Selection of a human chromosome 21 enriched YAC sub-library using a chromosome-specific composite probe.

The subdivision of total genomic human yeast artificial chromosome (YAC) libraries into specific chromosome clone collections will greatly facilitate the construction of an integrated genetic, physical and transcriptional map of the genome. We report the isolation of 388 YAC clones from a human library with an average insert size of 620 kilobases (kb) by the hybridization of a composite chromosome 21 probe to a high-density array of YAC clones. Roughly half of these clones hybridize to chromosome 21 by fluorescence in situ hybridization. These clones represent a twofold coverage of the chromosome. The technique offers the potential of sub-dividing whole genomic YAC libraries into their chromosomal elements to produce high-resolution tools for genome mapping.

Fusion of two novel genes, RBM15 and MKL1, in the t(1;22)(p13;q13) of acute megakaryoblastic leukemia.

t(1;22) is the principal translocation of acute megakaryoblastic leukemias. Here we show this chromosomal rearrangement to result in the fusion of two novel genes, RNA-binding motif protein-15 (RBM15), an RNA recognition motif-encoding gene with homology to Drosophila spen, and Megakaryoblastic Leukemia-1 (MKL1), a gene encoding an SAP (SAF-A/B, Acinus and PIAS) DNA-binding domain.

Molecular cloning of a novel 11q23 breakpoint associated with non-Hodgkin's lymphoma.

Chromosomal analysis of a non-Hodgkin's lymphoma revealed a t(11;14)(q23;q32) translocation amongst other abnormalities. To investigate the molecular basis of this translocation, a cosmid library was constructed from the tumour DNA and the rearranged IGH locus was isolated in a single cosmid. Fluorescence in situ hybridization confirmed that the cloned region contained sequences from chromosome 11q23 fused to chromosome 14q32. Sequence analysis identified the breakpoint as a fusion between a region from the switch segment of the C gamma 4 gene of the IGH locus and an unknown sequence on chromosome 11. The chromosome 11 sequence maps proximal to the CD3 gene cluster and is therefore distinct from both the HTRX1 gene (rearranged in acute leukaemias) and the RCK gene (rearranged in a cell line derived from a histiocytic B-cell lymphoma). This newly identified region contains a cluster of rare cutting restriction enzyme sites located within 200 bases of the breakpoint, suggestive of a CpG island. Although this t(11;14)(q23;q32) translocation and that in the RC-K8 cell line affect different regions on chromosome 11, the breakpoints on chromosome 14 were found to have occurred at equivalent positions of S gamma 2 and S gamma 4 segments.

Human epidermal differentiation complex in a single 2.5 Mbp long continuum of overlapping DNA cloned in bacteria integrating physical and transcript maps.

Terminal differentiation of keratinocytes involves the sequential expression of several major proteins which can be identified in distinct cellular layers within the mammalian epidermis and are characteristic for the maturation state of the keratinocyte. Many of the corresponding genes are clustered in one specific human chromosomal region 1q21. It is rare in the genome to find in such close proximity the genes belonging to at least three structurally different families, yet sharing spatial and temporal expression specificity, as well as interdependent functional features. This DNA segment, termed the epidermal differentiation complex, contains 27 genes, 14 of which are specifically expressed during calcium-dependent terminal differentiation of keratinocytes (the majority being structural protein precursors of the cornified envelope) and the other 13 belong to the S100 family of calcium binding proteins with possible signal transduction roles in the differentiation of epidermis and other tissues. In order to provide a bacterial clone resource that will enable further studies of genomic structure, transcriptional regulation, function and evolution of the epidermal differentiation complex, as well as the identification of novel genes, we have constructed a single 2.45 Mbp long continuum of genomic DNA cloned as 45 p1 artificial chromosomes, three bacterial artificial chromosomes, and 34 cosmid clones. The map encompasses all of the 27 genes so far assigned to the epidermal differentiation complex, and integrates the physical localization of these genes at a high resolution on a complete NotI and SalI, and a partial EcoRI restriction map. This map will be the starting resource for the large-scale genomic sequencing of this region by The Sanger Center, Hinxton, U.K.

