Mapping and characterization of the mouse and human SS18 genes, two human SS18-like genes and a mouse Ss18 pseudogene.

We have previously isolated and characterized a mouse cDNA orthologous to the human synovial sarcoma associated SS18 (formerly named SSXT and SYT) cDNA. Here, we report the characterization of the genomic structure of the mouse Ss18 gene. Through in silico methods with sequence information contained in the public databases, we did the same for the human SS18 gene and two human SS18 homologous genes, SS18L1 and SS18L2. In addition, we identified a mouse Ss18 processed pseudogene and mapped it to chromosome 1, band A2-3. The mouse Ss18 gene, which is subject to extensive alternative splicing, is made up of 11 exons, spread out over approximately 45 kb of genomic sequence. The human SS18 gene is also composed of 11 exons with similar intron-exon boundaries, spreading out over about 70 kb of genomic sequence. One alternatively spliced exon, which is not included in the published SS18 cDNA, corresponds to a stretch of sequence which we previously identified in the mouse Ss18 cDNA. The human SS18L1 gene, which is also made up of 11 exons with similar intron-exon boundaries, was mapped to chromosome 20 band q13.3. The smaller SS18L2 gene, which is composed of three exons with similar boundaries as the first three exons of the other three genes, was mapped to chromosome 3 band p21. Through sequence and mutation analyses this gene could be excluded as a candidate gene for 3p21-associated renal cell cancer. In addition, we created a detailed BAC map around the human SS18 gene, placing it unequivocally between the CA-repeat marker AFMc014wf9 and the dihydrofolate reductase pseudogene DHFRP1. The next gene in this map, located distal to SS18, was found to be the TBP associated factor TAFII-105 (TAF2C2). Further analogies between the mouse Ss18 gene, the human SS18 gene and its two homologous genes were found in the putative promoter fragments. All four promoters resemble the promoters of housekeeping genes in that they are TATA-less and embedded in canonical CpG islands, thus explaining the high and widespread expression of the SS18 genes.     

Chromosome analysis of walking catfish,Clarias magur (Teleostei,Siluriformes, Clariidae), using staining,FISH with 18S, 5S and BAC probes

The chromosomal characteristics of Clarias magur were examined using conventional (Giemsa-staining, Ag-impregnation and CMA₃ + DAPI fluorescence) and molecular/ FISH (18S & 5S rDNA probes + one BAC DNA probe) cytogenetic tools. The diploid chromosome number was 50 and the karyotype consisted of 14 metacentric, 20 sub-metacentric, 8 sub-telocentric, 8 acrocentric chromosomes with 84 chromosome arms without any heteromorphic pair. The C-heterochromatic blocks were located on centromeric position of 13 pairs of chromosomes. The NOR sites, visualized by AgNO₃- and CMA₃- staining, were situated at p arms of chromosome pair No. 21, which also corresponded to 18S rDNA site visualized by FISH. The FISH signal of ICF_001_D19 clone probe was observed on 18th chromosome pair. The findings of the present study on C. magur provided valuable markers for the chromosome identification and locations of genes of the BAC clone on the chromosome will lead to the construction of physical map of genome of this species.     

Prenatal diagnosis of tetrasomy 18p using multiplex fluorescent PCR and comparison with a variety of techniques

We report genetic characterization of isochromosome 18p using a combination of cytogenetic and molecular genetic methods, including multiplex fluorescent PCR. The patient was referred for chorionic villus sampling (CVS) due to advanced maternal age and maternal anxiety. The placental karyotype was 47,XX,+mar, with the marker having the appearance of a small supernumerary isochromosome. Because differentiating between isochromosomes and other structural rearrangements is normally very difficult, a variety of genetic tests including fluorescence in situ hybridization (FISH), PCR, and multiplex fluorescent PCR were undertaken to determine chromosomal origin and copy number and, thus, allow accurate diagnosis of the corresponding syndrome. FISH determined that the marker chromosome contained chromosome 18 material. PCR of a variety of short tandem repeats (STRs) confirmed that there was at least one extra copy of the maternal 18p material. However, neither FISH nor PCR could accurately determine copy number. Multiplex fluorescent PCR (MF-PCR) of STRs simultaneously determined that: (1) the marker included 18p material; (2) the marker was maternal in origin; (3) allele copy number indicated tetrasomy; and (4) contamination of the sample could be ruled out. Results were also rapid with accurate diagnosis of the syndrome tetrasomy 18p possible within 5 hours.     

