Isolation of human chromosome 21 sequences and their application to in situ hybridization

Summary We report the isolation of 50 independent unique sequences from a human chromosome 21 library (identification code LA21 NSO1). These sequences were individually assigned to chromosome 21 using a mouse-human somatic hybrid cell line, WAVR 4d-F94a. Use of these unique clones as a mixture of probes for in situ hybridization of human metaphase chromosomes demonstrated strong signals on chromosome 21. These unique DNA sequences should provide useful tools for structural and functional analysis of human chromosome 21. The use of these sequences for the detection of Down syndrome is discussed.     

Isolation and regional mapping of DNA sequences unique to human chromosome 21.

To isolate DNA sequences unique to chromosome 21 we have used a recombinant-DNA library, constructed from a mouse-human somatic-cell hybrid line containing chromosome 21 as the only human chromosome. Individual recombinant phage containing human DNA inserts were identified by their hybridization to total human DNA sequences and by their failure to hybridize to total mouse DNA sequences. A repeat-free human DNA fragment was then subcloned from each of 14 such recombinant phage. An independent somatic-cell hybrid was used to assign all 14 subcloned fragments to chromosome 21. Thirteen of the fragments have been regionally mapped using a somatic-cell hybrid containing a human 21 translocation chromosome. Two probes map proximal to the 21q21.2 translocation breakpoint, and 11 probes map distal to this breakpoint, placing them in the region 21q21.2-21q22. One of seven probes used to screen for restriction-fragment-length polymorphisms recognized polymorphic DNA fragments when hybridized to genomic DNA from unrelated individuals. These 14 unique probes provide useful tools for studying the structure and function of human chromosome 21 as well as for investigating the molecular biology of Down syndrome.     

Formation of novel CENP-A domains on tandem repetitive DNA and across chromosome breakpoints on human chromosome 8q21 neocentromeres

Endogenous human centromeres form on megabase-sized arrays of tandemly repeated alpha satellite DNA. Human neocentromeres form epigenetically at ectopic sites devoid of alpha satellite DNA and permit analysis of centromeric DNA and chromatin organization. In this study, we present molecular cytogenetic and CENP-A chromatin immunoprecipitation (ChIP) on CHIP analyses of two neocentromeres that have formed in chromosome band 8q21 each with a unique DNA and CENP-A chromatin configuration. The first neocentromere was found on a neodicentric chromosome 8 with an inactivated endogenous centromere, where the centromeric activity and CENP-A domain were repositioned to band 8q21 on a large tandemly repeated DNA. This is the first example of a neocentromere forming on repetitive DNA, as all other mapped neocentromeres have formed on single copy DNA. Quantitative fluorescent in situ hybridization (FISH) analysis showed a 60% reduction in the alpha satellite array size at the inactive centromere compared to the active centromere on the normal chromosome 8. This neodicentric chromosome may provide insight into centromere inactivation and the role of tandem DNA in centromere structure. The second neocentromere was found on a neocentric ring chromosome that contained the 8q21 tandemly repeated DNA, although the neocentromere was localized to a different genomic region. Interestingly, this neocentromere is composed of two distinct CENP-A domains in bands 8q21 and 8q24, which are brought into closer proximity on the ring chromosome. This neocentromere suggests that chromosomal rearrangement and DNA breakage may be involved in neocentromere formation. These novel examples provide insight into the formation and structure of human neocentromeres.     

Molecular and cytogenetic characterization of a de novo t(5p;21q) in a patient previously diagnosed as monosomy 21.

Genomic single-copy DNA fragments were used to characterize an undetected chromosome translocation in an individual whose metaphase chromosome analysis revealed apparent monosomy 21. Eight RFLPs detected by six probes were used to identify homologous sequences from chromosome 21 in DNA digests from the proband and her parents. These family studies showed that the proband was disomic for the distal region of 21q. Reverse banding and in situ hybridization of chromosome 21-specific probes to metaphase chromosomes from the proband revealed a de novo translocation with breakpoints at 5p13 or 14 and 21q11 or 21. In situ hybridization permitted orientation of the translocated portion of chromosome 21 on the derivative chromosome 5 and, in conjunction with molecular analysis and previous mapping studies, refined the physical map for the long arm of chromosome 21.     

