Overlapping Yeast Artificial Chromosome Clones Research Articles

DNA rescue by the vectorette method.

AbstractA major advance in physical mapping of the human genome was the development of yeast artificial chromosome (YAC) vectors (1). This has enabled the cloning of pieces of DNA several hundred kilobases in length (2). The availability of such large cloned genomic DNA fragments means that by ordering a series of overlapping YAC clones, a contiguous stretch of DNA, several megabases in length, can be isolated around a genomic region of interest (e.g., the region of a chromosome linked to a particular disease gene). The successful isolation of terminal sequences of a given YAC can be very useful in assembling an ordered “contig” of YAC clones. Such terminal clones may be used directly as hybridization probes or sequenced and used to generate sequence tagged sites (STSs) to identify overlaps between, and isolate other, members of the contig. Several methods have been used to this end, including PCR with vector-specific primers in combination with primers designed either for repetitive elements, such as Alu sequences (3), or in combination with random nonspecific primers (4). However, these techniques rely on a suitable repetitive element or random primer sequence occurring close enough to the end of the YAC so as to be amplified by PCR. Furthermore, probes isolated in this manner may well contain highly repetitive sequences that, if unsuccessfully blocked, will increase nonspecific signal in any subsequent hybridization procedures (5).KeywordsTerminal SequenceYeast Artificial ChromosomeEnzyme BufferAgarose PlugYeast Artificial Chromosome CloneThese keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Identification of YAC clones containing the mutable slender glume locus slg in rice (Oryza sativa L.)

A mutable slender glume gene slg, which often reverts to the wild-type state, was induced by gamma-ray irradiation of seeds of the japonica rice cultivar 'Gimbozu'. The final goal was to understand whether the slender glume mutation was associated with the insertion of a transposable element, utilizing map-based cloning techniques. The RFLP (restriction fragment length polymorphism) analysis revealed that the slg locus was located between two RFLP loci, XNpb33 and R1440, on chromosome 7 with recombination values of 3.1% and 1.0%, respectively. Using these two RFLP loci as probes, five YAC (yeast artificial chromosome) clones containing either of these two loci were selected from a YAC library. Subsequently, both end fragments of these YAC clones, amplified by the inverse PCR (IPCR) method, were used to select new YAC clones more closely located to the slg locus. After repeating such a procedure, we successfully constructed a 6-cM YAC contig, and identified four overlapping YAC clones, Y1774, Y3356, Y5124, and Y5762, covering the slg locus. The chromosomal location of the slg was narrowed down to the region with a physical distance of less than 280 kb between the right-end fragments of Y1774 and Y3356.Key words: Oryza sativa, mutable gene, slender glume mutation, YAC contig.

Identification of YAC clones containing the mutable slender glume locus slg in rice (Oryza sativa L.).

A mutable slender glume gene slg, which often reverts to the wild-type state, was induced by gamma-ray irradiation of seeds of the japonica rice cultivar 'Gimbozu'. The final goal was to understand whether the slender glume mutation was associated with the insertion of a transposable element, utilizing map-based cloning techniques. The RFLP (restriction fragment length polymorphism) analysis revealed that the slg locus was located between two RFLP loci, XNpb33 and R1440, on chromosome 7 with recombination values of 3.1% and 1.0%, respectively. Using these two RFLP loci as probes, five YAC (yeast artificial chromosome) clones containing either of these two loci were selected from a YAC library. Subsequently, both end fragments of these YAC clones, amplified by the inverse PCR (IPCR) method, were used to select new YAC clones more closely located to the slg locus. After repeating such a procedure, we successfully constructed a 6-cM YAC contig, and identified four overlapping YAC clones, Y1774, Y3356, Y5124, and Y5762, covering the slg locus. The chromosomal location of the slg was narrowed down to the region with a physical distance of less than 280 kb between the right-end fragments of Y1774 and Y3356.

Chromosome landing at the barley Rar1 locus.

The barley Rar1 gene is an essential component of the race-specific, Mla-12-specified powdery mildew resistance reaction. As part of a map-based cloning strategy designed to isolate Rar1, five barley yeast artificial chromosomes (YACs) have been identified, ranging in size from 300 to 1100 kb. PCR-based YAC end-specific markers have been established and were employed to construct a local YAC contig. Four out of five YAC clones were found to be non-colinear with the source DNA. High-resolution genetic mapping of the YAC ends demonstrated that the set of five overlapping YAC clones encompasses the barley Rar1 gene.

