Efficiency and specificity of gene isolation by exon amplification

Exon amplification is an increasingly popular approach to the identification of transcribed sequences and will complement other strategies to isolate genes. We have used this system to amplify candidate exons from 32 cosmids, including 8 cosmids which span a well characterized 185-kb region of the human major histocompatibility class II region on Chromosome (Chr) 6. We have examined the efficiency, specificity, and reproducibility of the system in isolating exons from genes known to be present on particular cosmids and have determined the nature and frequency of artefact amplifications in routine cosmid screening. We were able to clone at least one exon from 88% (7/8) of all known genes tested (including exons which are differentially spliced) and obtained artefacts from 19% (6/32) of the cosmids tested. Such artefacts generally arise from the amplification of noncoding sequences flanked by regions with high homology to acceptor and donor splice junctions. We show that the exon amplification procedure can be used successfully with a wide variety of cosmids which have different numbers of genes and gene structures and describe several approaches to the characterization of novel exons cloned in this study.     

Studies on locus expansion, library representation, and chromosome walking using an efficient method to screen cosmid libraries

We have developed an efficient screening method to search for clones in cosmid libraries prepared from human genomic DNA. Genomic, cDNA, and cosmid probes have been used to isolate homologous cosmids from human chromosomes 7, 10, 16, 17 and X as part of a search for polymorphic nucleotide sequences. This method has been successfully applied to chromosome walking experiments at the interstitial retinol-binding protein locus on chromosome 10, and may be a useful tool for investigating representation of cloned sequences in cosmid libraries. Our library was prepared in the vector c2RB (Bates and Swift, 1983), but the method is applicable to any cosmid cloning system in which the inserted DNA can be separated from the vector by restriction enzyme digestion. A cosmid library containing five human genome equivalents can be rapidly screened using three to four Southern hybridization filters. This results in substantial labor saving, particularly when screening genomes of high complexity with many different probes. Another advantage of the system is that it allows for the long-term storage of the cosmids so that they can be screened whenever necessary. As a consequence, cosmid screening can be made a routine laboratory procedure.     

Screening cosmid libraries with oligonucleotides corresponding to splice-site consensus sequences

To facilitate the identification of genes within genomic DNA, we have developed a method based on the use of short oligonucleotides designed from the consensus sequences of splice sites. We describe here the hybridization and washing conditions under which such oligonucleotides can be used to screen cosmid libraries. We confirm the presence of genes within cosmids identified by screening with one oligonucleotide by showing that DNA isolated from such cosmids will hybridize to another splice-site oligonucleotide.     

Rapid isolation of cosmids from defined subregions by differential Alu-PCR hybridization on chromosome 22-specific library.

A method based on the differential screening of a chromosome-specific cosmid library with amplified inter-Alu sequences obtained from a set of somatic cell hybrids has been developed to target the isolation of probes from predefined subchromosomal regions. As a model system, we have used a chromosome 22-specific cosmid library and four cell hybrids containing different parts of this chromosome. The procedure has identified cosmids that demonstrate differential hybridization signals with Alu-PCR products from these cell hybrids. We show, by in situ hybridization or individual mapping, that their hybridization pattern is indicative of their sublocalization on chromosome 22, thus resulting in a large enrichment factor for the isolation of probes from specific small chromosome subregions. Depending on the local Alu-sequence density, from 3 to 10 independent loci per megabase of genome can thus be identified.     

A Genetic Linkage Map of the Male Goat Genome

This paper presents a first genetic linkage map of the goat genome. Primers derived from the flanking sequences of 612 bovine, ovine and goat microsatellite markers were gathered and tested for amplification with goat DNA under standardized PCR conditions. This screen made it possible to choose a set of 55 polymorphic markers that can be used in the three species and to define a panel of 223 microsatellites suitable for the goat. Twelve half-sib paternal goat families were then used to build a linkage map of the goat genome. The linkage analysis made it possible to construct a meiotic map covering 2300 cM, i.e., >80% of the total estimated length of the goat genome. Moreover, eight cosmids containing microsatellites were mapped by fluorescence in situ hybridization in goat and sheep. Together with 11 microsatellite-containing cosmids previously mapped in cattle (and supposing conservation of the banding pattern between this species and the goat) and data from the sheep map, these results made the orientation of 15 linkage groups possible. Furthermore, 12 coding sequences were mapped either genetically or physically, providing useful data for comparative mapping.     

