Chromosomal distribution of 320 genes from a brain cDNA library

Analysis of a human brain transcriptome map

BACKGROUND

Genome wide transcriptome maps can provide tools to identify candidate genes that are over-expressed or silenced in certain disease tissue and increase our understanding of the structure and organization of the genome. Expressed Sequence Tags (ESTs) from the public dbEST and proprietary Incyte LifeSeq databases were used to derive a transcript map in conjunction with the working draft assembly of the human genome sequence.

RESULTS

Examination of ESTs derived from brain tissues (excluding brain tumor tissues) suggests that these genes are distributed on chromosomes in a non-random fashion. Some regions on the genome are dense with brain-enriched genes while some regions lack brain-enriched genes, suggesting a significant correlation between distribution of genes along the chromosome and tissue type. ESTs from brain tumor tissues have also been mapped to the human genome working draft. We reveal that some regions enriched in brain genes show a significant decrease in gene expression in brain tumors, and, conversely that some regions lacking in brain genes show an increased level of gene expression in brain tumors.

CONCLUSIONS

This report demonstrates a novel approach for tissue specific transcriptome mapping using EST-based quantitative assessment.

The sequence of the human genome

A 2.91-billion base pair (bp) consensus sequence of the euchromatic portion of the human genome was generated by the whole-genome shotgun sequencing method. The 14.8-billion bp DNA sequence was generated over 9 months from 27,271,853 high-quality sequence reads (5.11-fold coverage of the genome) from both ends of plasmid clones made from the DNA of five individuals. Two assembly strategies-a whole-genome assembly and a regional chromosome assembly-were used, each combining sequence data from Celera and the publicly funded genome effort. The public data were shredded into 550-bp segments to create a 2.9-fold coverage of those genome regions that had been sequenced, without including biases inherent in the cloning and assembly procedure used by the publicly funded group. This brought the effective coverage in the assemblies to eightfold, reducing the number and size of gaps in the final assembly over what would be obtained with 5.11-fold coverage. The two assembly strategies yielded very similar results that largely agree with independent mapping data. The assemblies effectively cover the euchromatic regions of the human chromosomes. More than 90% of the genome is in scaffold assemblies of 100,000 bp or more, and 25% of the genome is in scaffolds of 10 million bp or larger. Analysis of the genome sequence revealed 26,588 protein-encoding transcripts for which there was strong corroborating evidence and an additional approximately 12,000 computationally derived genes with mouse matches or other weak supporting evidence. Although gene-dense clusters are obvious, almost half the genes are dispersed in low G+C sequence separated by large tracts of apparently noncoding sequence. Only 1.1% of the genome is spanned by exons, whereas 24% is in introns, with 75% of the genome being intergenic DNA. Duplications of segmental blocks, ranging in size up to chromosomal lengths, are abundant throughout the genome and reveal a complex evolutionary history. Comparative genomic analysis indicates vertebrate expansions of genes associated with neuronal function, with tissue-specific developmental regulation, and with the hemostasis and immune systems. DNA sequence comparisons between the consensus sequence and publicly funded genome data provided locations of 2.1 million single-nucleotide polymorphisms (SNPs). A random pair of human haploid genomes differed at a rate of 1 bp per 1250 on average, but there was marked heterogeneity in the level of polymorphism across the genome. Less than 1% of all SNPs resulted in variation in proteins, but the task of determining which SNPs have functional consequences remains an open challenge.

The TIGR gene indices: reconstruction and representation of expressed gene sequences

Expressed sequence tags (ESTs) have provided a first glimpse of the collection of transcribed sequences in a variety of organisms. However, a careful analysis of this sequence data can provide significant additional functional, structural and evolutionary information. Our analysis of the public EST sequences, available through the TIGR Gene Indices (TGI; http://www.tigr.org/tdb/tdb.html ), is an attempt to identify the genes represented by that data and to provide additional information regarding those genes. Gene Indices are constructed for selected organisms by first clustering, then assembling EST and annotated gene sequences from GenBank. This process produces a set of unique, high-fidelity virtual transcripts, or tentative consensus (TC) sequences. The TC sequences can be used to provide putative genes with functional annotation, to link the transcripts to mapping and genomic sequence data, and to provide links between orthologous and paralogous genes.

Expression of the gene encoding the matrix gla protein by mature osteoblasts in human fracture non-unions

BACKGROUND

Osteoblast phenotypic abnormality, namely the expression of collagen type III, has been shown previously in fracture non-union woven bone.

AIMS

To investigate osteoblasts from fracture non-unions for evidence of gene expression of non-collagenous bone matrix proteins that have been implicated in mineralisation, namely matrix gla protein (MGP), osteonectin, osteopontin, and osteocalcin. MGP is a consistent component of bone matrix, but there are no reports of osteoblasts in the skeleton expressing the gene for MGP, and the site of synthesis of skeletal MGP (perhaps the liver) has yet to be determined.

