A high-resolution cytogenetic map of 168 cosmid DNA markers for human chromosome 11.

We have constructed a high-resolution cytogenetic map with 168 DNA markers, including 90 RFLP markers for human chromosome 11. The cosmid clones were mapped by fluorescence in situ suppression hybridization, in which discrete fluorescent signals can be detected directly on prometaphase R-banded chromosomes. Although these cosmid clones were distributed throughout the chromosome, they had some tendency to localize in the regions of R-positive band, such as 11p15, 11p11.2, 11q13, 11q23, and 11q25. Since these regions of chromosome 11 are considered to contain genes responsible for certain genetic diseases, cancer breakpoints involved in chromosome rearrangements, and tumor-suppressor genes, this high-resolution cytogenetic map will contribute to the molecular characterization of such genes. This map will also provide many landmarks essential for construction of the complete physical map with contigs of cosmid and YAC clones.     

An Integrated Physical Map of 210 Markers Assigned to the Short Arm of Human Chromosome 11

Using a panel of patient cell lines with chromosomal breakpoints, we constructed a physical map for the short arm of human chromosome 11. We focused on 11p15, a chromosome band harboring at least 25 known genes and associated with the Beckwith-Wiedemann syndrome, several childhood tumors, and genomic imprinting. This underlines the need for a physical map for this region. We divided the short arm of chromosome 11 into 18 breakpoint regions, and a large series of new and previously described genes and markers was mapped within these intervals using fluorescence in situ hybridization. Cosmid fingerprint analysis showed that 19 of these markers were included in cosmid contigs. A detailed 10-Mb pulsed-field physical map of the region 11p15.3-pter was constructed. These three different approaches enabled the high-resolution mapping of 210 markers, including 22 known genes.     

A physical map with yeast artificial chromosome (YAC) clones covering 63% of the 12 rice chromosomes.

A new YAC (yeast artificial chromosome) physical map of the 12 rice chromosomes was constructed utilizing the latest molecular linkage map. The 1439 DNA markers on the rice genetic map selected a total of 1892 YACs from a YAC library. A total of 675 distinct YACs were assigned to specific chromosomal locations. In all chromosomes, 297 YAC contigs and 142 YAC islands were formed. The total physical length of these contigs and islands was estimated to 270 Mb which corresponds to approximately 63% of the entire rice genome (430 Mb). Because the physical length of each YAC contig has been measured, we could then estimate the physical distance between genetic markers more precisely than previously. In the course of constructing the new physical map, the DNA markers mapped at 0.0-cM intervals were ordered accurately and the presence of potentially duplicated regions among the chromosomes was detected. The physical map combined with the genetic map will form the basis for elucidation of the rice genome structure, map-based cloning of agronomically important genes, and genome sequencing.     

A 5.5-Mb High-Resolution Integrated Map of Distal 11q13

The distal part of 11q13, which contains several genes relevant to human diseases, has been poorly mapped as part of genome-wide mapping efforts. In the prospect of drawing a fine-scale integrated map of the area containingKRN1andOMP,we have established a framework of markers by hybridization to DNA of somatic cell hybrids and by fluorescencein situhybridization (FISH) on metaphase chromosomes. The probes studied were used to isolate 27 YACs and 16 cosmids that could be organized in three contigs covering approximately 6 Mb. These contigs were separated by two gaps that are likely to contain sequences underrepresented in YAC libraries. They were then integrated based on long-range restriction mapping and DNA-fiber FISH into a high-resolution physical map, which covers a 5.5-Mb region and includes 36 anonymous markers and 10 genes. This map will be used to search for genes within the 2/3 of this region where none have been localized as yet. It will also lay the ground for the characterization of an amplicon surroundingGARPin breast cancer and for the search of disease genes within this region.     

A radiation hybrid map of the proximal short arm of the human X chromosome spanning incontinentia pigmenti 1 (IP1) translocation breakpoints.

