D17S1293, when assuming a dominant inheritance model (Z=3.88). We also analyzed a repeat in the promoter region of the NOS2A gene, a strong candidate gene in the region, but no association was found. The locus on chromosome 17 has previously been identified in genetic studies of multiple sclerosis families. Several other interesting regions were found at 1p35, 1q31, 3q26, 5p15, 11q23 and 19q13, confirming previously identified loci for SLE or other autoimmune diseases.A list of members of the Collaborative Group on the Genetics of SLE and the Argentine Collaborative Group is given in the AppendixBernardo Pons-Estel is the coordinator of the Argentine Collaborative Group     

Twenty-seven nonoverlapping zinc finger cDNAs from human T cells map to nine different chromosomes with apparent clustering.

cDNA clones encoding zinc finger structures were isolated by screening Molt4 and Jurkat cDNA libraries with zinc finger consensus sequences. Candidate clones were partially sequenced to verify the presence of zinc finger-encoding regions; nonoverlapping cDNA clones were chosen on the basis of sequences and genomic hybridization pattern. Zinc finger structure-encoding clones, which were designated by the term "Kox" and a number from 1 to 32 and which were apparently unique (i.e., distinct from each other and distinct from those isolated by other laboratories), were chosen for mapping in the human genome. DNAs from rodent-human somatic cell hybrids retaining defined complements of human chromosomes were analyzed for the presence of each of the Kox genes. Correlation between the presence of specific human chromosome regions and specific Kox genes established the chromosomal locations. Multiple Kox loci were mapped to 7q (Kox 18 and 25 and a locus detected by both Kox 8 cDNA and Kox 27 cDNA), 8q24 5' to the myc locus (Kox 9 and 32), 10cen----q24 (Kox 2, 15, 19, 21, 30, and 31), 12q13-qter (Kox 1 and 20), 17p13 (Kox 11 and 26), and 19q (Kox 5, 6, 10, 22, 24, and 28). Single Kox loci were mapped to 7p22 (Kox 3), 18q12 (Kox 17), 19p (Kox 13), 22q11 between IG lambda and BCR-1 (locus detected by both Kox 8 cDNA and Kox 27 cDNA), and Xp (Kox 14). Several of the Kox loci map to regions in which other zinc finger structure-encoding loci have already been localized, indicating possible zinc finger gene clusters. In addition, Kox genes at 8q24, 17p13, and 22q11--and perhaps other Kox genes--are located near recurrent chromosomal translocation breakpoints. Others, such as those on 7p and 7q, may be near regions specifically active in T cells.