Chromosomal map of human brain malformations

The etiology of most central nervous system (CNS) malformations remains unknown. We have utilized the fact that autosomal chromosome aberrations are commonly associated with CNS malformations to identify new causative gene loci. The human cytogenetic database, a computerized catalog of the clinical phenotypes associated with cytogenetically detectable human chromosome aberrations, was used to identify patients with 14 selected brain malformations including 541 with deletions, and 290 carrying duplications. These cases were used to develop an autosomal deletion and duplication map consisting of 67 different deleted malformation associated bands (MABs) in 55 regions and 88 different duplicated MABs in 36 regions; 31 of the deleted and 8 duplicated MABs were highly significantly associated (P < 0.001). All holoprosencephaly MABs found in the database contained a known HPE gene providing some level of validation for the approach. Significantly associated MABs are discussed for each malformation together with the published data about known disease-causing genes and reported malformation-associated loci, as well as the limitations of the proposed approach.     

A deletion map of the human Y chromosome based on DNA hybridization.

The genomes of 27 individuals (19 XX males, two XX hermaphrodites, and six persons with microscopically detectable anomalies of the Y chromosome) were analyzed by hybridization for the presence or absence of 23 Y-specific DNA restriction fragments. Y-specific DNA was detected in 12 of the XX males and in all six individuals with microscopic anomalies. The results are consistent with each of these individuals carrying a single contiguous portion of the Y chromosome; that is, the results suggest a deletion map of the Y chromosome, in which each of the 23 Y-specific restriction fragments tested can be assigned to one of seven intervals. We have established the polarity of this map with respect to the long and short arms of the Y chromosome. On the short arm, there is a large cluster of sequences homologous to the X chromosome. The testis determinant(s) map to one of the intervals on the short arm.     

Somatic cell hybrid deletion map of human chromosome 18.

The creation of a physical map of chromosome 18 will be useful for the eventual identification of specific chromosomal regions that are critical in the occurrence of Edwards syndrome, the 18q- syndrome, and the 18p- syndrome. To begin the investigation of these syndromes, a physical map has been constructed to order random DNA fragments to specific portions of chromosome 18. A set of somatic cell hybrids that retain deletions or translocations involving chromosome 18 has been isolated and characterized. Over 200 lambda phage from a chromosome 18-specific library have been localized to 11 distinct regions of chromosome 18 using the chromosomal breakpoints present in the somatic cell hybrids.     

A chromosomal duplication map of malformations: regions of suspected haplo- and triplolethality--and tolerance of segmental aneuploidy--in humans.

The distribution of simple autosomal duplications associated with congenital malformations has been analyzed by means of data contained in the Human Cytogenetics Database. For each of the 47 malformations, the frequency of duplication of a given chromosome band associated with the malformation was compared with the overall frequency of duplication of that band recorded in the database. In total, there were 143 malformation-associated chromosomal regions (MACR); 21 of these contained at least one band with a highly significant (P<.001) association. The average number of bands per MACR was 3.1. Eight bands, representing 2.1% of haploid autosomal length, were not involved in any duplication, and we suggest that these are potentially triplolethal. This compares with 31 bands, representing 11% of haploid autosomal length, that were identified in the previously reported deletion map and that were not involved in any deletion and are potentially haplolethal. In both cases, approximately half of these bands are pericentromeric. The longest duplication involves 4.3% of haploid autosomal length, and the longest deletion involves 2.7%.     

A chromosomal linkage map of Azotobacter vinelandii

Summary A chromosomal map of Azotobacter vinelandii strain UW was constructed. The map was based on measures of cotransfer of various markers mediated by plasmids R68.45 and pJB3JI, on results obtained from conjugal experiments with R-primes, and on recombinants obtained by chromosomal transfer mediated by RP4/Tn5-Mob.     

A deletion map of the WAGR region on chromosome 11.

The WAGR (Wilms tumor, aniridia, genitourinary anomalies, and mental retardation) region has been assigned to chromosome 11p13 on the basis of overlapping constitutional deletions found in affected individuals. We have utilized 31 DNA probes which map to the WAGR deletion region, together with six reference loci and 13 WAGR-related deletions, to subdivide this area into 16 intervals. Specific intervals have been correlated with phenotypic features, leading to the identification of individual subregions for the aniridia and Wilms tumor loci. Delineation, by specific probes, of multiple intervals above and below the critical region and of five intervals within the overlap area provides a framework map for molecular characterization of WAGR gene loci and of deletion boundary regions.     