Assignment of 35 single-copy and 17 repetitive sequence DNA probes to human chromosome 3: high-resolution physical mapping of 7 DNA probes by in situ hybridization

Thirty-five single-copy and 17 repetitive sequence DNA probes specific for human chromosome 3 were isolated from human chromosome 3-derived genomic libraries. Seven DNA clones, including three that are polymorphic for BglII or MspI, were mapped by in situ hybridization. Four probes were mapped to 3p subregions and 3 were mapped to 3q subregions. Three of the DNA sequences map to regions overlapping a segment of chromosome 3 (3p14-23) frequently deleted in small cell lung cancer cells. By Southern blot analysis on a deletion hybrid panel, we previously mapped 6 of these probes to three distinct chromosome 3 subregions. Our in situ data support these assignments and more precisely determine the localization of each clone to the following regions: D3S34 (3p14-21), D3S35 (3p21), D3S39 (3p21), D3S40 (3p12-13), D3S37 (3q21-23), and D3S36 (3q21). Clone pL84c, a low repeat sequence clone (approximately 30 copies), was mapped to the 3q21-29 subregion. These DNA clones mapped by in situ hybridization can provide useful landmarks for the ordering and localization of other clones.     

染色体特异DNA文库的构建与鉴定

为构建人类21号染色体特异DNA文库, 以应用于人类遗传疾病的鉴定和研究, 文章采用循环温度梯度法溶解释放微分离的人外周血细胞21号染色体DNA, 将其进行简并寡核苷酸引物PCR(Degenerate oligo nucleotide primer-PCR, DOP-PCR)扩增后, 利用100~500 bp和500~2 000 bp分段回收纯化的两种不同片段大小的DOP-PCR产物构建染色体特异DNA文库, 并分别采用荧光原位杂交(Florescence in situ hybridization, FISH)和斑点杂交对DOP-PCR产物的来源和随机取样的文库克隆进行检测以评估所构建DNA文库的特异性。结果表明: 循环温度梯度法能有效溶解释放微分离的21号染色体DNA; 通过对DOP-PCR产物的分段回收纯化和克隆, 增加了大片段DNA的连接效率; 利用FISH技术和斑点杂交双重鉴定实验证明了文库的特异性, 从而构建了21号染色体特异的DNA文库, 并建立了构建染色体特异DNA文库及检测其特异性的方法, 为21号染色相关遗传疾病的鉴定和研究奠定了基础。     

PCR amplification of chromosome-specific alpha satellite DNA: definition of centromeric STS markers and polymorphic analysis.

Alpha satellite DNA is a tandemly repetitive DNA family found at the centromere of every human chromosome. Chromosome-specific subsets have been isolated for over half the chromosomes and have prove useful as markers for both genetic and physical mapping. We have developed specific oligonucleotide primer sets for polymerase chain reaction (PCR) amplification of alpha satellite DNA from chromosomes 3, 7, 13/21, 17, X, and Y. For each set of primers, PCR products amplified from human genomic DNA are specific for the centromere of the target chromosome(s), as shown by somatic cell hybrid mapping and by fluorescence in situ hybridization. These six subsets represent several evolutionarily related alpha satellite subfamilies, suggesting that specific primer pairs can be designed for most or all chromosomal subsets in the genome. The PCR products from chromosome 17 directly reveal the polymorphic nature of this subset, and a new DraI polymorphism is described. The PCR products from chromosome 13 are also polymorphic, allowing in informative cases genetic analysis of this centromeric subset distinguished from the highly homologous chromosome 21 subset. These primer sets should allow placement of individual centromeres on the proposed STS map of the human genome and may be useful for somatic cell hybrid characterization and for making in situ probes. In addition, the ability to amplify chromosome-specific repetitive DNA families directly will contribute to the structural and functional analysis of these abundant classes of DNA.     

Construction and characterization of a partial library of yeast artificial chromosomes from human chromosome 21

We report a protocol for cloning large DNA fragments in yeast artificial chromosomes (YAC). A partial library has been constructed from a somatic hybrid containing chromosome 21 as the single source of human DNA. About 4.0 Mb of human DNA was recovered in 17 YAC clones. Three clones were analyzed by in situ hybridization and mapped on chromosome 21. One clone hybridized with the chromosome 21 centromeric region and may provide new insight both on the molecular structure of centromere and on the localization of Alzheimer disease gene.     

A polymorphic alpha satellite sequence specific for human chromosome 13 detected by oligonucleotide primed in situ labelling (PRINS)

The centromeric alpha satellite DNA subfamilies from chromosomes 13 and 21 are almost identical in sequence and cannot be easily distinguished by mean of probes for Southern blot or in situ hybridisation. We have used the oligonucleotide-primed in situ (PRINS) labelling technique with primers defined from the alpha satellite sequence of chromosome 13. One primer was found to label specifically the centromeric region of chromosomes 13 and allowed the detection of a polymorphism between two chromosome 13 homologues in one individual.     

