Completion of the detailed restriction map of the E. coli genome by the isolation of overlapping cosmid clones.

Ordered sets of cosmids derived from E. coli K-12 803 overlap the 6 remaining gaps left in the physical map of strain W3110. We present detailed restriction maps of the gaps and surrounding regions, thus providing a comparison of about 30% of the genome of the two E. coli strains. Our analysis shows that there is a high degree of homology between the strains, with only occasional restriction fragment differences. However, the large inversion occurring between rrnD (72.1') and rrnE (90.4') in strain W3110 is absent in strain 803. Instead, a new inversion and adjacent deletion near argF is present in strain 803. The distribution of cosmid clones at, and adjacent to, the gaps shows that all gaps except one were difficult to clone in both lambda and cosmid clones. A low copy number cosmid vector, pOU61cos, developed previously, was essential for cloning 3 of the 8 gaps.     

Identification and purification of overlapping cosmid clones of the region Xq24-qter of human X chromosome using HPLC.

The assembly of a large physical map of genomes requires simultaneous analysis of many cosmid clones for overlapping regions. The search for overlapping regions may be achieved by various means. High-performance liquid chromatography (HPLC) provides an alternative to gel electrophoresis since microgram amounts of each DNA fragment may be collected into individual test tubes for further analysis. HPLC has been used to identify overlapping cosmid clones from a pool of cosmid DNA containing the terminal portion of the long arm of the human X chromosome (Xq24-qter). Among 400 cosmids analyzed, 3 were shown to overlap.     

Cosmid linking clones localized to the long arm of human chromosome 11.

Molecular probes that contain DNA flanking CpG-rich restriction sites are extremely valuable in the construction of physical maps of chromosomes and in the identification of genes associated with hypomethylated HTF (HpaII tiny fragment) islands. We describe a new approach to the isolation and characterization of linking clones in arrayed chromosome-specific cosmid libraries through the large-scale semiautomated restriction mapping of cosmid clones. We utilized a cosmid library representing human chromosome 11q12-11qter and carried out automated restriction enzyme analysis, followed by regional localization to chromosome 11q using high-resolution in situ suppression hybridization. Using this approach, 165 cosmid linking clones containing one or more NotI, BssHII, SfiI, or SacII sites were identified among 960 chromosome-specific cosmids. Furthermore, this analysis allowed clones containing a single site to be distinguished from those containing clusters of two or more rare sites. This analysis demonstrated that more than 75% of cosmids containing a rare restriction site also contained a second rare restriction site, suggesting a high degree of CpG-rich restriction site clustering. Thirty chromosome 11q-specific cosmids containing rare CpG-rich restriction sites were regionally localized by high-resolution fluorescence in situ suppression hybridization, demonstrating that all of the CpG-rich sites detected by this method were located in bands 11q13 and 11q23. In addition, the distribution of (CA)n repetitive sequences was determined by hybridization of the arrayed cosmid library with oligonucleotide probes, confirming a random distribution of microsatellites among CpG-rich cosmid clones. This set of reagent cosmid clones will be useful for physical linking of large restriction fragments detected by pulsed-field gel electrophoresis and will provide a new and highly efficient approach to the construction of a physical map of human chromosome 11q.     

A yeast artificial chromosome contig encompassing the cystic fibrosis locus.

The gene responsible for cystic fibrosis (CF) has recently been identified. Coding sequence for the cystic fibrosis transmembrane conductance regulator (CFTR) spans at least 230 kb of the human genome. Although all 27 exons of the gene are represented in cosmid or bacteriophage clones, there are still several gaps in the physical map of this region. It should be possible to complete the map and to clone the entire CFTR gene in a single fragment of DNA using a yeast artificial chromosome (YAC) vector. Herein we describe the construction and physical mapping of a 1.5-Mb YAC contig which encompasses D7S8 (J3.11) and D7S23 (KM19), two genetic loci flanking the CF locus. One of the clones in the contig, 37AB12, contains a 310-kb YAC which includes the entire CFTR gene and flanking sequence in both the 5' and 3' directions.     

Chromosome 16-specific repetitive DNA sequences that map to chromosomal regions known to undergo breakage/rearrangement in leukemia cells.