Recurrent proximal 18p monosomy and 18q trisomy in a family with a maternal pericentric inversion of chromosome 18

We report a recurrent partial monosomy of 18p10-->11.2 and proximal partial trisomy of 18q10-->21.3 caused by a maternal pericentric inversion of chromosome 18, involving breakpoints p11.2 and q21q21.3 Based on cytogenetics and FISH analysis, we speculate that the recurrent chromosome abnormality in the proband and in the fetus was the result of a translocation, possibly in a germ cell or germ cell precursor, between the maternal normal 18 and her inverted 18, resulting in maternal germinal mosaicism, i.e. 46,XX,inv(18)/46,XX,t[18;inv(18)][q10;q10]. The unbalanced karyotype of the proband and the fetus is 46,XY,+18,der[18;inv(18)][q10;q10]. To the best of our knowledge, there are no reports of this combination of proximal 18p monosomy and proximal 18q trisomy. The other interesting observation was association of Hirschsprung's disease in the proband.     

Physical mapping of the 5S and 18S-25S rRNA genes by FISH as evidence that Arachis duranensis and A. ipaensis are the wild diploid progenitors of A. hypogaea (Leguminosae)

The 5S and the 18S-25S rRNA genes were physically mapped by fluorescent in situ hybridization (FISH) in all botanical varieties of cultivated peanut Arachis hypogaea (2n = 4x = 40), in the wild tetraploid A. monticola, and in seven wild diploid species considered as putative ancestors of the tetraploids. A detailed karyotype analysis including the FISH signals and the heterochromatic bands was carried out. Molecular cytogenetic landmarks are provided for the construction of a FISH-based karyotype in Arachis species. The size, number, and chromosome position of FISH signals and heterochromatic bands are similar in all A. hypogaea varieties and A. monticola, but vary among the diploid species. Genome constitution of the species is discussed and several chromosome homeologies are established. The bulk of the chromosome markers mapped, together with data on geographical distribution of the taxa, suggest that peanut originated upon domestication of A. monticola and evidence that the diploids A. duranensis and A. ipaensis are the most probable ancestors of both tetraploid species. Allopolyploidy could have arisen by a single event or, if by multiple events, always from the same diploid species.     

Isolation of monochromosomal hybrids for mouse Chromosomes 3, 6, 10, 12, 14, and 18

Mouse/human somatic cell hybrids constitute a valuable resource for both genetic and physical mapping. In this report, we describe the production and characterization of a series of six monochromosomal hybrids generated by fusion of murine microcells with intact human recipient cells. The presence of each mouse chromosome was characterized by PCR analysis and the integrity of the mouse chromosome retained in the hybrids confirmed by fluorescence in situ hybridization (FISH) analysis. Received: 22 August 1996 / Accepted: 19 September 1996     

FISH mapping of 18S-28S and 5S ribosomal DNA, (GATA)n and (TTAGGG)n telomeric repeats in the periwinkle Melarhaphe neritoides (Prosobranchia, Gastropoda, Caenogastropoda)

Spermatocyte chromosomes of Melarhaphe neritoides (Mollusca, Prosobranchia, Caenogastropoda) were studied using fluorescent in situ hybridization (FISH) with four repetitive DNA probes (18S rDNA, 5S rDNA, (TTAGGG)n and (GATA)n). Single-colour FISH consistently mapped one chromosome pair per spread using either 18S or 5S rDNA as probes. The telomeric sequence (TTAGGG)n hybridized with termini of all chromosomes whereas the (GATA)n probe did not label any areas. Simultaneous 18S-5S rDNA and 18S-(TTAGGG)n FISH demonstrated that repeated units of the three multicopy families are closely associated on the same chromosome pair.     

