Chromosomes 17 and 22 involved in marker formation in neurofibrosarcoma in von Recklinghausen disease

Summary We describe the cytogenetic findings in a recurrent neurofibrosarcoma in a patient with nonfamilial von Recklinghausen disease. The composite karyotype was: 40,Y,-X,+dic r(X;20)(:Xp22.2q26::20p13 q13:), -1, +der(1)t(1;3) (p21;p24),-3,-4,-5,+der(5) t(5;?)(q31;?),-9,-9,+der(9)t(3;9)(q21 or q13;p24 or p22), -11,+der(11)t(11;?)(q22.2;?), -17,+der(17)t(17; 22;?)(q21;q13.1;?), -20, -21, -22, -22, +der(22)t(17; 22;?)(q21;q13.1;?),t(2;10)(q37;q22). The derivative chromosomes were demonstrated at the 500 band level. Chromosomes 17 and 22 were shown to be involved in an unbalanced three-way translocation: t(17;22;?)(q21;q13.1;?). This event was confirmed by in situ hybridization, using two probes mapped to chromosome 17. Hill H is a probe derived from the novel oncogene TRE and is located at 17q12–22. The second probe, derived from the granulocyte colony-stimulating factor (G-CSF), is located at 17q11–q21. The rearrangement between chromosomes 17 and 22 showed breakpoints similar or close to the gene loci for neurofibromatosis 1 (NF-1) and NF-2. Based on our observations we recommend that genetic studies on NF-1 tumors include both gene sites (NF-1 and NF-2) rather than focus on one gene locus.     

ZOO-FISH Suggests a Complete Homology between Human and Capuchin Monkey (Platyrrhini) Euchromatin

Chromosome comparisons usingin situhybridization of all human chromosome-specific libraries on Capuchin monkey (Cebus capucinus,Cebidae, Platyrrhini) metaphases were performed with a new technique simultaneously revealing a G-banding and chromosome “painting.” A complete homology between human (HSA) andC. capucinus(CCA) chromosomes was demonstrated, except for constitutive heterochromatin. ElevenC. capucinuschromosomes are homologous to 11 human chromosomes: CCA 2 = HSA 4; CCA 3 = HSA 6; CCA 12 = HSA 9; CCA 16 = HSA 11; CCA 10 = HSA 12; CCA 11 = HSA 13; CCA 20 = HSA 17; CCA 8 = HSA 19; CCA 23 = HSA 20; CCA 24 = HSA 22; and CCA X = HSA X. TenC. capucinuschromosomes are homologous to parts of human chromosomes: CCA 13 = HSA 8q; CCA 14 = HSA 2q; CCA 15 = HSA 1p + 1q proximal; CCA 17 = HSA 7 part; CCA 18 and 19 = HSA 3 part; CCA 21 and 22 = HSA 1q distal; CCA 25 = HSA 10p; and CCA 26 = HSA 15q part. SixC. capucinuschromosomes are homologous to parts of two human chromosomes: CCA 1 = HSA 5 + 7 part; CCA 4 = HSA 2p + q proximal + 16q; CCA 5 = HSA 10q + 16p; CCA 6 = HSA 14 + 15 part; CCA 7 = HSA 8p + 18; and CCA 9 = HSA 3 part + 21. Many previous banding comparisons were confirmed but several cryptic or complex rearrangements could be identified. With theC. capucinuskaryotype having been shown to be fairly ancestral, this comparison opens the possibility to compare human chromosomes to most Cebidae species.     

Chromosomal localization of 9 KOX zinc finger genes: physical linkages suggest clustering of KOX genes on chromosomes 12, 16, and 19

Nine KOX zinc finger genes were localized on four human chromosomes by in situ hybridization of cDNA probes to metaphase chromosomes. KOX1 (ZNF10), KOX11 (ZNF18), and KOX12 (ZNF19) were mapped to chromosome bands 12q24.33, 17p13-p12, and 16q22-q23, respectively. Six other KOX genes were localized on chromosome 19: KOX6 (ZNF14) and KOX13 (ZNF20) to 19p13.3-p13.2, KOX5 (ZNF13) and KOX22 (ZNF27) to 19q13.2-qter, and KOX24 (ZNF28) and KOX28 (ZNF30) to 19q13.4. Pulsed field gel electrophoresis experiments showed that the pairs of KOX genes found on the chromosome bands 12q24.33, 16q22-q23, 19p13.3-p13.2, or 19q13.3-qter lie within 200–300 kb DNA fragments. This suggests the existence of KOX gene clusters on these chromosomal bands.     