Toward a long-range map of human chromosomal band 22q11

Human chromosome band 22q11 is involved in numerous chromosomal rearrangements. A long-range molecular map of this region would allow the more precise localization of the various breakpoints of these rearrangements. Toward this goal we have constructed a genomic DNA library that allows the isolation of DNA clones that are directly adjacent to NotI sites. NotI was chosen because it is a restriction enzyme that digests infrequently in the human genome. The genomic DNA used in this library was from a human/hamster hybrid cell line that has a chromosome 22 as the only visible human chromosome. Two clones were isolated and mapped to different regions of 22q11 using a somatic cell hybrid mapping panel. A long-range restriction map flanking the NotI site of each of these two clones was produced using NotI and other infrequently cutting enzymes. Both NotI sites analyzed were located in HTF islands, regions often associated with the 5' end of genes. Thus, the NotI map of 22q11 may also aid in the cloning of undiscovered genes, giving a starting point for the study of duplication/deficiency syndromes of the region.     

A comparative map of the porcine and human genomes demonstrates ZOO-FISH and gene mapping-based chromosomal homologies

ZOO-FISH with chromosome-specific DNA libraries (CSLs) from individual flow-sorted human chromosomes was applied on porcine metaphase chromosomes to establish segment homology between the pig and human karyotypes. Forty-seven porcine chromosomal segments corresponding to all human chromosomes except the Y were delineated, resulting in a nearly complete coverage of the porcine karyotype. The syntenic segments detected were further confirmed by the gene mapping information available in the two species. A map demarcating physical boundaries of human homologies on individual pig chromosomes is complemented with a detail survey of the physical and genetic linkage mapping data in the two species. The resultant map, thus, provides a comprehensive and updated comparative status of the human and porcine genomes. Received: 9 September 1995 / Accepted: 4 December 1995     

A compositional map of human chromosome 21.

GC-poor and GC-rich isochores, the long (greater than 300 kb) compositionally homogeneous DNA segments that form the genome of warm-blooded vertebrates, are located in G- and R-bands respectively of metaphase chromosomes. The precise correspondence between GC-rich isochores and R-band structure is still, however, an open problem, because GC-rich isochores are compositionally heterogeneous and only represent one-third of the genome, with the GC-richest family (which is by far the highest in gene concentration) corresponding to less than 5% of the genome. In order to clarify this issue and, more generally, to correlate DNA composition and chromosomal structure in an unequivocal way, we have developed a new approach, compositional mapping. This consists of assessing the base composition over 0.2-0.3 Mb (megabase) regions surrounding landmarks that were previously localized on the physical map. Compositional mapping was applied here to the long arm of human chromosome 21, using 53 probes that had already been used in physical mapping. The results obtained provide a direct demonstration that the DNA stretches of G-bands essentially correspond to GC-poor isochores, and that R-band DNA is characterized by a compositional heterogeneity that is much more striking than expected, in that it comprises isochores covering the full spectrum of GC levels. GC-poor isochores of R-bands may, however, correspond to 'thin' G-bands, as visualized at high resolution, leaving GC-rich and very GC-rich isochores as the real components of (high-resolution) R-band DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Normalization of a chromosomal contact map

ABSTRACT: BACKGROUND: Chromatin organization has been increasingly studied in relation with its important influence on DNA-related metabolic processes such as replication or regulation of gene expression. Since its original design ten years ago, capture of chromosome conformation (3C) has become an essential tool to investigate the overall conformation of chromosomes. It relies on the capture of long-range trans and cis interactions of chromosomal segments whose relative proportions in the final bank reflect their frequencies of interactions, hence their average spatial proximity. The recent coupling of 3C with deep sequencing approaches now allows the generation of high resolution genome-wide chromosomal contact maps. Different protocols have been used to generate such maps in various organisms. This includes mammals, drosophila and yeast. The massive amount of raw data generated by the genomic 3C has to be carefully processed to alleviate the various biases and byproducts generated by the experiments. Our study aims at proposing a simple normalization procedure to take into account these unwanted but inevitable events. RESULTS: Careful analysis of the raw data generated previously for budding yeast Saccharomyces cerevisiae led to the identification of three main biases affecting the final datasets, including an original bias resulting from the circularization of DNA molecules exhibiting specific lengths in accordance with laws from polymer physics. We then developed a simple normalization procedure to process the data and allow the generation of a normalized, highly contrasted, chromosomal contact map for S. cerevisiae. The same method was then extended to the first human genome contact map. Using the normalized data, we revisited the preferential interactions originally described between subsets of discrete chromosomal features. Notably, the detection of preferential interactions between tRNA in yeast and CTCF, PolII binding sites in human can vary with the normalization procedure used. CONCLUSIONS: We quantitatively reanalyzed the genomic 3C data obtained for S. cerevisiae, identified some of the biases inherent to the technique and proposed a simple normalization procedure to analyze them. Such an approach can be easily generalized for genomic 3C experiments in other organisms. More experiments and analysis will be necessary to reach optimal resolution and accuracies of the maps generated through these approaches. Working with cell population presenting highest levels of homogeneity will prove useful in this regards.     