Isolation of A/D and C genome specific dispersed and clustered repetitive DNA sequences from Avena sativa.

DNA gel-blot and in situ hybridization with genome-specific repeated sequences have proven to be valuable tools in analyzing genome structure and relationships in species with complex allopolyploid genomes such as hexaploid oat (Avena sativa L., 2n = 6x = 42; AACCDD genome). In this report, we describe a systematic approach for isolating genome-, chromosome-, and region-specific repeated and low-copy DNA sequences from oat that can presumably be applied to any complex genome species. Genome-specific DNA sequences were first identified in a random set of A. sativa genomic DNA cosmid clones by gel-blot hybridization using labeled genomic DNA from different Avena species. Because no repetitive sequences were identified that could distinguish between the A and D gneomes, sequences specific to these two genomes are refereed to as A/D genome specific. A/D or C genome specific DNA subfragments were used as screening probes to identify additional genome-specific cosmid clones in the A. sativa genomic library. We identified clustered and dispersed repetitive DNA elements for the A/D and C genomes that could be used as cytogenetic markers for discrimination of the various oat chromosomes. Some analyzed cosmids appeared to be composed entirely of genome-specific elements, whereas others represented regions with genome- and non-specific repeated sequences with interspersed low-copy DNA sequences. Thus, genome-specific hybridization analysis of restriction digests of random and selected A. sativa cosmids also provides insight into the sequence organization of the oat genome.     

Physical mapping of sequences homologous to an endogenous retrovirus LTR on human chromosome 19

The human genome contains multiple copies of sequences related to the HERV-K family of endogenous retroviruses, homologous to the B-type mouse mammary tumour virus. A DNA fragment closely resembling an HERV-K long tandem repeat (LTR) was detected in a library of hncDNA clones enriched for sequences from human chromosome 19. Sites showing homology to the sequence of this fragment have been identified on human chromosome 19 by hybridization to previously mapped chromosome 19 cosmids. Thus the distribution of LTR sequences on a specific human chromosome has been mapped for the first time. We estimate the total number of such sites on human chromosome 19 to be at least 110. Many of these sites are located in the vicinity of known genes. The precise localizations (to specific cosmids) of LTR-homologous sequences on chromosome 19 can serve as a reference source and will automatically provide further insight into LTR-gene relationships as new genes are mapped onto the chromosome.     

Isolation of region-specific cosmids from chromosome 5 by hybridization with microdissection clones.

A method is described for the isolation of chromosome region specific cosmids. The 5q35 region of the long arm of human chromosome 5 was microdissected, digested with MboI, ligated to oligonucleotide adaptors, amplified by the polymerase chain reaction and cloned into a plasmid vector. Inserts which did not contain highly repetitive sequences were used to screen a chromosome 5 cosmid library by direct hybridization. There were 33 positive cosmid clones identified with 4 microclones. Individual cosmid clones were biotinylated and used as probes for fluorescence in situ hybridization to metaphase chromosomes. Of the 33 cosmids that were mapped, 29 localized to q35 and 4 to q34, demonstrating the specificity of the microdissection library and the cosmids.     

Mapping of 50 cosmid clones isolated from a flow-sorted human X chromosome library by fluorescence in situ hybridization.

Fifty cosmids have been mapped to metaphase chromosomes by fluorescence in situ hybridization under conditions that suppress signals from repetitive DNA sequences. The cosmid clones were isolated from a flow-sorted human X chromosome library. Thirty-eight of the clones were localized to chromosome X and 12 to autosomes such as chromosomes 3, 7, 8, 14, and 17. Although most of the cosmids mapped to the X chromosome appeared to be scattered along both the short and long arms, 10 cosmids were localized to the centromeric region of the chromosome. Southern blot analysis revealed that only two of these clones hybridized to probe pXBR-1, which detects the DXZ1 locus. In addition, 4 out of 5 cosmids mapped on chromosome 8 also localized on the centromeric region. While localization of X-specific cosmids will facilitate the physical mapping of the human X chromosome, cosmids mapped to the centromeric regions of chromosomes X and 8 should be especially useful for studying the structure and organization of these regions.     

