A chromosome 11 YAC library

The pericentromeric region of human chromosome 11: evidence for a chromosome-specific duplication

We have identified a chromosome duplication in the pericentromeric region of human chromosome 11 located in 11p11 and 11q14. A detailed physical map of each duplicated region was generated to describe the nature of the duplication, the involvement at the centromere and to resolve the correct maps. All clones were evaluated to ensure they were representative of their genetic origin. The order of clones, based on their marker content, as well as the distance covered was determined by SEGMAP. Each duplication encompasses more than 1 Mb of DNA and appears to be chromosome 11 specific. Ten STS markers were mapped within each duplication. Comparative sequence analysis along the duplication identified 35 nucleotide changes in 2,036 bp between the two copies, suggesting the duplication occurred over 14 million years ago. A suggested organization of the pericentromeric region, including the duplications and alpha-related repetitive sequences, is presented.

Organization and evolution of olfactory receptor genes on human chromosome 11

Olfactory receptors (OR) are encoded by a large multigene family including hundreds of members dispersed throughout the human genome. Cloning and mapping studies have determined that a large proportion of the olfactory receptor genes are located on human chromosomes 6, 11, and 17, as well as distributed on other chromosomes. In this paper, we describe and characterize the organization of olfactory receptor genes on human chromosome 11 by using degenerate PCR-based probes to screen chromosome 11-specific and whole genome clone libraries for members of the OR gene family. OR genes were identified by DNA sequencing and then localized to regions of chromosome 11. Physical maps of several gene clusters were constructed to determine the chromosomal relationships between various members of the family. This work identified 25 new OR genes located on chromosome 11 in at least seven distinct regions. Three of these regions contain gene clusters that include additional members of this gene family not yet identified by sequencing. Phylogenetic analysis of the newly described OR genes suggests a mechanism for the generation of genetic diversity.

Linkage-disequilibrium mapping without genotyping

Genomic mismatch scanning (GMS) is a technique that enriches for regions of identity by descent (IBD) between two individuals without the need for genotyping or sequencing. Regions of IBD selected by GMS are mapped by hybridization to a microarray containing ordered clones of genomic DNA from chromosomes of interest. Here we demonstrate the feasibility and efficacy of this form of linkage-mapping, using congenital hyperinsulinism (HI), an autosomal recessive disease, whose relatively high frequency in Ashkenazi Jews suggests a founder effect. The gene responsible (SUR1) encodes the sulfonylurea receptor, which maps to chromosome 11p15.1. We show that the combination of GMS and hybridization of IBD products to a chromosome-11 microarray correctly maps the HI gene to a 2-Mb region, thereby demonstrating linkage-disequilibrium mapping without genotyping.

Contig maps and genomic sequencing identify candidate genes in the usher 1C locus

Usher syndrome 1C (USH1C) is a congenital condition manifesting profound hearing loss, the absence of vestibular function, and eventual retinal degeneration. The USH1C locus has been mapped genetically to a 2- to 3-cM interval in 11p14-15.1 between D11S899 and D11S861. In an effort to identify the USH1C disease gene we have isolated the region between these markers in yeast artificial chromosomes (YACs) using a combination of STS content mapping and Alu-PCR hybridization. The YAC contig is approximately 3.5 Mb and has located several other loci within this interval, resulting in the order CEN-LDHA-SAA1-TPH-D11S1310-(D11S1888/KCNC1 )-MYOD1-D11S902D11S921-D11S 1890-TEL. Subsequent haplotyping and homozygosity analysis refined the location of the disease gene to a 400-kb interval between D11S902 and D11S1890 with all affected individuals being homozygous for the internal marker D11S921. To facilitate gene identification, the critical region has been converted into P1 artificial chromosome (PAC) clones using sequence-tagged sites (STSs) mapped to the YAC contig, Alu-PCR products generated from the YACs, and PAC end probes. A contig of >50 PAC clones has been assembled between D11S1310 and D11S1890, confirming the order of markers used in haplotyping. Three PAC clones representing nearly two-thirds of the USH1C critical region have been sequenced. PowerBLAST analysis identified six clusters of expressed sequence tags (ESTs), two known genes (BIR, SUR1) mapped previously to this region, and a previously characterized but unmapped gene NEFA (DNA binding/EF hand/acidic amino-acid-rich). GRAIL analysis identified 11 CpG islands and 73 exons of excellent quality. These data allowed the construction of a transcription map for the USH1C critical region, consisting of three known genes and six or more novel transcripts. Based on their map location, these loci represent candidate disease loci for USH1C. The NEFA gene was assessed as the USH1C locus by the sequencing of an amplified NEFA cDNA from an USH1C patient; however, no mutations were detected.

