A physical map of the Myxococcus xanthus chromosome.

A physical map of the 9.2-Mbp Myxococcus xanthus DK1622 chromosome at a resolution of 25 kbp was constructed by using a strategy that is applicable to virtually all microorganisms. Segments of the chromosome were used as hybridization probes to subdivide a yeast artificial chromosome (YAC) library into groups of linked clones. The clones were aligned by comparing their EcoRI restriction patterns. The groups of YAC clones ("contigs") were oriented and aligned with the genomic restriction map by means of common genetic and physical markers such as rare restriction sites and transposon insertions. Over 95% of the genome is represented by cloned DNA. Sixty genetic loci including > 100 genes, many of which play a role in fruiting body development, have been mapped in this way. Additional genes can now be located on the chromosome map by hybridization of their sequences to the ordered set of YAC chromosomes. The mapped genetic loci account for approximately 2% of the genome.     

A high-resolution physical map of human chromosome 11.

The development of a highly reliable physical map with landmark sites spaced an average of 100 kbp apart has been a central goal of the Human Genome Project. We have approached the physical mapping of human chromosome 11 with this goal as a primary target. We have focused on strategies that would utilize yeast artificial chromosome (YAC) technology, thus permitting long-range coverage of hundreds of kilobases of genomic DNA, yet we sought to minimize the ambiguities inherent in the use of this technology, particularly the occurrence of chimeric genomic DNA clones. This was achieved through the development of a chromosome 11-specific YAC library from a human somatic cell hybrid line that has retained chromosome 11 as its sole human component.To maximize the efficiency of YAC contig assembly and extension, we have employed an Alu-PCR-based hybridization screening system. This system eliminates many of the more costly and time-consuming steps associated with sequence tagged site content mapping such as sequencing, primer production, and hierarchical screening, resulting in greater efficiency with increased throughput and reduced cost. Using these approaches, we have achieved YAC coverage for >90% of human chromosome 11, with an average intermarker distance of <100 kbp. Cytogenetic localization has been determined for each contig by fluorescent in situ hybridization and/or sequence tagged site content. The YAC contigs that we have generated should provide a robust framework to move forward to sequence-ready templates for the sequencing efforts of the Human Genome Project as well as more focused positional cloning on chromosome 11.     

A high-density physical map of Sinorhizobium meliloti 1021 chromosome derived from bacterial artificial chromosome library.

As part of the European Sinorhizobium meliloti (strain 1021) chromosome sequencing project, four genomic bacterial artificial chromosome (BAC) libraries have been constructed, one of which was mainly used for chromosome mapping. This library consists of 1,824 clones with an average insert size of 80 kilobases and represents approximately 20-fold total genome coverage [6.8 megabases (Mbs)]. PCR screening of 384 BAC clones with 447 chromosomal markers (PCR primer pairs), consisting of 73 markers representing 118 genes (40 individual genes and 78 genes clustered in 23 operons), two markers from the rrn operon (three loci), four markers from insertion sequences (approximately 16 loci) and 368 sequence-tagged sites allowed the identification of 252 chromosomal BAC clones and the construction of a high-density physical map of the whole 3.7-Mb chromosome of S. meliloti. An average of 5.5 overlapping and colinear BAC clones per marker, correlated with a low rate of deleted or rearranged clones (0.8%) indicate a solid BAC contigation and a correct mapping. Systematic BLASTX analysis of sequence-tagged site marker sequences allowed prediction of a biological function for a number of putative ORFs. Results are available at. This map, whose resolution averages one marker every 9 kilobases, should provide a valuable tool for further sequencing, functional analysis, and positional cloning.     

Construction of the physical map for three loci in chromosome band 13q14: comparison to the genetic map.