High-resolution localization of 69 potential human zinc finger protein genes: a number are clustered.

In this study, we describe the identification and partial characterization of 101 potential human zinc finger protein genes (ZnFPs). These sequences were isolated by hybridization of cosmids, obtained from mouse-human cell lines enriched for chromosome 11p, with an oligonucleotide specific for the "link" sequence between contiguous zinc fingers. Sixty-nine of these cosmids were regionally localized to human prometaphase chromosomes by in situ hybridization. The localization of these cosmids suggests that a number of finger protein genes occur in linked clusters. Their assignment to chromosomes 3p, 11p, 19p, 19qter, 20p, and 21q makes them valuable as markers or "candidate" genes for diseases associated with these chromosome regions.     

Use of a cDNA library for studies on evolution and developmental expression of the chorion multigene families

A cDNA library has been constructed from an RNA preparation highly enriched in silkmoth chorion mRNAs. Many distinct clones have been identified from this library using a stepwise procedure: scoring for infrequent hexanucleotide restriction enzyme recognition sequences; detailed characterization with restriction enzymes that recognize relatively frequent tetranucleotide sequences; probing the arrangement of the corresponding sequences in chromosomal DNA by the Southern procedure; and detailed cross-hybridization analysis. Unique clones, as well as two classes of distinct but related clones, were revealed by hybridization. The cross-hybridization analysis was greatly facilitated by a newly developed, semiquantitative dot hybridization procedure. The same procedure made it feasible to conveniently estimate the relative abundance of several different sequences in an mRNA mixture. Cloned sequences which scored as relatively abundant in total chorion mRNA were tested with stage-specific chorion mRNA at a very stringent criterion of hybridization. They were thus characterized as early, middle or late sequences with respect to development. The characterized cDNA clones can now be used as probes for studying the evolution, chromosomal organization and regulated developmental expression of the chorion multigene families.     

Four restriction fragment length polymorphisms revealed by probes from a single cosmid map to human chromosome 12q

Summary Human gene mapping would be greatly facilitated if marker loci with sufficient polymorphism information content were generally available. As a source of such markers, we have used cosmids from a human genomic library. We have used a rapid method for screening random cosmids to identify those homologous to genomic regions especially rich in restriction fragment length polymophisms (Litt and White 1985). This method allows whole cosmids to be used as probes against Southern transfers of genomic DNA; regions of cosmid probes homologous to repeated genomic sequences are rendered unable to anneal with Southern transfers by prerendered of the probes with a vast excess of non-radioactive genomic DNA. From one cosmid (C1-11) identified by this procedure, we have isolated four single-copy probes, each of which identifies a polymorphic locus. Despite the existence of some linkage disequilibrium in this system, the polymorthism information content was computed as 0.73. Using a somatic cell hybrid mapping panel, we have mapped probes from cosmid 1–11 to human chromosome 12q. Additionally, in situ hybridization of the whole cosmid to metaphase spreads allowed more precise assignment of the locus to the region 12cenq13. The locus revealed by probes from cosmid 1–11 has been designated D12S6.     

Direct selection of DNA sequences conserved between species.

An essential requirement in the analysis of genomes is the identification of functionally important sequence elements, which are often evolutionarily conserved. We describe here the development of a novel procedure for the selective isolation of conserved sequences which is based on hybridization of PCR-amplifiable DNA fragments from the whole genome of one species to biotinylated DNA from a genomic region of another species. The interspecies DNA hybrids are immobilized and the PCR-amplifiable DNA fragments are eluted, amplified and after further hybridization-amplification rounds cloned. This method was used for the generation of sublibraries of conserved sequences from mouse and pig DNA from regions corresponding to cosmids from the human Xq28 region. Mouse and pig homologs of sequences containing exons of known human genes, as well as exons from novel genes have been identified.     

