Molecular cloning and mapping of the ecotropic leukemia provirus Emv-23 provides molecular access to the albino-deletion complex in mouse chromosome 7

Genetic analysis of radiation-induced deletion mutations involving the chromosome 7 albino (c) locus has expanded the functional map of this 6 to 11-cM region of the mouse genome. To generate one of many points of molecular access necessary for intensifying the analysis of the genes and phenotypes associated with this particular complex of deletions, we have cloned an endogenous ecotropic leukemia provirus (Emv-23), known to be closely linked to c, along with its flanking chromosome 7 sequences. A unique-sequence probe (23.3), derived from a region immediately 5' to the proviral integration site, was found to map less than 0.5 cM from c in a standard backcross analysis. Southern blot analysis of DNAs from animals carrying homozygous or overlapping albino deletions demonstrated that the 23.3 probe was deleted in several relatively small c-region deletions. The deletion mapping of the 23.3 probe places the Emv-23 locus between c and Mod-2, just proximal to a region important for male fertility and juvenile fitness. Mapping of this locus also provides a refinement of the genetic/deletion map for several mutations within this deletion complex.     

Genomic analysis and marker development for the Tsn1 locus in wheat using bin-mapped ESTs and flanking BAC contigs

The wheat Tsn1 gene confers sensitivity to the host-selective toxin Ptr ToxA produced by the tan spot fungus (Pyrenophora tritici-repentis). The long-term goal of this research is to isolate Tsn1 using a positional cloning approach. Here, we evaluated 54 ESTs (expressed sequence tags) physically mapped to deletion bin 5BL 0.75–0.76, which is a gene-rich region containing Tsn1. Twenty-three EST loci were mapped as either PCR-based single-stranded conformational polymorphism or RFLP markers in a low-resolution wheat population. The genetic map corresponding to the 5BL 0.75–0.76 deletion bin spans 18.5 cM and contains 37 markers for a density of 2 markers/cM. The EST-based genetic map will be useful for tagging other genes, establishing colinearity with rice, and anchoring sequence ready BAC contigs of the 5BL 0.75–0.76 deletion bin. High-resolution mapping showed that EST-derived markers together with previously developed AFLP-derived markers delineated Tsn1 to a 0.8 cM interval. Flanking markers were used to screen the Langdon durum BAC library and contigs of 205 and 228 kb flanking Tsn1 were assembled, sequenced, and anchored to the genetic map. Recombination frequency averaged 760 kb/cM across the 228 kb contig, but no recombination was observed across the 205 kb contig resulting in an expected recombination frequency of more than 10 Mb/cM. Therefore, chromosome walking within the Tsn1 region may be difficult. However, the sequenced BACs allowed the identification of one microsatellite in each contig for which markers were developed and shown to be highly suitable for marker-assisted selection of Tsn1.     

用微卫星标记构建两系稻培矮64s/E32的分子遗传连锁图 Construction of a Microsatellite Linkage Map in a DH Population

用两系杂交稻强优组合培矮64s/E32的一个加倍单倍体（DH）群体,共86个株系,构建了水稻的SSR标记遗传连锁图。选用美国康耐尔大学公布的302对SSR引物,共有127对在两个亲本间检测到多态性,比率为4205%。建成的水稻染色体的图谱（记为PEMAP）共包含122个SSLP标记座位,总长度为1213.4 cM。PEMAP与Temnykh等发表的图谱（记为CUMAP）具有很高的可比性,绝大多数标记都被定位于相同的染色体上,且排列顺序一致。该DH群体的偏分离情况较严重,122个标记座位中有34个发生显著偏分离,比例达27.8%。值得注意的是,在第1、3、10、11染色体上的标记全部偏向培矮64s,第4、6、7、8、9染色体上的标记则全部偏向E32。 Abstract:A doubled haploid population (DH) consisting of 86 lines derived by anther culture of Peiai64s/E32,a two-line hybrid rice variety with high heterosis,was used to construct a microsatellite or SSLP linkage map of rice chromosomes.A total of 302 PCR primers for SSLP analysis on these chromosomes were chosen from a map published by Cornell University (designated CUMAP) and 127 (42.05%) of them were found polymorphic between the two parents.Those polymorphic PCR primers were used for population genotyping.The map (designated PEMAP) comprises 122 microsatellite maker loci,covering a total length of 1213.4 cM.The PEMAP is highly comparable with the CUMAP.Most of the markers were mapped onto the same chromosomes and aligned in the same order.Serious segregation distortion was observed in this DH population,with 34 (27.8%) markers showing significant deviation.It is noted that all markers on chromosomes 1,3,10 and 11 were biased to Peiai64s,while those on chromosomes 4,6,7,8 and 9 were opposite.     