METHODS

Biopsies from normally healing human fractures and non-unions were examined by means of in situ hybridisation, using 35S labelled probes and autoradiography to disclose levels of gene expression.

RESULTS

In normally healing fractures, mature osteoblasts on woven bone were negative for MGP mRNA, but positive for osteonectin, osteopontin, and osteocalcin mRNA molecules. In non-unions, osteoblasts displayed a novel phenotype: they were positive for MGP mRNA, in addition to osteonectin, osteopontin, and osteocalcin mRNA molecules.

CONCLUSIONS

Mature osteoblasts in slowly healing fractures have an unusual phenotype: they express the gene encoding MGP, which indicates that control of osteoblast gene expression in non-unions is likely to be abnormal. This might be of importance in the pathogenesis of non-uniting human fractures, and is of current interest given the emerging status of MGP as an inhibitor of mineralisation.

Cytogenetic and molecular characterization of random chromosomal rearrangements activating the drug resistance gene, MDR1/P-glycoprotein, in drug-selected cell lines and patients with drug refractory ALL

Drug resistance, both primary and acquired, is a major obstacle to advances in cancer chemotherapy. In vitro, multidrug resistance can be mediated by P-glycoprotein (PGY1), a cell surface phosphoglycoprotein that acts to efflux natural products from cells. PGY1 is encoded by the MDR1 gene located at 7q21.1. Overexpression of MDR1 has been demonstrated in many cancers, both in patient tumors and in cell lines selected with a variety of chemotherapeutic agents. Recent studies in drug-selected cell lines and patients samples have identified hybrid mRNAs comprised of an active, but apparently random, gene fused 5' to MDR1. This observation indicates that random chromosomal rearrangements, such as translocations and inversions, leading to "capture" of MDR1 by constitutively expressed genes may be a mechanism for activation of this gene following drug exposure. In this study, fluorescence in situ hybridization (FISH) using whole chromosome paints (WCP) and bacterial artificial chromosome (BAC)-derived probes showed structural rearrangements involving 7q in metaphase and interphase cells, and comparative genomic hybridization (CGH) revealed high levels of amplification at chromosomal breakpoints. In an adriamycin-selected resistant colon cancer line (S48-3s/Adr), WCP4/WCP7 revealed t(4;7)(q31;q21) and BAC-derived probes demonstrated that the breakpoint lay between MDR1 and sequences 500-1000 KB telomeric to it. Similarly, in a subline isolated following exposure to actinomycin D (S48-3s/ActD), a hybrid MDR1 gene composed of heme oxygenase-2 sequences (at 16p13) fused to MDR1 was identified and a rearrangement confirmed with WCP7 and a subtelomeric 16p probe. Likewise, in a paclitaxel-selected MCF-7 subline where CASP sequences (at 7q22) were shown to be fused to MDR1, WCP7 showed an elongated chromosome 7 with a homogeneously staining regions (hsr); BAC-derived probes demonstrated that the hsr was composed of highly amplified MDR1 and CASP sequences. In all three selected cell lines, CGH demonstrated amplification at breakpoints involving MDR1 (at 7q21) and genes fused to MDR1 at 4q31, 7q22, and 16p13.3. Finally, in samples obtained from two patients with drug refractory ALL, BAC-derived probes applied to archived marrow cells demonstrated that a breakpoint occurred between MDR1 and sequences 500-1000 KB telomeric to MDR1, consistent with a random chromosomal rearrangement. These results support the proposal that random chromosomal rearrangement leading to capture and activation of MDR1 is a mechanism of acquired drug resistance.

A comprehensive, high-resolution genomic transcript map of human skeletal muscle

We present the Human Muscle Gene Map (HMGM), the first comprehensive and updated high-resolution expression map of human skeletal muscle. The 1078 entries of the map were obtained by merging data retrieved from UniGene with the RH mapping information on 46 novel muscle transcripts, which showed no similarity to any known sequence. In the map, distances are expressed in megabase pairs. About one-quarter of the map entries represents putative novel genes. Genes known to be specifically expressed in muscle account for <4% of the total. The genomic distribution of the map entries confirmed the previous finding that muscle genes are selectively concentrated in chromosomes 17, 19, and X. Five chromosomal regions are suspected to have a significant excess of muscle genes. Present data support the hypothesis that the biochemical and functional properties of differentiated muscle cells may result from the transcription of a very limited number of muscle-specific genes along with the activity of a large number of genes, shared with other tissues, but showing different levels of expression in muscle. [The sequence data described in this paper have been submitted to the EMBL data library under accession nos. F23198-F23242.]

