Analysis of human chromosome 21: correlation of physical and cytogenetic maps; gene and CpG island distributions

Viral etiology of Parkinson's disease: Focus on influenza A virus

Some clinical reports and epidemiological data suggest that a virus may play a role in the etiology of Parkinson's disease (PD). Following intracerebral injection of a neurovirululent strain of influenza A virus into mice, the virus was found to be particularly localized in neurons of the substantia nigra and hippocampus. Although efforts to detect virus particles in the brains, or antibodies in the serum or CSF of patients with PD have been generally unsuccessful, recent immunohistochemical work has revealed the presence of complement proteins and the interferon-induced MxA in association with Lewy bodies and swollen neuronal processes. Although a viral etiology for PD is not now widely accepted, we proposed such an hypothesis. Neurovirulent influenza A virus is a candidate, but some other viruses or complex infection of these viruses may be responsible for the formation of Lewy bodies and the later death of nigral neurons.

Pathways to cognitive deficits in Down syndrome

Major efforts in Down syndrome (DS) research have been directed at the identification and functional characterization of genes encoded by human chromosome 21 (HSA21). In parallel with this, tissue samples and cell lines derived from individuals with DS have been examined for abnormalities in gene expression and cellular morphology, and mouse models of DS have been characterized for abnormalities at the molecular, cellular, electrophysiological, and behavioral level. One goal of such investigations has been the identification of effective targets for pharmacotherapies that can prevent or correct the abnormalities and, by extension to human clinical trials, prevent or lessen aspects of the cognitive deficits seen in people with DS. Because it is caused by an extra copy of an entire chromosome, DS has been considered by some as too complicated a genetic perturbation to be amenable to postnatal pharmacological interventions. However, recent data from experiments with one mouse model, the Ts65Dn, have clearly demonstrated that several pharmacological interventions can indeed rescue DS-relevant learning and memory deficits. Extension of mouse data to successful human clinical trials will be aided by understanding the molecular basis of successful drug treatments, that is, how increased expression of HSA21 genes perturbs molecular mechanisms that are targeted and rescued by specific drugs. Here, we review information on HSA21 genes, their expression and their likely contributions to the DS phenotype. We then describe results of a bioinformatics effort that integrates information on genes known to cause intellectual disability when mutated, the pathways in which these genes function, and how these pathways are impacted by HSA21 encoded proteins. This pathway approach to the molecular basis of ID in DS aids in understanding why some drug therapies have been successful in the Ts65Dn and in predicting whether these same drugs are likely to be successful in treating ID in DS. These data can be used to design new experiments and interpret information for prediction of additional targets for effective drug treatments.

Inherited 14q duplication and 21q deletion: a rare adjacent-2 segregation in multiple family members

We present a family with multiple carriers of a subtle balanced translocation t(14;21)(q21.2;q21.2) and three patients with a resultant adjacent-2 malsegregation containing a +der(14)t(14;21)(q21.2;q21.2),-21 in their chromosome complement. The initial study was performed when a 2-month-old female was referred to genetics clinic for evaluation of developmental delay, growth retardation, and failure to thrive. Physical findings included prominent eyes, micrognathia, prominent and simple external ears, camptodactyly, contractures of the wrists, ankles, and hips, hypoplasia of the corpus callosum, prominent atria and occipital horns, cerebellopontine hypoplasia; and small atrial septal defect. High resolution chromosomes showed an extra band on the proximal 21q and fluorescence in situ hybridization (FISH) demonstrated only one signal for the centromere of 21. Karyotypes of the parents and grandparents revealed that the mother and maternal grandfather were carriers of a balanced translocation, and the propositus contained an unbalanced chromosome complement with partial duplication of proximal 14q and partial deletion of proximal 21q. Investigations performed on an institutionalized maternal aunt revealed identical karyotypic abnormalities as in the propositus. More recently, array comparative genomic hybridization (aCGH) on a subsequent child with multiple congenital anomalies further out in the extended family allowed for more accurate identification of the breakpoints. Our investigation includes analysis on a total of 11 family members spanning three generations. Among those investigated, there were no living members with other possible consequential unbalanced translocations or with adjacent-2 segregation resulting in -14,+der(21). Chromosome rearrangements require FISH and aCGH studies for accurate identification and elucidation of the abnormality and breakpoints.

Pulsed-field gel electrophoresis for long-range restriction mapping

This unit describes procedures for generating long-range restriction maps of genomic DNA and for analysis of large insert clones. The basic protocol details restriction digestion of agarose-embedded DNA, PFGE separation, Southern transfer, and hybridization. Support protocols describe the preparation of high-molecular-weight genomic DNA samples in agarose blocks and in agarose microbeads, respectively. Additional support protocols describe the preparation of DNA size standards from l phage and two yeast species, Saccharomyces cerevisiae and Schizosaccharomyces pombe. An alternative method of preparing S. cerevisiae size standards using lithium dodecyl sulfate (LiDS) solubilization is provided. The final protocol details the preparation of BAC DNA suitable for digestion, mapping, and sequencing.

Antiviral actions of interferons

Tremendous progress has been made in understanding the molecular basis of the antiviral actions of interferons (IFNs), as well as strategies evolved by viruses to antagonize the actions of IFNs. Furthermore, advances made while elucidating the IFN system have contributed significantly to our understanding in multiple areas of virology and molecular cell biology, ranging from pathways of signal transduction to the biochemical mechanisms of transcriptional and translational control to the molecular basis of viral pathogenesis. IFNs are approved therapeutics and have moved from the basic research laboratory to the clinic. Among the IFN-induced proteins important in the antiviral actions of IFNs are the RNA-dependent protein kinase (PKR), the 2',5'-oligoadenylate synthetase (OAS) and RNase L, and the Mx protein GTPases. Double-stranded RNA plays a central role in modulating protein phosphorylation and RNA degradation catalyzed by the IFN-inducible PKR kinase and the 2'-5'-oligoadenylate-dependent RNase L, respectively, and also in RNA editing by the IFN-inducible RNA-specific adenosine deaminase (ADAR1). IFN also induces a form of inducible nitric oxide synthase (iNOS2) and the major histocompatibility complex class I and II proteins, all of which play important roles in immune response to infections. Several additional genes whose expression profiles are altered in response to IFN treatment and virus infection have been identified by microarray analyses. The availability of cDNA and genomic clones for many of the components of the IFN system, including IFN-alpha, IFN-beta, and IFN-gamma, their receptors, Jak and Stat and IRF signal transduction components, and proteins such as PKR, 2',5'-OAS, Mx, and ADAR, whose expression is regulated by IFNs, has permitted the generation of mutant proteins, cells that overexpress different forms of the proteins, and animals in which their expression has been disrupted by targeted gene disruption. The use of these IFN system reagents, both in cell culture and in whole animals, continues to provide important contributions to our understanding of the virus-host interaction and cellular antiviral response.

