(CAG)nCAA and GGN repeats in the human androgen receptor gene are not associated with prostate cancer in a French-German population.

Alleles of the CAG and the GGC repeat in the first exon of the human androgen receptor (AR) gene have been shown to be associated with the risk of (advanced) prostate cancer. These studies had been carried out in the United States. We have analysed these polymorphisms in a French-German collection of 105 controls, 132 sporadic cases, and a sample of prostate cancer families comprising 85 affected and 46 not affected family members. The allele distributions were very similar in all four groups and chi square statistics on contingency tables did not detect any significant differences. The relative risk (odds ratio, OR) were calculated using logistic regression and did not reach significance despite sufficient numbers of patients and controls. Typical results were OR = 1.007; 95% Confidence Interval (CI) 0.97-1.1, P = 0.87 for CAG as continuous variable and OR = 1.2 (95% CI 0.7-2.0), P = 0.47 for CAG classes < 22 and > = 22 repeats. Similar results were obtained for subgroups defined by age or Gleason score. We conclude that these polymorphisms can not be used as predictive parameters for prostate cancer in the French or German population.

Mirror-symmetric duplicated chromosome 21q with minor proximal deletion, and with neocentromere in a child without the classical Down syndrome phenotype.

We report on a mentally retarded child with multiple minor anomalies and an unusually rearranged chromosome 21. This der(21) chromosome has a deletion of 21p and of proximal 21q, whereas the main portion of 21q is duplicated leading to a mirror-symmetric appearance with the mirror axis at the breakpoint. The centromere is only characterized by a secondary constriction (with a centromeric index of a G chromosome) at an unexpected distal position, but fluorescence in situ hybridization (FISH) with either chromosome specific or with all human centromeres alpha satellite DNA shows no cross hybridization. Thus, the marker chromosome represents a further example of an "analphoid marker with neocentromere." Molecular analysis using polymorphic markers on chromosome 21 verified a very small monosomic segment of the proximal long arm of chromosome 21, and additionally trisomy of the remaining distal segment. Although trisomic for almost the entire 21q arm, our patient shows no classical Down syndrome phenotype, but only a few minor anomalies found in trisomy 21 and in monosomy of proximal 21q, respectively.

A palindromic structure in the pericentromeric region of various human chromosomes.

The primate-specific multisequence family chAB4 is represented with approximately 40 copies within the haploid human genome. Former analyis revealed that unusually long repetition units ( > 35 kb) are distributed to at least eight different chromosomal loci. Remarkably varying copy-numbers within the genomes of closely related primate species as well as the existence of human specific subfamilies, which most probably arose by frequent sequence exchanges, demonstrate that chAB4 is an unstable genomic element, at least in an evolutionary sense. To analyze the chAB4 basic unit in more detail we established a cosmid contig and found it to be organized as inverted duplications of approximately 90 kb flanking a noninverted core sequence of approximately 60 kb. FISH as well as the analysis of chromosome-specific hybrid cell lines revealed a chromosomal localization of chAB4 on chromosomes 1, 3, 4, 9, Y, and the pericentromeric region of all acrocentrics. Furthermore, we can detect chAB4 sequences together with alpha satellites, beta satellites, and satellite III sequences within a single chromosome 22-specific YAC clone, indicating that chAB4 is located in close proximity to the centromere, at least on the acrocentrics. Hence, chAB4 represents an unstable genomic structure that is located just in the chromosomal region that is very often involved in translocation processes.

Evolution of the chAB4 multisequence family in primates.

Approximately 50 members of the primate-specific multisequence family chAB4 are located as clusters at eight different chromosomal loci within the human genome. The whole cloned region of chAB4 represents a single-copy or low-copy sequence in all nonhuman primates tested, with the exception of the chimpanzee, for which we found chAB4 copy numbers similar to those in the human. An Alu element was inserted into chAB4 after the divergence of the Old World monkeys from the hominoids but before chAB4 was amplified. The first amplification step could be dated after the great apes and the human diverged from the Old World monkeys. We have evidence that neither the copy numbers nor the chromosomal locations remained stable after this initial step and that gross alterations in the relative copy numbers of individual family members occurred even after the divergence of the human and the chimpanzee. Taken together, our data suggest that chAB4, in an evolutionary sense, is an unusually unstable sequence family.

A new multisequence family in human.

By hybridizing total human DNA with probes derived from the extrachromosomal circular DNA fraction of cultured cells, we detected a human multisequence family, called chAB4, previously unknown. Approximately 50 copies of this sequence are located in the haploid human genome. The repetition units of chAB4 are 35 kb long and the units are tandemly arranged. DNA sequence analysis of parts of the chAB4 unit revealed no direct evidence for a possible function of the family, but possibly chAB4 harbors a gene. Family members are located on human chromosomes 1, 3, and 9 and on the short arms of chromosomes 13-15, 21, and 22. Therefore, in addition to the rDNA, chAB4 is the second class of clustered repetitive sequences with a relatively long repetition unit localized on the short arms of all acrocentric chromosomes. Some evolutionary aspects arising from the structure of chAB4, the established parts of its DNA sequences, and the chromosomal localization of this new multisequence family are discussed.

Mapping of members of the low-copy-number repetitive DNA sequence family chAB4 within the p arms of human acrocentric chromosomes: characterization of Robertsonian translocations.