A high-resolution STS, EST, and gene-based physical map of the hereditary paraganglioma region on chromosome 11q23

The genes responsible for hereditary paragangliomas (glomus tumors, MIM No. 168000) have been mapped to two distinct loci on the long arm of chromosome 11. Most of the informative families appear to be linked to the distal locus on chromosome 11q23 (PGL1), which has been previously confined to a 2-cM interval by haplotype analysis in an extended Dutch pedigree. To facilitate the identification of the PGL1 disease gene, we constructed an approximately 4-Mb ordered clone contig map of Sequence tagged sites, expressed sequence tags (ESTs), and known genes that spans the PGL1 critical region on chromosome 11q23. Among 29 new positional candidate ESTs, only two (EST100999 and EST241777) mapped within the PGL1 critical region. We further characterized the genomic organization of the promyelocytic leukemia zinc finger (PLZF) gene that maps within the PGL1 critical region and physically excluded the serotonin receptor type 3 (5HT3R) gene. Finally, we identified a common, silent, single-base substitution polymorphism in the 5HT3R gene and characterized the allele sets of two new highly polymorphic microsatellite repeats within the PGL1 critical region.

A 3-Mb contig from D11S987 to MLK3, a gene-rich region in 11q13

We have combined genetic, radiation-reduced somatic cell hybrid (RRH), fluorescent in situ hybridization (FISH), and physical mapping methods to generate a contig of overlapping YAC, PAC, and cosmid clones corresponding to > 3 continuous Mb in 11q13. A total of 15 STSs [7 genes (GSTP1, ACTN, PC, MLK3, FRA1, SEA, HNP36), 4 polymorphic loci (D11S807, D11S987, GSTP1, D11S913), 3 ESTs (D11S1956E, D11S951E, and W1-12191), and 1 anonymous STS (D11S703)], mapping to three independent RRH segregation groups, identified 26 YAC, 7 PAC, and 16 cosmid clones from the CGM, Roswell Park, CEPH Mark I, and CEPH MegaYAC YAC libraries, a 5 genome equivalent PAC library, and a chromosome II-specific cosmid library. Thirty-six Alu-PCR products derived from 10 anonymous bacteriophage lambda clones, a cosmid containing the polymorphic marker D11S460, or STS-positive YAC or cosmid clones were identified and used to screen selected libraries by hybridization, resulting in the identification of 19 additional clones. The integrity and relative position of a subset of clones was confirmed by FISH and were found to be consistent with the physical and RRH mapping results. The combination of STS and Alu-PCR-based approaches has proven to be successful in attaining contiguous cloned coverage in this very GC-rich region, thereby establishing for the first time the absolute order and distance between the markers: CEN-MLK3-(D11S1956E/D11S951E/W1-12191)-FRA1-D 11S460-SEA-HNP36/ D11S913-ACTN-PC-D11S703-GSTP1-D11S987-TEL.

A 2.8-Mb clone contig of the multiple endocrine neoplasia type 1 (MEN1) region at 11q13

Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant disorder that results in parathyroid, anterior pituitary, and pancreatic and duodenal endocrine tumors in affected individuals. The MEN1 locus is tightly linked to the marker PYGM on chromosome 11q13, and linkage analysis has placed the MEN1 gene within a 2-Mb interval flanked by D11S1883 and D11S449. As a step toward cloning the MEN1 gene, we have constructed a 2.8-Mb clone contig consisting of YAC and bacterial clones (PAC, BAC, and P1) for the D11S480 to D11S913 region. The bacterial clones alone represent nearly all of the 2.8-Mb contig. The contig was assembled based on a high-density STS-content analysis of 79 genomic clones (YAC, PAC, BAC, and P1) with 118 STSs. The STSs included 22 polymorphic markers and 20 transcripts, with the remainder primarily derived from the end sequences of the genomic clones. An independent cosmid contig for the 1-Mb PYGM-SEA region was also generated. Support for correctness of the 2.8-Mb contig map comes from an independent ordering of the clones by fiber-FISH. This sequence-ready contig will be a useful resource for positional cloning of MEN1 and other disease genes whose loci fall within this region.