USP25, a novel gene encoding a deubiquitinating enzyme, is located in the gene-poor region 21q11.2

We have identified a new gene, USP25, spanning over 150 kb at 21q11. 2, one of the lowest gene-density regions of the human genome. USP25 is made up of 25 exons and encodes a 1087-aa protein. Database comparisons reveal high homology with members of the ubiquitin protease family (UBP). Basal expression was observed in all human tissues tested, and two main transcripts were identified. The homologous murine gene has also been characterized. In situ hybridization in mouse embryonic brains showed a clear correlation of expression with proliferative neuroepithelial cells and postmitotic neurons. Moreover, high expression was observed in adult mouse testis. UBPs belong to a complex family of deubiquitinating enzymes that specifically cleave ubiquitin conjugates on a great variety of substrates. These enzymes have an essential role in protein degradation via the 26S proteasome and thus regulate many cellular pathways. An increase in USP25 gene dosage in Down syndrome patients could seriously disturb the balance between ubiquitinated and deubiquitinated substrates.

Densely methylated sequences that are preferentially localized at telomere-proximal regions of human chromosomes

We have constructed a library of densely methylated DNA sequences from human blood DNA by selecting fragments with a high affinity for a methyl-CpG binding domain (MBD) column. PCR analysis of the library confirmed the presence of known densely methylated CpG island sequences. Analysis of random clones, however, showed that the library was dominated by sequences whose G+C content and CpG frequency were intermediate between those of bulk genomic DNA and bona fide CpG islands. When human chromosomes were probed with the library by fluorescent in situ hybridisation (FISH), the predominant sites of labelling were at terminal regions of many chromosomes, approximately corresponding to T-bands. Analysis of the methylation status of random clones indicated that all were heavily methylated at CpGs in blood DNA, but many were under-methylated in sperm DNA. Lack of methylation in germ cells may reduce CpG depletion at some sub-terminal sequences and result in a high density of methyl-CpG when these regions become methylated in somatic cells.

Misrejoining of DNA double-strand breaks in primary and transformed human and rodent cells: a comparison between the HPRT region and other genomic locations

Many studies of radiation response and mutagenesis have been carried out with transformed human or rodent cell lines. To study whether the transfer of results between different cellular systems is justified with regard to the repair of radiation-induced DNA double-strand breaks (DSBs), two assays that measure the joining of correct DSB ends and total rejoining in specific regions of the genome were applied to primary and cancer-derived human cells and a Chinese hamster cell line. The experimental procedure involves Southern hybridization of pulsed-field gel electrophoresis blots and quantitative analysis of specific restriction fragments detected by a single-copy probe. The yield of X-ray-induced DSBs was comparable in all cell lines analyzed, amounting to about 1 x 10(-2) breaks/Mbp/Gy. For joining correct DSB ends following an 80 Gy X-ray exposure all cell lines showed similar kinetics and the same final level of correctly rejoined breaks of about 50%. Analysis of all rejoining events revealed a considerable fraction of unrejoined DSBs (15-20%) after 24 h repair incubation in the tumor cell line, 5-10% unrejoined breaks in CHO cells and complete DSB rejoining in primary human fibroblasts. To study intragenomic heterogeneity of DSB repair, we analyzed the joining of correct and incorrect break ends in regions of different gene density and activity in human cells. A comparison of the region Xq26 spanning the hypoxanthine guanine phosphoribosyl transferase locus with the region 21q21 revealed identical characteristics for the induction and repair of DSBs, suggesting that there are no large variations between Giemsa-light and Giemsa-dark chromosomal bands.

Structures, sequence characteristics, and synteny relationships of the transcription factor E4TF1, the splicing factor U2AF35 and the cystathionine beta synthetase genes from Fugu rubripes

A cosmid containing the beta-amyloid precursor protein (APP) from Fugu rubripes has been completely sequenced. In addition to APP, the cosmid contains the E4TF1-60 transcription factor, the U2AF35 pre-mRNA splicing factor, and the cystathionine beta synthetase (CBS) gene. The human homologues of all four genes map to human chromosome 21 but are not clustered; APP and E4TF1-60 map within 21q21, whereas U2AF35 and CBS map approximately 20Mb distal in 21q22. 3. The protein sequences of the Fugu genes vary in their overall level of similarity to their mammalian homologues, but several regions of functional importance are almost identical. As expected, the intron/exon structures of the homologous pairs of genes are highly conserved, but there are significant differences in the compaction ratios. The introns of APP and E4TF1-60 are 49- and 24-fold smaller in Fugu than in human, and the intergenic distance is compressed at least 100-fold. For U2AF35 and CBS, the introns are compressed only five- to eightfold. These size differences were compared with those for a number of previously reported Fugu genes; in general, levels of compaction of Fugu genes are consistent with the isochore locations of the human homologues.

