Molecular markers linked to the Rf2 fertility restorer gene in cotton.

Cytoplasmic male sterility (CMS) is a maternally inherited trait in which plants do not produce viable pollen. Fertility in plants with CMS can be recovered by nuclear restorer genes. Most restorer genes cloned so far are members of the pentatricopeptide repeat (PPR) protein family. The objective of our study was to use the CMS-D8 and restoration (Rf2) system of cotton (Gossypium hirsutum L.) to develop more DNA markers for the Rf2 gene. In a backcross population with 112 plants, segregation of male fertility was 1 fertile : 1 sterile. Three new RAPD markers were identified for Rf2, one of which was converted to a CAPS marker. In addition, 2 AFLP markers and 1 SSR marker were identified to be linked to the fertility restorer gene (Rf2). PPR motif primers were designed based on the conserved PPR motifs and used in combination with AFLP primers to test the mapping population, and 1 PPR-AFLP marker was identified. A linkage map with 9 flanking markers including 1 from a previous study was constructed.     

Genetic and physical mapping of<Emphasis Type="Italic"> Pi5(t)</Emphasis>, a locus associated with broad-spectrum resistance to rice blast

To gain an understanding of the molecular basis for resistance to rice blast (Magnaporthe grisea), we have initiated a project to clone Pi5(t), a locus associated with broad-spectrum resistance to diverse blast isolates. AFLP-derived markers linked to Pi5(t)-mediated resistance were isolated using bulked segregant analysis of F(2) populations generated by crossing three recombinant inbred lines (RILs), RIL125, RIL249, and RIL260 with the susceptible line CO39. The most tightly linked AFLP marker, S04G03, was positioned on chromosome 9 of the fingerprint-based physical map of Nipponbare, a well-characterized rice genotype. Flanking BAC-based Nipponbare markers were generated for saturation mapping using four populations, the three initial RILs and an additional one derived from a cross between M202 and RIL260. A BIBAC (binary BAC) library was constructed from RIL260. Using these resources Pi5(t) was mapped to a 170-kb interval, and a contiguous set of BIBAC clones spanning this region was constructed. It had previously been suggested that Pi3(t) and Pi5(t) might be allelic, due to their identical resistance spectrum and tight linkage. We therefore compared genomic regions for lines containing Pi3(t) using the Pi5(t)-linked markers. DNA gel-blot analyses indicated that the region around Pi3(t) is identical to that of Pi5(t), suggesting that Pi3(t) and Pi5(t) are the same resistance gene.     

Locating the petunia Rf gene on a 650-kb DNA fragment

 A bulked segregant analysis was conducted in order to find RAPD and AFLP markers linked to the restorer of fertility (Rf ) gene in petunia. One RAPD marker, OP704, and one AFLP marker, ECCA/ MACT, were found to be closely linked to Rf (<1 cM) in our mapping population produced from an intraspecific Petunia hybrida cross. These two single-copy markers bracketing Rf were then mapped as RFLPs on the tomato map. Despite some rearrangement between the petunia and the tomato genomes, this synteny survey revealed two tomato markers, TG250 and CT24, closely linked to Rf. Physical mapping indicates that CT24, OP704 and ECCA/MACT lie on the same 650-kb MluI fragment. A physical to genetic distance ratio of 400 kb/cM around the Rf gene should make it feasible to identify markers physically very close to Rf. Received: 20 August 1997 / Accepted: 21 October 1997     

AFLP and PCR-based markers linked to Rf3, a fertility restorer gene for S cytoplasmic male sterility in maize

The Rf3 gene restores the pollen fertility disturbed by S male sterile cytoplasm. In order to develop molecular markers tightly linked to Rf3, we used amplified fragment length polymorphism (AFLP) technique with near isogenic lines (NILs) and bulk segregant analysis (BSA). A BC₁F₁ population from a pair of NILs with different Rf3 locus was constructed and 528 primer combinations was screened. A linkage map was constructed around the Rf3 locus, which was mapped on the distal region of chromosome 2 long arm with the help of SSR marker UMC2184. The closest marker E7P6 was 0.9 cM away from Rf3. Marker E3P1, 2.4 cM from Rf3, and E12M7, 1.8 cM from Rf3, were converted into a codominant CAPS and a dominant SCAR marker, and designated as CAPSE3P1 and SCARE12M7, respectively. These markers are useful for marker-assisted selection and map-based cloning of the Rf3 gene.     

