A SSR-based composite genetic linkage map for the cultivated peanut (<Emphasis Type="Italic">Arachis hypogaea</Emphasis> L.) genome

Background  

The construction of genetic linkage maps for cultivated peanut (Arachis hypogaea L.) has and continues to be an important research goal to facilitate quantitative trait locus (QTL) analysis and gene tagging for use in a marker-assisted selection in breeding. Even though a few maps have been developed, they were constructed using diploid or interspecific tetraploid populations. The most recently published intra-specific map was constructed from the cross of cultivated peanuts, in which only 135 simple sequence repeat (SSR) markers were sparsely populated in 22 linkage groups. The more detailed linkage map with sufficient markers is necessary to be feasible for QTL identification and marker-assisted selection. The objective of this study was to construct a genetic linkage map of cultivated peanut using simple sequence repeat (SSR) markers derived primarily from peanut genomic sequences, expressed sequence tags (ESTs), and by "data mining" sequences released in GenBank.     

A 2-Megabase Physical Contig Incorporating 43 DNA Markers on the Human X Chromosome at p11.23–p11.22 from ZNF21 to DXS255

A comprehensive physical contig of yeast artificial chromosomes (YACs) and cosmid clones between ZNF21 and DXS255 has been constructed, spanning 2 Mb within the region Xp11.23–p11.22. As a portion of the region was found to be particularly unstable in yeast, the integrity of the contig is dependent on additional information provided by the sequence-tagged site (STS) content of cosmid clones and DNA marker retention in conventional and radiation hybrids. The contig was formatted with 43 DNA markers, including 19 new STSs from YAC insert ends and an internalAlu-PCR product. The density of STSs across the contig ranges from one marker every 20 kb to one every 60 kb, with an average density of one marker every 50 kb. The relative order of previously known genes and expressed sequence tags in this region is predicted to be Xpter–ZNF21–DXS7465E (MG66)–DXS7927E (MG81)–WASP, DXS1011E, DXS7467E (MG21)–DXS- 7466E (MG44)–GATA1–DXS7469E (Xp664)–TFE3–SYP (DXS1007E)–Xcen. This contig extends the coverage in Xp11 and provides a framework for the future identification and mapping of new genes, as well as the resources for developing DNA sequencing templates.     

Development,Characterization and Cross Species Amplification of Polymorphic Microsatellite Markers from Expressed Sequence Tags of Turmeric (<Emphasis Type="Italic">Curcuma longa</Emphasis> L.)

Expressed sequence tags (ESTs) from turmeric (Curcuma longa L.) were used for the screening of type and frequency of Class I (hypervariable) simple sequence repeats (SSRs). A total of 231 microsatellite repeats were detected from 12,593 EST sequences of turmeric after redundancy elimination. The average density of Class I SSRs accounts to one SSR per 17.96 kb of EST. Mononucleotides were the most abundant class of microsatellite repeat in turmeric ESTs followed by trinucleotides. A robust set of 17 polymorphic EST–SSRs were developed and used for evaluating 20 turmeric accessions. The number of alleles detected ranged from 3 to 8 per loci. The developed markers were also evaluated in 13 related species of C. longa confirming high rate (100%) of cross species transferability. The polymorphic microsatellite markers generated from this study could be used for genetic diversity analysis and resolving the taxonomic confusion prevailing in the genus.     

Refined Linkage Disequilibrium and Physical Mapping of the Gene Locus for X-Linked Dystonia–Parkinsonism (DYT3)

X-linked dystonia-parkinsonism (XDP) is a recessive disorder characterized by generalized dystonia with some patients exhibiting parkinsonism. The disease gene, DYT3, is located between DXS453 (DXS993) and DXS559, and strongest linkage disequilibrium is found distal to DXS7117 and proximal to DXS559. We have isolated and analyzed four novel polymorphic markers between DXS7117 and DXS559 and, by haplotype analysis, have narrowed the candidate interval to <350 kb. A sequence-ready contig of 700 kb has been constructed spanning DXS7117 to DXS559 and is composed of 35 PACs, BACs, and cosmids. Nine genes and novel ESTs have been mapped into this contig, and mutations in the coding regions and intron-exon borders of two genes have been excluded as the cause of XDP. Several of the other genes and ESTs located within the contig code for proteins implicated in normal brain development and function and are candidates for DYT3.     