Linkage analysis of candidate genes in autoimmune thyroid disease. II. Selected gender-related genes and the X-chromosome. International Consortium for the Genetics of Autoimmune Thyroid Disease

Hashimoto's thyroiditis (HT) and Graves' disease (GD) are autoimmune thyroid diseases (AITD) in which multiple genetic factors are suspected to play an important role. Until now, only a few minor risk factors for these diseases have been identified. Susceptibility seems to be stronger in women, pointing toward a possible role for genes related to sex steroid action or mechanisms related to genes on the X-chromosome. We have studied a total of 45 multiplex families, each containing at least 2 members affected with either GD (55 patients) or HT (72 patients), and used linkage analysis to target as candidate susceptibility loci genes involved in estrogen activity, such as the estrogen receptor alpha and beta and the aromatase genes. We then screened the entire X-chromosome using a set of polymorphic microsatellite markers spanning the whole chromosome. We found a region of the X-chromosome (Xq21.33-22) giving positive logarithm of odds (LOD) scores and then reanalyzed this area with dense markers in a multipoint analysis. Our results excluded linkage to the estrogen receptor alpha and aromatase genes when either the patients with GD only, those with HT only, or those with any AITD were considered as affected. Linkage to the estrogen receptor beta could not be totally ruled out, partly due to incomplete mapping information for the gene itself at this time. The X-chromosome data revealed consistently positive LOD scores (maximum of 1.88 for marker DXS8020 and GD patients) when either definition of affectedness was considered. Analysis of the family data using a multipoint analysis with eight closely linked markers generated LOD scores suggestive of linkage to GD in a chromosomal area (Xq21.33-22) extending for about 6 cM and encompassing four markers. The maximum LOD score (2.5) occurred at DXS8020. In conclusion, we ruled out a major role for estrogen receptor alpha and the aromatase genes in the genetic predisposition to AITD. Estrogen receptor beta remains a candidate locus. We found a locus on Xq21.33-22 linked to GD that may help to explain the female predisposition to GD. Confirmation of these data in HT may require study of an extended number of families because of possible heterogeneity.

Two sequence-ready contigs spanning the two copies of a 200-kb duplication on human 21q: partial sequence and polymorphisms

Physical mapping across a duplication can be a tour de force if the region is larger than the size of a bacterial clone. This was the case of the 170- to 275-kb duplication present on the long arm of chromosome 21 in normal human at 21q11.1 (proximal region) and at 21q22.1 (distal region), which we described previously. We have constructed sequence-ready contigs of the two copies of the duplication of which all the clones are genuine representatives of one copy or the other. This required the identification of four duplicon polymorphisms that are copy-specific and nonallelic variations in the sequence of the STSs. Thirteen STSs were mapped inside the duplicated region and 5 outside but close to the boundaries. Among these STSs 10 were end clones from YACs, PACs, or cosmids, and the average interval between two markers in the duplicated region was 16 kb. Eight PACs and cosmids showing minimal overlaps were selected in both copies of the duplication. Comparative sequence analysis along the duplication showed three single-basepair changes between the two copies over 659 bp sequenced (4 STSs), suggesting that the duplication is recent (less than 4 mya). Two CpG islands were located in the duplication, but no genes were identified after a 36-kb cosmid from the proximal copy of the duplication was sequenced. The homology of this chromosome 21 duplicated region with the pericentromeric regions of chromosomes 13, 2, and 18 suggests that the mechanism involved is probably similar to pericentromeric-directed mechanisms described in interchromosomal duplications.

Bacterial contig map of the 21q11 region associated with Alzheimer's disease and abnormal myelopoiesis in Down syndrome

We present a high-resolution bacterial contig map of 3.4 Mb of genomic DNA in human chromosome 21q11-q21, encompassing the region of elevated disomic homozygosity in Down Syndrome-associated abnormal myelopoiesis and leukemia, as well as the markers, which has shown a strong association with Alzheimer's Disease that has never been explained. The map contains 89 overlapping PACs, BACs, or cosmids in three contigs (850, 850, and 1500 kb) with two gaps (one of 140-210 kb and the second <5 kb). To date, eight transcribed sequences derived by cDNA selection, exon trapping, and/or global EST sequencing have been positioned onto the map, and the only two genes so far mapped to this cytogenetic region, STCH and RIP140 have been precisely localized. This work converts a further 10% of chromosome 21q into a high-resolution bacterial contig map, which will be the physical basis for the long-range sequencing of this region. The map will also enable positional derivation of new transcribed sequences, as well as new polymorphic probes, that will help in elucidation of the role the genes in this region may play in abnormal myelopoiesis and leukemia associated with trisomy 21 and Alzheimer's Disease.

Clonability and gene distribution on human chromosome 21: reflections of junk DNA content?

Data from transcriptional mapping of human chromosome 21 have been compiled from a number of sources. Regardless of the gene identification technique used, a consistent picture has developed: the centromere proximal half of 21q, which contains 50% of the DNA (20 Mb), harbors only 10% of the expressed sequences. Because of the variety of gene isolation techniques used, this result is unlikely to arise simply from methodological artefacts, biases in clonability or tissue specificity of expression. This region is known to be AT-rich and to contain APP, the largest gene (spanning 300 kb) currently analyzed on 21q. Interesting preliminary data from analysis of the Fugu rubripes homolog of APP has shown an unusually high, 50-fold, compaction of intron size, raising the intriguing possibility that >90% of the DNA in the human gene may be functionless. Thus, data from a variety of approaches suggest that a large part of 21q very likely has neither coding capacity nor associated regulatory function. By these criteria, it is a good candidate for a repository of junk DNA.

Genomic structure of the human GT334 (EHOC-1) gene mapping to 21q22.3

Several inherited diseases have been mapped to the distal tip of human chromosome 21. In our recent efforts to clone candidate genes for some of these disorders, we have assembled a cosmid and BAC contig spanning 770 kb. We have identified expressed sequences from this contig by means of a cDNA hybrid selection scheme. We present here the isolation, cDNA sequence, genomic organization, and polymorphisms analysis of one such expressed sequence, GT334, which had been identified independently and designated EHOC-1. GT334 is split into 23 exons, and spans an estimated 95 kb of genomic DNA. A pseudogene of the histone H2AZ gene has been identified, and maps within the third intron. We have identified an ORF potentially encoding a protein 1259 amino acids in length, longer than that described in the EHOC-1 gene. The GT334 gene was screened for single base pair changes using single-strand conformation polymorphism (SSCP) analysis and we have identified seven sequence variations within this gene. These polymorphisms can be used as markers in the genetic mapping of other diseases localized to this region.