人体乳腺癌细胞系Bcap－37和MCF－7的细胞遗传学研究

应用低温同步法与秋水酰胺处理,对人体乳腺癌细胞系Ｂｃａｐ－３７和ＭＣＦ－７的中期及早中期细胞进行Ｇ－显带分析。研究表明,Ｂｃａｐ－３７细胞染色体众数为６３,可识别其结构的标记染色体１７条;ＭＣＦ－７细胞染色体众数为５６,可识别其结构的标记染色体１３条。结合文献报道以及本研究结果显示,乳腺癌中最常涉及到第１、３、５、７、１１、１３和１７号染色体结构及数目的异常,染色体断裂点１ｐ１１（１ｑ１１）、１ｐ１３、３ｐ２１、３ｑ１１、５ｑ１１、６ｑ１３、６ｑ２３、７ｑ２２、１１ｐ１３和１１ｐ１５也经常涉及;它们可能与癌相关基因的激活和抗癌基因的丢失有关,从而在乳腺癌发生发展中起一定作用。     

Chromosomal localization of the Epstein-Barr virus (EBV) genome in Bloom's syndrome B-lymphoblastoid cell lines transformed with EBV

The localization of the Epstein-Barr virus (EBV) genome in chromosomes of human B-lymphoblastoid cell lines (LCLs) transformed with EBV, and the effect of EBV DNA on the level of sister chromatid exchange (SCE) in Bloom's syndrome (BS) B-LCLs, were examined with chromosomal in situ hybridization techniques using a ³H-EBV DNA probe. EBV DNA was detected in chromosomes 1–5 and 13–15 at specific G band regions in BS as well as in normal B-LCLs, regardless of SCE. Several chromosomal sites (1p31, 1q31, 4q22–24, 5q21, 13q21, 14q21) carrying EBV DNA seemed to be very characteristic in normal as well as in BS B-LCLs. There was no statistically significant difference in silver grain counts due to EBV DNA and their distribution in different chromosomes or groups among normal and BS B-LCLs with normal and high SCE. These findings strongly indicate that EBV infection did not introduce a correcting factor for BS SCE.     

Topography of genetic loci in the nuclei of cells of colorectal carcinoma and adjacent tissue of colonic epithelium

To determine the influence of increased gene expression and amplification in colorectal carcinoma on chromatin structure, the nuclear distances between pairs of bacterial artificial chromosome (BAC) clones with genomic separation from 800 to 29,000 kb were measured and compared between the tumor and parallel epithelial cells of six patients. The nuclear distances were measured between the loci in chromosomal bands 7p22.3–7p21.3; 7q35–7q36.3; 11p15.5–11p15.4; 20p13; 20p12.2; 20q11.21 and 20q12 where increased expression had been found in all types of colorectal carcinoma. The loci were visualized by three-dimensional fluorescence in situ hybridization using 22 BAC clones. Our results show that for short genomic separations, mean nuclear distance increases linearly with increased genomic separation. The results for some pairs of loci fell outside this linear slope, indicating the existence of different levels of chromatin folding. For the same genomic separations the nuclear distances were frequently shorter for tumor as compared with epithelial cells. Above the initial growing phase of the nuclear distances, a plateau phase was observed in both cell types where the increase in genomic separation was not accompanied by an increase in nuclear distance. The ratio of the mean nuclear distances between the corresponding loci in tumor and epithelium cells decreases with increasing amplification of loci. Our results further show that the large-scale chromatin folding might differ for specific regions of chromosomes and that it is basically preserved in tumor cells in spite of the amplification of many loci.Communicated by T. Hassold     

FISH studies on the telomeric regions of the T-cell acute lymphoblastic leukemia cell line CCRF-CEM