Human chromosome 16-specific low-abundance repetitive (CH16LAR) DNA sequences have been identified during the course of constructing a physical map of this chromosome. At least three CH16LAR sequences exist and they are interspersed, in small clusters, over four regions that constitute more than 5% of the chromosome. CH16LAR sequences were observed in one unusually large cosmid contig (number 55), where the ordering of clones was difficult because these sequences led to false overlaps between noncontiguous clones. Contig 55 contains 78 clones, or approximately 2% of all the clones contained within the present cosmid contig physical map. Fluorescent in situ hybridization of multiple clones, including cosmid and YAC contig 55 clones, mapped the four CH16LAR-rich regions to bands p13, p12, p11, and q22. These regions are of biological interest since the pericentric inversion and the interhomologue translocation breakpoints commonly found in acute nonlymphocytic leukemia (ANLL) subtype M4 fall within these bands. Sequence analysis of a 2.2-kb HindIII fragment from a cosmid containing a CH16LAR sequence indicated that one of the CH16LAR elements is similar to a minisatellite sequence in that the core repeat is only 40 bp in length. Additional characterization of other repetitive elements is in progress.     

Physical map of the 3'' region of the human immunoglobulin heavy chain locus: clustering of autoantibody-related variable segments in one haplotype.

We have constructed the physical map of the 3' region of the human immunoglobulin heavy chain variable region (VH) genes. DNA segments extending to 200 kb upstream of the JH segment were isolated in two YAC clones. Five VH segments were identified in this region in the 5' to 3' order, V(II-5), V(IV-4), V(I-3), V(I-2), and V(VI-1) segments which were all structurally normal and orientated in the same direction as the JH segments. From DNA of a different cell line we have isolated a cosmid contig containing the same DNA region which has extraordinary polymorphism. The YAC and cosmid DNAs were called haplotypes A and B, respectively. Haplotype B contained an additional VH-I segment (V(I-4.1b)) between the V(II-5) and V(IV-4) segments. V(I-4.1b) segment is almost identical to a previously published VH sequence encoding a rheumatoid factor. Another VH segment in the B haplotype (V(I-3b)) corresponding to the V(I-3) segment also showed 99.7% nucleotide sequence homology with an anti-DNA autoantibody VH sequence. However, none of the VH sequences in haplotype A showed such strong homology with autoantibody VH sequences. The results suggest that VH haplotypes may have linkage with autoantibody production.     

High-Resolution Physical Map of the Immunoglobulin λ Variant Gene Cluster Assembled by Quantitative DNA Fiber Mapping

Quantitative DNA fiber mapping (QDFM) allows rapid construction of near-kilobase-resolution physical maps by hybridizing specific probes to individual stretched DNA molecules. We evaluated the utility of QDFM for the large-scale physical mapping of a rather unstable, repeat-rich 850-kb region encompassing the immunoglobulin λ variant (IGLV) gene segments. We mapped a minimal tiling path composed of 32 cosmid clones to three partially overlapping yeast artificial chromosome (YAC) clones and determined the physical size of each clone, the extent of overlap between clones, and contig orientation, as well as the sizes of gaps between adjacent contigs. Regions of germline DNA for which we had no YAC coverage were characterized by cosmid to cosmid hybridizations. Compared to other methods commonly used for physical map assembly, QDFM is a rapid, versatile technique delivering unambiguous data necessary for map closure and preparation of sequence-ready minimal tiling paths.     

Mitochondrial DNA of Marchantia polymorpha as a single circular form with no incorporation of foreign DNA.

A cosmid library and physical maps of mitochondrial DNA (mtDNA) from a liverwort, Marchantia polymorpha, were constructed using the cosmid clones. Electrophoresis profile and the physical maps indicated that the liverwort mtDNA was approximately 183 kb long, the smallest among plant mtDNAs, and that it consisted of a single circular molecule. Southern hybridization analysis showed that genes typical to the mitochondrial genome existed in a single copy, and also that there was no incorporation of chloroplast DNA fragments into the mitochondrial genome.     

Long-range chromosomal mapping of the carcinoembryonic antigen (CEA) gene family cluster

A long-range physical map of the carcinoembryonic antigen (CEA) gene family cluster, which is located on the long arm of chromosome 19, has been constructed. This was achieved by hybridization analysis of large DNA fragments separated by pulse-field gel electrophoresis and of DNA from human/rodent somatic cell hybrids, as well as the assembly of ordered sets of cosmids for this gene region into contigs. The different approaches yielded very similar results and indicate that the entire gene family is contained within a region located at position 19q13.1-q13.2 between the CYP2A and the D19S15/D19S8 markers. The physical linkage of nine genes belonging to the CEA subgroup and their location with respect to the pregnancy-specific glycoprotein (PSG) subgroup genes have been determined, and the latter are located closer to the telomere. From large groups of ordered cosmid clones, the identity of all known CEA subgroup genes has been confirmed either by hybridization using gene-specific probes or by DNA sequencing. These studies have identified a new member of the CEA subgroup (CGM8), which probably represents a pseudogene due to the existence of two stop codons, one in the leader and one in the N-terminal domain exons. The gene order and orientation, which were determined by hybridization with probes from the 5' and 3' regions of the genes, are as follows: cen/3'-CGM7-5'/3'-CGM2-5'/5'-CEA-3'/5'-NCA-3'/5'-CGM1- 3'/3'-BGP-5'/3'- CGM9-5'/3'-CGM6-5'/5'-CGM8-3'/PSGcluster/qter.     