A type I interferon signaling factor, ISF21, encoded on chromosome 21 is distinct from receptor components and their down-regulation and Is necessary for transcriptional activation of interferon-regulated genes

The type I interferons (IFNs) are a family of cytokines, comprising at least 17 subtypes, which exert pleiotropic actions by interaction with a multi-component cell surface receptor and at least one well characterized signal transduction pathway involving JAK/STAT (Janus kinase/signal transducer and activator of transcription) proteins. In a previous report, we showed that a signaling factor, encoded by a gene located on the distal portion of chromosome 21, distinct from the IFNAR-1 receptor, was necessary for 2'-5'-oligoadenylate synthetase activity and antiviral responses, but not for high affinity ligand binding. In the present studies using hybrid Chinese hamster ovary cell lines containing portions of human chromosome 21, we show that the type I IFN signaling molecule, designated herein as ISF21, is distinct from the second receptor component, IFNAR-2, which is expressed in signaling and non-signaling cell lines. The location of the gene encoding ISF21 is narrowed to a region between the 10;21 and the r21 breakpoints, importantly eliminating the Mx gene located at 21q22.3 (the product of which is involved in IFN-induced antiviral responses) as a candidate for the signaling factor. To characterize the action of this factor in the type I IFN signaling pathway, we show that it acts independently of receptor down-regulation following ligand binding, both of which occur equally in the presence or absence of the factor. In addition, we demonstrate that ISF21 is necessary for transcriptional activation of 2'-5'-oligoadenylate synthetase, 6-16, and guanylate-binding protein gene promoter reporter constructs, which are mediated by several signaling pathways. ISF21 represents a novel factor as the localization to chromosome 21, and the data presented in this study exclude any of the known type I IFN signal-transducing molecules.

A compositional map of the cen-q21 region of human chromosome 21

A compositional map of the centromere and of the subcentromeric region of the long arm of human chromosome 21 was established by determining the GC levels (GC is the molar fraction of guanine+cytosine in DNA) of 11 YACs (yeast artificial chromosomes) covering this 13-14 Mb region which extends from the alpha-satellite sequences of the C(entromeric) band q11.1, through R(everse) band q11.2, to the proximal part of G(iemsa) band q21. The entire region is made up of GC-poor, or L, isochores with only one GC-rich H1 isochore, at least 2 Mb in size, located in band q21. The almost identical GC levels of the centromeric alpha-satellite repeats (38.5%), of R band q11.2 (39%), and of G bands (38-40%) provide a direct demonstration that base composition cannot be the only cause of the cytogenetic differences between C, G, and the majority of R bands, namely the H3- R bands (which do not contain the GC-richest H3 isochores). The results obtained also show that isochores may be as long as 6 Mb, at least in the GC-poor regions of the genome, and support previous observations suggesting that YACs from isochore borders are unstable and/or difficult to clone. Genes and CpG islands are very rare in the GC-poor region investigated, as expected from the fact that their concentration is proportional to the GC levels of the isochores in which they are contained.

A complete YAC contig and cosmid interval map covering the entirety of human Xq21.33 to Xq22.3 from DXS3 to DXS287

We have produced a physical map that covers the entirety of Xq21.33 to Xq22.3, from DXS3 to DXS287, approximately 15-17 Mb of the proximal long arm of the human X chromosome. This region has already been shown to contain a number of genes involved in genetic disorders, some of which have yet to be cloned. The physical map consists of a contig of 420 yeast artificial chromosome (YAC) clones ordered with respect to 142 DNA markers, approximately one probe every 110 kb. Forty-three YACs from across the contig have been used to isolate 2019 cosmids that have been mapped into 87 intervals, and 667 of these clones are positive for at least 1 single-copy marker. These YACs and cosmids have been used to confirm data from other published contigs that map to the region. The physical map described here constitutes the first step toward a complete transcriptional map of the region.

Gene identification and DNA sequence analysis in the GC-poor 20 megabase region of human chromosome 21

In contrast to the distal half of the long arm of chromosome 21, the proximal half of approximately 20 megabases of DNA, including 21q11-21 bands, is low in GC content, CpG islands, and identified genes. Despite intensive searches, very few genes and cDNAs have been found in this region. Since the 21q11-21 region is associated with certain Down syndrome pathologies like mental retardation, the identification of relevant genes in this region is important. We used a different approach by constructing microdissection libraries specifically for this region and isolating unique sequence microclones for detailed molecular analysis. We found that this region is enriched with middle and low-copy repetitive sequences, and is also heavily methylated. By sequencing and homology analysis, we identified a significant number of genes/cDNAs, most of which appear to belong to gene families. In addition, we used unique sequence microclones in direct screening of cDNA libraries and isolated 12 cDNAs for this region. Thus, although the 21q11-21 region is gene poor, it is not completely devoid of genes/cDNAs. The presence of high proportions of middle and low-copy repetitive sequences in this region may have evolutionary significance in the genome organization and function of this region. Since 21q11-21 is heavily methylated, the expression of genes in this region may be regulated by a delicate balance of methylation and demethylation, and the presence of an additional copy of chromosome 21 may seriously disturb this balance and cause specific Down syndrome anomalies including mental retardation.

BAC and PAC contigs covering 3.5 Mb of the Down syndrome congenital heart disease region between D21S55 and MX1 on chromosome 21

Chromosome 21 is a model for the study of human chromosomal aneuploidy, and the construction of its physical and transcriptional maps is a necessary step in understanding the molecular basis of aneuploidy-dependent phenotypes. To identify the gene(s) responsible for Down syndrome congenital heart disease (DS-CHD), we constructed a physical map of the D21S55 to MX1 region. A bacterial artificial chromosome (BAC) library was screened using several YACs spanning the interval, and a P1-derived artificial chromosome (PAC) library was screened using radiolabeled STS PCR products and whole BACs in gap-filling initiatives. FISH confirmed the location of all BAC and PAC clones to 21q22.2-q22.3. Overlaps were established using clone-to-clone Southerns and 24 new STSs, generated from the direct sequencing of BAC and PAC ends, along with 35 preexisting STSs. Approximately 3.5 Mb of the 4- to 5-Mb D21S55 to MX1 interval is covered in 85 BACs and 24 PACs, representing fourfold coverage within the contigs. These BAC and PAC contigs are valuable reagents for isolating the genes for DS-CHD.