Pulsed-field gel electrophoresis (PFGE) and deletion mapping are being used to construct a physical map of the long arm of human chromosome 13. The present study reports a 2700-kilobase (kb) Not I long-range restriction map encompassing the 13q14-specific loci D13S10, D13S21, and D13S22, which are detected by the cloned DNA markers p7D2, pG24E2.4, and pG14E1.9, respectively. Analysis of a panel of seven cell lines that showed differential methylation at a Not I site between D13S10 and D13S21 proved physical linkage of the two loci to the same 875-kb Not I fragment. D13S22 mapped to a different Not I fragment, precluding the possibility that D13S22 is located between D13S10 and D13S21. PFGE analysis of Not I partial digests placed the 1850-kb Not I fragment containing D13S22 immediately adjacent to the 875-kb fragment containing the other two loci. The proximal rearrangement breakpoint in a cell line carrying a del13(q14.1q21.2) was detected by D13S21 but not by D13S10, demonstrating that D13S21 lies proximal to D13S10. Quantitative analysis of hybridization signals of the three DNA probes to DNA from the same cell line indicated that only D13S10 was deleted, establishing the order of these loci to be cen-D13S22-D13S21-D13S10-tel. Surprisingly, this order was estimated to be 35,000 times less likely than that favored by genetic linkage analysis.     

A compositional map of human chromosome band Xq28.

The molar fractions of guanine plus cytosine (GC) in DNA were determined for 36 yeast artificial chromosomes (YACs) which almost completely cover human chromosome band Xq28, a terminal reverse band, corresponding to about 8 Mb of DNA. This allowed the construction of the most complete compositional map to date of a chromosomal band; three regions were observed: (i) a proximal 3.5-Mb region formed by GC-poor L and GC-rich H1 isochores; (ii) a middle 2,2-Mb region essentially formed by a GC-rich H2 isochore and a very GC-rich H3 isochore separated by a GC-poor L isochore, YACs from this region being characterized by a striking compositional heterogeneity and instability; and (iii) a distal 1.3-Mb region exclusively formed by GC-poor L isochores. Gene and CpG island concentrations increased with the GC levels of the isochores, as expected. Xq28 exemplifies a subset of reverse bands which are different from the two other subsets, namely from telomeric bands, which are characterized by specific cytogenetic properties and by the predominance of H2 and H3 isochores, and from the majority of reverse bands, which do not contain H2 and H3 isochores.     

Genetic and physical map of the von Recklinghausen neurofibromatosis (NF1) region on chromosome 17.

The von Recklinghausen neurofibromatosis 1 (NF1) locus has been previously assigned to the proximal long arm of chromosome 17, and two NF1 patients have been identified who have constitutional balanced translocations involving 17q11.2. We have constructed a cosmid library from a chromosome-mediated gene transfectant, KLT8, that contains approximately 10% of chromosome 17, including 17q11.2. Cosmids isolated from this library have been mapped across a panel of somatic cell hybrids, including the hybrids from the two patients, and have been localized to seven small regions of proximal 17q. We have 5 cosmids that map directly above the two NF1 translocations, and 11 cosmids that map directly below. Of these, 2 cosmids in each region are linked to the disease locus and 3 of these cosmids show no recombination. One distal cosmid, 2B/B35, detects the two NF1 translocations by pulsed-field gel analysis and has been used to produce a long-range restriction map that covers the translocations.     

A high-resolution annotated physical map of the human chromosome 13q12-13 region containing the breast cancer susceptibility locus BRCA2.

Various types of physical mapping data were assembled by developing a set of computer programs (Integrated Mapping Package) to derive a detailed, annotated map of a 4-Mb region of human chromosome 13 that includes the BRCA2 locus. The final assembly consists of a yeast artificial chromosome (YAC) contig with 42 members spanning the 13q12-13 region and aligned contigs of 399 cosmids established by cross-hybridization between the cosmids, which were selected from a chromosome 13-specific cosmid library using inter-Alu PCR probes from the YACs. The end sequences of 60 cosmids spaced nearly evenly across the map were used to generate sequence-tagged sites (STSs), which were mapped to the YACs by PCR. A contig framework was generated by STS content mapping, and the map was assembled on this scaffold. Additional annotation was provided by 72 expressed sequences and 10 genetic markers that were positioned on the map by hybridization to cosmids.     