Chromosome-specific recombinant DNA libraries from the fungus Aspergillus nidulans.

Development of physical genomic maps is facilitated by identification of overlapping recombinant DNA clones containing long chromosomal DNA inserts. To simplify the analysis required to determine which clones in a genomic library overlap one another, we partitioned Aspergillus nidulans cosmid libraries into chromosome-specific subcollections. The eight A. nidulans chromosomes were resolved by pulsed field gel electrophoresis and hybridized to filter replicas of cosmid libraries. The subcollections obtained appeared to be representative of the chromosomes based on the correspondence between subcollection size and chromosome length. A sufficient number of clones was obtained in each chromosome-specific subcollection to predict the overlap and assembly of individual clones into a limited number of contiguous regions. This approach should be applicable to many organisms whose genomes can be resolved by pulsed field gel electrophoresis.     

DNA fiber mapping techniques for the assembly of high-resolution physical maps.

High-resolution physical maps are indispensable for directed sequencing projects or the finishing stages of shotgun sequencing projects. These maps are also critical for the positional cloning of disease genes and genetic elements that regulate gene expression. Typically, physical maps are based on ordered sets of large insert DNA clones from cosmid, P1/PAC/BAC, or yeast artificial chromosome (YAC) libraries. Recent technical developments provide detailed information about overlaps or gaps between clones and precisely locate the position of sequence tagged sites or expressed sequences, and thus support efforts to determine the complete sequence of the human genome and model organisms. Assembly of physical maps is greatly facilitated by hybridization of non-isotopically labeled DNA probes onto DNA molecules that were released from interphase cell nuclei or recombinant DNA clones, stretched to some extent and then immobilized on a solid support. The bound DNA, collectively called "DNA fibers," may consist of single DNA molecules in some experiments or bundles of chromatin fibers in others. Once released from the interphase nuclei, the DNA fibers become more accessible to probes and detection reagents. Hybridization efficiency is therefore increased, allowing the detection of DNA targets as small as a few hundred base pairs. This review summarizes different approaches to DNA fiber mapping and discusses the detection sensitivity and mapping accuracy as well as recent achievements in mapping expressed sequence tags and DNA replication sites.     

Ig VH, DH, and JH germ-line gene segments linked by overlapping cosmid clones of rabbit DNA

Overlapping cosmid clones of rabbit germ-line DNA containing VH, DH and JH gene segments were isolated. The map of this cluster of cosmid clones indicated that the rabbit VH and JH regions were separated by 63 kb. Hybridization of Southern blots of these cosmid clones with two different DH segment probes identified a total of six DH segments within the region between the VH and JH regions. The nucleotide sequences of the JH region and one of the DH segments have been determined. The DH segment has conserved heptamer and nonamer sequences separated by 12 and 11 bp at the 3' and 5' sides, respectively, of the coding region and hence, appears to be a functional gene. The nucleotide sequence of the JH region revealed four functional JH gene segments and one JH pseudogene. Inasmuch as the JH region had previously been linked by contiguous overlapping clones with C mu, C gamma, C epsilon, and one C alpha gene, this VH-DH-JH cluster and the clones containing the Ig H chain C region genes represent 190 kb of contiguous germ-line DNA of the Ig H chain locus.     

Direct cloning of a long restriction fragment aided with a jumping clone.