Subregional localization of 21 chromosome 7-specific expressed sequence tags (ESTs) by FISH using newly identified YACs and P1s

Twenty-one putative chromosome 7-derived expressed sequence tags (ESTs) identified 33 yeast artificial chromosomes (YACs) or P1 clones, which were then used as reagents for physical mapping. FISH mapping established that the ESTs contained within these clones were distributed throughout chromosome 7, with all major cytogenetic bands represented, except 7p13-p15, 7p11, 7q31.2, and 7q35. Each EST sequence identified at least one other sequence in publicly available databases (using search tools such as BLASTN, basic local alignment search tool), and many of the ESTs identified cDNAs and several genomic DNA sequences. However, 7 ESTs did not identify highly significant matches (P < 1 x 10(-5)). Only one (EST01924-D7S2281E) failed to identify any other EST from the dbEST homology searches. BLAST analysis identified at least five genes from EST sequence comparisons: protein tyrosine phosphatase zeta (PTPRZ, also known as RPTPZ) (EST02092), which we had mapped to 7q31.3, in agreement with previous studies; cAMP-dependent protein kinase regulatory subunit bI (EST01644); rat integral membrane glycoprotein (EST00085); human IFNAR gene for interferon alpha/beta receptor (EST00817); and rat 14-3.3 protein gamma subtype (putative protein kinase C regulatory protein) (EST00762). These ESTs will help to develop the map of chromosome 7, which integrates physical, transcriptional, and cytogenetic data, as well as to provide candidate disease genes for chromosome 7-specific disorders.

Expansion of the pig comparative map by expressed sequence tags (EST) mapping

We have used a PCR-based approach for the genetical and physical mapping of 34 transcripts isolated from a porcine small intestine cDNA library. All but one gene were regionally localized by using a somatic pig-rodent cell hybrid panel, and 12 genes were mapped by linkage analysis of single-stranded conformational polymorphisms developed in 3' untranslated regions of transcripts. For 20 of the transcripts, the human homolog has already been mapped. This study thus represents a significant contribution to the pig comparative map. Some important findings were that we could clarify the extent of a previously identified inversion event in a region of conserved synteny between SSC6q and HSA1p, that SSC14q does contain a region homologous to HSA1, a situation not clear from earlier ZOO-FISH studies, and that the homology between SSC17 and HSA20 includes the p-arm of HSA20.

C2H2-171: a novel human cDNA representing a developmentally regulated POZ domain/zinc finger protein preferentially expressed in brain

We describe a novel human zinc finger cNDA. C2H2-171. This cDNA represents an mRNA which encodes a protein of 484 amino acids and a calculated molecular weight of 54 kD. Four zinc finger-like domains are found in the C-terminal end of the protein. At the N-terminus, C2H2-171 contains a POZ/tramtrack-like domain similar to that found in the tumor associated zinc finger proteins LAZ-3/BCL-6 and PLZ-F, as well as in non-zinc finger proteins. C2H2-171 RNA is preferentially expressed in the brain, and increases during the course of murine development, with maximal expression in the adult. C2H2-171 RNA is differentially expressed in brain regions, with the highest level of expression in the cerebellum. C2H2-171 RNA was expressed at high levels in primary cerebellar granule cell neurons compared to astrocytes. The gene encoding C2H2-171 is highly conserved in vertebrates, and maps to the terminus of human chromosome 1 (1q44-ter). This chromosomal location is associated with a number of cytogenetic aberrations including those involving brain developmental anomalies and tumorigenesis. These data suggest that C2H2-171 may play an important role in vertebrate brain development and function.

Isolation of chromosome 18-specific brain transcripts as positional candidates for bipolar disorder

Several studies have proposed the existence of susceptibility loci for bipolar disorder on chromosome 18. To identify possible candidate genes for this disease, we isolated brain-expressed transcripts by direct cDNA selection on chromosome 18-specific biotinylated cosmid clones. Longer cognate cDNA clones of the selected cDNAs were isolated from a normalized infant brain cDNA library. Physical mapping by PCR on a panel of somatic cell hybrids was conducted by the use of primers derived from partial sequences on either the 5' or 3' ends of the clones. In our initial analysis, 48 cDNA clones were found to be chromosome 18-specific, mapping to different subchromosomal regions. Sequence redundancy among these clones yielded 30 unique transcripts, five of which were represented in previously known genes. Further sequencing of the remaining 25 unique cDNA clones confirmed the absence of significant homology to known genes, indicating that these transcripts represented novel genes. Mapping with the use of a radiation hybrid panel positioned the brain cDNAs to within = 100 to 1100 kb from reference sequence tag sites (STSs) and assembled them into six high resolution linkage groups. The majority of the transcripts were found to cluster to discrete locations on 18p and 18q, previously hypothesized as susceptibility regions for bipolar disorder, identifying them as positional candidate genes.