14个染色体区带特异性探针池的构建

本文运用人类染色体显微切割和ＰＣＲ技术,成功地构建了１４个染色体区带特异性探针池,并通过染色体原位杂交证明它们均分别来源于相应的被切割的染色体区带。     

Isolation and characterization of DNA sequences from flow-sorted human chromosome 22 libraries

Two flow-sorted chromosome 22 libraries were used to isolate DNA sequences specific for chromosome 22. 45-phage DNAs were probed against human genomic DNA. 12 of them showed unique or low-copy character. Using digested DNA from rodent-human hybrid cell lines, 3 of the 12 recombinants were assigned unique to chromosome 22 and regionally mapped. 1 clone mapped to 22pter-q11, 1 clone to 22q12-qter and 1 clone, for which in situ hybridization was performed, to 22q13.1. 2 low-copy probes, 1 of them displaying polymorphisms in MspI and TaqI digests of individual DNAs, must have similar sequences on 22 and additional chromosomes. Furthermore, a highly repetitive DNA representing a compound locus of some hundred kilobases on chromosome 22 was isolated. These 6 probes may provide useful tools for studying the structure and function of this small chromosome involved in a relatively high number of inherited and acquired diseases.     

Rapid generation of region-specific genomic clones by chromosome microdissection: isolation of DNA from a region frequently deleted in malignant melanoma.

Malignant melanoma is frequently characterized by the deletion of the long arm of chromosome 6 (usually encompassing 6q16-q21). In an effort to saturate this region with DNA markers, microdissection and molecular cloning of DNA from banded human metaphases recent development of a novel chromosome microdissection scheme that omits microchemical manipulation of DNA. Microdissection was targeted on band 6q21. Direct PCR amplification of dissected DNA was first used as a probe in chromosomal in situ hybridization of normal metaphases to confirm the specificity of material excised for cloning. A genomic library of 20,000 clones, which is highly enriched for sequences encompassing 6q21, was then constructed. Clones from this library have been mapped against a human-rodent somatic cell hybrid mapping panel that divides chromosome 6 into seven regions, confirming the localization of probes within the target region. Direct PCR amplification of DNA excised by microdissection greatly simplifies and facilitates this chromosome band-specific cloning strategy. The isolation of microclones from this region of chromosome 6 should assist in establishing a physical map of the melanoma deletion region.     

Regional localization of DNA sequences on chromosome 21 using somatic cell hybrids.

We have used a panel of Chinese hamster X human somatic cell hybrids, each containing various portions of chromosome 21 as the only detectable human chromosome component, for regional mapping of cloned, chromosome 21-derived DNA sequences. Thirty unique and very low-repeat sequences were mapped to the short arm and three sections of the long arm. Three unique sequences map to the proximal part of the terminal band 21q22.3, and five to the distal part of this band. Some of these may represent parts of gene sequences that may be relevant to the pathogenesis of Down syndrome, as 21q22 is the area required to be present in triplicate for the full clinical picture.     

Coverage of chromosome 6 by chromosome microdissection: generation of 14 subregion-specific probes

Human chromosome 6 has been subdivided by chromosome microdissection into 14 unique regions. Following microdissection, polymerase chain reaction (PCR) amplification of dissected DNA was performed using a universal primer to generate subregion-specific probes that provided complete coverage of chromosome 6. All 16 microdissections have been regionally assigned along chromosome 6 by fluorescence in situ hybridization (FISH) using biotin-labeled dissected DNA hybridized to G-banded normal metaphase chromosomes. These probes can be used as region-specific paints to generate unique bar codes and for analysis of chromosome alterations involving chromosome 6 that are unidentifiable by conventional banding analysis.     

Isolation and comparative mapping of a human chromosome 20-specific alpha-satellite DNA clone.

We have isolated and characterized a human genomic DNA clone (PZ20, locus D20Z2) that identifies, under high-stringency hybridization conditions, an alphoid DNA subset specific for chromosome 20. The specificity was determined using fluorescence in situ hybridization. Sequence analysis confirmed our previously reported data on the great similarity between the chromosome 20 and chromosome 2 alphoid subsets. Comparative mapping of pZ20 on chimpanzee and gorilla chromosomes, also performed under high-stringency conditions, indicates that the alphoid subset has ancestral sequences on chimpanzee chromosome 11 and gorilla chromosome 19. However, no hybridization was observed to chromosomes 21 in the great apes, the homolog of human chromosome 20.     

Cloned DNA probes regionally mapped to human chromosome 21 and their use in determining the origin of nondisjunction.