Tetrasomy 18p de novo: Identification by FISH with conventional and microdissection probes and analysis of parental origin and formation by short sequence repeat typing

We report a de novo supernumerary isochromosome 18p in a child with tetrasomy 18p, analyzed by a straightforward combination of cytogenetic and molecular cytogenetic methods. The diagnostic procedure consisted of standard banding techniques and fluorescence in situ hybridization (FISH) with centromere and library DNA probes for chromosome 18, and 18p-specific FISH probes prepared by chromosome microdissection and in vitro amplification. The maternal origin as well as the most probable cell stages of formation of the supernumerary isochromosome were determined by typing of short sequence repeats (SSRs). The pattern of allelic distribution suggests a nondisjunction during meiosis followed by a centromeric misdivision in an early postzygotic mitosis as the most probable mode of isochromosome 18p formation. The combination of the applied methods represents a powerful tool to investigate the nature and the origin of de novo marker chromosomes. Received: 28 August 1995 / Revised: 3 November 1995; 20 December 1995     

Detection of aneuploidy involving chromosomes 13, 18, or 21, by fluorescence in situ hybridization (FISH) to interphase and metaphase amniocytes.

Fluorescence in situ hybridization (FISH) with chromosome-specific probes has been applied to detection of numerical aberrations involving chromosomes 13, 18, and 21 in metaphase and interphase amniocytes. High-complexity, composite probes for chromosomes 13, 18, and 21 were used as hybridization probes for this study. These probes were constructed as chromosome-specific libraries in Bluescribe plasmids and are designated pBS-13, pBS-18, and pBS-21. Elements of these probes bind at numerous sites along the target chromosome and, when detected fluorescently, stain essentially the entire long arm of the target chromosome. The target chromosome number (i.e., the number of chromosomes of the type for which the probe was specific) was correctly determined in 20 of 20 samples in which metaphase spreads were analyzed and in 43 of 43 samples in which interphase nuclei were analyzed; all of these studies were conducted in blind fashion. These results suggest the utility of FISH with composite probes for rapid detection of numerical aberrations in metaphase and interphase amniotic cells.     

Trisomy of chromosome 18 in the baboon (Papio hamadryas anubis)

Trisomy 18 is usually a lethal chromosomal abnormality and is the second most common autosomal trisomy in humans, with an incidence of 1:8000 live births. It is commonly associated with abnormalities of the lower and upper extremities, having the frequency of 95% and 65%, respectively. A newborn female olive baboon (Papio hamadryas anubis) was diagnosed with intrauterine growth retardation and severe arthrogryposis-like congenital joint deformities. Cytogenetic analysis including G-banding and fluorescence in situ hybridization (FISH) revealed that the congenital abnormalities were associated with chromosomal mosaicism for trisomy 18. Genetic analysis with microsatellites from chromosome 18 confirmed the maternal origin of the extra chromosome 18. This is the first report of trisomy 18 in the baboon, which may be a promising animal model of human disease.     

Mosaic isodicentric chromosome 18q: sixth report and review

We describe a girl with a mosaic isodicentric chromosome 18q with discrete features of trisomy 18. She presented with prenatal growth retardation, prominent occiput, small face, high nasal bridge, large nose, thin lips, a perimembranous ventricular septal defect, and subsequent slow psychomotor development and slow growth. Amosaic isopseudodicentric chromosome 18q was detected in cultured lymphocytes: mos 46,XX,psu idic(18)(q23)[74]/ 46,XX[26]. Monosomy of the distal end of 18q23 could not be confirmed by fluorescent in situ hybridization (FISH) with RP 1l-565D23, one of the most telomere located probes of 18q23. Isopseudodicentric chromosome 18q is very rare. Most cases are mosaics. The phenotype varies. More or less distinct features of trisomy 18 and monosomy 18q can be found depending on the degree of mosaicism and the breakpoint in 18q.     