The homeobox gene MEIS1 is amplified in IMR-32 and highly expressed in other neuroblastoma cell lines.

Neuroblastoma is a childhood tumour of the sympathetic nervous system that demonstrates striking clinical heterogeneity. In order to determine which genes are abnormally expressed in neuroblastoma, we screened regions of amplification from the short arm of chromosome 2 in the neuroblastoma cell line IMR-32 and found that the homeobox gene, myeloid ecotropic integration site 1 (MEIS1), is highly amplified. MEIS1 normally maps to chromosome band 2p14. High expression of MEIS1 without amplification was also found in other neuroblastoma cell lines, with and without MYCN amplification, and in medulloblastoma and crythroleukaemia cell lines. MEIS1 is highly expressed in cerebellum and ubiquitously expressed in normal immunohaematopoietic tissues and is thought to be important in cell proliferation and differentiation. While several lines of evidence point towards a role for homeobox genes in the development of other malignancies, this is the first report showing the amplification of a homeobox gene in neuroblastoma.

Trisomic dose of several chromosome 21 genes perturbs haematopoietic stem and progenitor cell differentiation in Down's syndrome.

Children with Down's syndrome (DS) have 20-50-fold higher incidence of all leukaemias (lymphoid and myeloid), for reasons not understood. As incidence of many solid tumours is much lower in DS, we speculated that disturbed early haematopoietic differentiation could be the cause of increased leukaemia risk. If a common mechanism is behind the risk of both major leukaemia types, it would have to arise before the bifurcation to myeloid and lymphoid lineages. Using the transchromosomic system (mouse embryonic stem cells (ESCs)) bearing an extra human chromosome 21 (HSA21)) we analyzed the early stages of haematopoietic commitment (mesodermal colony formation) in vitro. We observed that trisomy 21 (T21) causes increased production of haemogenic endothelial cells, haematopoietic stem cell precursors and increased colony forming potential, with significantly increased immature progenitors. Transchromosomic colonies showed increased expression of Gata-2, c-Kit and Tie-2. A panel of partial T21 ESCs allowed us to assign these effects to HSA21 sub-regions, mapped by 3.5 kbp-resolution tiling arrays. The Gata-2 increase on one side, and c-Kit and Tie-2 increases on the other, could be attributed to two different, non-overlapping HSA21 regions. Using human-specific small interfering RNA silencing, we could demonstrate that an extra copy of RUNX1, but not ETS-2 or ERG, causes an increase in Tie-2/c-Kit levels. Finally, we detected significantly increased levels of RUNX1, C-KIT and PU.1 in human foetal livers with T21. We conclude that overdose of more than one HSA21 gene contributes to the disturbance of early haematopoiesis in DS, and that one of the contributors is RUNX1. As the observed T21-driven hyperproduction of multipotential immature precursors precedes the bifurcation to lymphoid and myeloid lineages, we speculate that this could create conditions of increased chance for acquisition of pre-leukaemogenic rearrangements/mutations in both lymphoid and myeloid lineages during foetal haematopoiesis, contributing to the increased risk of both leukaemia types in DS.

Functional genomics of the Down syndrome.

Down syndrome, as a phenotypic result of trisomy 21, is a complex condition with a set of over 30 phenotypic features, which manifest themselves with varying frequencies among affected individuals. The importance for molecular medicine of understanding the molecular mechanisms underlying Down syndrome becomes fully appreciated when a striking feature of Down syndrome is taken into account: that the overdose of otherwise perfectly normal genes causes disorders of human health, indistinguishable from major public health problems of the general population, such as mandatory early onset Alzheimer s degeneration, increased risk of leukemia, and protection from cancer of solid tissues. The DNA sequence of human chromosome 21 is, at the moment, the most complete piece of DNA sequence known in the whole of human genome. The challenge for the future is an integrated, multidisciplinary approach to the molecular biology of chromosome 21 genes, in conjunction with the research into the variation in their genotype, expression, and function in the normal population, in Down syndrome individuals with well-characterized phenotypic traits, and in euploid patients suffering from diseases associated with phenotypic components of Down syndrome: mental retardation, developmental defects, hematological and solid tissue malignancies, and Alzheimer s disease.