A YAC, P1, and Cosmid Contig and 17 New Polymorphic Markers for the Werner Syndrome Region at 8p12–p21

A yeast artificial chromosome (YAC), P1, and cosmid clone contig was constructed for the Werner syndrome (WRN) region of chromosome 8p12–p21 and used to clone a candidate gene forWRN.This region also possibly contains a familial breast cancer locus. The contig was initiated by isolating YACs for the glutathione reductase (GSR) gene and extended in either direction by walking techniques. Sequence-tagged site (STS) markers were generated from subclones of 2GSRYACs and used to identify P1 and cosmid clones. Additional STSs were generated from P1 and cosmid clones and from potential expressed sequences identified by cDNA selection and exon amplification methods. The final contig was assembled by typing 17 YACs, 20 P1 clones, and 109 cosmids for 54 STS markers. TheWRNregion could be spanned by 2 nonchimeric YACs covering approximately 1.4 Mb. A P1/cosmid contig was established covering the core 700–800 kb of theWRNregion. Fifteen new short tandem repeat polymorphisms and 2 biallelic polymorphic markers were identified and included as STSs in the contig. Analysis of these markers in Werner syndrome subjects demonstrates that the candidate WRN gene is in a region of linkage disequilibrium.     

YAC contigs mapping the human COL4A5 and COL4A6 genes and DXS118 within Xq21.3–q22

Sequence-tagged sites (STSs) were developed for three loci of uncertain X chromosomal localization (DXS122, DXS137, and DXS174) and were used to seed YAC contigs. Two contigs now total about 3.3 Mb formatted with 34 STSs. One contains DXS122 and DXS174 within 250 kb on single YACs; it is placed in Xq21.3–q22.1 by FISH analysis, which is consistent with somatic cell hybrid panel analyses and with the inclusion of a probe that detects polymorphism at the DXS118 locus already assigned to that general region. The other contig, which contains DXS137, is in Xq22.2 by FISH, consistent with cell hybrid analyses and with the finding that it covers the human COL4A5 and COL4A6 genes known to be in that vicinity. In addition to extending the cloned coverage of this portion of the X chromosome, these materials should aid, for example, in the further analysis of Alport syndrome.     

Genetic and physical mapping around the properdin P gene.

A CA repeat has been found on the human X chromosome within 16 kb of the gene encoding properdin P factor (PFC) and has been shown to be a highly informative marker. Two more polymorphic CA repeats were found in a cosmid containing DXS228. The CA repeats, and other markers from proximal Xp, were mapped genetically in CEPH families and the likely order of markers was established as Xpter-(DXS7, MAO-A, DXS228)-(PFC, DXS426)-(TIMP, OATL1)-DXS255-Xcen. This places PFC in the region Xp11.3-Xp11.23, thus refining previous in situ hybridization data. Two yeast artificial chromosomes (YACs) (440 and 390 kb) contain both PFC and DXS426, and one of them (440 kb) also contains TIMP. This confirms the genetic order TIMP-(PFC, DXS426). PFC and TIMP are located on the same 100-kb SalI/PvuI fragment of the 440-kb YAC. Given the genetic orientation of TIMP and (PFC, DXS426), this YAC can now serve as a starting point for directional walking toward disease genes located in Xp11.3-Xp11.2 such as retinitis pigmentosa (RP2) and Wiskott-Aldrich syndrome.     

X-Linked syndrome of polyendocrinopathy, immune dysfunction, and diarrhea maps to Xp11.23-Xq13.3

We describe genetic analysis of a large pedigree with an X-linked syndrome of polyendocrinopathy, immune dysfunction, and diarrhea (XPID), which frequently results in death during infancy or childhood. Linkage analysis mapped the XPID gene to a 17-cM interval defined by markers DXS8083 and DXS8107 on the X chromosome, at Xp11. 23-Xq13.3. The maximum LOD score was 3.99 (recombination fraction0) at DXS1235. Because this interval also harbors the gene for Wiskott-Aldrich syndrome (WAS), we investigated mutations in the WASP gene, as the molecular basis of XPID. Northern blot analysis detected the same relative amount and the same-sized WASP message in patients with XPID and in a control. Analysis of the WASP coding sequence, an alternate promoter, and an untranslated upstream first exon was carried out, and no mutations were found in patients with XPID. A C-->T transition within the alternate translation start site cosegregated with the XPID phenotype in this family; however, the same transition site was detected in a normal control male. We conclude that XPID maps to Xp11.23-Xq13.3 and that mutations of WASP are not associated with XPID.     