Radiation hybrid mapping was used in combination with physical mapping techniques to order and estimate distances between 14 loci in the proximal region of the short arm of the human X chromosome. A panel of radiation hybrids containing human X-chromosomal fragments was generated from a Chinese hamster-human cell hybrid containing an X chromosome as its only human DNA. Sixty-seven radiation hybrids were screened by Southern hybridization with sets of probes that mapped to the region Xp11.4-Xcen to generate a radiation hybrid map of the area. A physical map of 14 loci was constructed based on the segregation of the loci in the hybrid clones. Using pulsed-field gel electrophoresis (PFGE) analyses and a somatic cell hybrid mapping panel containing naturally occurring X; autosome translocations, the order of the 14 loci was verified and the loci nearest to the X-chromosomal translocation breakpoints associated with the disease incontinentia pigmenti 1 (IP1) were identified. The radiation hybrid panel will be useful as a mapping resource for determining the location, order, and distances between other genes and polymorphic loci in this region as well as for generating additional region-specific DNA markers.     

A cosmid library specific for human Chromosome regions 6p21.3 and 6q27

We have explored the potential of irradiation-fusion gene transfer (IFGT) hybrids as a source of well-defined human chromosome fragments from which probes can be derived. Extensive characterization of the IFGT hybrid 4J4 with a full panel of markers from Chromosome (Chr) 6 showed that the human DNA content derives largely from 6p21.3 and 6q27. A cosmid library has been constructed from 4J4 DNA, and 370 recombinants containing human DNA have been isolated and overlapping clones ordered into 20 contigs. Regional localization of representative clones from each contig, determined by fluorescent in situ hybridization (FISH), places 13 contigs in 6q27 and 6 in 6p21.3. Preliminary screening of cDNA libraries with selected cosmids has identified two expressed sequences. Since there are a number of medically important genes in both these regions of human Chr 6 with several disease loci linked to the HLA-A region in 6p21.3 and various tumor suppressor genes to 6q27, this library will provide a valuable resource to aid the isolation of candidate genes for these diseases. In addition, unique markers for detailed physical and genetic mapping of these regions of human Chr 6 can be easily obtained.     

Identification of 28 DNA fragments that detect RFLPs in 13 distinct physical regions of the short arm of chromosome 5.

A series of 175 lambda phage carrying human inserts isolated from a library that is specific for the short arm of human chromosome 5 (5p) have been regionally mapped on 5p using a deletion mapping panel of 16 human-hamster cell hybrids, each of which contains a chromosome 5 with a different deletion in the short arm. Seventy-five single copy DNA fragments were screened with 12 restriction enzymes for their ability to detect restriction fragment length polymorphisms (RFLPs). Twenty-eight of these DNA fragments, which are located in 13 distinct physical regions of 5p, were found to detect RFLPs. These DNA markers make it possible to construct a linkage map that will span the entire length of 5p and will allow the relationship between genetic and physical distance for this region of the genome to be examined at a high level of resolution.     

Genetic and physical maps of human chromosome 4 based on dinucleotide repeats.

Characterization of inherited variations within tandem arrays of dinucleotide repeats has substantially advanced the construction of genetic maps using linkage approaches over the last several years. Using a backbone of 10 newly identified microsatellite repeats on human chromosome 4 and 6 previously identified short tandem repeat element polymorphisms, we have constructed several genetic maps and a physical map of human chromosome 4. The genetic and physical maps are in complete concordance with each other. The genetic maps include a 15-locus microsatellite-based linkage map, a framework map of high support incorporating a total of 39 independent loci, a 25-locus high-heterozygosity, easily used index map, and a gene-based comprehensive map that provides the best genetic location for 35 genes mapped to chromosome 4. The 16 microsatellite markers are each localized to one of nine regions of chromosome 4, delineated by a panel of somatic cell hybrids. These results demonstrate the utility of PCR-based repeat elements for the construction of genetic maps and provide a valuable resource for continued high-resolution mapping of chromosome 4 and of genetic disorders to this chromosome.     

Physical mapping of 60 DNA markers in the p21.1----q21.3 region of the human X chromosome.