Isolation and FISH mapping of Yeast Artificial Chromosomes (YACs) encompassing an allele of the Gm2 gene for gall midge resistance in rice

Ten yeast artificial chromosomes (YACs) spanning the Gm2 locus have been isolated by screening high-density filters containing a total of approximately 7000 YAC (representing six genome equivalents) clones derived from a japonica rice, Nipponbare. The screening was done with five RFLP markers flanking a gall midge resistance gene, Gm2, which was previously mapped onto chromosome 4 of rice. This gene confers resistance to biotype 1 and 2 of gall midge (Orseolia oryzae), a major insect pest of rice in South and Southeast Asia. The RFLP markers RG214, RG329 and F8 hybridized with YAC Y2165. Two overlapping YAC clones (Y5212 and Y2165) were identified by Southern hybridization, with Gm2-flanking RFLP markers, and their inserts isolated. The purified YACs and RFLP markers flanking Gm2 were labeled and physically mapped by the fluorescence in situ hybridization (FISH) technique. All of them mapped to the long arm of chromosome 4 of the resistant variety of rice, ‘Phalguna’, confirming the previous RFLP mapping data.

A High-Density STS Map Based on a Single Contig of YAC and P1 Clones in the Chromosome 8p12–p21 Region

We have constructed a yeast artificial chromosome (YAC) and P1 contig in the 8p12–p21 region. The contig comprises 16 overlapping YAC clones and 44 overlapping P1 clones. Twelve dinucleotide-repeat polymorphic sequence-tagged site (STS) markers that were previously isolated mainly from these YAC and P1 clones were genetically mapped. A total of 46 nonpolymorphic STS markers were newly established mainly from the YAC and P1 clone end fragments, and 28 of the 46 nonpolymorphic STSs, as well as the 12 polymorphic STSs, were also mapped physically onto the contig based on STS content analysis of YAC pools and of the P1 and YAC clones. As a result, the YAC and P1 clones were assembled into a single contig covering a minimum of 1.5 Mb physically and 2.8 cM genetically with 12 polymorphic and 28 nonpolymorphic STSs within the 8p12–p21 region. Average STS spacing in the contig was estimated to be 40 kb/STS. In addition, further characterization of the contig suggested that this contig includes a region where genetic recombination occurs frequently. Thus, the resulting cloned region, together with densely mapped STS markers on the contig, should help to promote our understanding of this region.

A Yeast Artificial Chromosome (YAC) Contig Encompassing the Critical Region of the X-Linked Lymphoproliferative Disease (XLP) Locus

X-linked lymphoproliferative disease (XLP) is characterized by a marked vulnerability to Epstein–Barr virus (EBV) infection. Infection of XLP patients with EBV invariably results in fatal mononucleosis, agammaglobulinemia, or malignant lymphoma. Initially the XLP gene was assigned to a 10-cM region in Xq25 between DXS42 and DXS37. Subsequently, an interstitial, cytogenetically visible deletion in Xq25 was identified in one XLP family, 43. In this study we estimated the deletion in XLP patient 43-004 by dual-laser flow karyotyping to involve 2% of the X chromosome, or approximately 3 Mb of DNA sequence. From a human chromosome Xq25-specific yeast artificial chromosome (YAC) sublibrary, five YACs containing DNA sequences deleted in patient 43-004 have been isolated. Sequence-tagged sites (STSs) from these YACs have been used to identify interstitial deletions in unrelated XLP patients. Three more families with interstitial deletions were found. Two of the patients (63-003 and 73-032) carried an interstitial deletion of 3.0 Mb overlapping the 43-004 deletion. In one XLP patient (30-011) who exhibited the characteristic postinfectious mononucleosis phenotype of XLP with hypogammaglobulinemia and malignant lymphoma, a deletion of approximately 250 kb was detected overlapping the deletion detected in patients 43-004, 63-003, and 73-032. A YAC contig of 2.2 Mb spanning the XLP critical region, whose orientation on chromosome X was determined by double-color fluorescencein situhybridization and which consists of 15 overlapping YAC clones, has been constructed. A detailed restriction enzyme map of the region has been constructed. YAC insert sizes were determined by counter-clamped homogenous electric field gel electrophoresis. Chimerism of YACs was determined by FISH and restriction mapping. On the basis of lambda subclones, YAC end-derived plasmids, and STSs with an average spacing of 100 kb, a long-range physical map was constructed using 5 rare-cutter restriction enzymes. The STSs and lambda subclones were used in Southern hybridization and PCR analyses. The work presented here substantially refines the critical region for XLP. The YAC contig with the overlapping interstitial deletions constitutes the basis for the construction of a transcriptional map of the critical region and facilitates the identification of the XLP gene.