The human HNP36 gene is localized to chromosome 11q13 and produces alternative transcripts that are not mutated in multiple endocrine neoplasia, type 1 (MEN I) syndrome

Multiple endocrine neoplasia, type 1 (MEN I), is an autosomal dominant syndrome of selected endocrine neoplasms whose causative gene, a suspected tumor suppressor, has been localized to chromosome 11q13, but has not been identified. Recently, the HNP36 cDNA was identified as a novel growth factor responsive gene of undetermined biological function that is expressed in the pituitary and parathyroid glands. In studies seeking the function of the HNP36 gene product, the gene was localized by fluorescence in situ hybridization within the 11q13 segment. Further analysis of radiation-reduced hybrid DNAs and chromosome 11-specific YAC clones established that the HNP36 gene is within 80 kb of D11S913, a marker tightly linked to the MEN1 gene. Consequently, the HNP36 gene was studied as a candidate for the MEN1 gene. The human HNP36 gene was cloned and determined to consist of 12 exons. Expression of the HNP36 gene from pituitary and parathyroid tissue and four patient tumors or lymphoblasts was confirmed by RT-PCR amplification of the coding sequences, and HNP36 transcripts were analyzed for mutations. All tissues expressed three HNP36 gene transcripts that result from alternative splicing and appear to encode related, but distinct, proteins. However, DNA sequence determination of the RT-PCR products from MEN I-associated tumors found no deletions and identified a single nucleotide difference that may be a polymorphism. Thus, mutations in the coding segments of the HNP36 gene are not the cause of the MEN I syndrome. Nevertheless, the assignment of the HNP36 gene to 11q13 and identification of new potential gene products provides a novel growth-regulated genetic candidate for other disorders whose genes map to this locus.

Binning clones by hybridization with complex probes: statistical refinement of an inner product mapping method

Molecular methods that use long-range information to solve genomics problems (i.e., top-down strategies) efficiently have become increasingly prominent in the genomics literature. One such method, an implementation of inner product mapping (IPM), uses noisy, long-range radiation hybrid (RH)/YAC overlap data and relatively noise-free RH/STS overlap data to localize clones to specific chromosomal regions. Because the molecular data are rarely noise-free, statistical models tailored to the top-down molecular methods make the methods far more effective. We develop two statistical models for IPM (or any other top-down strategy of similar form), a parametric logit model and a nonparametric order-restricted model, and show how these models can be implemented within a hierarchical Bayes framework. Using these models, we refine the chromosome 11 map reported in M. Perlin et al. (1995, Genomics 28: 315-327). Our analyses improve the IPM map, both in terms of successful localization of clones and in terms of the confidence with which they are localized.

A sequence-ready high-resolution physical map of the best macular dystrophy gene region in 11q12-q13

Best disease, an autosomal dominant inherited macular degenerative disorder, was previously localized between D11S1765 and UGB (uteroglobin) in 11q13 by genetic linkage analysis. Since this region was found to be refractory to cloning in YAC (yeast artificial chromosome)-based vectors, a P1 artificial chromosome (PAC) contig was assembled. Gridded PAC libraries representing a 16-fold genome equivalent were screened by hybridization using PCR products representing STSs derived from YAC end sequences, markers binned to 11q13, and PAC-derived insert ends. A highly marker dense approximately 1.7-Mb PAC contig that encompassed the disease gene region was constructed, allowing us to order accurately the markers throughout the region and to provide the most precise estimate of its physical size. Using this contig, thus far we have mapped seven anonymous ESTs and five known genes into this region. This high-resolution physical map will facilitate the isolation of polymorphic markers for refinement of the disease gene region, as well as the identification of candidate genes by exon trapping, cDNA selection, and gene prediction from PAC-derived genomic sequence.