Members of the long-range, low-copy-number repetitive DNA sequence family chAB4 are located on nine different human chromosome pairs and the Y chromosome, i.e. on the short arms of all the acrocentrics. To localize the chAB4 sequences more precisely on the acrocentrics, chAB4-specific probes together with rDNA and a number of satellite sequences were hybridized to metaphase chromosomes of normal probands and of carriers of Robertsonian translocations of the frequent types rob(13q14q) and rob(14q21q). The results demonstrate that chAB4 is located on both sides of the rDNA on all the acrocentrics; the exact location, however, may be chromosome specific. Chromosome 22, most probably, is the only chromosome where chAB4 is found in the direct neighbourhood of the centromere. Fluorescence in situ hybridization analyses of metaphase chromosomes of carriers of rob(21q22q) revealed breakpoint diversity for this rare type of Robertsonian translocation chromosome. A direct involvement of chAB4 sequences in recombination processes leading to the Robertsonian translocations analysed in this study can be excluded.

Concerted evolution of members of the multisequence family chAB4 located on various nonhomologous chromosomes.

During the last years it became obvious that a lot of families of long-range repetitive DNA elements are located within the genomes of mammals. The principles underlying the evolution of such families, therefore, may have a greater impact than anticipated on the evolution of the mammalian genome as a whole. One of these families, called chAB4, is represented with about 50 copies within the human and the chimpanzee genomes and with only a few copies in the genomes of gorilla, orang-utan, and gibbon. Members of chAB4 are located on 10 different human chromosomes. FISH of chAB4-specific probes to chromosome preparations of the great apes showed that chAB4 is located, with only one exception, at orthologous places in the human and the chimpanzee genome. About half the copies in the human genome belong to two species-specific subfamilies that evolved after the divergence of the human and the chimpanzee lineages. The analysis of chAB4-specific PCR-products derived from DNA of rodent/human cell hybrids showed that members of the two human-specific subfamilies can be found on 9 of the 10 chAB4-carrying chromosomes. Taken together, these results demonstrate that the members of DNA sequence families can evolve as a unit despite their location at multiple sites on different chromosomes. The concerted evolution of the family members is a result of frequent exchanges of DNA sequences between copies located on different chromosomes. Interchromosomal exchanges apparently take place without greater alterations in chromosome structure.

Characterization of an alphoid subfamily located near p-arm sequences on human chromosome 22.

The centromeric heterochromatin of all human chromosomes is composed of tandemly repeated alpha satellite DNA. Here we describe another alphoid subfamily that maps to human chromosome 22 as determined by FISH. The alphoid sequences were isolated from three YAC-clones carrying DNA from the pericentromeric region of the short arm of human chromosome 22 and limited amounts of alphoid DNA. This property enabled us to map the members of the subfamily to the border of the centromeric region and the short arm of the chromosome. The new alphoid subfamily may contribute to the closure of the gap remaining between the centromeric and short-arm maps of human chromosome 22.

Chromosomal changes during progression of transitional cell carcinoma of the bladder and delineation of the amplified interval on chromosome arm 8q.

The cascade of genetic alterations leading to malignant transformation has been described for adenocarcinoma of the colon but is not established for other common tumor entities. In the present study, different stages of transitional cell carcinoma (TCC) of the bladder are analyzed by comparative genomic hybridization. A dynamic pattern of the chromosomal changes during tumor progression is described. Deletion of chromosome arm 9q is the earliest genetic alteration in pTa tumors. In stage pT1 carcinomas, losses of 9q, 9p, and 11p and gain of 1q and 8q are the most common. In addition to the changes specific for earlier stages, gain of 5p and 20q becomes prominent in carcinomas stage > or =pT2. Association analysis reveals a remarkable cooccurrence of 9p deletion with gain of 5p and 20q in > or =pT2 tumors. In order to determine more precisely the size of the amplified segment and the degree of amplification on chromosome arm 8q in stage pT1 tumors, this region was analyzed by semiquantitative PCR using polymorphic microsatellite markers. These studies revealed an up to 13-fold amplification. The common region of amplification could be narrowed down to 8q22.3 and between GAAT1A4 and D8S1834 (about 7 cM).

Detailed marker chromosome analysis in cell line U-BLC1, established from transitional-cell carcinoma of the bladder.

A permanent cell line, U-BLC1, was established from a primary transitional-cell carcinoma, TCC, of the urinary bladder. Karyotype analysis showed the line to be highly aberrant, with a near-triploid chromosome number of 68 to 73. Comparative genomic hybridization revealed some distinct differences between the primary tumor and the established cell line. Karyotype analysis showed 3 marker chromosomes with homogeneously staining regions, HSRs, in the cell line. The HSRs were isolated by microdissection and the microdissection probes were hybridized to normal metaphase chromosomes. The HSRs contain sequences known to be frequently involved in amplification in transitional-cell carcinoma of the bladder, 6p22, 7p11-p12, 9p23-pter, and one region not yet reported to be amplified in primary TCC of the bladder, 1p31-p32. A candidate-gene approach showed that in the region 7p11-p12 the EGFR locus is amplified and highly expressed.

Predisposing gene for early-onset prostate cancer, localized on chromosome 1q42.2-43.

There is genetic predisposition associated with >=10% of all cancer of the prostate (CaP). By means of a genomewide search on a selection of 47 French and German families, parametric and nonparametric linkage (NPL) analysis allowed identification of a locus, on chromosome 1q42.2-43, carrying a putative predisposing gene for CaP (PCaP). The primary localization was confirmed with several markers, by use of three different genetic models. We obtained a maximum two-point LOD score of 2.7 with marker D1S2785. Multipoint parametric and NPL analysis yielded maximum HLOD and NPL scores of 2.2 and 3.1, respectively, with an associated P value of . 001. Homogeneity analysis with multipoint LOD scores gave an estimate of the proportion of families with linkage to this locus of 50%, with a likelihood ratio of 157/1 in favor of heterogeneity. Furthermore, the 9/47 families with early-onset CaP at age <60 years gave multipoint LOD and NPL scores of 3.31 and 3.32, respectively, with P = .001.