Stabilization of a terminal inversion duplication of 8p by telomere capture from 18q

Terminal inversion duplications of the short arm of chromosome 8 are one of the more common chromosome rearrangements in humans. We report an infant with multiple congenital anomalies, in whom karyotype analysis showed a terminal inversion duplication of 8p including additional material at the distal end of the derivative chromosome, shown to be of chromosome 18q origin. Terminal inversion duplications of 8p are the result of meiotic recombination between inverted olfactory gene receptor repeats in 8p. This recombination generates a dicentric intermediate that breaks during anaphase, and the broken chromosome end is stabilized by telomere healing or telomere capture. The origin of the telomeric region in the majority of constitutional chromosome deletions studied to date was shown to be from telomere healing; the de novo addition of telomeric repeats. In the proband a cytogenetically detectable piece of chromosome 18q was present on the distal end of the derivative 8, suggesting that this chromosome was stabilized by telomere capture of 18q. FISH analyses of additional cases may yield information as to whether telomere capture or telomere-healing events are the predominant mechanism of chromosome stabilization in terminal inversion duplications of 8p.     

Constitutive heterochromatin, 5S and 18S rDNA genes in Apareiodon sp. (Characiformes, Parodontidae) with a ZZ/ZW sex chromosome system

Karyotype, sex chromosome system and cytogenetics characteristics of an unidentified species of the genus Apareiodon originating from Piquiri River (Paraná State, Brazil) were investigated using differential staining techniques (C-banding and Ag-staining) and fluorescent in situ hybridization (FISH) with 5S and 18S rDNA probes. The diploid chromosome number was 2n = 54 with 25 pairs of meta- (m) to submetacentric (sm) and 2 pairs of subtelocentric (st) chromosomes. The major ribosomal rDNA sites as revealed by Ag-staining and FISH with 18S rDNA probe were found in distal region of longer arm of st chromosome pair 26, while minor 5S sites were observed in the interstitial sites on chromosome pairs 2 (smaller cluster) and 7 (larger one). The C-positive heterochromatin had pericentromeric and telomeric distribution. The heteromorphic sex chromosome system consisted of male ZZ (pair 21) and female middle-sized m/st Z/W chromosomes. The pericentric inversion of heterochromatinized short arm of ancestral Z followed by multiplication of heterochromatin segments is hypothesized for origin of W chromosome. The observed karyotype and chromosomal markers corresponded to those found in other species of the genus.     

Chromosomal mapping of 18S-28S rRNA genes and 10 cDNA clones of human chromosome 1 in the musk shrew (Suncus murinus).

The direct R-banding fluorescence in situ hybridization (FISH) method was used to map 18S-28S ribosomal RNA genes and 10 human cDNA clones on the chromosomes of the musk shrew (Suncus murinus). The chromosomal locations of 18S-28S ribosomal RNA genes were examined in the five laboratory lines and wild animals captured in the Philippines and Vietnam, and the genes were found on chromosomes 5, 6, 9, and 13 with geographic variation. The comparative mapping of 10 cDNA clones of human chromosome 1 demonstrated that human chromosome 1 consisted of at least three segments homologous to Suncus chromosomes (chromosomes 7, 10, and 14). This approach with the direct R-banding FISH method is useful for constructing comparative maps between human and insectivore species and for explicating the process of chromosomal rearrangements during the evolution of mammals.     