Growth and storage of YAC clones in Hogness Freezing Medium

To date, frozen storage of YAC libraries have relied on the administration of glycerol to the medium subsequent to cell growth. By adding Hogness Freezing Medium prior to inoculation, cultures can be frozen directly after cell growth, with no adverse effect on the stability of the YAC DNA or on the viability of the cells even after repeated freezing and defrosting. Although a relatively simple modification, the procedure notably improves the handling of YAC libraries and significantly reduces the risk of contamination, especially when dealing with large numbers of clones.

Construction of a transcription map around the gene for ataxia telangiectasia: identification of at least four novel genes

We have constructed YAC, PAC, and cosmid contigs in the ataxia-telangiectasia gene region and used the assembled clones to isolate expressed sequences by exon trapping and hybridization selection. In the interval between D11S1819 and D11S2029, exons and cDNAs for potentially 13 different genes were identified. Three of these genes, F37, K28, and 6.82, are large novel genes expressed in a variety of different tissues. K28 shows sequence homology to the Rab GTP binding protein family and gene 6.82 homology to the rabbit vasopressin activated calcium mobilizing receptor, while gene F37 has no homology to any known sequence in the database. Three further clones, exon 6.41 and cDNAs K22 and E74, from the interval between D11S1819 and D11S2029, appear to be expressed endogenous retrovirus sequences. The fourth large novel genes, E14, together with two further possible novel genes, E13 and E3, was identified from exons and cDNAs in the more telomeric 300-kb interval between markers D11S2029 and D11S2179. These are in addition to the genes for mitochondrial acetoacetyl-CoA-acetyltransferase (ACAT) and the ATM gene in the same region. Genes E3, E13, and E14 do not show homology to any known genes. K28, 6.82, ACAT, and ATM all appear to have the same transcriptional orientation toward the telomere.

Framework YAC contig anchored into a 3.2-Mb high-resolution physical map in proximal 11q13

Despite the presence on band q13 of chromosome 11 of a number of genes predisposing individuals to various human diseases, most of this genomic region remains loosely mapped. Moreover, there is a relative dearth of yeast artificial chromosome (YAC) contigs from genome-wide studies: YACs are irregularly distributed over this chromosomal region and have not been arranged into contigs. We have thus undertaken fine-scale mapping of a 3.2-Mb region flanked by ACTN3 and FGF3. Since this region has demonstrated a high degree of YAC instability, we have established a framework contig by anchoring YACs and cosmids into a high-resolution physical map based on fluorescence in situ hybridization and long-range restriction mapping. The 3.2-Mb area studied includes the boundaries of regions thought to contain genes predisposing individuals to osteoporosis-pseudoglioma syndrome and insulin-dependent diabetes mellitus, as well as genes driving amplification events in human carcinomas. Another feature of this genomic area is that it cross-hybridizes to nonsyntenic regions of the genome. In addition, it spans the region where syntenic conservation with mouse chromosome 19 ends, making clones that we have anchored there valuable tools in understanding genome evolution.

The EXT2 multiple exostoses gene defines a family of putative tumour suppressor genes

Hereditary multiple exostoses (EXT) is an autosomal dominant condition characterized by short stature and the development of bony protuberances at the ends of all the long bones. Three genetic locl have been identified by genetic linkage analysis at chromosomes 8q24.1, 11p11-13 and 19p. The EXT1 gene on chromosome 8 was recently identified and characterized. Here, we report the isolation and characterization of the EXT2 gene. This gene shows striking sequence similarity to the EXT1 gene, and we have identified a four base deletion segregating with the phenotype. Both EXT1 and EXT2 show significant homology with one additional expressed sequence tag, defining a new multigene family of proteins with potential tumour suppressor activity.

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.