Evolutionary relationships between the t and H-2 haplotypes in the house mouse.

Thirty-three mouse strains carrying t haplotypes were typed with a large battery of monoclonal and polyclonal antibodies specific for class I and class II antigens controlled by the H-2 complex. Among these t haplotypes were representatives of the six complementation groups defined previously and of eight new groups defined by us recently. The typing resulted in the identification of the H-2 haplotypes of these strains and of their alleles at K, D, A, and E loci. Nineteen of the 33 strains proved to carry a mutation that prevents the expression of the E molecule on the cell surface. All H-2 haplotypes of the t strains are related in terms of sharing certain antigenic determinants, most of which have not, as yet, been found in inbred strains or in wild mice that do not carry t haplotypes. According to the degree of serological relatedness, the haplotypes can be arranged into a pedigree presumably reflecting the evolutionary history of the t chromosomes. The ancestral t chromosome from which the 33 chromosomes derive was presumably present in the mouse population before the divergence of the Mus musculus and Mus domesticus species. The E0 mutation, too, is apparently ancient because it occurs in different branches of the evolutionary tree.

Major histocompatibility complex of the mole-rat. II. Restriction fragment polymorphism.

The major histocompatibility complex (Mhc) is a group of loci coding for lymphocyte membrane glycoproteins that provide the context for the recognition of foreign antigens in the initial phase of the immune response. The complex contains a large number of loci, some of which are highly polymorphic. The complexity and polymorphism pose a number of questions concerning the evolution of the Mhc. In an attempt to answer some of these questions, we have begun to study the Mhc of the mole-rat, Spalax ehrenbergi, a rodent representing a complex of sibling species occupying ecologically and geographically clearly delineated regions within the borders of Israel. In an earlier publication we identified the Spalax major histocompatibility (Smh) complex serologically and biochemically. Here, we analyze the Smh by Southern blotting of DNA fragments produced by restriction enzyme digestion. The fragments were hybridized to mouse probes specific for class I, class II, and C4 genes. The analysis has revealed that the Smh complex contains as many class I genes as the mouse does and that these genes are polymorphic. The number of class II genes could not be determined with certainty, but it is probably not greater than in the mouse. Polymorphism was also detected at the loci coding for the complement component 4 (C4), which are probably closely linked to the Smh complex. The polymorphism of mole-rat class I loci contrasts with the reported monomorphism of these loci in the Syrian hamster. Since the mole-rat leads a solitary, subterranean life, as the Syrian hamster does, ecology cannot be an explanation for the lack of class I polymorphism in the latter species.

Evolution of mouse major histocompatibility complex genes borne by t chromosomes.

Virtually all wild mouse populations carry t haplotypes that cause embryonic lethality or semilethality, distortion of segregation ratios, suppression of crossing-over, and male sterility. The t complex of genes is located on chromosome 17, closely linked to the H-2, the major histocompatibility complex of the mouse. The t haplotypes differ from each other not only in lethal genes they carry but also in their linked H-2 haplotypes. In this study, we compared the class II H-2 genes present on 31 t chromosomes extracted from wild populations in different parts of the world. The comparison was based on the analysis of DNA fragments obtained after digestion with restriction endonucleases. The results reveal the existence of three major groups of class II alleles representing main branches on the evolutionary tree of the t chromosomes. Alleles within each group are similar if not identical, although they are borne by chromosomes that have been separated in time and space. The presence of similar alleles in Mus musculus and Mus domesticus suggests that some of them may have been separated for more than 1 million years. This must also be the minimal age of the t chromosomes but, because at least two of the three main branches appear to be related in their origin, the actual age of t chromosomes could be much greater. The observations support the proposal that H-2 genes evolve slowly.