A number of unique sequence recombinant DNA clones were isolated from a recombinant DNA library constructed from DNA enriched for chromosome 21 by flow sorting. Of these, five were mapped to chromosome 21 using a somatic cell hybrid. Regional mapping of these probes and of a probe previously assigned to chromosome 21, was carried out with the aid of chromosome 21 rearrangements using both chromosome sorting and a somatic cell hybrid. Three probes were shown to be located on either side of the breakpoint 21q21.2. Two of the probes were shown to identify restriction fragment length polymorphisms (RFLPs) with high rare-allele frequencies (0.46 and 0.43). A Bgl II RFLP revealed the parental origin of non-disjunction in three of ten families with Down's syndrome.     

Owl monkey gene map: evidence for a homologous human chromosome 7q region near the cystic fibrosis locus

We have demonstrated the assignments of two gene loci (COLIA2, MET) and two noncoding DNA markers (D7S13, D7S8) to owl monkey chromosome 14 (K-VI) by hybridizing DNA probes from the cystic fibrosis (CF) region of human chromosome 7q21-32 to panels of rodent-owl monkey somatic cell hybrids. The assignments are substantiated by in situ chromosome hybridization of markers COLIA2, MET, and D7S13 to the distal long arm of chromosome 14 (K-VI). These results support genomic conservation of the human CF region, at least in the higher primates.     

Chromosome mapping of the human genes encoding the MAP kinase kinase MEK1 (MAP2K1) to 15q21 and MEK2 (MAP2K2) to 7q32

Activation of the ERK mitogen-activated protein (MAP) kinase pathway has been implicated in the regulation of cell growth, differentiation and senescence. In this pathway, the MAP kinases ERK1/ERK2 are phosphorylated and activated by the dual-specificity kinases MEK1 and MEK2, which in turn are activated by serine phosphorylation by a number of MAP kinase kinase kinases. We report here the chromosomal localization of the human genes encoding the MAP kinase kinase isoforms MEK1 and MEK2. Using a combination of fluorescence in situ hybridization, somatic cell hybrid analysis, DNA sequencing and yeast artificial chromosome (YAC) clone analysis, we have mapped the MEK1 gene (MAP2K1) to chromosome 15q21. We also present evidence for the presence of a MEK1 pseudogene on chromosome 8p21. The MEK2 gene (MAP2K2) was mapped to chromosome 7q32 by fluorescence in situ hybridization and YAC clone analysis.     

Human alpha-satellite DNA specific to chromosomes 13 and 21: use for the analysis of polymorphism of acrocentric chromosomes and the origin of the additional chromosome 21 in Down's syndrome]

Chromosomal distribution of cloned human alpha-satellite DNA alpha R1-6 has been studied by in situ hybridization technique. The sequence under study has been shown to be predominantly located in the centromeric regions of chromosomes 13 and 21. Intercellular variability of labelling patterns in every person under analysis being insignificant, there exists strong individual variability of interchromosomal distribution of the satellite. This variability leads to the differences of the chromosome labelling density (i.e. the number of satellite DNA copies) both between and within chromosome pairs. The difference in the copy number between two homologues chromosomes, 13 and 21 reaches up to 5 times. No correlation between nondisjunction and the number of copies of alpha-satellite DNA was found. Analysis of individual distribution of satellite between homologues of chromosome 21 provides new possibilities for determination of the origin of extra chromosome in the patients with trisomy 21.     

Cytogenetic,FISH and DNA studies in 11 individuals from a family with two siblings with dup(21q) Down syndrome

A Spanish family has previously been described with two siblings with dup(21q) Down syndrome. The father has a normal karyotype. The mother has a microchromosome. Cytogenetic, fluorescence in situ hybridization and DNA studies have now been carried out on the family. Findings include that the mother has three different chromosome anomalies, viz. (1) a chromosome 22 with an unusual pericentromeric region that contains alphoid DNA from chromosomes 21/13 and chromosome 22, (2) an isochromosome 21p in the frequent cell line and (3) an isochromosome 21q in a rare second cell line. A possible explanation is that the mother developed from a zygote with trisomy 21 and that mitotic error in early development resulted in the formation of two cell lines with karyotypes of 47,XX,+i(21p) and 47,XX,+i(21q), respectively. The unusual chromosome 22 represents a hitherto undescribed chromosome anomaly and one possible explanation is a translocation of the short arms between chromosomes 21/13 and 22 in the ancestry of the family. The relationship between the unusual chromosome 22 and the isochromosome formation in the mother is not known. However, all three chromosome anomalies involve the alphoid DNA of chromosome 21/13, indicating that this is not a chance finding.