Generation of a YAC contig encompassing the extra glume gene,eg, in rice

We have used DNA markers from a high density molecular map of rice (Oryza sativa) to tag a single gene expressed as a flower morphogenesis mutation, extra glume (eg). Using an F2 population segregating for eg, obtained from a cross between IR24 and F136 (eg/eg), we constructed a partial molecular map and located eg relative to restriction fragment length polymorphism markers. The region between two markers appears to span the eg locus on rice chromosome 1 and extends to a genetic length of 3.8 cM. The yeast artificial chromosome (YAC) library obtained from rice variety 'Nipponbare', which carries the wild-type allele of eg, was screened to completely cover the locus by overlapping YAC clones. The eg allele should be contained in two overlapping YACs. YAC size determination by pulsed-field gel electrophoresis indicated that this region has a physical length of approximately 400 kb. We anticipate that the tagging of eg in a relatively short stretch of DNA will allow a molecular characterization of this gene through map-based cloning. Key words : rice, gene tagging, YAC contig, flower morphogenesis, extra glume.

Refined Mapping and YAC Contig Construction of the X-Linked Cleft Palate and Ankyloglossia Locus (CPX) Including the Proximal X–Y Homology Breakpoint within Xq21.3

The gene for X-linked cleft palate (CPX) has previously been mapped in an Icelandic kindred between the unordered proximal markers DXS1002/DXS349/DXS95 and the distal marker DXYS1X, which maps to the proximal end of the X–Y homology region in Xq21.3. Using six sequence-tagged sites (STSs) within the region, a total of 91 yeast artificial chromosome (YAC) clones were isolated and overlapped in a single contig that spans approximately 3.1 Mb between DXS1002 and DXYS1X. The order of microsatellite and STS markers in this was established as DXS1002–DXS1168–DSX349–DXS95–DXS364–DXS1196–DXS262–DXS110–DXS1066–(DXS1169, DXS1222)–DXS472–DXS1217–DXYS1X. A long-range restriction map of this region was created using eight nonchimeric, overlapping YAC clones. Analysis of newly positioned polymorphic markers in recombinant individuals from the Icelandic family has enabled us to identify DXS1196 and DXS1217 as the flanking markers for CPX. The maximum physical distance containing the CPX gene has been estimated to be 2.0 Mb, which is spanned by a minimum set of five nonchimeric YAC clones. In addition, YAC end clone and STS analyses have pinpointed the location of the proximal boundary of the X–Y homology region within the map.

A YAC-based contig of 1.5 Mb spanning the human multidrug resistance gene region and delineating the amplification unit in three human multidrug-resistant cell lines.

A contig of 21 nonchimeric yeast artificial chromosomes (YACs) has been assembled across 1.5 Mb of the multidrug resistance (MDR) gene region located at 7q21, and formatted with four previously reported probes, six newly isolated probes, and three sequence-tagged sites (STSs) from internal and end fragments of YACs. A physical map of rare cutter restriction enzyme sites across the region was also constructed by pulsed-field gel electrophoretic (PFGE) analysis of four overlapping YAC clones. The amplification unit of this region in different cell lines was then determined by Southern blot analysis on the basis of the physical map and probes. Amplified DNA was located in extrachromosomal elements in human MDR cell lines studied here, and the size of the amplification unit was determined to be discrete in one MDR amplification but variable in others.

Structure and Organization of the Human Glucose Phosphate Isomerase Gene (GPI)

Two overlapping yeast artificial chromosome clones containing the human glucose 6-phosphate isomerase gene (GPI) have been isolated. PCR and direct sequencing were used to determine the exon/intron structure of the gene. The gene spans in excess of 40 kb and consists of 18 exons ranging in size from 44 to 153 bp. All splice sites conform to the GT/AG rule.