Assignment of 55 novel cosmids to seven subregions of chromosome 13 using fluorescence in situ hybridization.

Fifty-five individual cosmids isolated from a chromosome 13-specific library have been regionally assigned using fluorescence in situ hybridization. These cosmids represent novel DNA markers that can be added to the limited number of DNA probes already available for this chromosome. Individual cosmids mapped along the length of the chromosome with almost equal distribution except that there appears to be an excess of probes from the distal 13q33-q34 region. Only two cosmids did not map back to chromosome 13, indicating that at least 96% of cosmids in this library are from this chromosome. The library is generally available as gridded colonies on nylon membranes suitable for hybridization screening.

Labelling oligonucleotides to high specific activity (I).

The normal procedure for labelling oligonucleotides radioactively is the use of polynucleotide kinase and gamma 32P-ATP. However, this has the disadvantage of only introducing one labelled base per molecule of the oligonucleotide. In this paper we describe an approach based on primer/template combinations using conventional fill-in conditions followed by the release of the labelled sequence by digestion with uracil-DNA glycosylase.

Control of partial digestion combining the enzymes dam methylase and MboI.

A method is described which allows the preparation of reproducible partial digests without previous establishment of the incubation conditions. It is based on a combined application of dam methylase and the restriction endonuclease MboI, both recognizing the sequence 5'-GATC-3' but MboI unable to cut the methylated site. Due to their competition for the same substrate the DNA is partially digested, with the size of the resulting fragments strongly dependent on the ratio of enzymes. The Km of the dam methylase was determined to be 115 ng DNA/microliters indicating a variance in fragment sizes generated at low DNA-concentrations. This effect is minimized above 150 ng/microliters. Any influence of digestion time is avoided, because the reaction runs until complete modification of all sites. The dependence on enzyme concentration and presence of agarose was checked. Knowledge of these parameters allows an accurate prediction of fragment sizes generated at different conditions. The technique was successfully used to construct libraries from different sources, in particular chromosome-specific libraries from small amounts of flow-sorted material.

High-resolution YAC fragmentation map of 1q21.

Chromosomal band 1q21 contains a number of genes, constituting the Epidermal differentiation complex (EDC), most of which are involved in the process of terminal differentiation of the human epidermis and implicated in several disorders of keratinization and cancer. The physical map of 1q21 has been refined by generating 400 YAC derivatives. These products have allowed us to localize EDC genes and additional ESTs precisely. The transcriptional map of the region has been extended by positioning 20 ESTs reported to map between D1S442 and D1S305. Eight of the ESTs are localized in two distinct clusters, confirmed by isolating PACs and chromosome 1-specific cosmids. Two of the ESTs correspond to the genes for YL1 and selenium-binding protein, both of which have potential tumor suppressor activity. Through the use of fragmented YACs and bacterial clones, the order of markers and ESTs in the region has been established as follows: cen-A002O32-Bda44g03-Cda10d12-Bdab5d06, H60056, A005K39-D1S442-WI5663-WI7969-Cx40-Cda0g e12-Cda0kh05-A002D26- A008S07-Cda0ff08-D1S498-S100A10-WI7815( THH)-WI7217(FLG)-D1S1664-INV-SPRR2A- LOR-A001X21-D1S305-tel.

Major histocompatibility complex of the mole-rat. I. Serological and biochemical analysis.