A High-Resolution PAC and BAC Map of the SCA2 Region

The spinocerebellar ataxia type 2 (SCA2) gene has been localized to chromosome 12q24.1. To characterize this region and to aid in the identification of the SCA2 gene, we have constructed a 3.9-Mb physical map, which covers markers D12S1328 and D12S1329 known to flank the gene. The map comprises a contig of 84 overlapping yeast artificial chromosomes (YACs), P1 artificial chromosomes (PACs), and bacterial artificial chromosomes (BACs) onto which we placed 82 PCR markers. We localized eight genes and expressed sequence tags on this map, many of which had not been precisely mapped before. In contrast to YACs, which showed a high degree of chimerism and deletions in this region, PACs and BACs were stable. Only 1 in 65 PACs contained a small deletion, and 2 in 18 BACs were chimeric. The high-resolution physical map, which was used in the identification of the SCA2 gene, will be useful for the positional cloning of other disease genes mapped to this region.     

Molecular definition of the chromosome 7 deletion in Williams syndrome and parent-of-origin effects on growth.

Williams syndrome (WS) is a developmental disorder with variable phenotypic expression associated, in most cases, with a hemizygous deletion of part of chromosomal band 7q11.23 that includes the elastin gene (ELN). We have investigated the frequency and size of the deletions, determined the parental origin, and correlated the molecular results with the clinical findings in 65 WS patients. Hemizygosity at the ELN locus was established by typing of two intragenic polymorphisms, quantitative Southern analysis, and/or FISH. Polymorphic markers covering the deletion and flanking regions were ordered by a combination of genetic and physical mapping. Genotyping of WS patients and available parents for 13 polymorphisms revealed that of 65 clinically defined WS patients, 61 (94%) had a deletion of the ELN locus and were also hemizygous (or noninformative) at loci D7S489B, D7S2476, D7S613, D7S2472, and D7S1870. None of the four patients without ELN deletion was hemizygous at any of the polymorphic loci studied. All patients were heterozygous (or noninformative) for centromeric (D7S1816, D7S1483, and D7S653) and telomeric (D7S489A, D7S675, and D7S669) flanking loci. The genetic distance between the most-centromeric deleted locus, D7S489B, and the most-telomeric one, D7S1870, is 2 cM. The breakpoints cluster at approximately 1 cM to either side of ELN. In 39 families informative for parental origin, all deletions were de novo, and 18 were paternally and 21 maternally derived. Comparison of clinical data, collected in a standardized quantifiable format, revealed significantly more severe growth retardation and microcephaly in the maternal deletion group. An imprinted locus, silent on the paternal chromosome and contributing to statural growth, may be affected by the deletion.     

Physical mapping of 14 new DNA markers isolated from the human distal Xp region.

We have isolated 14 new DNA markers from the human Xpter-Xp21 region distal to the Duchenne muscular dystrophy gene by targeted cloning, employing two somatic cell hybrids containing this region as their sole human material. High-resolution physical localization of these markers within this region was obtained by hybridization to two mapping panels consisting of DNA from patients carrying various translocations and deletions in distal Xp. Five markers were assigned to the pseudoautosomal region where their position on the long-range map of this region was further determined by pulsed-field gel electrophoresis. The other nine markers map to the X-specific region. Informative TaqI restriction fragment length polymorphisms were observed for four loci. One of these represents a region-specific low-copy repeated element. These 14 new markers represent useful tools for the understanding of distal Xp deletion and translocation mechanisms and for the positional cloning of disease genes in the region.     

Resistance genes for rye stem rust (SrR) and barley powdery mildew (Mla) are located in syntenic regions on short arm of chromosome.