So far, the problem of an influence of translocations on the telomeres of the involved chromosomes has not been addressed yet in human cells. Therefore, the telomeres of a karyotypically rather well characterized T-cell acute lymphoblastic leukemia (T-ALL) cell line (CCRF-CEM) with several marker chromosomes were examined using peptide nucleic acid (PNA) telomere FISH probes to compare the telomere length of these markers with that of the chromosome arms of their origin. In addition, chromosome libraries, centromeric probes, and subtelomeric DNA probes were used to further define the marker chromosomes. Two markers could be newly defined and a concise karyotype of the cell line could be obtained by these detailed examinations: 42-47,X,-X,del(5) (q35?),t(5;15)(q14;q13.2),t(8;9)(p11;p24),del(9)(:p13-->qter)/inv(9)(pter-->p12::q21-->p12::q21-->qter),+13,+20,+der(22)(p+ [HSR?])[cp]. The relative telomere length of all chromosomes showed considerable interchromosomal, intercellular, and inter-passage variation. However, it could be shown, that in four different passages of the examined cell line the observed differences between relative telomere lengths of the markers and the chromosomes of their origin, with two exceptions (short arms of del/inv9 and der22), were not significant. On the other hand, because of its mentioned variability, telomere length alone is not sufficient to reliably define the derivation of markers.     

Construction and characterization of band-specific DNA libraries

Summary A universally primed polymerase chain reaction was developed to amplify DNA dissected from GTG-banded human chromosomes. The amplification products are cloned into plasmid vectors, which allow the rapid characterization of recombinant clones. Starting from 20–40 chromosome fragments, several thousand independent clones detecting single-copy sequences can be obtained. Although these libraries comprise only a few percent of the dissected DNA, they provide narrowly spaced anchor clones for the molecular characterization of chromosome bands and the identification of gene sequences. Here we describe the construction and characterization of DNA libraries for the Langer-Giedion syndrome chromosome region (LGCR, 8q23–24.1), Wilms tumor chromosome region 1 (WT1, 11p13), Prader-Willi syndrome/Angelman syndrome chromosome region (PWCR/ANCR, 15q11.2–12), meningioma chromosome region (MGCR, 22q12–13), and fragile X chromosome region (FRAXA, Xq27.3).     

Non-random distribution of Alu-family repeats in human chromosomes

A phage lambda recombinant clone containing at least 8 Alu-family repeats (AFRs) has been isolated from a human genomic library, and DNA from the phage was used as a probe for in situ hybridization on G-banded human metaphase chromosomes of healthy donors and leukemic patients. Some chromosome bands show prominent clusters of silver grains in all individuals examined: 1p34, 1q23, 2q21–22, 10p14, 11p14, 10q21 and 11q14. The data suggest non-random distribution of AFRs in the human genome.     

Chromosomal mapping of human adenylyl cyclase genes type III,type V and type VI

Adenylyl cyclase activity plays a central role in the regulation of most cellular processes. At least eight different adenylyl cyclases have been identified, which are endowed with various and sometimes opposing regulatory properties. Recently we have localized the human genes encoding two of these adenylyl cyclases: the gene for type 11 adenylyl cyclase is located on chromosome 2 (sub-band 2p15.3), the gene for type VIII is located on chromosome 8 (sub-band 8824.2). More recently the type I gene has been located on chromosome 7 (sub-band 7pl2–7p13). Using in situ hybridization, we have now localized the genes for three other adenylyl cyclases: the type III gene has been localized on chromosome 2 in the sub-band 2p22–2p24, the type V gene on chromosome 3 at position 3q13.2–3q21, and the type VI gene on chromosome 12 at position 12q12–12q13. It therefore appears that all adenylyl cyclase genes, known at present are located on different chromosomes and thus are likely to be independently regulated.     