High-Resolution Physical Map of the X-linked Retinoschisis Interval in Xp22

X-linked retinoschisis (RS) is the leading cause of macular degeneration in young males and has been mapped to Xp22 between DXS418 and DXS999. To facilitate identification of the RS gene, we have constructed a yeast artificial chromosome (YAC) contig across this region comprising 28 YACs and 32 sequence-tagged sites including seven novel end clone markers. To establish the definitive marker order, a PAC contig containing 50 clones was also constructed, and all clones were fingerprinted. The marker order is: Xpter–DXS1317–(AFM205yd12–DXS7175–DXS7992)–60N8T7–DXS1195–DXS7993–DXS7174–60N8-SP6–DXS418–DXS7994–DXS7995–DXS7996–HYAT2–25HA10R–HYAT1–DXS7997–DXS7998–DXS257–434E8R–3542R–DXS6762–DXS7999–DXS6763–434E8L–DXS8000–DXS6760–DXS7176–DXS8001–DXS999–3176R–PHKA2–Xcen. A long-range restriction map was constructed, and the RS region is estimated to be 1300 kb, containing three putative CpG islands. An unstable region was identified between DXS6763 and 434E8L. These data will facilitate positional cloning of RS and other disease genes in Xp22.     

Construction of an intra-specific sweet cherry (<Emphasis Type="Italic">Prunus avium</Emphasis> L.) genetic linkage map and synteny analysis with the <Emphasis Type="Italic">Prunus</Emphasis> reference map

Linkage maps of the sweet cherry cultivar ‘Emperor Francis’ (EF) and the wild forest cherry ‘New York 54’ (NY) were constructed using primarily simple sequence repeat (SSR) markers and gene-derived markers with known positions on the Prunus reference map. The success rate for identifying SSR markers that could be placed on either the EF or NY maps was only 26% due to two factors: a reduced transferability of other Prunus-species-derived markers and a low level of polymorphism in the mapping parents. To increase marker density, we developed four cleaved amplified polymorphic sequence markers (CAPS), 19 derived CAPS markers, and four insertion–deletion markers for cherry based on 101 Prunus expressed sequence tags. In addition, four gene-derived markers representing orthologs of a tomato vacuolar invertase and fruit size gene and two sour cherry sorbitol transporters were developed. To complete the linkage analysis, 61 amplified fragment length polymorphism and seven sequence-related amplified polymorphism markers were also used for map construction. This analysis resulted in the expected eight linkage groups for both parents. The EF and NY maps were 711.1 cM and 565.8 cM, respectively, with the average distance between markers of 4.94 cM and 6.22 cM. A total of 82 shared markers between the EF and NY maps and the Prunus reference map showed that the majority of the marker orders were the same with the Prunus reference map suggesting that the cherry genome is colinear with that of the other diploid Prunus species. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

A 1.6-Mb contig of yeast artificial chromosomes around the human factor VIII gene reveals three regions homologous to probes for the DXS115 locus and two for the DXYS64 locus.

Two yeast artificial chromosome (YAC) libraries were screened for probes in Xq28, around the gene for coagulation factor VIII (F8). A set of 30 YACs were recovered and assembled into a contig spanning at least 1.6 Mb from the DXYS64 locus to the glucose 6-phosphate dehydrogenase gene (G6PD). Overlaps among the YACs were determined by several fingerprinting techniques and by additional probes generated from YAC inserts by using Alu-vector or ligation-mediated PCR. Analysis of more than 30 probes and sequence-tagged sites (STSs) made from the region revealed the presence of several homologous genomic segments. For example, a probe for the DXYS64 locus, which maps less than 500 kb 5' of F8, detects a similar but not identical locus between F8 and G6PD. Also, a probe for the DXS115 locus detects at least three identical copies in this region, one in intron 22 of F8 and at least two more, which are upstream of the 5' end of the gene. Comparisons of genomic and YAC DNA suggest that the multiple loci are not created artifactually during cloning but reflect the structure of uncloned human DNA. On the basis of these data, the most likely order for the loci analyzed is tel-DXYS61-DXYS64-(DXS115-3-DXS115-2)-5'F8-(D XS115-1)-3'F8-G6PD.     