Sugar beet BAC library construction and assembly of a contig spanning <Emphasis Type="Italic">Rf1</Emphasis>, a restorer-of-fertility gene for Owen cytoplasmic male sterility

Rf1 is a nuclear gene that controls fertility restoration in cases of cytoplasmic male sterility caused by the Owen cytoplasm in sugar beet. In order to isolate the gene by positional cloning, a BAC library was constructed from a restorer line, NK198, with the genotype Rf1Rf1. The library contained 32,180 clones with an average insert size of 97.8 kb, providing 3.4 genome equivalents. Five AFLP markers closely linked to Rf1 were used to screen the library. As a result, we identified eight different BAC clones that were clustered into two contigs. The gap between the two contigs was filled by chromosome walking. To map the Rf1 region in more detail, we developed five cleaved amplified polymorphic sequence (CAPS) markers from the BAC DNAs identified, and carried out genotyping of 509 plants in the mapping population with the Rf1-flanking AFLP and CAPS markers. Thirteen plants in which recombination events had occurred in the vicinity of the Rf1 locus were identified and used to map the molecular markers relative to each other and to Rf1. In this way, we were able to restrict the possible location of the Rf1 gene to a minimum of six BAC clones spanning an interval of approximately 250 kb. The first two authors contributed equally to this work.     

AFLP maps of Petunia hybrida: building maps when markers cluster

AFLP mapping in Petunia hybrida was undertaken with the intention of building a high-density genetic map suitable for applications such as map-based gene cloning. In total five maps were constructed from two mapping populations, with placement of more than 800 markers. Despite the large number of markers the resulting map is roughly ten-fold smaller than those of other plant species, including the closely related tomato. Low levels of recombination are reflected in clusters of tightly linked markers, both AFLPs and RFLPs, in all the maps. Clustering patterns vary between mapping populations, however, such that loci tightly linked in one population may be separable in another. Combined with earlier reports of aberrant meiotic pairing and recombination, our results suggest that, for species like petunia, map-based cloning may be more complex than in model species such as arabidopsis and tomato.     

Inheritance and molecular mapping of two fertility-restoring loci for Honglian gametophytic cytoplasmic male sterility in rice (<Emphasis Type="Italic">Oryza sativa </Emphasis>L.)

The Honglian cytoplasmic male sterility (cms-HL) system, a novel type of gametophytic CMS in indica rice, is being used for the large-scale commercial production of hybrid rice in China. However, the genetic basis of fertility restoration (Rf) in cms-HL remains unknown. Previous studies have shown that fertility restoration is controlled by a single locus located on chromosome 10, close to the loci Rf1 and Rf4, which respond to cms-BT and cms-WA, respectively. To determine if the Rf locus for cms-HL is different from these Rf loci and to establish fine-scale genetic and physical maps for map-based cloning of the Rf gene, high-resolution mapping of the Rf gene was carried out using RAPD and microsatellite markers in three BCF₁ populations. The results of the genetic linkage analysis indicated that two Rf loci respond to cms-HL, and that these are located in different regions of chromosome 10. One of these loci, Rf5 , co-segregates with the SSR marker RM3150, and is flanked by RM1108 and RM5373, which are 0.9 cM and 1.3 cM away, respectively. Another Rf locus, designated as Rf6(t), co-segregates with RM5373, and is flanked by RM6737 and SBD07 at genetic distances of 0.4 cM. The results also demonstrated these loci are distinct from Rf1 and Rf4. A 105-kb BAC clone covering the Rf6(t) locus was obtained from a rice BAC library. The sequence of a 66-kb segment spanning the Rf6(t) locus was determined by a BLASTX search in the genomic sequence database established for the cultivar 93-11.Communicated by R. Hagemann     

A composite map of expressed sequences and phenotypic traits of the sunflower (Helianthus annuus L.) genome

 A map of the sunflower genome, based on expressed sequences and consisting of 273 loci, was constructed. The map incorporates data from seven F₂ populations, for a total of 1115 individuals. Two hundred and fourty five loci corresponding to 170 anonymous cDNA markers and four loci for morphological markers were mapped. We also mapped 18 loci corresponding to previously described genes or to sequences obtained through homology cloning. The unit maps vary from 774 cM to 1060 cM, with an average value of 14 major linkage groups. The integrated map is arranged in 17 major linkage groups including 238 loci, plus four small segments with 2–5 marker loci; and covers 1573 cM with an overall average marker interval of 7 cM. Thirty five percent of the markers were dominant in nature and 30% showed inter-linkage group duplication without any indication of homoeologous linkage groups. Evidence is provided for the independence of two distinct fertility restoration genes, for the presence of two loosely linked branching loci, and for marker tightly linked to the Rf1 restoration locus. This map provides an efficient tool in breeding applications such as disease-resistance mapping, QTL analyses and marker-assisted selection. Received: 27 August 1998 / Accepted: 28 December 1998     

Exploitation of Arabidopsis-tomato synteny to construct a high-resolution map of the ovatecontaining region in tomato chromosome 2.