Biological significance of chromosomal imbalance aberrations in gastrointestinal stromal tumors

Gastrointestinal stromal tumors (GISTs) are the most common mesenchymal tumors of the gastrointestinal tract. Current criteria for the diagnosis of malignant GISTs do not always reliably predict patient outcomes. In order to search for genetic markers with prognostic potential, chromosomal imbalance aberrations (CIAs) were analyzed in 28 subjects with GIST using comparative genomic hybridization and correlated with clinicopathological features. Except for a small rectal tumor, CIAs were identified in all GISTs, including 14 from the stomach, 11 from the small intestine, 1 from the esophagus, and 1 from the rectum. Losses were more common than gains. The median number of CIAs in high-risk GISTs was significantly higher than that in low-risk GISTs (5.60±2.59 vs. 3.38±2.55; p<0.05), especially for losses (4.60±1.84 vs. 2.63±2.13; p<0.01). Loss of 14q was the most common CIA in both low-risk and high-risk GISTs, and can be regarded as an early event of GIST development. Losses of 1p and 15q were also very common, often coexisting, and were slightly more frequent in high-risk GISTs than in low-risk GISTs. Other recurrent CIAs, including losses of 10q, 13q, 15q, 18q, and 22q and gains of 5p, 12q, 17q, and 20q were relatively less common in this series. Among these CIAs, losses of 13q, 10q (with minimal overlapping on q11–q22), and 22q were most likely the chromosomal loci potentially harboring the tumor suppressor gene(s) which may be related to early recurrence and/or metastasis during malignant transformation of GISTs.     

Localization of the beta-globin gene by chromosomal in situ hybridization

A 3.7-kilobase (kb) genomic clone of the human beta-globin gene, including 1.5-kb upstream and approximately 0.5-kb downstream, was utilized in chromosomal in situ hybridization for precise mapping of the beta-globin locus on peripheral blood lymphocyte-derived metaphases from a normal male, and for further evaluation of a clonal t(7;11) (q22;p15) translocation on bone marrow-derived metaphases from a 46-year-old male with erythroleukemia. Analyses of 205 midmetaphases from a normal male hybridized with the tritium-labeled beta-globin probe and stained with quinacrine mustard dihydrochloride revealed approximately 12% of spreads to have silver-grain deposition over the p15 band of chromosome 11. Of the 365 silver grains observed to be located on or beside chromosomes, 25 (approximately 7%) grains were localized in band p15. Karyotype analysis of a bone marrow specimen from the patient with erythroleukemia revealed hypodiploidy with various unidentified marker chromosomes as well as a presumably balanced translocation between 7q and 11p . Chromosomal in situ hybridization showed localization of silver grains at the junction between chromosomes 7 and 11 as well as to the normal chromosome 11, indicating that the beta-globin locus had not been translocated in the chromosomal rearrangement. This case demonstrates the value of chromosomal in situ hybridization in the definition of chromosome rearrangements and provides further evidence for the localization of the beta-globin gene to 11p15 .     

Pericentric inversions in man: personal experience and review of the literature

Summary The Leuven cytogenetic centre experience on pericentric inversion in man is discussed with exclusion of the pericentric inversions of the heterochromatic blocks of chromosomes 1 and 9. In a total of 51,500 patients, referred for constitutional chromosome analysis during the period 1970–1985, pericentric inversions were found in 24 index patients. The breakpoints detected in these different pericentric inversions are summarized and compared to those found in previous reports. Bands 2p13, 2q21, 5q31, 6c21, 10q22, and 12q13 were shown to be repeatedly involved in the different studies and, furthermore, breakpoints at bands 2q11, 5p13, 5p15, 5q13, 7q11, 11q25, and 14p11 were present in this study as well as in our previous review on reciprocal autosomal translocations. In 13 familial pericentric inversions, even after exclusion of all inversion carrier probands, a 1.6:1 excess of pericentric inversion carriers versus karyotypically normal progeny was observed. While chromosomally unbalanced offspring represent 3.5% of all chromosomally investigated liveborns of the present study, 7.1% of all liveborn inversion carrier offspring presented with a mental retardation and/or multiple congenital anomalies (MR/MCA) problem. Additional chromosomal abnormalities, i.e. a 21 trisomy and an accessory small ring chromosome were observed in two pericentric inversion carriers. These data and results are discussed and compared to the data available in the literature.     