Migration patterns in pulsed-field electrophoresis of DNA restriction fragments from log-phase mammalian cells after irradiation and incubation for repair

An assay system was developed to detect changes of restriction fragment profiles obtained after pulsed-field gel electrophoresis (PFGE) for DNA from mammalian cells that were irradiated and incubated for repair. DNA was prepared from irradiated log-phase human melanoma cells (MRI 221) after incubation for repair (6 h) and was digested with the rare-cutting restriction enzyme NotI (RE) prior to PFGE separation. DNA-fragment size distributions were compared to the respective PFGE profiles from unirradiated controls. After doses of 5 and 10 Gy (plus a 6-h incubation for repair), the relative amount of DNA retained in the plug during PFGE was increased. For higher doses (30 and 60 Gy), this phenomenon was superimposed by the residual fragmentation (25-30% of the initial breakage of 0.42 dsb/100 Mbp/Gy). Since irradiated cells accumulated in S phase during incubation for repair, a correction for the reduced electrophoretic migration of DNA from S-phase cells was necessary, and a 0.5% increase in DNA retention per 1% S-phase increment was found. However, the % retention for the 5 Gy plus repair sample was significantly higher than for the S-phase adjusted control (p < 0.01). Radiation induced DNA-protein crosslinks cannot account for the observed phenomenon because of the extensive proteolysis in DNA preparation, and also a loss of restriction enzyme recognition sites appear to be an unlikely explanation from simple quantitative considerations. Based on the recent observation of misrejoining during dsb repair, it is proposed that the incorrect joining of DNA ends also causes a more random distribution of replicating DNA in restriction fragments derived from cells in S phase after incubation for repair. This process would necessarily increase the proportion of DNA unable to migrate in PFGE.

Isolation and genomic structure of a human homolog of the yeast periodic tryptophan protein 2 (PWP2) gene mapping to 21q22.3

As part of efforts to identify candidate genes for disease mapping to the 21q22.3 region, we have assembled a 770-kb cosmid and BAC contig containing eight tightly linked markers. These cosmids and BACs were restriction mapped using eight rare cutting enzymes, with the goal of identifying CpG-rich islands. One such island was identified by the clustering of NotI, EagI, SstII, and BssHII sites, and corresponded to the NotI linking clone LJ104 described previously. A 7.6-kb HindIII fragment containing this CpG-rich island was subcloned and partially sequenced. A homology search using the sequence obtained from either side of the NotI site identified an expressed sequence tag with homology to the yeast periodic tryptophan protein 2 (PWP2). Several cDNAs corresponding to the human PWP2 gene were identified and partially sequenced. Northern blot analysis revealed a 3.3-kb transcript that was well expressed in all tissues tested. A cDNA consensus of 3157 bp was obtained, and an open reading frame potentially encoding 919 amino acid residues was identified. The predicted protein shows 42% identity and 57% similarity at the amino acid level to the yeast PWP2 protein, which is a member of the WD-repeat containing superfamily, and potentially encodes a G-protein beta subunit. The PWP2 gene is split into 21 exons, ranging in size from 53 to 516 bp, and spans an estimated 25 kb. The gene is transcribed in a 21cen-->21qter direction, with its 5' end mapping approximately 195 kb proximal to the 5' end of the phosphofructokinase-liver isoform gene. Four single base-pair polymorphisms were identified using single-stranded conformation polymorphism analysis. Possible functions of the protein based on homology to other members of the WD-repeat-containing family are discussed.

Cartographic study: breakpoints in 1574 families carrying human reciprocal translocations

Reciprocal translocations (rcp) are among the most common constitutional chromosomal aberrations in man. Using a European database of 1574 families carrying autosomal rcp, a cartographic study was done on the breakpoints involved. The breakpoints are non-randomly distributed along the different chromosomes, indicating "hot spots". Breakpoints of rcp that result in descendants that are unbalanced chromosomally at birth are more frequent in a distal position on chromosomal arms, and 65% of them are localised in R-bands. Among the R-bands, bands rich in GC islands and poor in Alu repetitive sequences are more frequently the site of breakpoints, as well as bands that include a fragile site. This result suggests that the variation in degree of methylation in GC islands could be involved in chromosomal breakage and hence in chromosomal rearrangements. The heterogeneity of the human chromosomal structure has been demonstrable by metaphase banding techniques since 1970. In contrast to G-bands, R-bands are sites of high gene concentration (Korenberg et al. 1978), are relatively rich in cytosine plus guanine (GC), and in Alu repetitive DNA sequences (Korenberg and Rykowski 1988). More recently Holmquist (1992) has proposed four types of R-bands, depending on their relative richness in GC and Alu DNA sequences. R-bands rich in GC correspond almost exactly to T-bands (Dutrillaux 1977). They contain 65% of all genes while they represent only 15% of the genome (Holmquist 1992). The aim of this study is to analyse the distribution of the breakpoints along chromosomes from a European database of autosomal rcp in order to relate it to the specificity of different chromosomal regions.

A long-range physical map of human chromosome 21q22.1 band from the YAC continuum

The human Chromosome (Chr) 21q22.1 region contains several genes for cytokines and neurotransmitters and the gene for superoxide dismutase (mutant forms of which can cause familial amyotrophic lateral sclerosis). A region of approximately 5.8 Mb encompassing D21S82 and the glycinamide ribonucleotide transformylase (GART) loci was covered by overlapping YAC clones, which were contiguously ordered by clone walking with sequence-tagged site (STSs). A total of 76 markers, including 29 YAC end-specific STSs, were unambiguously ordered in this 5.8-Mb region, and the average interval between markers was 76 kb. Restriction maps of the YAC clones with rare-cutting enzymes were simultaneously prepared, and the restriction sites were aligned to obtain a consensus restriction map of the proximal region of the 21q22.1 band. The restriction map made from 44 overlapping YACs contains 54 physically assigned STSs. By integrating the consensus map of the adjacent 1.8-Mb region, we obtained a fine physical map spanning 6.5 Mb of human Chr 21q22.1. This map contains 24 precisely positioned end-specific STSs and 12 NotI-linking markers. More than 39 potential CpG islands were identified in this region and were found to be unevenly distributed. This physical map and the YACs should be useful as a reference map and as a resource for further structural analysis of the Giemsa-negative band (R-band) of Chr 21q22.1.