Using a panel of human/rodent somatic cell hybrids and human lymphoblast lines segregating 18 different human X-chromosome rearrangements and deletions, we have assigned 60 DNA markers to the physical map of the X chromosome from Xp21.1 to Xq21.3. Data from Southern blot hybridization and polymerase chain reaction (PCR) amplification assign these markers to 15 primary map intervals. This provides a basis for further long-range cloning and mapping of the pericentromeric region of the X chromosome.     

A comparative map of chicken chromosome 24 and human chromosome 11

To improve the physical and comparative map of chicken chromosome 24 (GGA24; former linkage group E49C20W21) bacterial artificial chromosome (BAC) contigs were constructed around loci previously mapped on this chromosome by linkage analysis. The BAC clones were used for both sample sequencing and BAC end sequencing. Sequence tagged site (STS) markers derived from the BAC end sequences were used for chromosome walking. In total 191 BAC clones were isolated, covering almost 30% of GGA24, and 76 STS were developed (65 STS derived from BAC end sequences and 11 STS derived within genes). The partial sequences of the chicken BAC clones were compared with sequences present in the EMBL/GenBank databases, and revealed matches to 19 genes, expressed sequence tags (ESTs) and genomic clones located on human chromosome 11q22-q24 and mouse chromosome 9. Furthermore, 11 chicken orthologues of human genes located on HSA11q22-q24 were directly mapped within BAC contigs of GGA24. These results provide a better alignment of GGA24 with the corresponding regions in human and mouse and identify several intrachromosomal rearrangements between chicken and mammals.     

Isolation and high-resolution mapping of new DNA markers from the pericentromeric region of chromosome 10.

The gene responsible for multiple endocrine neoplasia type 2A (MEN 2A) has been localized to the pericentromeric region of chromosome 10. Several markers that fail to recombine with MEN2A have been identified, including D10Z1, D10S94, D10S97, and D10S102. Meiotic mapping in the MEN2A region is limited by the paucity of critical crossovers identified and by the dramatically reduced rates of recombination in males. Additional approaches to mapping loci in the pericentromeric region of chromosome 10 are required. We have undertaken the generation of a detailed physical map by radiation hybrid mapping. Here we report the development of a radiation hybrid panel and its use in the mapping of new DNA markers in pericentromeric chromosome 10. The radiation-reduced hybrids used for mapping studies all retain small subchromosomal fragments that include both D10S94 and D10Z1. One hybrid was selected as the source of DNA for cloning. One hundred five human recombinant clones were isolated from a lambda library made with pp11A DNA. We have completed regional mapping of 22 of those clones using our radiation hybrid mapping panel. Seven markers have been identified and, when taken together with previously meiotically mapped markers, define eight radiation hybrid map intervals between D10S34 and RBP3. The identical order is found for a number of these using either the radiation hybrid mapping panel or the meiotic mapping panel. We believe that this combination cloning and mapping approach will facilitate the precise positioning of new markers in pericentromeric chromosome 10 and will help in refining further the localization of MEN2A.     

Integration of the Physical and Genetic Linkage Map for Human Chromosome 13

We have used a panel of somatic cell hybrids containing different rearrangements of human chromosome 13 to integrate genetic and physical maps of this chromosome. The positions of 17 translocation/deletion breakpoints on human chromosome 13 have been determined relative to the microsatellite markers on the genetic linkage map compiled by Généthon. Because markers on maps from several other Consortium groups have also been analyzed using many of the same hybrids, it was possible to relate these with the Généthon map. The position of all of the chromosome breakpoints have been placed, wherever possible, between two adjacent markers on the genetic linkage maps using PCR analysis for the presence/absence of the markers in the somatic cell hybrids. The positions of the breakpoints have already been determined cytogenetically, and some of these breakpoints are located at landmark positions on the chromosome. The relative density of markers along the chromosome differs between independently derived maps, and, based on the known locations of certain breakpoints in the physical map, inconsistencies in the genetic maps have been identified.     

Towards a physical map of the Drosophila melanogaster genome: mapping of cosmid clones within defined genomic divisions.