Analysis of pericentromeric chromosome 21 specific YAC clones by FISH: Identification of new markers for molecular-cytogenetic application

Fluorescence in situ hybridization (FISH) of chromosome 21 specific yeast artificial chromosome (YAC) clones after Alu-PCR (polymerase chain reaction) amplification has been used to find new region-specific DNA probes for the heterochromatic region of chromosome 21. Six overlapping YAC clones from a pericentromeric contig map (region 21cen-21q11) were analyzed. Four YAC clones were characterized as hybridizing to several chromosomal locations. They are, therefore, either chimeric or shared by different chromosomes. Two of them containing alphoid satellite DNA, are localized at the centromeric regions of chromosomes 13 and 21 (clone 243A11), and on 13cen, 21cen and 1q3 (clone 781G5); the two others are localized at both 21q11 and 13q2 (clone 759D3), and at 18p (clone 770B3). Two YACs were strongly specific for chromosome 21q11 only (clones 124A7 and 881D2). These YACs were used effectively as probes for identifications of chromosome 21 during metaphase and interphase analysis of 12 individuals, including three families with Down syndrome offspring, and 6 aminocyte samples. The location of YAC clones on 21q11 close to the centromeric region allows the application of these clones as molecular probes for the analysis of marker chromosomes with partial deletions of the long arm as well as for pre- and postnatal diagnosis of trisomy 21 when alphoid or more distal region-specific DNA probes are uninformative. Overlapping YAC clones covering human chromosome 21q may be systematically used to detect a set of band-specific DNA probes for molecular-cytogenetic application.

A set of ninety-seven overlapping yeast artificial chromosome clones spanning the human Y chromosome euchromatin.

Contiguous arrays of yeast artificial chromosomes (YACs) extending from proximal heterochromatic Yq into the pseudoautosomal portion of the Y chromosome and separated by a small interval at the centromere have been constructed. A total of 97 YACs have been aligned along the Y chromosome by STS content analysis using 222 sequence tagged sites (STSs) that detect 263 loci. Forty-five of the STSs used are novel. Their inclusion provides a significant improvement over previously available maps on the density of STS coverage along the Y chromosome, reducing the average spacing to 120 kb assuming a length of 30 Mb for the euchromatin. The average size of 61 YACs determined by pulsed-field gel electrophoresis analysis was at least 0.9 Mb. Minor differences noted between the ordering of STSs on this map compared with those previously reported may be attributed to inherent polymorphism between the Y chromosomes used to construct the YAC libraries.

DNA class organization on maize Adh1 yeast artificial chromosomes.

The organization of higher plant genomes is poorly understood. These genomes are typified by their large size and extensive repetitive DNA component. To further our understanding of the composition and arrangement of genomic DNA sequences, we have performed a detailed analysis of a contiguous interval of 280 kb surrounding the Adh1 locus of maize. A series of overlapping lambda subclones was isolated, and individual fragments were characterized with respect to their genomic copy number. Cross-hybridization analyses were used to define a minimum of 37 repetitive DNA classes within the 280-kb interval. Hybridizations with highly repetitive DNAs cloned from other regions of the maize genome suggested that > 50% of all highly repetitive elements in maize are represented on this single yeast artificial chromosome. These repeated sequences were found in an organizational pattern not previously observed; individual repetitive elements are interspersed with one another in an apparently random fashion and are spatially separate from single copy number sequences. Extensive tandem arrays were not found. Sequences from one end of the 280-kb interval were used to isolate overlapping yeast artificial chromosome clones, representing the first step in a chromosome walk.

X-linked mixed deafness (DFN3): cloning and characterization of the critical region allows the identification of novel microdeletions.

We have found that the microsatellite marker AFM207zg5 (DXS995) maps to all previously described deletions which are associated with X-linked mixed deafness (DFN3) with or without choroideremia and mental retardation. Employing this marker and pHU16 (DXS26) we have identified two partially overlapping yeast artificial chromosome clones which were used to construct a complete 850 kb cosmid contig. Cosmids from this contig have been tested by Southern blot analysis on DNA from 16 unrelated males with X-linked deafness. Two novel microdeletions were detected in patients which exhibit the characteristic DFN3 phenotype. Both deletions are completely contained within one of the known DFN3-deletions, but one of them does not overlap with two previously described deletions in patients with contiguous gene syndromes consisting of DFN3, choroideremia, and mental retardation. Assuming that only a single gene is involved, this suggests that the DFN3 gene spans a chromosomal region of at least 400 kb.

Physical mapping of the split hand/split foot locus on chromosome 7 and implication in syndromic ectrodactyly.