Tetraodon fluviatilis, a new puffer fish model for genome studies

The puffer fish Fugu rubripes rubripes was recently introduced by S. Brenner et al. (1993, Nature 366: 265-268) as a new model for genomic studies. Due to difficulties in obtaining material from this Japanese marine puffer, we have started work on Tetraodon fluviatilis, a small, freshwater puffer fish that can be kept and bred in an aquarium. It was originally described by E. Hinegardner (1968, Am. Nat. 102(928) 517-523) as the teleost with the smallest amount of DNA per cell (0.4 pg, 380 Mb). To estimate the extent of divergence between T. fluviatilis and F. r. rubripes, part of the mitochondrial cytochrome b (cyt b) gene from both fishes was cloned and sequenced. A comparison of these two sequences indicated that F.r. rubripes and T. fluviatilis diverged approximately 18-30 million years ago, and phylogenetic analysis placed both fishes at the base of the Perciformes lineage. To facilitate and extend further the use of the puffer fish as a model for genome studies, we have constructed and characterized a T. fluviatilis cDNA library.

2006 expressed-sequence tags derived from human chromosome 7-enriched cDNA libraries

The establishment and mapping of gene-specific DNA sequences greatly complement the ongoing efforts to map and sequence all human chromosomes. To facilitate our studies of human chromosome 7, we have generated and analyzed 2006 expressed-sequence tags (ESTs) derived from a collection of direct selection cDNA libraries that are highly enriched for human chromosome 7 gene sequences. Similarity searches indicate that approximately two-thirds of the ESTs are not represented by sequences in the public databases, including those in dbEST. In addition, a large fraction (68%) of the ESTs do not have redundant or overlapping sequences within our collection. Human DNA-specific sequence-tagged sites (STSs) have been developed from 190 of the ESTs. Remarkably, 180 (96%) of these STSs map to chromosome 7, demonstrating the robustness of chromosome enrichment in constructing the direct selection cDNA libraries. Thus far, 140 of these EST-specific STSs have been assigned unequivocally to YAC contigs that are distributed across the chromosome. Together, these studies provide > 2000 ESTs highly enriched for chromosome 7 gene sequences, 180 new chromosome 7 STSs corresponding to ESTs, and a definitive demonstration of the ability to enrich for chromosome-specific cDNAs by direct selection. Furthermore, the libraries, sequence data, and mapping information will contribute to the construction of a chromosome 7 transcript map.

Chromosomal assignment of 311 sequences transcribed in human adult testis

A total of 311 expressed sequence tags (ESTs) derived from human adult testis have been assigned to human chromosomes by Southern analysis of a monochromosome somatic cell hybrid panel. Over 70% of the ESTs show conservation to hamster and mouse DNA, and the overall distribution of transcripts correlates well with physical chromosome size and to a greater extent with male meiotic chromosome length. The notable exception is the X chromosome, for which the number of testis-derived ESTs is greatly underrepresented. This finding may reflect inactivation of the X chromosome during the meiotic phase of spermatogenesis and a consequent selection against large numbers of X-linked germ cell transcripts. Further analysis of the distribution of testis ESTs showed that the EST density remains significantly correlated with the recombination density of each autosome. Analysis of a comparable number (320) of brain EST autosome assignments showed no similar correlation. These data suggest a specific association between transcription in testis tissue and male meiotic recombination.

A collection of 1814 human chromosome 7-specific STSs

An established goal of the ongoing Human Genome Project is the development and mapping of sequence-tagged sites (STSs) every 100 kb, on average, across all human chromosomes. En route to constructing such a physical map of human chromosome 7, we have generated 1814 chromosome 7-specific STSs. The corresponding PCR assays were designed by the use of DNA sequence determined in our laboratory (79%) or generated elsewhere (21%) and were demonstrated to be suitable for screening yeast artificial chromosome (YAC) libraries. This collection provides the requisite landmarks for constructing a physical map of chromosome 7 at < 100-kb average spacing of STSs.

Identification of the gene-richest bands in human chromosomes

The human genome is a mosaic of isochores, long DNA segments which are compositionally homogeneous and which can be partitioned into five families, L1, L2, H1, H2 and H3, characterized by increasing GC levels and by increasing gene concentrations. Previous investigations showed that in situ hybridization with a DNA fraction derived from the GC-richest and gene-richest isochores of the H3 family produced the highest concentration of signals on 25 R(everse) bands that include the 22 most thermal-denaturation-resistant T(elomeric) bands, a subset of R bands. Using an improved protocol for in situ hybridization and cloned H3 isochore DNA, we have now shown (i) that the number of bands which are characterized by strong hybridization signals, and which are here called T or H3+, is 28; (ii) that 31 additional R bands, here called T'or H3* bands, also contain H3 isochores, although at a lower concentration than H3+ bands; and (iii) that the remaining R bands (about 140 out of 200, at a resolution of 400 bands), here called R" or H3- bands, do not contain any detectable H3 isochores. H3+ and H3* bands contain all the gene-richest isochores of the human genome. The existence of three distinct sets of R bands is further supported (i) by the different compositional features of genes located in them; (ii) by the very low gene density of chromosomes 13 and 18, in which all R bands are H3- bands; (iii) by the compositional map of a H3* band, Xq28; (iv) by the overwhelming presence of GC-rich and GC-poor long (> 50 kb) DNA sequences in H3+/H3* and in H3-/G bands, respectively; and (v) by the large degree of coincidence of H3+ and H3* bands with CpG island-positive bands. These observations have implications for our understanding of the causes of chromosome banding and provide a classification of chromosomal bands that is related to GC level (and to gene concentration).