A physical map of the human pseudoautosomal region.

A physical map of the human pseudoautosomal region has been constructed using pulsed field gel electrophoresis and the infrequently cutting restriction enzymes BssHIII, EagI, SstII, NotI, MluI and NruI. This map extends 2.3 Mbp from the telomere to sex-chromosome-specific DNA, includes at least seven CpG islands and locates four genetically mapped loci. Five of the CpG islands are organized into two clusters. One cluster is adjacent to the telomere, the other extends into sex-chromosome-specific DNA. There is congruence between the genetic and physical maps which implies that the frequency of recombination is approximately uniform throughout the DNA.     

A genetic map of Peromyscus with chromosomal assignment of linkage groups (a Peromyscus genetic map)

The rodent genus Peromyscus is the most numerous and species-rich mammalian group in North America. The naturally occurring diversity within this genus allows opportunities to investigate the genetic basis of adaptation, monogamy, behavioral and physiological phenotypes, growth control, genomic imprinting, and disease processes. Increased genomic resources including a high quality genetic map are needed to capitalize on these opportunities. We produced interspecific hybrids between the prairie deer mouse (P. maniculatus bairdii) and the oldfield mouse (P. polionotus) and scored meiotic recombination events in backcross progeny. A genetic map was constructed by genotyping of backcross progeny at 185 gene-based and 155 microsatellite markers representing all autosomes and the X-chromosome. Comparison of the constructed genetic map with the molecular maps of Mus and Rattus and consideration of previous results from interspecific reciprocal whole chromosome painting allowed most linkage groups to be unambiguously assigned to specific Peromyscus chromosomes. Based on genomic comparisons, this Peromyscus genetic map covers ~83 % of the Rattus genome and 79 % of the Mus genome. This map supports previous results that the Peromyscus genome is more similar to Rattus than Mus. For example, coverage of the 20 Rattus autosomes and the X-chromosome is accomplished with only 28 segments of the Peromyscus map, but coverage of the 19 Mus autosomes and the X-chromosome requires 40 chromosomal segments of the Peromyscus map. Furthermore, a single Peromyscus linkage group corresponds to about 91 % of the rat and only 76 % of the mouse X-chromosomes.     

A first-draft human protein-interaction map

Background

Protein-interaction maps are powerful tools for suggesting the cellular functions of genes. Although large-scale protein-interaction maps have been generated for several invertebrate species, projects of a similar scale have not yet been described for any mammal. Because many physical interactions are conserved between species, it should be possible to infer information about human protein interactions (and hence protein function) using model organism protein-interaction datasets.

Results

Here we describe a network of over 70,000 predicted physical interactions between around 6,200 human proteins generated using the data from lower eukaryotic protein-interaction maps. The physiological relevance of this network is supported by its ability to preferentially connect human proteins that share the same functional annotations, and we show how the network can be used to successfully predict the functions of human proteins. We find that combining interaction datasets from a single organism (but generated using independent assays) and combining interaction datasets from two organisms (but generated using the same assay) are both very effective ways of further improving the accuracy of protein-interaction maps.

Conclusions

The complete network predicts interactions for a third of human genes, including 448 human disease genes and 1,482 genes of unknown function, and so provides a rich framework for biomedical research.

     

The human genetic map.

The introduction of new technology and increased effort from around the world is driving the completion of the human gene map. In parallel with the creation of the map, we are beginning to see the biomedical benefits that are a direct consequence of learning more about our own genome.