Mapping of human chromosome Xq28 by two-color fluorescence in situ hybridization of DNA sequences to interphase cell nuclei.

We have used the proximity of probe hybridization sites in interphase chromatin to derive the order of DNA sequences in a 2-3-Mbp region of human chromosome Xq28. The map generated bridges the results of genetic and pulsed-field gel electrophoresis mapping to produce a more complete map of Xq28 than possible with either of these other techniques alone. Two-color fluorescence in situ hybridization (FISH) was used to detect the positions of two or more probes in G1 male interphase nuclei. We show that cosmids that are 50 kbp to 2-3 Mbp apart can be ordered rapidly with two alternative approaches: (1) by comparing the average measured distance between two probes and (2) simply by scoring the order of red and green fluorescent dots after detection of three or more probes with two fluorochromes. The validity of these approaches is demonstrated using five cosmids from a region spanning approximately 800 kbp that includes the factor VIII (F8), glucose-6-phosphate dehydrogenase (G6PD), and color-vision pigment (CV) genes. The cosmid map derived from interphase mapping is consistent with the map determined by restriction-fragment analysis. The two interphase mapping approaches were then used (1) to orient the F8/CV cluster relative to two markers, c1A1 and st14c, which we show by metaphase mapping to be proximal to the F8/CV cluster, (2) to position st14c (DXS52) between c1A1 and F8, and (3) to orient the CV gene cluster relative to G6PD by using two CV-flanking cosmids, 18b41 and fr7. The probe order in Xq28 derived from interphase proximity is cen-c1A1-st14c-5'F8 (p624-p542-p625)-G6PD-18b41-3' green-green-red-fr7-tel. We also show that, to determine their order by using metaphase chromosomes, sequences must be at least 1 Mbp apart, an order of magnitude greater than required in interphase chromatin. The data show that FISH mapping is a simple way to order sequences separated by greater than or equal to 50 kbp for the construction of long-range maps of mammalian genomes.     

Pig microsatellites isolated from cosmids revealing polymorphism and localized on chromosomes

One of the most widely studied simple sequences in the mammalian genome is the (TG)_n dinucleotide sequence. Because these microsatellites are highly polymorphic, we chose to study microsatellites from cosmids to provide genetic markers for the porcine genome. After screening a porcine cosmid library with a (CA)₁₀ probe, 20 cosmids containing microsatellites were subcloned and 17 microsatellites identified by sequencing. Oligonucleotide primers flanking the repeat were designed for seven (TG)_n microsatellites with n > 14. These seven microsatellites revealed polymorphism and were regionally assigned to chromosomes by fluorescent in situ hybridization of initial cosmids. These seven loci will be useful for both the construction of the genetic map and as landmark loci on the physical map of the porcine genome.     

Mitochondrial DNA transfer to the nucleus generates extensive insertion site variation in maize

Mitochondrial DNA (mtDNA) insertions into nuclear chromosomes have been documented in a number of eukaryotes. We used fluorescence in situ hybridization (FISH) to examine the variation of mtDNA insertions in maize. Twenty overlapping cosmids, representing the 570-kb maize mitochondrial genome, were individually labeled and hybridized to root tip metaphase chromosomes from the B73 inbred line. A minimum of 15 mtDNA insertion sites on nine chromosomes were detectable using this method. One site near the centromere on chromosome arm 9L was identified by a majority of the cosmids. To examine variation in nuclear mitochondrial DNA sequences (NUMTs), a mixture of labeled cosmids was applied to chromosome spreads of ten diverse inbred lines: A188, A632, B37, B73, BMS, KYS, Mo17, Oh43, W22, and W23. The number of detectable NUMTs varied dramatically among the lines. None of the tested inbred lines other than B73 showed the strong hybridization signal on 9L, suggesting that there is a recent mtDNA insertion at this site in B73. Different sources of B73 and W23 were examined for NUMT variation within inbred lines. Differences were detectable, suggesting either that mtDNA is being incorporated or lost from the maize nuclear genome continuously. The results indicate that mtDNA insertions represent a major source of nuclear chromosomal variation.     