Long-range physical mapping with rare-cutting restriction enzymes (rare cutters) is an important step for structural analysis of complex genomes. Combination of two types of DNA clones bearing the rare-cutter sites, linking clones and jumping clones (Fig. 1a), facilitates the physical mapping [Poustka et al., Nature 325 (1987) 353-355]. A step followed by the physical mapping is the cloning of the large (rare-cutter-generated) restriction fragment of interest. For facilitating this step, we devised a method to directly clone a long restriction fragment without constructing the whole genomic DNA library using the jumping clone as starting material. The short DNA segments of a jumping clone, which are derived from the 5' and 3' terminal regions of the large restriction fragment, are inserted into the yeast artificial chromosome plasmid (pYAC) vector, and then converted into single strands with T7 gene 6-encoded 5'----3' exonuclease. The total genomic DNA digested with the restriction enzyme is also treated with the exonuclease to convert the terminal regions of the restriction fragments into single strands. In the resulting products, only the fragment corresponding to the jumping clone can form hybrids with the just-mentioned, single-stranded DNAs, which are connected to the pYAC, and only this fragment is cloned in yeast. We describe the protocol of this method with Escherichia coli DNA as a model experiment. Judging from the cloning efficiency, this method could be applied to cloning single-copy regions of the human genome, provided a jumping clone is available. The instability of inserts in the pYAC vector is also discussed.     

Molecular cloning of lin-29, a heterochronic gene required for the differentiation of hypodermal cells and the cessation of molting in C.elegans.

The lin-29 gene product of C.elegans activates a temporal developmental switch for hypodermal cells. Loss-of-function lin-29 mutations result in worms that fail to execute a stage-specific pattern of hypodermal differentiation that includes exist from the cell cycle, repression of larval cuticle genes, activation of adult cuticle genes, and the cessation of molting. Combined genetic and physical mapping of restriction fragment length polymorphisms (RFLPs) was used to identify the lin-29 locus. A probe from the insertion site of a Tc1 (maP1), closely linked and to the left of lin-29 on the genetic map, was used to identify a large set of overlapping cosmid, lambda and yeast artificial chromosome (YAC) clones assembled as part of the C.elegans physical mapping project. Radiolabeled DNA from one YAC clone identified two distinct allele-specific alterations that cosegregated with the lin-29 mutant phenotype in lin-29 intragenic recombinants. lin-29 sequences were severely under-represented in all cosmid and lambda libraries tested, but were readily cloned in a YAC vector, suggesting that the lin-29 region contains sequences incompatible with standard prokaryotic cloning techniques.     

Organization of a Chinese hamster ovary dihydrofolate reductase gene identified by phenotypic rescue.

We have constructed a genomic DNA library from a methotrexate-resistant Chinese hamster ovary cell line (CHOC 400) in the cosmid vector pHC79. By utilizing a murine dihydrofolate reductase (DHFR) cDNA clone, we have identified 66 DHFR+ clones among the 11,000 colonies screened by colony hybridization. To isolate a recombinant cosmid containing the entire DHFR gene, we have tested these colonies for their ability to rescue a DHFR- Chinese hamster ovary cell line, using the spheroplast fusion method of gene transfer developed by W. Schaffner (Proc. Natl. Acad. Sci. U.S.A. 77:2163-2167, 1980). One clone (cH1) was able to transform DHFR- cells to the DHFR+ phenotype and was shown in hybridization studies to contain all of the gene except a small portion of the 3' untranslated region. We have mapped cosmid cH1 and several overlapping cosmids with a variety of restriction enzymes and have determined the approximate positions of the five (and possibly six) exons within the DHFR gene. Differences between the sizes of homologous genes in hamster cells (24.5 kilobases [kb]) and in mouse cells (31.5 kb) are shown to reside primarily in the length of the 3' intron, which is 8 kb in the hamster gene and 16 kb in length in the mouse gene. Our studies confirm the utility of cosmid libraries for the isolation of large genes, as previously shown by R. de Saint Vincent et al. (Cell 27:267-277, 1981). In addition, a cosmid that contains a functional DHFR gene will be a useful vector for the co-amplification and subsequent overexpression of other cloned genes.     

High-yield recovery of recombinant DNA from poorly growing cosmid and lambda genomic clones.

Certain genomic sequences cannot be recovered efficiently in cosmid or lambda bacteriophage clones, presenting a barrier to efforts to construct a contiguous cloned library of a genome. We have encountered such sequences during our efforts to isolate cosmid and bacteriophage lambda clones carrying members of the human type 2 cystatin gene family. Several cosmid clones constructed in the pWE 15 vector did not survive purification, and using standard techniques, we were unable to obtain significant amounts of cosmid DNA from those clones we could purify. Similarly, several lambda bacteriophage clones constructed in the lambda DASH II vector could not be purified, and those lambda clones we were able to isolate gave low titers in liquid lysates. In this paper, we describe generally applicable methods for preparing high yields of recombinant DNA from such recalcitrant cosmid and lambda clones constructed in these vectors.