Two type II keratin genes are localized on human chromosome 12

Summary Human genomic DNA containing two type II keratin genes, one coding for keratin 1 (K1, a 68-kD basic protein) and another closely linked type II gene 10–15 kb upstream (K?, gene product unknown), was isolated on a single cosmid clone. EcoRI restriction fragments of the cosmid were subcloned into pGEM-3Z, and specific probes comprising the C-terminal coding and 3 noncoding regions of the two genes were constructed. The type II keratin genes were localized by in situ hybridization of the subcloned probes to normal human lymphocyte chromosomes. In a total of 70 chromosome spreads hybridized with the K? probe (gHK?-3, PstI, 800 bp), 36 of the 105 grains observed were on chromosome 12, and 32 of these were clustered on the long arm near the centromere (12q11–13). In 100 labeled metaphases hybridized with the K1 probe (gHK1–3, BamHI-PstI, 2100 bp), 53 grains localized to chromosome 12 and 46 of these were found in the same region (q11–13). Therefore, both the gene for human keratin 1, a specific marker for terminal differentiation in mammalian epidermis, and another closely linked unknown type II keratin gene (K?, 10–15 kb upstream of K1) are on the long arm (q11–13) of human chromosome 12.     

Subregional physical mapping of an αB-crystallin sequence and of a new expressed sequence D11S877E to human 11q

We report the regional assignment on Chromosome (Chr) 11q of two cDNA clones selected as sequences expressed in mature kidney and not expressed in Wilms' tumor. Clone T70 was identified as an B-crystallin sequence (CRYA2). CRYA2 has previously been mapped to 11q22.3–23.1 by in situ hybridization. Clone 6.2 represents a new gene expressed in adult and fetal kidney, pancreas, and liver. In order to map sequences corresponding to clone 6.2 and to physically define the boundaries of the localization of CRYA2, we used somatic cell hybrids carrying either different human chromosomes or Chr 11 segments and a cell line established from a patient with an interstitial deletion of region 11q14.3–q22.1. We showed that CRYA2 lies proximal to the 11q23.2 breakpoint defined by the constitutional t(11;22) and distal to the 11q22.1 breakpoint (between D11S388 and D11S35) of a constitutional interstitial deletion. This is in agreement with previous data obtained by in situ hybridization and provides proximal and distal physical benchmarks for this localization. Clone 6.2-related sequence (D11S877E) was assigned to region 11q23.2–q24.2 defined by the breakpoints of the constitutional t(11;22) and of the Ewing's sarcoma neuroepithelioma t(11;22).     

Localization of the active type I DNA topoisomerase gene on human chromosome 20q11.2-13.1, and two pseudogenes on chromosomes 1q23-24 and 22q11.2-13.1

Summary Different subfragments of a cDNA coding for DNA topoisomerase I were used as probes to determine the chromosomal localization of topoisomerase I sequences in human cells. Southern blotting of restricted DNA from a panel of rodent-human somatic cell hybrids revealed the localization of the complete gene on chromosome 20 and the presence of two truncated topoisomerase I pseudogene sequences on chromosomes 1 and 22. In situ chromosome hybridzation experiments confirmed these results showing the location of the complete gene on band q11.2–13.1 of chromosome 20, and the location of the pseudogene sequences on band q23–24 of chromosome 1 and q11.2–13.1 of chromosome 22.     

A Retrospective Observational Study of the Relationship between Single Nucleotide Polymorphisms Associated with the Risk of Developing Colorectal Cancer and Survival

BackgroundThere is variability in clinical outcome for patients with apparently the same stage colorectal cancer (CRC). Single nucleotide polymorphisms (SNPs) mapping to chromosomes 1q41, 3q26.2, 6p21, 8q23.3, 8q24.21, 10p14, 11q13, 11q23.1, 12q13.13, 14q22, 14q22.2, 15q13.3, 16q22.1, 18q21.1, 19q13.11, 20p12, 20p12.3, 20q13.33 and Xp22 have robustly been shown to be associated with the risk of developing CRC. Since germline variation can also influence patient outcome the relationship between these SNPs and patient survivorship from CRC was examined.MethodsAll enrolled into the National Study of Colorectal Cancer Genetics (NSCCG) were genotyped for 1q41, 3q26.2, 6p21, 8q23.3, 8q24.21, 10p14, 11q13, 11q23.1, 12q13.13, 14q22, 14q22.2, 15q13.3, 16q22.1, 18q21.1, 19q13.11, 20p12, 20p12.3, 20q13.33 and xp22 SNPs. Linking this information to the National Cancer Data Repository allowed patient genotype to be related to survival.ResultsThe linked dataset consisted of 4,327 individuals. 14q22.22 genotype defined by the SNP rs4444235 showed a significant association with overall survival. Specifically, the C allele was associated with poorer observed survival (per allele hazard ratio 1.13, 95% confidence interval 1.05–1.22, P = 0.0015).ConclusionThe CRC susceptibility SNP rs4444235 also appears to exert an influence in modulating patient survival and warrants further evaluation as a potential prognostic marker.     