High-resolution physical mapping in Arabidopsis thaliana and tomato by fluorescence in situ hybridization to extended DNA fibres

A technique to detect DNA sequences on extended DNA fibres (EDF) prepared from interphase nuclei from tomato (Lycopersicon esculentum) and Arabidopsis thaliana leaves by fluorescence in situ hybridization (FISH) is described. Three nuclear lysis procedures have been tested for their ability to decondense chromatin and to generate highly extended intact DNA fibres on microscopic slides. DNA probes of various sizes have been used in FISH experiments to EDFs to establish the resolution and sensitivity of the technique. The fluorescent signals of a 5S rDNA probe hybridized to tomato EDFs revealed continuous strings of about 200 µm, that corresponded to a molecular size of about 660 kb. In A. thaliana, a contig of three cosmids spanning a genomic region with a total length of about 89 kb was analysed. By means of multi-colour hybridization the physical positions of the cosmids were visualized as red and green fluorescence strings with overlapping regions in yellow. Comparison of the length of the fluorescent signals with the molecular data revealed a stretching degree of the DNA fibres at 3.27 kb µm^?1, which is close to the Watson-Crick DNA length estimate of 2.9 kb µm^?1. Other experiments on small size molecular probes with both lambda clones (13.5–17 kb insert sizes) and plasmids (4.2 and 5 kb) in a contig of A. thaliana, and the 5S rDNA region in tomato showed close agreement with molecular data. The lower limit of the detection, which was established in a hybridization experiment with two DNA probes from the 45S ribosomal gene on extended fibres of tomato, was about 0.7 kb. Consistent patterns of alternating fluorescent red and green spots were obtained reflecting the tandemly repeated arrangement of the 18S and 25S ribosomal sequences. On the basis of the microscopic distance between these hybridization spots the size of the ribosomal unit was estimated at 8.2 kb. This implies a drastic improvement of high-resolution physical mapping of DNA sequences by FISH on plant DNA.     

A Physical Map of the X Chromosome of Drosophila Melanogaster: Cosmid Contigs and Sequence Tagged Sites

A physical map of the euchromatic X chromosome of Drosophila melanogaster has been constructed by assembling contiguous arrays of cosmids that were selected by screening a library with DNA isolated from microamplified chromosomal divisions. This map, consisting of 893 cosmids, covers ~64% of the euchromatic part of the chromosome. In addition, 568 sequence tagged sites (STS), in aggregate representing 120 kb of sequenced DNA, were derived from selected cosmids. Most of these STSs, spaced at an average distance of ~35 kb along the euchromatic region of the chromosome, represent DNA tags that can be used as entry points to the fruitfly genome. Furthermore, 42 genes have been placed on the physical map, either through the hybridization of specific probes to the cosmids or through the fact that they were represented among the STSs. These provide a link between the physical and the genetic maps of D. melanogaster. Nine novel genes have been tentatively identified in Drosophila on the basis of matches between STS sequences and sequences from other species.     

Evaluation of a cosmid contig physical map of human chromosome 16.

A cosmid contig physical map of human chromosome 16 has been developed by repetitive sequence finger-printing of approximately 4000 cosmid clones obtained from a chromosome 16-specific cosmid library. The arrangement of clones in contigs is determined by (1) estimating cosmid length and determining the likelihoods for all possible pairwise clone overlaps, using the fingerprint data, and (2) using an optimization technique to fit contig maps to these estimates. Two important questions concerning this contig map are how much of chromosome 16 is covered and how accurate are the assembled contigs. Both questions can be addressed by hybridization of single-copy sequence probes to gridded arrays of the cosmids. All of the fingerprinted clones have been arrayed on nylon membranes so that any region of interest can be identified by hybridization. The hybridization experiments indicate that approximately 84% of the euchromatic arms of chromosome 16 are covered by contigs and singleton cosmids. Both grid hybridization (26 contigs) and pulsed-field gel electrophoresis experiments (11 contigs) confirmed the assembled contigs, indicating that false positive overlaps occur infrequently in the present map. Furthermore, regional localization of 93 contigs and singleton cosmids to a somatic cell hybrid mapping panel indicates that there is no bias in the coverage of the euchromatic arms.