SINE and LINE within human centromeres

A number of the Alu and L1 elements present within the centromeric regions of the human chromosomes have been analyzed by polymerase chain reaction amplification. The oligonucleotide primers were homologous to the 3' end consensus sequences of either Alu or L1 in conjunction with an oligonucleotide primer homologous to alphoid sequences specific to different chromosomes. This allowed one to detect an unusual number of Alu and L1 polymorphisms at different loci. It is proposed that this results from molecular rearrangements which occur within the alpha-satellite DNA in which they are embedded (Marçais et al. J. Mol. Evol. 33:42-48, 1991) and not because the centromeric regions are targets for new insertions of such elements. The same analyses were made on cosmids and YACs originating from the centromeric region of chromosome 21 as well as on a collection of somatic hybrids containing chromosome 21 centromere as unique common human genetic material. The results were consistent with the above hypothesis.

1.8-megabases fine physical map encompassing IFNAR and AML1 loci on human chromosome 21q22.1

A long-range restriction map of the 1.8-megabases (mb) region encompassing the area between the interferon-alpha receptor and the acute myelogenous leukemia loci on human chromosome 21q22.1 was constructed after analysis of both the contiguous yeast artificial chromosome (YAC) clones and genomic DNA. Analysis of pulsed-field gel electrophoresis of lymphoblastoid DNA digested with three rare-cutting enzymes, Not I, Mlu I, and Nru I, revealed the positions of 17 markers on each restriction map. The 1.8-mb YAC contig that covers this region was obtained through YAC walking mediated by sequence-tagged sites (STSs), with 29 STSs including 12 newly generated YAC end-specific STSs. The consensus restriction map from 15 overlapping YACs and the positioning of the STS markers on each clone allowed 24 markers including 4 Not I-linking STSs to be ordered and mapped physically. Comparison of the maps revealed that the proximal region contains more unmethylated CpG islands than the distal region, which suggests that many expressed genes are in the proximal region. This fine consensus physical map will be informative and useful for construction of contigs of cosmid, P1, or BAC clones for further large-scale sequencing in this gene-rich region.

Molecular analysis and breakpoint definition of a set of human chromosome 21 somatic cell hybrids

Rodent-human somatic cell hybrids containing single human chromosomes or chromosome fragments are extremely valuable in physical mapping, marker analysis, and disease mapping. Chromosome 21 has been extensively studied in this fashion, and a single set of hybrids has been utilized in mapping the majority of chromosome 21 markers. The utility of a set of hybrids depends upon the definition of the human chromosome content. Recently, Chumakov and coworkers (1) utilized 198 chromosome 21 markers in the preliminary analysis of YACs spanning chromosome 21q. We have used these same markers to evaluate the STS content of a set of 27 chromosome 21 somatic cell hybrids, resulting in the description of the breakpoints at the molecular level, as well as the definition of 35 "bins. " The detailed molecular definition of chromosome 21 content of the hybrids, in combination with the further analysis of chromosome 21 YACs (2), has resulted in the most detailed picture of chromosome 21 to date.

YAC analysis and minimal tiling path construction for chromosome 21q

We have undertaken a detailed analysis of several hundred YACs from widely available YAC libraries which map to human chromosome 21 with the goal of improving the physical map of chromosome 21 and determining the feasibility of producing a minimal tiling path of well characterized, stable, non-chimeric YACs spanning the long arm of the chromosome (21q). We report information on over 500 YACs known to contain STS from 21q including information on size, stability, chimerism, marker content, and NotI restriction sites. YACs derive from the CEPH and St. Louis YAC libraries, and STSs include the set of 198 markers originally used do assemble a YAC contig of 21q, as well as additional anonymous probes and gene markers. This information has assisted in refinements of STS order, has defined a region of general instability in 2lq22.3, has identified an increased number of NotI restriction sites, and has defined cryptic gaps, particularly in 2lq2l, for which few or no markers are available. These results have allowed us to develop and assess a minimal tiling path of overlapping YACs consisting of 59 YACs (and two PI clones), largely non chimeric, stable, and of verified STS content. They total 30 mb of non-overlapping DNA, and contain all chromosome 21 specific STSs originally used to define the 810 YAC 21q YAC contig. When integrated with the analysis of a somatic cell hybrid mapping panel of chromosome 21 reported in the accompanying manuscript, a greatly enhanced understanding of the physical map of chromosome 21 is obtained.

Mutant U5A cells are complemented by an interferon-alpha beta receptor subunit generated by alternative processing of a new member of a cytokine receptor gene cluster

The cellular receptor for the alpha/beta interferons contains at least two components that interact with interferon. The ifnar1 component is well characterized and a putative ifnar2 cDNA has recently been identified. We have cloned the gene for ifnar2 and show that it produces four different transcripts encoding three different polypeptides that are generated by exon skipping, alternative splicing and differential use of polyadenylation sites. One polypeptide is likely to be secreted and two are transmembrane proteins with identical extracellular and transmembrane domains but divergent cytoplasmic tails of 67 and 251 amino acids. A mutant cell line U5A, completely defective in IFN-alpha beta binding and response, has been isolated and characterized. Expression in U5A cells of the polypeptide with the long cytoplasmic domain reconstitutes a functional receptor that restores normal interferon binding, activation of the JAK/STAT signal transduction pathway, interferon-inducible gene expression and antiviral response. The IFNAR2 gene maps at 0.5 kb from the CRFB4 gene, establishing that together IFNAR2, CRFB4, IFNAR1 and AF1 form a cluster of class II cytokine receptor genes on human chromosome 21.