Fish techniques for constructing physical maps on schistosome chromosomes

In an effort to provide useful information about parasites important in tropical diseases, the WHO has initiated genome mapping projects for a number of parasites. One goal of this effort is to establish physical maps of the genomes of the targeted parasites. Multicellular parasites (helminths) contain various numbers of chromosomes, some large, that condense during the cell cycle. Here Hirohisa Hirai and Phil LoVerde present details of fluorescence in situ hybridization as a means to localize genes and DNA fragments to schistosome chromosomes. Although the techniques presented are for schistosome chromosomes, they are applicable to any system where the chromosomes condense at metaphase.

Mapping of ribosomal protein S3 and internally nested snoRNA U15A gene to human chromosome 11q13.3-q13.5

The mammalian ribosome is a massive structure composed of 4 RNA species and about 80 different proteins. One of these ribosomal proteins, S3, appears to function not only in translation but also as an endonuclease in repair of UV-induced DNA damage. Moreover, the first intron of human RPS3 transcripts is processed to generate U15A, a small nucleolar RNA. We localized the nested RPS3/U15A genes to the immediate vicinity of D11S356 and D11S533 on human chromosome 11q13.3-q13.5 using a combination of somatic cell hybrid analysis, fluorescence in situ hybridization, and YAC/STS content mapping. These findings add to the evidence that genes encoding ribosomal proteins are scattered about the human genome.

A human chromosome 7 yeast artificial chromosome (YAC) resource: construction, characterization, and screening

The paradigm of sequence-tagged site (STS)-content mapping involves the systematic assignment of STSs to individual cloned DNA segments. To date, yeast artificial chromosomes (YACs) represent the most commonly employed cloning system for constructing STS maps of large genomic intervals, such as whole human chromosomes. For developing a complete YAC-based STS-content map of human chromosome 7, we wished to utilize a limited set of YAC clones that were highly enriched for chromosome 7 DNA. Toward that end, we have assembled a human chromosome 7 YAC resource that consists of three major components: (1) a newly constructed library derived from a human-hamster hybrid cell line containing chromosome 7 as its only human DNA; (2) a chromosome 7-enriched sublibrary derived from the CEPH mega-YAC collection by Alu-polymerase chain reaction (Alu-PCR)-based hybridization; and (3) a set of YACs isolated from several total genomic libraries by screening for > 125 chromosome 7 STSs. In particular, the hybrid cell line-derived YACs, which comprise the majority of the clones in the resource, have a relatively low chimera frequency (10-20%) based on mapping isolated insert ends to panels of human-hamster hybrid cell lines and analyzing individual clones by fluorescence in situ hybridization. An efficient strategy for polymerase chain reaction (PCR)-based screening of this YAC resource, which totals 4190 clones, has been developed and utilized to identify corresponding YACs for > 600 STSs. The results of this initial screening effort indicate that the human chromosome 7 YAC resource provides an average of 6.9 positive clones per STS, a level of redundancy that should support the assembly of large YAC contigs and the construction of a high-resolution STS-content map of the chromosome.

Yeast artificial chromosome (YAC)-based genome mapping of Schistosoma mansoni

Schistosoma mansoni has 7 pairs of autosomal chromosomes and one pair of sex chromosomes (ZZ for a male worm and ZW for a female), of a haploid genome size of 2.7 x 10(8) bp. We initiated the molecular genetic approach for the detailed characterization and understanding of the evolutionary biology of schistosomes. We have constructed a yeast artificial chromosome (YAC)-library with partially digested parasite genomic DNA, and the chromosome location of each insert was detected by fluorescent in situ hybridization (FISH). The library contains > 2283 clones with an average insert size of 358 kb, which represents a 2.6-fold coverage of the genome (> 7.2 x 10(8) bp). 100 randomly selected YAC clones were localized by FISH and found to be distributed widely among all chromosomes. The assembly of 14 YACs distributed almost the whole region of chromosome 3. Generated expressed sequenced tags (ESTs) derived from a unidirectional cDNA library were also used for further characterization of the YAC inserts. These results indicate that an extensive contig assembly of the entire chromosomes and a reasonably detailed gene map should be feasible in the near future.