植物荧光原位杂交技术的发展及其在植物基因组分析中的应用

荧光原位杂交(FISH)是在染色体、间期核和DNA纤维上定位特定DNA序列的一种有效而精确的分子细胞遗传学方法。20年来,植物荧光原位杂交技术发展迅速:以增加检测的靶位数为目的,发展了双色FISH、多色FISH和多探针FISH鸡尾酒技术;为增加很小染色体目标的检测灵敏度,发展了BAC-FISH和酪胺信号放大FISH(TSA-FISH)等技术;以提高相邻杂交信号的空间分辨力为主要目的,发展了高分辨的粗线期染色体FISH、间期核FISH、DNA纤维FISH和超伸展的流式分拣植物染色体FISH技术。在植物基因组分析中,FISH技术发挥了不可替代的重要作用,它可用于:物理定位DNA序列,并为染色体的识别提供有效的标记;对相同DNA序列进行比较物理定位,探讨植物基因组的进化;构建植物基因组的物理图谱;揭示特定染色体区域的DNA分子组织;分析间期核中染色质的组织和细胞周期中染色体的动态变化;鉴定植物转基因。     

Physical mapping of the holoprosencephaly critical region in 18p11.3.

Holoprosencephaly (HPE) is a common developmental defect that results in a spectrum of craniofacial malformations. HPE is genetically heterogeneous, some cases being associated with deletions of the short arm of chromosome 18. In order to map the putative HPE gene located on 18p (HPE4) more precisely, six patients with various cytogenetic 18p deletions and clinical features of HPE have been characterized by using a combination of somatic cell hybrid analysis and FISH. By using a set of 27 chromosome 18p-specific markers, the deletion in each patient was characterized. The HPE minimal critical region on 18p was defined on a molecular level, localizing the HPE4 gene to 18p11.3.     

Preferential segregation of marker chromosomes 14 and 18 in mouse recombinant inbred strains derived from the KE and CBA/Kw strains

The segregation pattern of chromosomes 14 and 18 were analyzed in recombinant inbred strains of mice developed from KE and CBA/Kw strains. The analysis was possible owing to the fact that the C-band on chromosomes 14 of the CBA/Kw strain and that of chromosome 18 of the KE strain show size polymorphism: while the CBA/Kw mice have a small sized C-band on chromosome 14, the KE mice show small C-bands on chromosome 18. Chromosomes were identified by G-banding and FISH. The results show that the chromosomes with small centromeric chromatin segregate preferentially.     

FISH of a maize sh2-selected sorghum BAC to chromosomes of Sorghum bicolor.

Fluorescence in situ hybridization (FISH) of a 205 kb Sorghum bicolor bacterial artificial chromosome (BAC) containing a sequence complementary to maize sh2 cDNA produced a large pair of FISH signals at one end of a midsize metacentric chromosome of S. bicolor. Three pairs of signals were observed in metaphase spreads of chromosomes of a sorghum plant containing an extra copy of one arm of the sorghum chromosome arbitrarily designated with the letter D. Therefore, the sequence cloned in this BAC must reside in the arm of chromosome D represented by this monotelosome. This demonstrates a novel procedure for physically mapping cloned genes or other single-copy sequences by FISH, sh2 in this case, by using BACs containing their complementary sequences. The results reported herein suggest homology, at least in part, between one arm of chromosome D in sorghum and the long arm of chromosome 3 in maize.     

Evolution of chromosome 6 of Solanum species revealed by comparative fluorescence in situ hybridization mapping

Comparative genetic linkage mapping using a common set of DNA markers in related species is an important methodology in plant genome research. Here, we demonstrate a comparative fluorescence in situ hybridization (FISH) mapping strategy in plants. A set of 13 bacterial artificial chromosome clones spanning the entire length of potato chromosome 6 was used for pachytene chromosome-based FISH mapping in seven distantly related Solanum species including potato, tomato, and eggplant. We discovered one paracentric inversion and one pericentric inversion within specific lineages of these species. The comparative FISH mapping data revealed the ancestral structure of this chromosome. We demonstrate that comparative FISH mapping is an efficient and powerful methodology to study chromosomal evolution among plant species diverged for up to 12 million years.