Genetic stocks were developed for the localization and eventual cloning of the stem rust resistance gene SrR that occurs in wheat lines carrying the 1RS translocation from Secale cereale 'Imperial' rye. We have used a mutation-based approach for molecular analysis of the SrR region in rye. Forty-one independent mutants resulting in loss of SrR resistance were isolated: many of these were deletions of various sizes that were used to locate SrR with respect to chromosome group 1S markers. The analysis of the mutants showed that markers about 1 Mb apart flanking the barley Mla locus also flank SrR. Additionally, three of the approximately 20 closely related sequences of Mla in rye are deleted in each of six interstitial deletion mutants of SrR. The results indicate that the SrR region in rye is syntenic to the Mla region in barley or that SrR is possibly orthologous to the Mla locus.     

Molecular Analysis of 36 Mutations at the Mouse Pink-Eyed Dilution (P) Locus

Thirty-six radiation- or chemically induced homozygous-lethal mutations at the p locus in mouse chromosome 7 have been analyzed at 17 loci defined by molecular probes to determine the types of lesions, numbers of p-region markers deleted or rearranged, regions of overlap of deletion mutations, and genetic distances between loci. A linear deletion map of the [Myod1, Ldh3]-[Snrpn, Znf127] region has been constructed from the molecular analyses of the p-locus deletions. The utility of these deletions as tools for the isolation and characterization of the genes specifying the neurological, reproductive, and developmental phenotypes genetically mapped to this region will grow as more detailed molecular analyses continue.     

High-resolution quantitative trait locus mapping for body weight in mice by recombinant progeny testing

A major obstacle to the positional cloning of quantitative trait loci (QTLs) lies in resolving genetic factors whose allelic effects are blurred by environmental and background genetic variation. We investigate a fine-mapping approach that combines the use of an interval-specific congenic strain with progeny testing of recombinants for markers flanking a QTL. We apply the approach to map a murine QTL with an approximately 20% effect on growth rate by progeny testing 39 recombinants in a 12 cM region of the X chromosome. We use a likelihood analysis in an attempt to maximize the information on QTL map location and effect. The major X-linked effect is mapped to an approximately 2 cM region flanked by markers about 5 cM apart, outside which LOD support for the QTL drops extremely steeply by about 80. Nearly unambiguous assignment of the QTL genotypic state is obtained for each recombinant. The resolution of individual recombinants in the region is therefore sufficiently high to facilitate the positional cloning of the locus, although progress has been hampered because the genomic region containing the QTL shows an exceptionally low level of polymorphism in comparison with recent studies.     

中国白菜RAPD分子遗传图谱的构建

A molecular genetic map of Brassica campestris L. (syn. B. rapa) was constructed based on the segregation of 99 RAPDs (random amplified polymorphic DNAs) markers from eighty-four 10-base random primers using DNA samples extracted from F2 population of turnip (B． campestris L. ssp. rapifera Metzg) × Chinese cabbage (B． campestris L. ssp. pekinensis Lour. Olsson). This genetic map covered 1 632.4 cM (centiMorgan) genome (Kosambi Function) with 16.5 cM mean intervals between flanking markers and defined thirteen linkage groups, in which the longest linkage group is 267.5 cM with 20.6 cM mean interval and the shortest linkage group is 62.2 cM with 15.6 cM mean interval. The size and distribution of linkage groups in this map is similar to other RFLP maps and karyotype data in B. campestris.     

Molecular characterization of two proximal deletion breakpoint regions in both Prader-Willi and Angelman syndrome patients.