Mapping Human Telomere Regions with YAC and P1 Clones: Chromosome-Specific Markers for 27 Telomeres Including 149 STSs and 24 Polymorphisms for 14 Proterminal Regions

A YAC library enriched for telomere clones was constructed and screened for the human telomere-specific repeat sequence (TTAGGG). Altogether 196 TYAC library clones were studied: 189 new TYAC clones were isolated, 149 STSs were developed for 132 different TYACs, and 39 P1 clones were identified using 19 STSs from 16 of the TYACs. A combination of mapping methods including fluorescencein situhybridization, somatic cell hybrid panels, clamped homogeneous electric fields, meiotic linkage, and BLASTN sequence analysis was utilized to characterize the resource. Forty-five of the TYACs map to 31 specific telomere regions. Twenty-four linkage markers were developed and mapped within 14 proterminal regions (12 telomeres and 2 terminal bands). The polymorphic markers include 12 microsatellites for 10 telomeres (1q, 2p, 6q, 7q, 10p, 10q, 13q, 14q, 18p, 22q) and the terminal bands of 11q and 12p. Twelve RFLP markers were identified and meiotically mapped to the telomeres of 2q, 7q, 8p, and 14q. Chromosome-specific STSs for 27 telomeres were identified from the 196 TYACs. More than 30,000 nucleotides derived from the TYAC vector-insert junction regions or from regions flanking TYAC microsatellites were compared to reported sequences using BLASTN. In addition to identifying homology with previously reported telomere sequences and human repeat elements, gene sequences and a number of ESTs were found to be highly homologous to the TYAC sequences. These genes include human coagulation factor V (F5), Wee1 protein tyrosine kinase (WEE1), neurotropic protein tyrosine kinase type 2 (NTRK2), glutathioneS-transferase (GST1), and β tubulin (TUBB). The TYAC/P1 resource, derivative STSs, and polymorphisms constitute an enabling resource to further studies of telomere structure and function and a means for physical and genetic map integration and closure.     

A Novel Stratification Method in Linkage Studies to Address Inter- and Intra-Family Heterogeneity in Autism

Most genome linkage scans for autism spectrum disorders (ASDs) have failed to be replicated. Recently, a new ASD phenotypic sub-classification method was developed which employed cluster analyses of severity scores from the Autism Diagnostic Interview-Revised (ADI-R). Here, we performed linkage analysis for each of the four identified ADI-R stratified subgroups. Additional stratification was also applied to reduce intra-family heterogeneity and to investigate the impact of gender. For the purpose of replication, two independent sets of single nucleotide polymorphism markers for 392 families were used in our study. This deep subject stratification protocol resulted in 16 distinct group-specific datasets for linkage analysis. No locus reached significance for the combined non-stratified cohort. However, study-wide significant (P = 0.02) linkage scores were reached for chromosomes 22q11 (LOD = 4.43) and 13q21 (LOD = 4.37) for two subsets representing the most severely language impaired individuals with ASD. Notably, 13q21 has been previously linked to autism with language impairment, and 22q11 has been separately associated with either autism or language disorders. Linkage analysis on chromosome 5p15 for a combination of two stratified female-containing subgroups demonstrated suggestive linkage (LOD = 3.5), which replicates previous linkage result for female-containing pedigrees. A trend was also found for the association of previously reported 5p14-p15 SNPs in the same female-containing cohort. This study demonstrates a novel and effective method to address the heterogeneity in genetic studies of ASD. Moreover, the linkage results for the stratified subgroups provide evidence at the gene scan level for both inter- and intra-family heterogeneity as well as for gender-specific loci.