Genetic Linkage Maps of <Emphasis Type="Italic">Betula platyphylla</Emphasis> Suk Based on ISSR and AFLP Markers

Two separate genetic linkage maps for Chinese silver birch based on inter-simple sequence repeat (ISSR) and amplified fragment-length polymorphism (AFLP) were constructed by a pseudo-testcross mapping strategy. Eighty F₁ progenies were obtained from the cross between two parental trees with desirable traits (the paternal one selected from ‘Qinghai’ and the maternal one from ‘Wangqing’). A total of 46 ISSR primers and 31 AFLP primers were employed to generate 102 ISSR and 355 AFLP polymorphic markers in the F₁ progenies. About 5.7% of all the markers displayed high segregation distortion with a P value below 0.01 and such markers were not used for map constructions. The paternal map consisted of 137 loci, spread over 13 groups and spanned 694.2 cM at an average distance of 5.1 cM between the markers, while in the maternal map, 147 loci were distributed in 14 groups covering a map distance about 949.62 cM at an average distance of 6.5 cM. These initial maps can serve as the basis for developing a more detailed genetic map.     

Construction of a framework map for Pinus koraiensis Sieb. et Zucc. using SRAP, SSR and ISSR markers

Genetic linkage maps are essential for molecular breeding program. The first genetic linkage map of Pinus koraiensis, using an F1 progeny of 94 individuals, was constructed in the present paper. One hundred and twenty-two molecular markers were mapped onto 11 linkage groups, 1 triple and 8 pairs at the linkage criteria LOD 4.0. Among these markers, there were 96 sequence-related amplified polymorphism (SRAP) markers, 25 simple sequence repeat (SSR) markers, and 1 inter-simple sequence repeat (ISSR) marker. The consensus map gained covers 857.464 cM Kosambi (K) with an average marker spacing of 7.03 cM K. The presented map provides a basis and crucial information for future genomic studies of P. koraiensis, in particular for quantitative trait loci (QTL) mapping of economically important breeding target traits.     

Endogenous pararetrovirus sequences associated with 24 nt small RNAs at the centromeres of Fritillaria imperialis L. (Liliaceae), a species with a giant genome

Endogenous pararetroviral sequences are the most commonly found virus sequences integrated into angiosperm genomes. We describe an endogenous pararetrovirus (EPRV) repeat in Fritillaria imperialis, a species that is under study as a result of its exceptionally large genome (1C = 42 096 Mbp, approximately 240 times bigger than Arabidopsis thaliana). The repeat (FriEPRV) was identified from Illumina reads using the RepeatExplorer pipeline, and exists in a complex genomic organization at the centromere of most, or all, chromosomes. The repeat was reconstructed into three consensus sequences that formed three interconnected loops, one of which carries sequence motifs expected of an EPRV (including the gag and pol domains). FriEPRV shows sequence similarity to members of the Caulimoviridae pararetrovirus family, with phylogenetic analysis indicating a close relationship to Petuvirus. It is possible that no complete EPRV sequence exists, although our data suggest an abundance that exceeds the genome size of Arabidopsis. Analysis of single nucleotide polymorphisms revealed elevated levels of C→T and G→A transitions, consistent with deamination of methylated cytosine. Bisulphite sequencing revealed high levels of methylation at CG and CHG motifs (up to 100%), and 15–20% methylation, on average, at CHH motifs. FriEPRV's centromeric location may suggest targeted insertion, perhaps associated with meiotic drive. We observed an abundance of 24 nt small RNAs that specifically target FriEPRV, potentially providing a signature of RNA‐dependent DNA methylation. Such signatures of epigenetic regulation suggest that the huge genome of F. imperialis has not arisen as a consequence of a catastrophic breakdown in the regulation of repeat amplification.