Construction of a porcine YAC library and mapping of the cardiac muscle ryanodine receptor gene to chromosome 14q22-q23

Large-scale physical mapping of the porcine genome has been limited because up to now no suitable genomic libraries for this purpose have been available. Therefore, we have constructed a yeast artificial chromosome (YAC) library from porcine lymphocytes. The library was cloned in the amplifiable vector pCGS966. A total of 10080 YAC clones was obtained and has been ordered into 105 96-well microtiter plates. An average insert size of 300 kb was calculated from the analysis of 78 randomly selected clones, giving a one-fold coverage of the porcine genome. To analyze the complexity, we have screened the library for five different genes and isolated four different clones containing parts of three of these genes. One YAC clone harboring parts of the porcine cardiac muscle ryanodine receptor (RYR2) gene allowed us to assign this locus to Chromosome (Chr) 14q22-q23. The data were confirmed by PCR analysis of a rodent-porcine hybrid cell panel.

Sequence tagged sites of microclones obtained by microdissection of a human chromosomal region 11q23 and isolation of yeast artificial chromosomes

A human chromosomal region 11q23-specific DNA library has been constructed by means of microdissection-microcloning method with polymerase chain reaction (PCR) technique (Seki et al., Genomics 16: 1993). DNA sequences were determined for 25 microclones that contained approximately 300-500 bp insert and gave a unique (single copy) signal in Southern blot analysis. The sequence tagged site (STS) was designed and appropriate condition for PCR was determined for each unique microclone. Twelve STSs were established and used for PCR-screening of human genomic libraries constructed with yeast artificial chromosome (YAC). Thirteen YAC clones have been isolated from eight STSs. These chromosomal region-specific STSs and YAC clones will be useful in the positional cloning of disease-related genes localized to the q23 region of chromosome 11.

Characterization of a cosmid library from flow-sorted chromosomes 11

A cosmid library specific for human chromosome 11 has been constructed from flow-sorted chromosomes. The flow-purified chromosomes were prepared from the hamster/human hybrid line J1 which contains chromosome 11 as the only human chromosome. Individual clones were sampled in 187 microtitre plates, resulting in a total of 17,952 colonies. Hybridization analysis revealed that 83.7% of these clones were of human and 10.4% of hamster origin. The average insert size was estimated at 33.6 kb, and only 2.4% of insert fragments appear to be rearranged. This should result in 494,487 kb of cloned human DNA representing 3.5 chromosome 11 equivalents. We have prepared high-density nylon membranes of the arrayed library containing 1,536 single colonies per filter. We have demonstrated the usefulness of the library in the molecular genetic analysis of human chromosome 11 by testing for the presence of possibly polymorphic simple repeat motifs, by identifying cosmids that contain inserts from the telomeric ends of chromosome 11 and by assessing the potential of the library for rapid chromosome walking.

Complete sequence of the yeast artificial chromosome cloning vector pYAC4

The cloning vector pYAC4 is widely used in the construction of yeast artificial chromosome (YAC) genomic libraries. The sequence of pYAC4, 11454 nucleotides (nt) in length, has been assembled from published sources and is presented in its entirety.

Identification of human chromosome region 3p14.2-21.3-specific YAC clones using Alu-PCR products from a radiation hybrid

Deletion of DNA sequences from at least three different regions on the short arm of human chromosome 3 (3p13-14, 3p21 and 3p25) are frequently observed during the development of many solid tumors, including lung cancers and renal cell carcinomas. In order to physically characterize the 3p21 region, we previously identified a radiation fusion hybrid that contained about 20 megabases of DNA from chromosome region 3p14.2-p21.3. In this study total Alu-PCR products from this hybrid were used as a probe to isolate 86 yeast artificial chromosomes (YAC) clones from a 620-kb average insert YAC library (ICRF). Sixty-nine Alu-PCR markers, generated from the YACs, and seven PCR primers were used to screen for overlaps between individual clones. Seven contigs were identified encompassing 32 YAC clones. Based on previous information about localization of the PCR primers, the three largest contigs could be assigned to smaller subregions between 3p14.2 and 3p21.3. By this work a large proportion of the 3p14.2-21.3 region is covered with large-insert YAC clones.