Prader-Willi syndrome (PWS) and Angelman syndrome (AS) are distinct mental retardation syndromes caused by paternal and maternal deficiencies, respectively, in chromosome 15q11-q13. Approximately 70% of these patients have a large deletion of approximately 4 Mb extending from D15S9 (ML34) through D15S12 (IR10). To further characterize the deletion breakpoints proximal to D15S9, three new polymorphic microsatellite markers were developed that showed observed heterozygosities of 60%-87%. D15S541 and D15S542 were isolated from YAC A124A3 containing the D15S18 (IR39) locus. D15S543 was isolated from a cosmid cloned from the proximal right end of YAC 254B5 containing the D15S9 (ML34) locus. Gene-centromere mapping of these markers, using a panel of ovarian teratomas of known meiotic origin, extended the genetic map of chromosome 15 by 2-3 cM toward the centromere. Analysis of the more proximal S541/S542 markers on 53 Prader-Willi and 33 Angelman deletion patients indicated two classes of patients: 44% (35/80) of the informative patients were deleted for these markers (class I), while 56% (45/80) were not deleted (class II), with no difference between PWS and AS. In contrast, D15S543 was deleted in all informative patients (13/48) or showed the presence of a single allele (in 35/48 patients), suggesting that this marker is deleted in the majority of PWS and AS cases. These results confirm the presence of two common proximal deletion breakpoint regions in both Prader-Willi and Angelman syndromes and are consistent with the same deletion mechanism being responsible for paternal and maternal deletions. One breakpoint region lies between D15S541/S542 and D15S543, with an additional breakpoint region being proximal to D15S541/S542.     

A Linkage Map of the Canine Genome

A genetic linkage map of the canine genome has been developed by typing 150 microsatellite markers using 17 three-generation pedigrees, composed of 163 F₂individuals. One hundred and thirty-nine markers were linked to at least one other marker with a lod score ≥ 3.0, identifying 30 linkage groups. The largest chromosome had 9 markers spanning 106.1 cM. The average distance between markers was 14.03 cM, and the map covers an estimated 2073 cM. Eleven markers were informative on the mapping panel, but were unlinked to any other marker. These likely represent single markers located on small, distinct canine chromosomes. This map will be the initial resource for mapping canine traits of interest and serve as a foundation for development of a comprehensive canine genetic map.     

Linkage Map of the Honey Bee, Apis Mellifera, Based on Rapd Markers

A linkage map was constructed for the honey bee based on the segregation of 365 random amplified polymorphic DNA (RAPD) markers in haploid male progeny of a single female bee. The X locus for sex determination and genes for black body color and malate dehydrogenase were mapped to separate linkage groups. RAPD markers were very efficient for mapping, with an average of about 2.8 loci mapped for each 10-nucleotide primer that was used in polymerase chain reactions. The mean interval size between markers on the map was 9.1 cM. The map covered 3110 cM of linked markers on 26 linkage groups. We estimate the total genome size to be ~3450 cM. The size of the map indicated a very high recombination rate for the honey bee. The relationship of physical to genetic distance was estimated at 52 kb/cM, suggesting that map-based cloning of genes will be feasible for this species.     

Development and characterization of SCAR markers linked to the citrus tristeza virus resistance gene from Poncirus trifoliata.

Twelve new dominant randomly amplified polymorphic DNA (RAPD) fragments associated with a single dominant gene for resistance to citrus tristeza virus (CTV) were identified using bulked segregant analysis of an intergeneric backcross family. These and eight previously reported RAPDs were mapped in the resistance gene (Ctv) region; the resulting localized linkage map spans about 32 cM, with nine close flanking markers within 2.5 cM of Ctv. Seven of 20 RAPD fragments linked with the resistance gene were cloned and sequenced, and their sequences were used to design longer primers to develop sequence characterized amplified region (SCAR) markers that can be utilized reliably in marker-assisted selection, high-resolution mapping, and map-based cloning of the resistance gene. All seven cloned RAPDs were converted successfully into SCARs by redesigning primers, optimizing PCR parameters (especially the annealing temperature), or digesting amplification products with restriction enzymes. Four of the seven remained dominant markers, displaying presence-absence polymorphism patterns; the other three detected restriction site changes or length variations and thus were transformed into codominant markers. Two genomic regions rich in variability were also detected by two codominant SCAR markers.     

Genetic linkage map of six polymorphic DNA markers around the gene for familial adenomatous polyposis on chromosome 5.