Interferons, Mx genes, and resistance to influenza virus

Human influenza is primarily an infection of the upper respiratory tract and central airways. The interferon (IFN) system appears to have a role in limiting viral spread and initiating recovery before the development of T-cell and B-cell responses in primary infection. All cellular responses to IFNs result from interaction with cell surface receptors that trigger the expression of a number of cellular genes. Among the IFN-inducible gene products, the Mx proteins have attracted much attention because they have potential activity against influenza virus and possibly against other viruses. Mx proteins are guanosine triphosphate (GTP)-binding proteins with intrinsic GTPase activity. They seem to act indirectly against viruses by modifying cellular functions needed along the viral replication pathway. In mice the Mx1 protein has been shown to be necessary and sufficient to protect against influenza virus infection because the resistance does not require a functioning immune system. In humans the MxA protein has antiviral activities against influenza viruses. The MxA protein is encoded on the distal part of the long arm of chromosome 21 together with several other proteins implicated in the IFN system. Patients with Down's syndrome (trisomy 21) have an increased expression of MxA protein, and their cells display an increased sensitivity to IFNs in vitro because of gene dosage effects. These patients, however, are more susceptible to upper respiratory infection than normal individuals. This susceptibility has been related to deficiencies in the immune system. Therefore, induction of MxA in man does not sem sufficient to prevent influenza spreading, and, in contrast to the murine Mx system, a functioning immune system is necessary for protection.

Further observations on MxA-positive Lewy bodies in Parkinson's disease brain tissues

MxA protein, one of the GTPases, is induced in the cytoplasm by interferons and confers a high degree of resistance to some viruses. We recently reported that in cases of Parkinson's disease (PD), Lewy bodies (LBs) in the substantia nigra (SN) were positive for MxA. This study aimed to provide more detailed data on MxA-positive structures in the SN in PD brain tissues. Swellings of neuronal processes, as well as LBs, were positive for MxA. Immuno-electron microscopy revealed that reaction products corresponding to MxA proteins localized in self-aggregations similar to those reported for Mx1 protein in mouse tissues. These results show that MxA may play a role in the formation of LBs and swellings of neuronal processes.

Molecular mapping of 21 features associated with partial monosomy 21: involvement of the APP-SOD1 region

We compared the phenotypes, karyotypes, and molecular data for six cases of partial monosomy 21. Regions of chromosome 21, the deletion of which corresponds to particular features of monosomy 21, were thereby defined. Five such regions were identified for 21 features. Ten of the features could be assigned to the region flanked by genes APP and SOD1: six facial features, transverse palmar crease, arthrogryposis-like symptoms, hypertonia, and contribution to mental retardation. This region, covering the interface of bands 21q21-21q22.1, is 4.7-6.4 Mb long and contains the gene encoding the glutamate receptor subunit GluR5 (GRIK1).

Characterisation of three microsatellite polymorphisms (D21S1262, D21S1419 and D21S1421) from band 21q22.1

We have isolated three clones, containing highly polymorphic CA-repeat sequences, from a human chromosome 21 phage library (LA21NS01). These clones have been localised to band q22.1 by using a chromosome 21 somatic cell hybrid panel. D21S1262 is located between breakpoints 6918-8a1 and 3x2S, and D21S1419 and D21S1421 are localised between breakpoints JC6-A and MRC2G. Their observed heterozygosities range between 0.75 and 0.85 as shown by unrelated reference parents from the Centre d'Etude du Polymorphisme Humain. These highly polymorphic markers should be useful for improving the analysis of this region of chromosome 21, which contains important genes such as SOD1, GART and IFNAR.

Human ribosomal RNA gene cluster: identification of the proximal end containing a novel tandem repeat sequence

Human ribosomal RNA genes (rDNA) are arranged as tandem repeat clusters on the short arms of five pairs of acrocentric chromosomes. We have demonstrated that a majority of the rDNA clusters are detected as 3-Mb DNA fragments when released from human genomic DNA by EcoRV digestion. This indicated the absence of the EcoRV restriction site within the rDNA clusters. We then screened for rDNA-positive cosmid clones using a chromosome 22-specific cosmid library that was constructed from MboI partial digests of the flow-sorted chromosomes. Three hundred twenty rDNA-positive clones negative for the previously reported distal flanking sequence (pACR1) were chosen and subjected to EcoRV digestion. Seven clones susceptible to EcoRV were further characterized as candidate clones that might have been derived from the junctions of the 3-Mb rDNA cluster. We identified one clone containing part of the rDNA unit sequence and a novel flanking sequence. Detailed analysis of this unique clone revealed that the coding region of the last rRNA gene located at the proximal end of the cluster is interrupted with a novel sequence of approximately 147 bp that is tandemly repeated and is connected with an intervening 68-bp unique sequence. This junction sequence was readily amplified from chromosomes 21 and 15 as well as 22 using the polymerase chain reaction. Fluorescence in situ hybridization further indicated that the approximately 147-bp sequence repeat is commonly distributed among all the acrocentric short arms.

Three distinct loci on human chromosome 21 contribute to interferon-alpha/beta responsiveness

The species specificity of interferons (IFNs) depends on restricted recognition of these ligands by multisubunit cell surface receptors. Expression of the human receptor subunit IFNAR in mouse cells conferred sensitivity only to one subtype of human IFN, IFN-alpha B. Other genes on human chromosome 21 were required for responses to other subtypes of type I IFN. In contrast, IFNAR expression in hamster cells did not confer sensitivity to any human IFN tested, including IFN-alpha B. Using human-hamster somatic cell hybrids, we mapped the Ifnabr gene, encoding a ligand-binding subunit of the IFN-alpha/beta (type I) receptor, to human chromosome 21. Ifnabr colocalized with Ifnar to the distal region of q22.1. The presence of a chromosomal fragment encoding IFNABR and IFNAR was also not sufficient to confer sensitivity to human IFN. In contrast, hybrids carrying in addition the region 21q22.2 showed a full response to human IFN-alpha B, suggesting that a gene located in this region encodes a third factor required for type I IFN receptor activity.