The mole-rat, Spalax ehrenbergi, is a complex subterranean rodent species whose habitat is restricted largely to the Middle East and North Africa. We typed over 50 mole-rats with mouse monoclonal and polyclonal antibodies specific for class I and class II major histocompatibility complex (Mhc) molecules. Some of these antibodies were produced against mouse Mhc molecules, others against Mhc molecules of other species. About 25% of the antibodies reacted with mole-rat lymphocytes in the cytotoxic test. Some of the serologically positive antibodies precipitated from a glycoprotein pool of mole-rat spleen cell molecules that corresponded in size with class I and class II molecules of other species. We conclude, therefore, that mole-rats, like other mammals, possess the Mhc which consists of class I and class II loci. We call this Mhc Spalax major histocompatibility (Smh) complex. The occurrence of a large number of different serotypes among the tested animals suggests that Smh loci are polymorphic. This Mhc polymorphism of the mole-rat contrasts with the monomorphism or oligomorphism of the Syrian hamster, a rodent with a similar ecology. Thus far no qualitative correlation could be found between Smh polymorphism and chromosome variation described in this superspecies.

W (A or T) sequences as probes and primers suitable for genomic mapping and fingerprinting.

A limitation to the use of oligonucleotide probes as tools for genetic and physical mapping has been the low hybridization positive frequency obtained by oligonucleotides of sufficient length to hybridize preferentially to cloned insert DNA (and not host E. coli genomic DNA). Both computer and experimental results now indicate that oligonucleotide probes composed of W (A or T) sequence are preferentially found in eukaryotic DNA, and can be used to provide high frequency, discriminative hybridization. Such W sequences may be useful as either probes or PCR primers in molecular diagnostic applications as well as in genetic and physical mapping.

Efficient identification and regional positioning of YAC and cosmid clones to human chromosome 21 by radiation fusion hybrids.

The use of integrated mapping strategies involving bacterial, yeast, and rodent cells as hosts simplifies the construction of maps, which combine long-range order, high resolution, and easy access to the cloned DNA. Radiation-fusion hybrids offer a specially powerful long-range mapping system for human chromosomes. We describe here techniques for establishing a radiation-fusion hybrid map of Chromosome (Chr) 21q and its integration with local information on YAC and cosmid positions.

Construction, arraying, and high-density screening of large insert libraries of human chromosomes X and 21: their potential use as reference libraries.

We have constructed cosmid libraries from flow-sorted human chromosomes X and 21, each of which contains greater than 30 genome equivalents, and have developed systems allowing permanent storage of primary clones, easy screening of libraries in high-density filter formats, and the simultaneous generation of fingerprinting and mapping data on the same set of cosmid clones. Clones are picked into microtiter plate wells and stored at -70 degrees C. A semiautomatic robot system allows the generation of filter replicas containing up to 10,000 clones per membrane. Sets of membranes containing 15-20 chromosome equivalents of both chromosomes will be used for the construction of ordered clone libraries by hybridization fingerprinting protocols. In addition, multiple sets of two membranes containing 4 chromosome equivalents of the human X chromosome, and one membrane containing 3 chromosome equivalents of chromosome 21, have been distributed to other interested laboratories as part of a system of reference libraries. This system allows other groups easy access to the clones and offers an efficient protocol to combine results generated in different laboratories using these libraries. Here we describe the construction of the libraries and demonstrate the use of high-density screening filters in oligonucleotide probe hybridizations and the isolation of cosmids by hybridization with probes from the X chromosome.

High-resolution physical map and identification of potentially regulatory sequences of the human SH3BGR located in the Down syndrome chromosomal region.

We have isolated, mapped and sequenced the 5' promoter region of the human SH3BGR (SH3-Binding Glutamine Rich) gene located in the Down syndrome region-2, between markers D21S55 and MX1 of human chromosome 21. This region has been postulated as the minimal region for congenital heart disease and 6 facial and dermatoglyphic features present in Down syndrome. The SH3BGR gene is expressed in fetal and adult heart and in skeletal muscle and therefore it is a candidate gene for the congenital heart defect and muscle hypotonia. The 5' region of the gene has been positioned in a 115 kb PAC/cosmid contig with full EcoRI/SmaI restriction map covering cosmid pockets 122-123 as well as cosmid pocket 124 located between markers D21S268 and D21S220. Sequencing of the SH3BGR promoter region has allowed the identification of several potential regulatory elements of this candidate gene for the congenital heart disease and other potential DS features. Several of the elements identified are also present in other muscle-expressed genes.