High-resolution combined linkage physical map of short tandem repeat loci on human chromosome band Xq28 for indirect haemophilia A carrier detection

Summary.  Haemophilia A, the most common severe hereditary bleeding disorder in humans, is chiefly caused by mutations in the coagulation factor VIII F8 gene, which maps on chromosome band Xq28. Linkage analysis with F8 intragenic and/or closely located extragenic short tandem repeat (STR) elements is an effective method for indirect tracing of F8 pathogenic allelic variants in at-risk families. STR profiling is currently limited to 14 markers, 11 of which are dinucleotide elements. The aim of this study was to define novel polymorphic STR loci for haemophilia A carrier screening. The combined linkage physical map was restricted to a 2.4-Mb region on Xq28 that hosts 81 annotated genes, F8 inclusive. The inventory was in silico through comparative analyses with three X chromosome reference sequences, using microsatellite mining and validation computer software. Genetic distances for unmapped markers were interpolated on the Rutgers map of the human genome. The effort yielded 94 STR loci: 53 extragenic and 41 intragenic (14 STR elements map on the F8 gene; the other 27 on 19 further genes). The distribution per repeat period size was 61.7% di-, 5.3% tri-, 26.6% tetra- and 6.4% pentanucleotide loci. The success rate of validation of polymorphism for the new STR loci was 56.3%. For STR elements 0.78 Mb equidistant of the F8 gene, the interpolated downstream genetic length is 3.27 times the upstream genetic length. The inventory represents a 5.7-fold increase in polymorphic STR loci useful in carrier detection. Genotyping with the upstream extragenic tetra- and pentanucleotide markers is thus apprized.     

A high-resolution whole-genome cattle-human comparative map reveals details of mammalian chromosome evolution

Approximately 3,000 cattle bacterial artificial chromosome (BAC)-end sequences were added to the Illinois-Texas 5,000-rad RH (RH, radiation hybrid) map. The BAC-end sequences selected for mapping are approximately 1 Mbp apart on the human chromosomes as determined by blastn analysis. The map has 3,484 ordered markers, of which 3,204 are anchored in the human genome. Two hundred-and-one homologous synteny blocks (HSBs) were identified, of which 27 are previously undiscovered, 79 are extended, 26 were formed by previously unrecognized breakpoints in 18 previously defined HSBs, and 23 are the result of fusions. The comparative coverage relative to the human genome is approximately 91%, or 97% of the theoretical maximum. The positions of 64% of all cattle centromeres and telomeres were reassigned relative to their positions on the previous map, thus facilitating a more detailed comparative analysis of centromere and telomere evolution. As an example of the utility of the high-resolution map, 22 cattle BAC fingerprint contigs were directly anchored to cattle chromosome 19 [Bos taurus, (BTA) 19]. The order of markers on the cattle RH and fingerprint maps of BTA19 and the sequence-based map of human chromosome 17 [Homo sapiens, (HSA) 17] were found to be highly consistent, with only two minor ordering discrepancies between the RH map and fingerprint contigs. The high-resolution Illinois-Texas 5,000-rad RH and comparative maps will facilitate identification of candidate genes for economically important traits, the phylogenomic analysis of mammalian chromosomes, proofing of the BAC fingerprint map and, ultimately, aid the assembly of cattle whole-genome sequence.     

Polynesian origins: insights from the Y chromosome

The question surrounding the colonization of Polynesia has remained controversial. Two hypotheses, one postulating Taiwan as the putative homeland and the other asserting a Melanesian origin of the Polynesian people, have received considerable attention. In this work, we present haplotype data based on the distribution of 19 biallelic polymorphisms on the Y chromosome in a sample of 551 male individuals from 36 populations living in Southeast Asia, Taiwan, Micronesia, Melanesia, and Polynesia. Surprisingly, nearly none of the Taiwanese Y haplotypes were found in Micronesia and Polynesia. Likewise, a Melanesian-specific haplotype was not found among the Polynesians. However, all of the Polynesian, Micronesian, and Taiwanese haplotypes are present in the extant Southeast Asian populations. Evidently, the Y-chromosome data do not lend support to either of the prevailing hypotheses. Rather, we postulate that Southeast Asia provided a genetic source for two independent migrations, one toward Taiwan and the other toward Polynesia through island Southeast Asia.     