Split hand/split foot (ectrodactyly; SHSF) is a human developmental malformation characterized by missing digits and claw-like extremities. An autosomal dominant form of this disorder has been mapped to 7q21.3-q22.1; the locus has been designated SHFD1. We have constructed a physical map consisting of overlapping yeast artificial chromosome clones for the entire region. Somatic cell hybrid and fluorescent in situ hybridization analyses were used to define SHSF-associated chromosomal rearrangements in twelve patients. An SHFD1 critical interval of 1.5 Mb was established by analysis of five patients with deletions. Translocation or inversion breakpoints found in six patients were mapped within 700 kb of each other in the critical region. Of note is that eight of the patients analyzed (67%) are in fact classified as having syndromic ectrodactyly. Thus, these mapping data establish a relationship between simple split hand/split foot and this more complex group of human birth defects. Finally, we have mapped DLX5, a member of the Distal-less homeobox gene family, to the SHFD1 critical interval.

Isochores and CpG Islands in YAC Contigs in Human Xq26.1-qter

GC levels were assessed at 37 loci across 30 Mb of Xq26.1-qter, a region physically mopped in overlapping yeast artificial chromosome clones. In 8 Mb of R band Xq26, GC is relatively high (up to 44%) in the proximal 4 Mb and relatively low (40-41%) in the distal 4 Mb. Consistently low GC values (38-41%) are observed in G band Xq27. In contrast, further toward the telomere in Xq28, the GC level rises progressively to reach 52% at 2 to 4 Mb from the end of the chromosome; this region is delimited by low GC loci. Across these regions of Xq, the content of rare-cutter restriction enzyme sites containing CpG, including "CpG islands" in the most completely mapped Xq26-27.1 region, is correlated with GC level. Isochore mapping can thus provide one index of putative gene content across mapped regions.

Construction of a yeast artificial chromosome contig spanning the spinal muscular atrophy disease gene region.

The childhood spinal muscular atrophies (SMAs) are the most common, serious neuromuscular disorders of childhood second to Duchenne muscular dystrophy. A single locus for these disorders has been mapped by recombination events to a region of 0.7 centimorgan (range, 0.1-2.1 centimorgans) between loci D5S435 and MAP1B on chromosome 5q11.2-13.3. By using PCR amplification to screen yeast artificial chromosome (YAC) DNA pools and the PCR-vectorette method to amplify YAC ends, a YAC contig was constructed across the disease gene region. Nine walk steps identified 32 YACs, including a minimum of seven overlapping YAC clones (average size, 460 kb) that span the SMA region. The contig is characterized by a collection of 30 YAC-end sequence tag sites together with seven genetic markers. The entire YAC contig spans a minimum of 3.2 Mb; the SMA locus is confined to roughly half of this region. Microsatellite markers generated along the YAC contig segregate with the SMA locus in all families where the flanking markers (D5S435 and MAP1B) recombine. Construction of a YAC contig across the disease gene region is an essential step in isolation of the SMA-encoding gene.

Chromosomal Localization and Structure of the Human Type II IMP Dehydrogenase Gene (IMPDH2)

We determined the chromosomal localization and structure of the gene encoding human type II inosine 5′-monophosphate dehydrogenase (IMPDH, EC 1.1.1.205), an enzyme associated with cellular proliferation, malignant transformation, and differentiation. Using polymerase chain reaction (PCR) primers specific for type II IMPDH, we screened a panel of human-Chinese hamster cell somatic hybrids and a separate deletion panel of chromosome 3 hybrids and localized the gene to 3p21.2→p24.2. Two overlapping yeast artificial chromosome clones containing the full gene for type II IMPDH (IMPDH2) were isolated, and a physical map of 117 kb of human genomic DNA in this region of chromosome 3 was constructed. The gene for type II IMPDH was localized and oriented on this map and found to span no more than 12.5 kb.

Transcriptional differences in polymorphic and conserved domains of a complete cloned P. falciparum chromosome

Classical genetic studies on the human malaria parasite Plasmodium falciparum have been hampered by a complex life cycle which alternates between vertebrate and invertebrate hosts. Consequently, only a few genetic crosses have been performed so far. In addition, molecular genetics has provided only limited access to the genes of this pathogen, a consequence of an unusually high A + T content. To overcome these limitations we have constructed an ordered telomere-to-telomere contig map of P. falciparum chromosome 2 by isolating overlapping yeast artificial chromosome clones. This approach was used to examine the strain-dependent polymorphisms commonly observed for P. falciparum chromosomes. Our analysis reveals that polymorphisms of chromosome 2 are restricted to regions at either end, representing 20% of the chromosome. Transcription mapping of the entire chromosome suggests a compartmentalization of chromosome 2 into a transcribed central domain and silent polymorphic ends.