X-linked mental retardation with neonatal hypotonia in a French family (MRX15): gene assignment to Xp11.22-Xp21.1

Linkage analysis was performed in a family with non-specific X-linked mental retardation (MRX 15). Hypotonia in infancy was the most remarkable physical manifestation. The severity of mental deficiency was variable among the patients, but all of them had poor or absent speech. Significant lod scores at a recombination fraction of zero were detected with the marker loci DXS1126, DXS255, and DXS573 (Zmax = 2.01) and recombination was observed with the two flanking loci DXS164 (Xp21.1) and DXS988 (Xp11.22), identifying a 17 cM interval. This result suggests a new gene localization in the proximal Xp region. In numerous families with non-specific X-linked mental retardation (MRX), the corresponding gene has been localized to the paracentromeric region in which a low recombination rate impairs the precision of mapping.

Identification and mapping of human cDNAs homologous to Drosophila mutant genes through EST database searching

Cross-species comparison is an effective tool used to identify genes and study their function in both normal and pathological conditions. We have applied the power of Drosophila genetics to the vast resource of human cDNAs represented in the expressed sequence tag (EST) database (dbEST) to identify novel human genes of high biological interest. Sixty-six human cDNAs showing significant homology to genes causing Drosophila mutant phenotypes were identified by screening dbEST using the "text string' option, and their map position was determined using both fluorescence in situ hybridization (FISH) and radiation hybrid mapping. Comparison between these genes and their putative partners in Drosophila may provide important insights into their function in mammals. Furthermore, integration of these genes into the transcription map of the human genome contributes to the positional candidate approach for disease gene identification.

Regional assignment of human ESTs by whole-genome radiation hybrid mapping

The UK HGMP Resource Centre's collection of human partial cDNA sequences (ESTs) have been examined for suitability for mapping by PCR on a panel of somatic cell hybrids. The chromosomal assignments of 92 ESTs were determined with a monochromosomal hybrid panel, and a subset of 45 were linked to genetic markers with a panel of whole-genome radiation hybrids (WG-RHs). These results demonstrate the potential of WG-RHs to construct a transcript map of the human genome.

Construction of a YAC contig encompassing the Usher syndrome type 1C and familial hyperinsulinism loci on chromosome 11p14-15.1

The Usher syndrome type 1C (USH1C) and familial hyperinsulinism (HI) loci have been assigned to chromosome 11p14-15.1, within the interval D11S419-D11S1310. We have constructed a yeast artificial chromosome (YAC) contig, extending from D11S926 to D11S899, which encompasses the critical regions for both USH1C and HI and spans an estimated genetic distance of approximately 4 cM. A minimal set of six YAC clones constitute the contig, with another 22 YACs confirming the order of sequence-tagged sites (STSs) and position of YACs on the contig. A total of 40 STSs, including 10 new STSs generated from YAC insert-end sequences and inter-Alu PCR products, were used to order the clones within the contig. This physical map provides a resource for identification of gene transcripts associated with USH1C, HI, and other genetic disorders that map to the D11S926-D11S899 interval.

Characterisation of a human chromosome 1 somatic cell hybrid mapping panel and regional assignment of 6 novel STS

A somatic cell hybrid mapping panel has been constructed which allows subdivision of human chromosome 1 into 8 distinct subregions. All of the hybrids carry copies of chromosome 1 with specific deletions and the position of the breakpoints has been determined relative to the location of microsatellite markers in the genetic linkage map produced by Genethon. The majority of the breakpoints can be positioned between adjacent loci on the map. The usefulness of this hybrid panel for physical mapping has been demonstrated by the regional assignment of 6 novel STS markers made from Alu-PCR clones generated from a hybrid which contains the short arm of chromosome 1.

Construction of a chromosome specific library of human MARs and mapping of matrix attachment regions on human chromosome 19

Using a novel procedure a representative human chromosome 19-specific library was constructed of short sequences, which bind preferentially to the nuclear matrix (matrix attachment regions, or MARs). Judging by 20 clones sequenced so far, the library contains > 50% of human inserts, about 90% of which are matrix-binding by the in vitro test. Computer analysis of sequences of eight human MARs did not reveal any significant homologies with the EMBL Nucleotide Data Base entries as well as between MARs themselves. Eight MARs were assigned to individual positions on the chromosome 19 physical map. The library constructed can serve as a good source of MAR sequences for comparative analysis and classification and for further chromosome mapping of MARs as well.