High-resolution genetic and physical maps were constructed for the region of chromosome 2 containing the major fruit-shape locus ovate. A total of 3,000 NIL F2 and F3 NILs derived from Lycopersicon esculentum cv. Yellow Pear (TA503) x L. pennellii (a wild tomato) were used to position ovate adjacent to the marker TG645 and flanked by markers TX700 and BA10R (a 0.03-cM interval). BAC libraries and a BIBAC library were screened with the closest marker, TG645. Genetic mapping with the ends of isolated BAC clones revealed that two BAC clones (100 and 140 kb) both contained the ovate locus. Screening of sequences from these BAC clones revealed synteny between this segment of tomato chromosome 2 and the chromosome-4 region of Arabidopsis containing the BAC clone ATAP22. Microsynteny between the two genomes was exploited to find additional markers near the ovate locus. The placement of ovate on a BAC clone will now allow cloning of this locus and, hence, may open the door to understanding the molecular basis of fruit development and also facilitate the genetic engineering of fruit-shape characteristics. This also represents the first time that microsynteny with Arabidopsis has been exploited for positional cloning purposes in a different plant family.     

运用近等基因系（NIL）、AFLP、RFLP和SCAR标记对玉米S组育性恢复基因（Rf3）的研究

以1对近等基因系（NIL）及其回交群体（BC     

Development and mapping of AFLP markers linked to the sorghum fertility restorer gene <Emphasis Type="Italic">rf4</Emphasis>

The restoration of male fertility in the sorghum IS1112 C (A3) male-sterile cytoplasm is through a two-gene gametophytic system involving complementary action of the restoring alleles Rf3 and Rf4. To develop markers suitable for mapping rf4, AFLP technology was applied to bulks of sterile and fertile individuals from a segregating BC₃F₁ population. Three AFLP markers linked to rf4 were identified and subsequently converted to STS/CAPS markers, two of which are co-dominant. Based on a population of 378 BC₁F₁ individuals, two STS/CAPS markers, LW7 and LW8, mapped to within 5.31 and 3.18 cM, respectively, of rf4, while an STS marker, LW9, was positioned 0.79 cM on the flanking side of rf4. Markers LW8 and LW9 were used to screen sorghum BAC libraries to identify the genomic region encoding rf4. A series of BAC clones shown to represent a genomic region of linkage group E were identified by the rf4-linked markers. A contig of BAC clones flanking the LW9 marker represent seed clones on linkage group E, from which fine mapping of the rf4 locus and chromosome walking can be initiated. Received: 20 June 2001 / Accepted: 3 August 2001     

Development and evaluation of broadly applicable markers for <Emphasis Type="Italic">Restorer-of-fertility</Emphasis> in pepper

The Restorer-of-fertility (Rf) gene is used for efficient hybrid seed production in chili pepper. Although molecular markers linked to Rf in pepper are available, their applications have been limited by lack of agreement between marker genotype and phenotype. To overcome this limitation, we developed new molecular markers using an Rf-segregating population for which most of previously developed markers are not suitable, because of lack of polymorphism. The petunia Rf gene was used as a candidate for marker development. First of all, a pepper bacterial artificial chromosome (BAC) library was screened using a pepper homolog of the petunia Rf gene. The 52 selected BAC clones were classified into three contig groups and each contig group was mapped to chromosome 6. Three markers were developed using the three groups; their genetic distances from the Rf locus were 1.4, 3.2 and 14 cM, respectively. In the second place, an Rf-linked marker was developed from the sequence of a tomoto BAC clone containing three genes which are homologous to petunia Rf gene. Genetic distance between this marker and Rf gene was 1.4 cM. When newly-, and previously-developed molecular markers linked to Rf were applied to 55 pepper breeding lines, one marker named CRF-SCAR was found to be the most broadly applicable, based on correct determination of phenotypes. In the present study, we demonstrate that previously cloned Rf genes can be used as candidate genes for development of new markers for the reliable detection of restorer lines. We expect that the newly-developed markers and information obtained from application of markers will be useful for reliable detection of restorer lines.     