A physical map of the D. melanogaster genome is being constructed, in the form of overlapping cosmid clones that are assigned to specific polytene chromosome sites. A master library of ca. 20,000 cosmids is screened with probes that correspond to numbered chromosomal divisions (ca. 1% of the genome); these probes are prepared by microdissection and PCR-amplification of individual chromosomes. The 120 to 250 cosmids selected by each probe are fingerprinted by Hinfl digestion and gel electrophoresis, and overlaps are detected by computer analysis of the fingerprints, permitting us to assemble sets of contiguous clones (contigs). Selected cosmids, both from contigs and unattached, are then localized by in situ hybridization to polytene chromosomes. Crosshybridization analysis using end probes links some contigs, and hybridization to previously cloned genes relates the physical to the genetic map. This approach has been used to construct a physical map of the 3.8 megabase DNA in the three distal divisions of the x chromosome. The map is represented by 181 canonical cosmids, of which 108 clones in contigs and 32 unattached clones have been mapped individually by in situ hybridization to chromosomes. Our current database of in situ hybridization results also includes the beginning of a physical map for the rest of the genome: 162 cosmids have been assigned by in situ hybridization to 129 chromosomal subdivisions elsewhere in the genome, representing 5 to 6 megabases of additional mapped DNA.     

The physical map of the chromosome of a serogroup A strain of Neisseria meningitidis shows complex rearrangements relative to the chromosomes of the two mapped strains of the closely related species N. gonorrhoeae.

A physical map of the chromosome of N. meningitidis Z2491 (serogroup A, subgroup IV-1) has been constructed. Z2491 DNA was digested with NheI, SpeI, SgfI, PacI, BglII, or PmeI, resulting in a limited number of fragments that were resolved by contour-clamped homogeneous electric field (CHEF) electrophoresis. The estimated genome size for this strain was 2,226 kb. To construct the map, probes corresponding to single-copy genes or sequences were used on Southern blots of chromosomal DNA digested with the different mapping enzymes and subjected to CHEF electrophoresis. By determining which fragments from different digests hybridized to each specific probe, it was possible to walk back and forth between digests to form a circular macrorestriction map. The intervals between mapped restriction sites range from 10 to 143 kb in size. A total of 117 markers have been placed on the map; 75 represent identified genes, with the remaining markers defined by anonymous cloned fragments of neisserial DNA. Comparison of the arrangement of genetic loci in Z2491 with that in gonococcal strain FA1090, for which a physical map was previously constructed, revealed complex genomic rearrangements between the two strains. Although gene order is generally conserved over much of the chromosome, a region of approximately 500 kb shows translocation and/or inversion of multiple blocks of markers between the two strains. Even within the relatively conserved portions of the maps, several genetic markers are in different positions in Z2491 and FA1090.     

A BAC-based physical map of the apple genome

Genome-wide physical mapping is an essential step toward investigating the genetic basis of complex traits as well as pursuing genomics research of virtually all plant and animal species. We have constructed a physical map of the apple genome from a total of 74,281 BAC clones representing approximately 10.5x haploid genome equivalents. The physical map consists of 2702 contigs, and it is estimated to span approximately 927 Mb in physical length. The reliability of contig assembly was evaluated by several methods, including assembling contigs using variable stringencies, assembling contigs using fingerprints from individual libraries, checking consensus maps of contigs, and using DNA markers. Altogether, the results demonstrated that the contigs were properly assembled. The apple genome-wide BAC-based physical map represents the first draft genome sequence not only for any member of the large Rosaceae family, but also for all tree species. This map will play a critical role in advanced genomics research for apple and other tree species, including marker development in targeted chromosome regions, fine-mapping and isolation of genes/QTL, conducting comparative genomics analyses of plant chromosomes, and large-scale genomics sequencing.     

Toward a complete linkage map of the human X chromosome: regional assignment of 16 cloned single-copy DNA sequences employing a panel of somatic cell hybrids.