The human CAS (cellular apoptosis susceptibility) gene mapping on chromosome 20q13 is amplified in BT474 breast cancer cells and part of aberrant chromosomes in breast and colon cancer cell lines

The CAS (cellular apoptosis susceptibility) gene is the human homolog of the yeast chromosome segregation gene CSE1. CAS may have a dual function in mammalian cells, one in apoptosis and another in cell proliferation. We have now mapped the CAS gene to chromosome 20q13. This region is known to harbor amplifications that correlate with aggressive breast cancer. Southern hybridizations with a CAS cDNA fragment and fluorescent in situ hybridization (FISH) with a P1 clone containing the CAS gene show elevated copy numbers in one leukemia, three of four colon, and in three of seven breast cancer cell lines. Elevated CAS copy number in CEM leukemia and COLO201 colon cancer cells was attributable to additional copies of chromosome 20. In SW480 and COLO205 colon cancer cells CAS is part of aberrant chromosomes containing large parts of 20q. In breast cancer cells CAS is also part of aberrant 20q chromosomes (MDA-MB-157 and UACC-812) or of additional 20q isochromosome in MDA-MB-134. In MDA-MB361 and BT-474 breast cancer cells CAS is separated from other markers centromeric and telomeric of CAS on 20q. MDA-MB 361 contains one additional copy of CAS, separated from the centromeric 20q control probe. BT-474 cells have up to 12 additional CAS copies that we separated from nearby telomeric and centromeric probes on 20q and that are translocated to abnormal chromosomes.

Chromosomal localization and expressed sequence tag generation of clones from a normalized human adult thymus cDNA library

Expressed sequence tags (ESTs) from 298 clones have been generated from a randomly primed, normalized human adult thymus cDNA library. We describe the chromosomal localization of 136 of these ESTs by PCR-based mapping to a human monochromosomal somatic cell hybrid panel. Data base similarities to known genes are also described. A subset (n = 18) of these randomly primed ESTs extended the sequence of ESTs from other tissues currently in dbEST. Of the nonrepetitive human adult thymus ESTs generated in this study, 237 (79.5%) have no similarity to current data base entries. This would suggest that our collection contains approximately 100 new coding regions from thymus tissue, a large proportion of which likely will represent the middle regions of genes. The mapped ESTs should prove useful as new gene-based markers for mapping and candidate gene hunting, particularly when anchored to a well-developed physical map of the human genome.

The Genexpress Index: a resource for gene discovery and the genic map of the human genome

Detailed analysis of a set of 18,698 sequences derived from both ends of 10,979 human skeletal muscle and brain cDNA clones defined 6676 functional families, characterized by their sequence signatures over 5750 distinct human gene transcripts. About half of these genes have been assigned to specific chromosomes utilizing 2733 eSTS markers, the polymerase chain reaction, and DNA from human-rodent somatic cell hybrids. Sequence and clone clustering and a functional classification together with comprehensive data base searches and annotations made it possible to develop extensive sequence and map cross-indexes, define electronic expression profiles, identify a new set of overlapping genes, and provide numerous new candidate genes for human pathologies.

Human chromosome-specific cDNA libraries: new tools for gene identification and genome annotation

To date, only a small percentage of human genes have been cloned and mapped. To facilitate more rapid gene mapping and disease gene isolation, chromosome 5-specific cDNA libraries have been constructed from five sources. DNA sequencing and regional mapping of 205 unique cDNAs indicates that 25 are from known chromosome 5 genes and 138 are from new chromosome 5 genes (a frequency of 79.5%). Sequence complexity estimates indicate that each library contains -20% of the approximately 5000 genes that are believed to reside on chromosome 5. This study more than doubles the number of genes mapped to chromosome 5 and describes an important new tool for disease gene isolation.

Gene-based sequence-tagged-sites (STSs) as the basis for a human gene map

Using our data set of 3,143 single pass sequences from human brain cDNA libraries, we have developed a strategy in which gene-based sequence-tagged-sites (STSs), derived from 3'untranslated regions of human cDNAs, are rapidly assigned to megabase-insert yeast artificial chromosomes and somatic cell hybrids to generate regional gene mapping data. Employing this approach, we have mapped 318 cDNAs, representing 308 human genes. Ninety-two of these mapped to regions implicated in human genetic diseases, identifying them as candidate genes. Extension of this strategy has the potential to result in virtually every human gene having, at its 3' end, its own associated STS, with each STS in turn specifying both a corresponding genomic clone and a specific regional location in the genome.

Regional assignment of 68 new human gene transcripts on chromosome 11

We have tested 80 expressed sequence-tagged site (eSTS) markers assigned to human chromosome 11 by the Genexpress program on a panel of somatic cell hybrids containing parts of this chromosome, characterized by cytogenetic data, reference markers, and with respect to the Généthon microsatellite genetic map. Sixty-eight new gene transcripts have been assigned to 25 subregions, one of which was newly defined by five of the eSTS markers. The markers are distributed on the short and long arms in agreement with their physical length. The genic map thus obtained has been integrated with the cytogenetic, genetic, and disease maps. Two eSTS markers have been further mapped with respect to a yeast artificial chromosome (YAC) contig close to the brain-derived neurotrophic factor (BDNF) gene and thus provide potential candidate genes for the mental retardation phenotype of WAGR (Wilms' tumor, aniridia, genitourinary abnormalities and mental retardation) syndrome. Altogether, the 68 new gene transcripts localized here represent more than a threefold increase in the number of unknown regionalized genes that could reveal potential candidate genes for the numerous orphan pathologies associated with chromosome 11.