A genetic linkage map of six polymorphic DNA markers close to the gene (APC) for familial adenomatous polyposis (FAP) on chromosome 5q is reported. One hundred fifty-five typed members of nine FAP kindred provided more than 90 meioses for linkage analysis. A number of crucial recombination events have been identified which are informative at three or more loci, allowing confident ordering of parts of the map. There was no evidence of genetic heterogeneity, with all families showing linkage of at least one chromosome 5 marker to the gene. Recombination data and two-point linkage analysis support a locus order of centromere-pi 227-C11P11-ECB27-L5.62-APC-EF5.44-YN5.48-telomer e, although EF5.44 could lie in the interval L5.62-APC or ECB27-L5.62. No recombinants were identified between APC and either EF5.44 or YN5.48, but published deletion mapping in colorectal carcinomas and linkage analysis in FAP suggest that YN5.48 is 1-3 cM from APC. The present study suggests that YN5.48 and L5.62 delineate a small region of chromosome 5 within which the EF5.44 locus lies very close to the APC gene. These data not only allow use of flanking markers for presymptomatic diagnosis of FAP but also provide a high-density map of the region for isolation of the APC gene itself and for further assessment of the role of chromosome 5 deletions in the biology of sporadic colorectal cancer.     

An 800-kb region of deletion at 13q14 in human prostate and other carcinomas

Deletions of regions at 13q14 have been detected by various genetic approaches in human cancers including prostate cancer. Several studies have defined one region of loss of heterozygosity (LOH) at 13q14 that seems to reside in a DNA segment of 7.1 cM between genetic markers D13S263 and D13S153. To define the smallest region of overlap (SRO) for deletion at 13q14, we first applied tissue microdissection and multiplex PCR to detect homozygous deletion and/or hemizygous deletion at 13q14 in 134 prostate cancer specimens from 114 patients. We detected deletions at markers D13S1227, D13S1272, and A005O48 in 13 (10%) of these tumor specimens. Of the 13 tumors with deletions, 12 were either poorly differentiated primary tumors or metastases of prostate cancer. To fine-map the deletion region, we then constructed a high-resolution YAC/BAC/STS/EST physical map based on experimental and database analyses. Several markers encompassing the deletion region were analyzed for homozygous deletion and/or hemizygous deletion in 61 cell lines/xenografts derived from human cancers of the prostate, breast, ovary, endometrium, cervix, and bladder, and a region of deletion was defined by duplex PCR assay between markers A005X38 and WI-7773. We also analyzed LOH at 13q14 in the 61 cell lines/xenografts using the homozygosity mapping of deletion approach and 26 microsatellite markers. We found 24 (39%) of the cell lines/xenografts to show LOH at 13q14 and defined a region of LOH by markers M1 and M5. Combination of homozygous or hemizygous deletion and LOH results defined the SRO for deletion to be an 800-kb DNA interval between A005X38 and M5. There are six known genes located in or close to the SRO for deletion. This region of deletion is at least 2 Mb centromeric to the RB1 tumor-suppressor gene and the leukemia-associated genes 1 and 2, each of which is located at 13q14. These data suggest that the 800-kb DNA segment with deletion contains a gene whose deletion may be important for the development of prostate and other cancers. This study also provides a framework for the fine-mapping, cloning, and identification of a novel tumor-suppressor gene at 13q14.     

Genomic targeting and high-resolution mapping of the domestication gene Q in wheat.

The Q locus is largely responsible for the domestication of bread wheat. Q confers the free-threshing character of the spike and influences other important agronomic traits. Using chromosome deletion lines, Q was placed on the physical map within a submicroscopic segment of the long arm of chromosome 5A. We targeted markers to the segment by comparative mapping of anonymous RFLP clones, AFLP, and mRNA differential display analysis of deletion lines 5AL-7 and -23, which have deletion breakpoints that flank the Q locus. Differentially expressed sequences detected fragments at various loci on group 5 chromosomes suggesting that Q may be a regulatory gene. We identified 18 markers within the Q gene deletion interval and used them to construct a genetic linkage map of the region in F2 populations derived from chromosome 5A disomic substitution lines. The genetic map corresponding to the deletion segment was 20-cM long, and we identified markers as close as 0.7 cM to the Q gene. An estimate of base pairs per centimorgan within the region is 250 kb/cM, an 18-fold increase in recombination compared with the genomic average. Genomic targeting and high-density mapping provide a basis for the map-based cloning of the Q gene.