Identification of two highly polymorphic CA-repeats (D21S1224 and D21S1261) on human chromosome 21q22.3

Two highly polymorphic CA-repeat microsatellites (D21S1224 and D21S1261) are reported. The clones containing these CA-repeats (ABM-C60 and ABM-C29) have been isolated from a human chromosome-21-specific library (LA21NS01) and have been localised to the q22.3 band using a specific chromosome 21 somatic cell hybrid panel. Both polymorphisms showed heterozygosities of 0.83 in the unrelated reference parents from the Centre d'Etude du Polymorphisme Humain. These new markers should improve the map of the 21q22.3 region, which is believed to contain a large number of genes.

Cloning of breakpoints in 3q21 associated with hematologic malignancy

Rearrangements of band 3q21 have been well documented in leukemia. To analyze the region involved, we have isolated a normal genomic P1 clone that spans the 3q21 breakpoints derived from two leukemia patients carrying t(3;3)(q21;q26). Both breakpoints are contained within a 50-kb NotI restriction fragment, but are not identical. They are separated by 9-11 kb and may disrupt genes associated with either the proximal or distal NotI sites. We further show that one patient carried a small insertion of material from chromosome 2 in the 3q- derivative. The P1 clone will allow isolation of candidate genes for these breakpoints and investigations into the clustering of other 3q21 leukemia breakpoints.

Physical structure of human chromosome 21: an analysis of YACs spanning 21q

We have resolved the sizes of the yeast artificial chromosomes (YACs) from an ordered library spanning the entire long arm of Chromosome (Chr) 21 to examine the proximity of sequence-tagged sites (STS) originally used to position these clones. The average insert length was 540 kilobases, and some 18% of the 765 clones have either lost or generated multiple YACs during cultivation. Comparing the sizes of YACs that share common sites allowed the identification of an additional 8% of the clones with large scale additions or deletions. Maximum physical distances between chromosome markers, as established by the co-occurrence of STS on a single YAC, generally agreed with those estimated by other procedures, except for a large region in 21q21. In addition to providing insights into the structure, mapping and organization of this chromosome, knowledge of the sizes and contents of these clones will greatly facilitate the acquisition of any sequence present in this library.

Isolation of human chromosome 21-specific cosmids and their uses in mapping of cosmid contigs on chromosomal subregions

A cosmid library of 3 x 10(5) clones has been constructed from a human x hamster hybrid cell line, 153E9a3, which contains human chromosome 21 (HC21) as the only human chromosome. From 56,500 clones of this library, 229 HC21-specific cosmids have been isolated by their hybridization to total human DNA and by their failure to hybridize to total Chinese hamster DNA. The cosmids isolated were then characterized, of these, 28 cosmids (12.2% of those tested) contained Not1 site(s), and 41 cosmids were localized on the eight subregions of HC21 by differential hybridization with Alu-PCR products obtained from a hybrid mapping panel. The cosmids localized were further integrated into the existing contigs using the end-specific probes of the clone insert. Therefore, they provided useful anchor points for contig mapping and walking.

Immunohistochemistry using antibodies to alpha-interferon and its induced protein, MxA, in Alzheimer's and Parkinson's disease brain tissues

The localization of alpha-interferon (alpha-IFN) and its induced protein, MxA, was examined in human brain tissues from neurologically normal, Alzheimer's disease (AD) and Parkinson's disease (PD) cases. In all cases, a few neurons in the superficial cortical layers and microglial cells in the white matter were stained with the antibody to alpha-IFN. In AD brains, white matter microglia were intensely labeled for alpha-IFN and reactive microglia, such as those on senile plaques, were strongly positive for MxA protein. In PD, Lewy bodies in the substantia nigra were positive for MxA, but there was no staining for alpha-IFN in that region. These results suggest that increased expression of alpha-IFN in the white matter microglia and appearance of MxA protein in reactive microglia contribute to Alzheimer pathology. The staining of some Lewy bodies for MxA may be indicative of a viral infection or other unknown factor.

The AML1 and ETO genes in acute myeloid leukemia with a t(8;21)

The translocation between chromosomes 8 and 21, t(8;21)(q22;q22), is the most frequent abnormality seen in approximately 46% of patients with acute myeloid leukemia with French-America-British (FAB)-M2 morphology and an aneuploid karyotype. The breakpoints in this translocation have been characterized at the molecular level, and the genes involved are AML1 on chromosome 21 and ETO (eight twenty one) on chromosome 8. AML1 has homology to the alpha subunit of the murine polyoma enhancer binding protein, pebp2, and to the segmentation gene, runt, of Drosophila melanogaster. ETO, also called MTG8 (myeloid translocation gene on 8) has no overall homology to known proteins, but it contains two DNA-binding zinc finger motifs and several regions that are proline- and serine-rich. Both AML1 and ETO are thought to be transcription factors because the motifs they contain are found in other transcription factors. Both genes are transcribed from telomere to centromere, and cytogenetic analysis of variant translocations has shown that the critical junction always conserved is on the derivative 8 chromosome. The rearrangement between the two chromosomes results in a fusion gene that contains the 5' region of AML1 including that homologous to runt fused to almost all of ETO. The fusion transcript from the der(8) chromosome is consistently detected in patients with the t(8;21). The translocation can be detected at the molecular level with selected genomic DNA probes from chromosome 21 and from chromosome 8 near the breakpoint in 80-100% of the t(8;21) patients at diagnosis and in relapse, and with reverse transcriptase-polymerase chain reaction (RT-PCR) in all of the patients at diagnosis and in long-term remission. These results indicate that leukemic clones are still circulating in patients who have been in remission for as long as 8 years.

Three CA/GT repeat polymorphisms from loci D21S414 and D21S1234 on human chromosome 21

We report three new polymorphic CA repeat microsatellites (ABM-21, ABM-C37A, and ABM-C37B) in two different loci (D21S414 and D21S1234), located in bands q21 and q11.2 of human chromosome 21 (HC21) and that were isolated from a HC21 phage library (LA21NS01). Heterozygosities for ABM-21, ABM-C37A, and ABM-C37B were 0.74, 0.50, and 0.67 respectively. These three CA repeat markers should be useful in the construction of a high resolution genetic map of this region of HC21.