Mapping human chromosomes

The construction of integrated maps at all levels of resolution will facilitate determination of the DNA sequence and, ultimately, the entire gene content of the human genome. In the past two years, the need for extensive frameworks on which to anchor the maps of the human chromosomes has been emphasized. The first framework has been provided following construction of the genetic map using microsatellite markers. This is now being united with extensive collections of expressed sequence tags and other landmarks using radiation hybrid mapping into higher resolution map. Rapid progress is also being made towards integrating these reagents through the construction of physical clone maps using yeast artificial chromosomes which provide near-complete cloned coverage of human chromosomes.

Development of a panel of monochromosomal somatic cell hybrids for rapid gene mapping

We have assembled a panel of monochromosomal somatic cell hybrids for use in gene mapping. DNA from each individual hybrid was used as a probe on normal human metaphases to identify the human chromosome and any fragments by reverse painting. To test the efficiency of the panel PCR amplification of DNA from the monochromosomal somatic cell hybrid panel was used in combination with human specific oligonucleotide primers to assign alpha-catenin (CTNNA1) and p21/WAF1 to chromosomes 5 and 6 respectively. These genes were localized further using hybrids containing specific translocations to 5q11-qter and 6p21 respectively. We also developed primers to enable us to assign 17 ESTs sequenced by the HGMP Resource Centre. The hybrid panel was developed with support of the UK HGMP and the DNA is available to all registered users.

Mapping of transcribed sequences on human chromosome 19

30 EST/STS have been mapped on human chromosome 19 using a highly specific hncDNA library as a source of transcribed sequences. In addition more than 50 sites constituting 19 families of closely related sequences containing at least one transcribed member each were mapped across the chromosome. Chromosome-19 specific hncDNA clones were hybridized to chromosome 19 cosmids that were previously assembled into contigs covering about 80% of Chr19. The hybridization results were verified by PCR. Such an approach to EST mapping provides information on possible locations of genes as transcribed units of genome and on location of repeated elements used for the priming the hncDNA synthesis. Mapped hncDNA sequences may serve as good starting points for the systematic sequencing of transcribed genomic regions.

Regional assignment by hybrid mapping of 36 expressed sequence tags (ESTs) on human chromosome 6

We have determined the regional chromosome assignment of 36 cDNAs from infant brain libraries by assessing the concordant segregation of PCR products using a human-rodent hybrid mapping panel that subdivides chromosome 6 into 15 regions. These mapped sequences serve as markers for the physical and expression maps of chromosome 6, as well as candidate genes for various disease loci. Sequence analysis has identified putative functions and motifs for some of these genes.

Codon usage and genome evolution

The rates and patterns of evolution at silent sites in codons reveal much about the basic features of molecular evolution. Recent increases in the amount of sequence data available for various species and more precise knowledge of the chromosomal locations of those sequences, coming in particular from genome projects, reveal that some features of molecular evolution vary around the genome.

Analysis of gene expression by tissue and developmental stage

High-throughput sequencing of cDNAs from multiple tissue- and stage-specific libraries is an efficient method for characterizing gene expression by tissue and developmental stage. When combined with functional information derived from the systematic study of transcription factors, signal transducers, and other regulatory molecules in model systems, data from expressed sequence tag projects provide an increasingly detailed picture of gene expression and its regulation. Understanding this picture will require the development of highly sophisticated databases to organize and correlate these data.

Fishing for complements: finding genes by direct selection

Deriving a saturated gene map of a complex genome is a daunting undertaking. By current methods, finding all the genes in even a single megabase of the human genome is technically difficult. Direct selection is a technique focussed upon the isolation of cDNAs encoded by such large genomic regions and involves hybridization-based selection and PCR methods. It is particularly useful in the positional cloning of loci associated with genetic disease and for rapidly searching large genomic regions for transcriptional units that are normally expressed at low levels. Direct selection can produce up to 100,000-fold enrichment of specific cDNAs, and allows simultaneous searches to be conducted on many complex tissues. The applications of this technique extend to many approaches that involve cDNA cloning, including isolating related genes from complex pools of cDNA.