Site-specific genetic engineering of the Anopheles gambiae Y chromosome

Despite its function in sex determination and its role in driving genome evolution, the Y chromosome remains poorly understood in most species. Y chromosomes are gene-poor, repeat-rich and largely heterochromatic and therefore represent a difficult target for genetic engineering. The Y chromosome of the human malaria vector Anopheles gambiae appears to be involved in sex determination although very little is known about both its structure and function. Here, we characterize a transgenic strain of this mosquito species, obtained by transposon-mediated integration of a transgene construct onto the Y chromosome. Using meganuclease-induced homologous repair we introduce a site-specific recombination signal onto the Y chromosome and show that the resulting docking line can be used for secondary integration. To demonstrate its utility, we study the activity of a germ-line–specific promoter when located on the Y chromosome. We also show that Y-linked fluorescent transgenes allow automated sex separation of this important vector species, providing the means to generate large single-sex populations. Our findings will aid studies of sex chromosome function and enable the development of male-exclusive genetic traits for vector control.Mosquito species of the Anopheles gambiae complex represent the principal vectors of human malaria, and they pose an enormous burden on global health and economies. Every year, 300–500 million people are infected by malaria and more than 1 million people die as a consequence of Plasmodium parasite infections (1). The malaria mosquito A. gambiae has two pairs of autosomes, termed 2 and 3, and a pair of heteromorphic sex chromosomes X and Y, XX in females and XY in males (2). Extensive nonpairing regions exist between the X and the degenerate Y chromosome. and evidence points to a factor located on the Y chromosome that primarily determines the sex in Anopheles (3). Current models suggest that the evolutionary differentiation of Y chromosomes begins with the acquisition of a male determining factor on a proto-Y chromosome (4, 5). This event is followed by a progressive suppression of recombination between the still largely homomorphic proto-sex chromosomes, a process attributed to the acquisition of sexually antagonistic mutations, which are beneficial to the heterogametic sex but detrimental to the homogametic sex (6–8). The lack of recombination, together with the male-limited transmission, leads to the degeneration of the Y chromosome, which involves accumulation of deleterious mutations, spread of transposable elements, and silencing of all or most of the genes present on the proto-Y (9–11). As a result, Y chromosomes of many species appear to be strongly heterochromatic and harbor only few genes often involved in male fertility (12–17). The accumulation of repetitive sequences, many of which are also present on other chromosomes, hampers the assembly of Y chromosome contigs following shotgun sequencing. Indeed, despite the completion of the A. gambiae genome project (18), and the knowledge that the primary signal is likely to be associated with the inheritance of the Y (3, 19), no assembly of the Anopheles Y chromosome has been achieved. At present, public databases host only a few hundred kilobases of A. gambiae sequences attributed to the Y, a chromosome that is estimated to comprise 10% of the genome and to be at least 20 Mb in size. None of these Y-specific scaffolds have been physically mapped, because the Y chromosome does not polytenize. The exploration of the Y chromosome will improve our understanding of the evolutionary forces involved in driving chromosome evolution and may enable the manipulation of the molecular pathways that control sex determination and sexual differentiation in mosquitoes. In a number of organisms, Y chromosome genes have been found to be essential for male fertility or sex determination. Recently, a number of excellent candidate genes potentially involved in these processes have been identified on the Y chromosome of anopheline mosquitoes (20, 21). Because interfering with male fertility is an essential part of vector control strategies such as the sterile insect technique, the identification of such genes is of particular interest to mosquito biologists. In this paper, we demonstrate the targeted molecular manipulation of the Y chromosome in A. gambiae, thus opening up a number of ways to explore one of the most fascinating of evolution’s upshots and to harness this genetic tool for vector control.     

Mini-chromosomes derived from the human Y chromosome by telomere directed chromosome breakage.