大豆遗传图谱的构建和分析

利用大豆栽培品种科丰1号和南农1138－2杂交得到的重组近交系NJRIKY,通过RFLP,SSR,RAPD和AFLP4种分子标记的遗传连锁分析,构建了包含24个连锁群,由792个遗传标记组成的大豆较高密度连锁图谱,该图谱覆盖2320．7cM,平均图距2．9cM,SSR标记的多态性较高,在基因组中的位置相对稳定,可以作为锚定标记,有利于连锁群的归并和不同图谱的比较整合;而AFLP标记对于增加图谱密度效率较高,但其容易出现聚集现象,从而造成连锁群上有很大的空隙（gap),另外,在连锁群中有21．7％的分子标记出现偏分离,该图谱为基因定位,比较基因组学和重要农艺性状的QTL定位等研究打下了基础。     

Construction of BAC and BIBAC libraries from sunflower and identification of linkage group-specific clones by overgo hybridization

Complementary BAC and BIBAC libraries were constructed from nuclear DNA of sunflower cultivar HA 89. The BAC library, constructed with BamHI in the pECBAC1 vector, contains 107,136 clones and has an average insert size of 140 kb. The BIBAC library was constructed with HindIII in the plant-transformation-competent binary vector pCLD04541 and contains 84,864 clones, with an average insert size of 137 kb. The two libraries combined contain 192,000 clones and are equivalent to approximately 8.9 haploid genomes of sunflower (3,000 Mb/1C), and provide a greater than 99% probability of obtaining a clone of interest. The frequencies of BAC and BIBAC clones carrying chloroplast or mitochondrial DNA sequences were estimated to be 2.35 and 0.04%, respectively, and insert-empty clones were less than 0.5%. To facilitate chromosome engineering and anchor the sunflower genetic map to its chromosomes, one to three single- or low-copy RFLP markers from each linkage group of sunflower were used to design pairs of overlapping oligonucleotides (overgos). Thirty-six overgos were designed and pooled as probes to screen a subset (5.1×) of the BAC and BIBAC libraries. Of the 36 overgos, 33 (92%) gave at least one positive clone and 3 (8%) failed to hit any clone. As a result, 195 BAC and BIBAC clones representing 19 linkage groups were identified, including 76 BAC clones and 119 BIBAC clones, further verifying the genome coverage and utility of the libraries. These BAC and BIBAC libraries and linkage group-specific clones provide resources essential for comprehensive research of the sunflower genome.     

Segregation distortion of T-DNA markers linked to the self-incompatibility (S) locus in Petunia hybrida

In plants with a gametophytic self-incompatibility system the specificity of the pollen is determined by the haploid genotype at the self-incompatibility (S) locus. In certain crosses this can lead to the exclusion of half the gametes from the male parent carrying a particular S-allele. This leads to pronounced segregation distortion for any genetic markers that are linked to the S-locus. We have used this approach to identify T-DNA insertions carrying a maize transposable element that are linked to the S-locus of Petunia hybrida. A total of 83 T-DNA insertions were tested for segregation distortion of the selectable marker used during transformation with Agrobacterium. Segregation distortion was observed for 12 T-DNA insertions and at least 8 of these were shown to be in the same linkage group by intercrossing. This indicates that differential transmission of a single locus (S) is probably responsible for all of these examples of T-DNA segregation distortion. The identification of selectable markers in coupling with a functional S-allele will allow the preselection of recombination events around the S-locus in petunia. Our approach provides a general method for identifying transgenes that are linked to gametophytic self-incompatibility loci and provides an opportunity for transposon tagging of the petunia S-locus.     

Linkage analysis between the partial restoration (pr) and the restorer-of-fertility (Rf) loci in pepper cytoplasmic male sterility