A radiation hybrid map of 506 STS markers spanning human chromosome 11

We present a high resolution radiation hybrid map of human chromosome 11 using 506 sequence tagged sites (STSs) scored on a panel of 86 radiation hybrids. The 506 STSs fall into 299 unique positions (average resolution of about 480 kilobases (kb)) that span the whole chromosome. A subset of 260 STSs (143 positions) form a framework map that has a resolution of approximately 1 megabase between adjacent positions and is ordered with odds of at least 1,000:1. The centromere was clearly defined with pericentric markers unambiguously assigned to the short or long arm. The map contains most genes (125) and expressed sequence tags (26) currently assigned to chromosome 11 and more than half of the STSs are polymorphic microsatellite loci. These markers and the map can be used for high resolution physical and genetic mapping.

Towards identification of X-linked mental retardation genes: a proposal

Identification of X linked mental retardation (XLMR) genes that can only be broadly localised by linkage analysis will ultimately depend on systematic screening of many probands for mutations in many candidate genes. This would be more efficiently performed by analysis of mRNA (or illegitimate transcripts) by reverse transcriptase-polymerase chain reaction (RT-PCR). A scheme is proposed that associates standardized reporting of XLMR families, including small families that would not by themselves yield statistically significant linkage information, and deposit of a lymphoblastoid cell line for one proband of each family to an accessible repository.

Toward the complete genomic map and molecular pathology of human chromosome 4

The identification of disease genes via molecular DNA cloning has revolutionized human genetics and medicine. Both the candidate gene approach and positional cloning have been used successfully. The defects causing Huntington's disease, facioscapulohumeral muscular dystrophy, piebaldism, Hurler/Scheie syndrome, one form of autosomal recessive retinitis pigmentosa, and a second locus for autosomal dominant polycystic kidney disease have recently been localized to chromosome 4. In addition to the rapid progress in the cloning of the 203-megabase chromosome, the presence of more than 60 closely spaced microsatellites on this chromosome will undoubtedly lead to the localization of additional disease genes. In order to consider cloned genes as potential candidates for disorders assigned to chromosome 4, it is important to collect and order all genes with respect to their chromosomal localization. Analysis of cytogenetically visible interstitial and terminal deletions should also be helpful in defining new disease gene loci and in mapping novel genes. These data represent the status quo of the integrated molecular map for chromosome 4.

Bioinformatics

Computer databases, networks and software tools are essential materials and methods for biomedical research and are involved in almost every aspect of disease gene mapping and positional cloning. Public databases of DNA and protein sequences and genetic and physical map information are increasing rapidly in size and complexity and are also improving in quality, comprehensiveness, interoperability and access. A new generation of software tools for navigating through the biomedical literature has become available. Programs for sequence homology searching and genetic map construction have become more sophisticated, yet easier to use. Global computer networks are bringing state-of-the-art capabilities to all.

Towards cloning the familial breast-ovarian cancer gene on chromosome 17

The past year has seen a great deal of excitement in the field of breast cancer genetics. Since linkage of the familial breast-ovarian cancer gene (BRCA1) to chromosome 17, the critical region has been narrowed to 1.0-1.5 Mb by recombination studies, a detailed physical map has been constructed and much of the region has been cloned in yeast artificial chromosome, bacteriophage P1 and cosmid vectors. The focus now lies on identifying the genes housed within the BRCA1 region and scanning them for oncogenic mutations.

Isolation of genes from cloned DNA

During the past year, improvements in the physical and genetic maps of the human genome, in combination with more efficient methods to isolate genes from cloned DNA, have made an increasing impact on the identification of disease genes. Sequence analysis of genomic DNA and the random sequencing and mapping of cDNA clones is helping to integrate the transcript map with the developing physical and genetic maps.

Genomic sequence sampling: a strategy for high resolution sequence-based physical mapping of complex genomes

We present a simple and efficient method for constructing high resolution physical maps of large regions of genomic DNA based upon sampled sequencing. The physical map is constructed by ordering high density cosmid contigs and determining a sequence fragment from each end of every clone. The resulting map, which contains 30-50% of the complete DNA sequence, allows the identification of many genes and makes possible PCR amplification of virtually any part of the genome. We apply this strategy to the automated analysis of the genome of the primitive eukaryote Giardia lamblia and evaluate its applicability to the physical mapping and DNA sequencing of the human genome.

Identification of new genes by systematic analysis of cDNAs and database construction

The large-scale collection of partial cDNA sequences is becoming a powerful tool in biology. Similarity or motif searches in DNA databases using these partial cDNA sequences have facilitated the discovery of new genes of interest. By collecting and registering large numbers of partial sequences with a well designed non-biased cDNA library, an expression profile of active genes in a particular tissue can be obtained. Tissue-specific or stage-specific genes can be discovered by comparing the profiles from different tissues or from a tissue at different stages of development, respectively. The compilation of such expression profiles enables genes to be mapped to the tissue(s) where they are actively transcribed. The large-scale collation of gene sequences actively expressed in the body into databases complements efforts directed towards the structural analysis of the genome, with the ultimate aim of decoding all the genetic information carried in the human genome. This cDNA strategy is also being widely applied to organisms other than man.