Closely linked restriction fragment length polymorphisms (RFLPs) are potentially useful as diagnostic markers of genetic defects, and, in principle, RFLPs can be employed to construct a complete linkage map of the human genome. On the X chromosome, linkage studies are particularly rewarding because in man more than 120 X-linked genes are known. Thus, it is probable that each X-specific RFLP will be of use as a genetic marker of one or several X-linked disorders. To facilitate the search for closely linked RFLPs, we have regionally assigned 16 cloned DNA sequences to various portions of the human X chromosome, employing a large panel of somatic cell hybrids. These probes have been used to correlate genetic and physical distances on Xp, and it can be extrapolated from these data that the number and distribution of available Xq sequences will also suffice to span the long arm of the X chromosome.     

Construction of YAC Contigs on Rice Chromosome 5

A physical map of rice chromosome 5 was constructed with yeastartificial chromosome (YAC) clones along a high-resolution molecularlinkage map carrying 118 DNA markers distributed over 123.7cM of genomic DNA. YAC clones have been identified by colonyand Southern hybridization for 105 restriction fragment lengthpolymorphism (RFLP) markers and by polymerase chain reaction(PCR) screening for 8 sequence-tagged site (STS) markers and5 randomly amplified polymorphic DNA (RAPD) markers. Of 458YACs, 235 individual YACs with an average insert length of 350kb were selected and ordered on chromosome 5 from the YAC library.Forty-eight contigs covering nearly 21 Mb were formed on thechromosome 5; the longest one was 6 cM and covered 1.5 Mb. Thelength covered with YAC clones corresponded to 62% of the totallength of chromosome 5. There were many multicopy sequencesof expressed genes on chromosome 5. The distribution of manycopies of these expressed gene sequences was determined by YACSouthern hybridization and is discussed. A physical map withthese characteristics provides a powerful tool for elucidationof genome structure and extraction of useful genetic informationin rice.     

Bacterial artificial chromosome library of Finegoldia magna ATCC 29328 for genetic mapping and comparative genomics

We constructed a bacterial artificial chromosome (BAC) library of Finegoldia magna ATCC 29328 DNA to facilitate further genome analysis of F. magna. The BAC library contained 385 clones with an average insert size of 55 kb, representing a 10.1-fold genomic coverage. Repeated DNA hybridization using primer sets designed on the basis of BAC-end sequences yielded nine contigs covering 95% of the chromosome and two contigs covering 98% of the plasmid. The contigs were localized on the physical map of F. magna ATCC 29328 DNA. A total of 121 BAC-end sequences revealed 103 unique genes, which had not been previously reported for F. magna. The homolog ORF of albumin-binding protein (urPAB), one of the known virulence factors from F. magna, was sequenced and localized on the physical map. Homology analysis of 121 BAC-end sequences revealed that F. magna is most closely related to clostridia, particularly Clostridium tetani. This close relationship is consistent with the recent classification of peptostreptococci based on 16S rRNA sequence analysis. The BAC library constructed here will be useful for the whole genome sequencing project and other postgenomic applications.     

Physical map of the genome of Rhodobacter capsulatus SB 1003.

A map of the chromosome of Rhodobacter capsulatus was constructed by overlapping the large restriction fragments generated by endonucleases AseI and XbaI. The analyses were done by hybridization of single fragments with the restriction fragments blotted from pulsed-field gels and by grouping cosmids of a genomic library of R. capsulatus into contigs, corresponding to the restriction fragments, and further overlapping of the contigs. A technical difficulty due to a repeated sequence made it necessary to use hybridization with cloned genes and prior knowledge of the genetic map in order to close the physical circle in a unique way. In all, 41 restriction sites were mapped on the 3.6-Mb circular genome and 22 genes were positioned at 26 loci of the map. Cosmid clones were grouped in about 80 subcontigs, forming two groups, one corresponding to the chromosome of R. capsulatus and the other corresponding to a 134-kb plasmid. cos site end labeling and partial digestion of cosmids were used to construct a high-resolution EcoRV map of the 134-kb plasmid. The same method can be extended to the entire chromosome. The cosmid clones derived in this work can be used as a hybridization panel for the physical mapping of new genes as soon as they are cloned.