We have used telomeric DNA to break two acrocentric derivatives of the human Y chromosome into mini-chromosomes that are small enough to be size- fractionated by pulsed-field gel electrophoresis. One of the mini-chromosomes is about 7 Mb in size and sequence-tagged site analysis of this molecule suggests that it corresponds to a simple truncation of the short arm of the Y chromosome. Five of the mini-chromosomes are derived from the long arm, are all rearranged by more than a simple truncation, and range in size from 4.0 Mb to 9 Mb. We have studied the mitotic stabilities of these mini-chromosomes and shown that they are stably maintained by cells proliferating in culture for about 100 cell divisions.     

A physical map for an Asian malaria mosquito, Anopheles stephensi

Physical mapping is a useful approach for studying genome organization and evolution as well as for genome sequence assembly. The availability of polytene chromosomes in malaria mosquitoes provides a unique opportunity to develop high-resolution physical maps. We report a 0.6-Mb-resolution physical map consisting of 422 DNA markers hybridized to 379 chromosomal sites of the Anopheles stephensi polytene chromosomes. This makes An. stephensi second only to Anopheles gambiae in density of a physical map among malaria mosquitoes. Three hundred sixty-three (363) probes hybridized to single chromosomal sites, whereas 59 clones yielded multiple signals. This physical map provided a suitable basis for comparative genomics, which was used for determining inversion breakpoints, duplications, and origin of novel genes across species.     

Y chromosome microdeletions and alterations of spermatogenesis

Three different spermatogenesis loci have been mapped on the Y chromosome and named "azoospermia factors" (AZFa, b, and c). Deletions in these regions remove one or more of the candidate genes (DAZ, RBMY, USP9Y, and DBY) and cause severe testiculopathy leading to male infertility. We have reviewed the literature and the most recent advances in Y chromosome mapping, focusing our attention on the correlation between Y chromosome microdeletions and alterations of spermatogenesis. More than 4,800 infertile patients were screened for Y microdeletions and published. Such deletions determine azoospermia more frequently than severe oligozoospermia and involve especially the AZFc region including the DAZ gene family. Overall, the prevalence of Y chromosome microdeletions is 4% in oligozoospermic patients, 14% in idiopathic severely oligozoospermic men, 11% in azoospermic men, and 18% in idiopathic azoospermic subjects. Patient selection criteria appear to substantially influence the prevalence of microdeletions. No clear correlation exists between the size and localization of the deletions and the testicular phenotype. However, it is clear that larger deletions are associated with the most severe testicular damage. Patients with Y chromosome deletions frequently have sperm either in the ejaculate or within the testis and are therefore suitable candidates for assisted reproduction techniques. This possibility raises a number of medical and ethical concerns, since the use of spermatozoa carrying Y chromosome deletions may produce pregnancies, but in such cases the genetic anomaly will invariably be passed on to male offspring.     

A bacterial artificial chromosome-based framework contig map of human chromosome 22q.

We have constructed a physical map of human chromosome 22q using bacterial artificial chromosome (BAC) clones. The map consists of 613 chromosome 22-specific BAC clones that have been localized and assembled into contigs using 452 landmarks, 346 of which were previously ordered and mapped to specific regions of the q arm of the chromosome by means of chromosome 22-specific yeast artificial chromosome clones. The BAC-based map provides immediate access to clones that are stable and convenient for direct genome analysis. The approach to rapidly developing marker-specific BAC contigs is relatively straightforward and can be extended to generate scaffold BAC contig maps of the rest of the chromosomes. These contigs will provide substrates for sequencing the entire human genome. We discuss how to efficiently close contig gaps using the end sequences of BAC clone inserts.     

Determination of sex and Y chromosome]

Years of speculations about the nature of the elusive testis determining factor (TDF) of the Y chromosome have ended last year. A gene named SRY satisfies many criteria expected of the testis determining gene, and gives us a basis to understand molecular mechanisms of the testis differentiation. The different steps which gave rise to SRY cloning are described.