Cytoplasmic male sterility (CMS) in chili pepper is restored by one major dominant nuclear gene, restorer-of-fertility (Rf), together with some modifier genes and is also affected by temperature. As a result, male fertility was identified as having several phenotypes. That identified and used in the present study allowed partial restoration of fertility, producing plants that simultaneously produce normal and aborted pollen grains, with most grains stuck to the anther wall, even after dehiscence, resulting in low seed set per fruit. The trait was visible only in the presence of Paterson's sterile cytoplasm and was controlled by a recessive nuclear gene, partial restoration (pr). A CAPS marker, PR-CAPS, closely linked to the trait, has been developed by Lee et al. (2008). In this study, linkage analysis was performed in 205 F(2) individuals derived from the 'Buja' Korean commercial F(1) chili pepper variety using the PR-CAPS marker and the three Rf-linked markers (OPP13-CAPS, AFRF8-CAPS, and CRF-SCAR) previously reported. Consequently, we found that these four markers were tightly linked. This result means that the pr gene might be tightly linked to the Rf locus or the third allele of Rf locus. The sequence diversity of the pr- and Rf-linked markers was also analyzed. The internal sequences of OPP13-CAPS (1,180 bp) and PR-CAPS (640 bp) markers in 91 Korean inbred lines were clearly divided into three haplotypes. According to the sequencing results, a new PR-CAPS (MseI or SphI digestion) marker was designed to distinguish the three haplotypes. This marker will be useful for marker-assisted selection to develop new maintainers and restorers in commercial hybrid pepper breeding using CMS.     

Molecular mapping of a fertility restorer gene for Owen cytoplasmic male sterility in sugar beet

We report here the molecular mapping of a fertility restorer gene (named Rf1) for Owen cytoplasmic male sterility in sugar beet. Eight AFLP and two RAPD markers, tightly linked to the Rf1 locus, were identified using bulked segregant analysis. Three AFLP markers, mAFEM972, mAFEM976 and mAFEM985, were found to co-segregate with the Rf1 allele in our mapping populations. With the help of RFLP markers, previously mapped on the sugar beet genome, we showed that Rf1 is positioned in the terminal region of linkage group Kiel III/Koeln IV. This map location agrees well with that found for the restorer gene X, which suggests that the Rf1 locus corresponds to the X locus. The availability of the molecular markers will facilitate the selection of maintainer–pollinator lines in breeding program and provide the foundation for map-based cloning of the Rf1 gene.     

Inheritance and fine mapping of fertility restoration for cytoplasmic male sterility in Gossypium hirsutum L

Genetics of CMS fertility restoration was presented through the analysis of classic genetics and molecular markers. Based on F(2) segregation of the crosses between CMS and the restoring lines, the testcrosses and F(1) x F(1) populations, together with RAPD and SSR mapping, one dominant gene was identified to control the CMS fertility restoration in cotton. The strategy of genotype representation analysis (GRA) was put forward to screen the markers linked with the Rf(1) locus. Using 1,025 random decamer primers and 282 pairs of SSR primers, two RAPD and three SSR markers were identified to be closely linked to the Rf(1) gene. Among the five markers, three were co-dominantly inherited. Additionally, based on the analysis of monosomic and telesomic lines with one SSR maker, the Rf(1) locus could be located on the long arm of chromosome 4. The molecular markers available here are helpful in the development of the elite restoring lines in cotton by marker-assisted selection.     

用微卫星标记定位小麦T型CMS的恢复基因

以T型细胞质雄性不育系 75 336 9A×恢复系 72 6 9 10的F2 群体作为育性调查和基因定位群体。通过育性分析 ,确定该恢复系含有 2个主效恢复基因 ;结合群分法 ,对恢复基因进行了SSR分子标记定位 ,在 2 30对微卫星引物中 ,微卫星标记Xgwm136和Xgwm5 5 0分别与 2个主效恢复基因连锁。这两个标记与Rf基因之间的遗传距离分别为 6 7cM和 5 1cM ,从而将该恢复基因定位在 1AS、1BS染色体上。     

Isolation of molecular markers from specific chromosomal intervals using DNA pools from existing mapping populations.

We present a general method for isolating molecular markers specific to any region of a chromosome using existing mapping populations. Two pools of DNA from individuals homozygous for opposing alleles for a targeted chromosomal interval, defined by two or more linked RFLP markers, are constructed from members of an existing mapping population. The DNA pools are then screened for polymorphism using random oligonucleotide primers and PCR (1). Polymorphic DNA bands should represent DNA sequences within or adjacent to the selected interval. We tested this method in tomato using two genomic intervals containing genes responsible for regulating pedicle abscission (jointless) and fruit ripening (non-ripening). DNA pools containing 7 to 14 F2 individuals for each interval were screened with 200 random primers. Three polymorphic markers were thus identified, two of which were subsequently shown to be tightly linked to the selected intervals. The third marker mapped to the same chromosome (11) but 45 cM away from the selected interval. A particularly attractive attribute of this method is that a single mapping population can be used to target any interval in the genome. Although this method has been demonstrated in tomato, it should be applicable to any sexually reproducing organism for which segregating populations are being used to construct genetic linkage maps.