Molecular mapping and candidate gene identification of the Rf2 gene for pollen fertility restoration in sorghum [Sorghum bicolor (L.) Moench]

The A1 cytoplasmic–nuclear male sterility system in sorghum is used almost exclusively for the production of commercial hybrid seed and thus, the dominant genes that restore male fertility in F₁ hybrids are of critical importance to commercial seed production. The genetics of fertility restoration in sorghum can appear complex, being controlled by at least two major genes with additional modifiers and additional gene–environment interaction. To elucidate the molecular processes controlling fertility restoration and to develop a marker screening system for this important trait, two sorghum recombinant inbred line populations were created by crossing a restorer and a non-restoring inbred line, with fertility phenotypes evaluated in hybrid combination with three unique cytoplasmic male sterile lines. In both populations, a single major gene segregated for restoration which was localized to chromosome SBI-02 at approximately 0.5 cM from microsatellite marker, Xtxp304. In the two populations we observed that approximately 85 and 87% of the phenotypic variation in seed set was associated with the major Rf gene on SBI-02. Some evidence for modifier genes was also observed since a continuum of partial restored fertility was exhibited by lines in both RIL populations. With the prior report (Klein et al. in Theor Appl Genet 111:994–1012, 2005) of the cloning of the major fertility restoration gene Rf1 in sorghum, the major fertility restorer locus identified in this study was designated Rf2. A fine-mapping population was used to resolve the Rf2 locus to a 236,219-bp region of chromosome SBI-02, which spanned ~31 predicted open reading frames including a pentatricopeptide repeat (PPR) gene family member. The PPR gene displayed high homology with rice Rf1. Progress towards the development of a marker-assisted screen for fertility restoration is discussed.     

Microcolinearity between a 2-cM region encompassing the grain protein content locus<Emphasis Type="Italic"> Gpc-6B1</Emphasis> on wheat chromosome 6B and a 350-kb region on rice chromosome 2

The conservation of the linear order (colinearity) of genetic markers along large chromosome segments in wheat and rice is well established, but less is known about the microcolinearity between both genomes at subcentimorgan distances. In this study we focused on the microcolinearity between a 2.6-cM interval flanked by markers Xcdo365 and Xucw65 on wheat chromosome 6B and rice chromosome 2. A previous study has shown that this wheat segment includes the Gpc-6B1 locus, which is responsible for large differences in grain protein content (GPC) and is the target of a positional cloning effort in our laboratories. Twenty-one recombination events between Xcdo365 and Xucw65 were found in a large segregating population (935 gametes) and used to map 17 genes selected from rice chromosome 2 in the wheat genetic map. We found a high level of colinearity between a 2.1-cM region flanked by loci Xucw75 and Xucw67 on wheat chromosome 6B and a 350-kb uninterrupted sequenced region in rice chromosome arm 2S. Colinearity between these two genomes was extended to the region proximal to Xucw67 (eight colinear RFLP markers), but was interrupted distal to Xucw75 (six non-colinear RFLP markers). Analysis of different comparative studies between rice and wheat suggests that microcolinearity is more frequently disrupted in the distal region of the wheat chromosomes. Fortunately, the region encompassing the Gpc-6B1 locus showed an excellent conservation between the two genomes, facilitating the saturation of the target region of the wheat genetic map with molecular markers. These markers were used to map the Gpc-6B1 locus into a 0.3-cM interval flanked by PCR markers Xucw79 and Xucw71, and to identify five candidate genes within the colinear 64-kb region in rice.     

Isolation and Analysis of Rice Rf1-Orthologus PPR Genes Co-segregating with <Emphasis Type="Italic">Rf3</Emphasis> in Maize

Using an in silico cloning approach, five putative maize pentatricopeptide repeat (PPR)-containing protein genes (PPR-814a, PPR-814b, PPR-814c, PPR-816, PPR-817) with complete open reading frames were identified in the inbred line S-Mo17^Rf3Rf3. The amino acid sequence indicated that these genes encoded mitochondrially targeted proteins containing repeats of a 35-aa PPR motif. The genes were mapped into the interval umc1525–bnlg1520 on chromosome 2. In a non-restoring genotype, we identified three homologous genes that contained deletions or nucleotide substitutions in the coding region. Sequence analysis revealed that one of the three genes (PPR-814a, PPR-814b, PPR-814c) could be considered a candidate restorer gene for S male sterility cytoplasm, and linkage analysis demonstrated that the genes co-segregated with the fertility restorer gene Rf3.     

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     

Delimitation of the rice wide compatibility gene S5 n to a 40-kb DNA fragment

Wide compatibility varieties (WCVs) are a special class of rice (Oryza sativa L.) germplasm that produces hybrids with normal pollen and spikelet fertility when crossed with both indica and japonica subspecies. The wide compatibility gene S5 ⁿ has been used extensively in intersubspecific hybrid breeding programs. We previously mapped the S5 locus to a 2.2-cM genomic region between RM253 and R2349 on chromosome 6, using a population of 356 F₁ plants derived from the three-way cross 02428/Nanjing11//Balilla. In this study, a chromosome walking strategy was employed to construct a physical map covering this genomic region using these two closest markers as the starting points. A physical map consisting of six overlapping BAC clones was formed, spanning a genomic region of 540-kb in length. By analyzing recombination events from a population of 8,000 F₁ plants derived from a three-way cross based on near isogenic lines of the S5 locus, the S5 locus was localized to a DNA fragment of 40-kb in length, flanked by two shotgun subclones, 7B1 and 15D2. Sequence analysis of this fragment predicted five open reading frames, encoding xyloglucan fucosyltransferases, dnak-type molecular chaperone BiP, a putative eukaryotic aspartyl protease, and a hypothetical protein. This result will be very useful in molecular cloning of the S5 ⁿ allele and marker-assisted transferring of the wide compatibility gene in rice breeding programs.     

OsPPR1, a pentatricopeptide repeat protein of rice is essential for the chloroplast biogenesis

In this paper, we report a novel pentatricopeptide repeat (PPR) protein gene in rice. PPR, a characteristic repeat motif consisted of tandem 35 amino acids, has been found in various biological systems including plant. Sequence analysis revealed that the gene designated OsPPR1 consisted of an open reading frame of 2433 nucleotides encoding 810 amino acids that include 11 PPR motifs. Blast search result indicated that the gene did not align with any of the characterized PPR genes in plant. The OsPPR1 gene was found to contain a putative chloroplast transit peptide in the N-terminal region, suggesting that the gene product targets to the chloroplast. Southern blot hybridization indicated that the OsPPR1 is the member of a gene family within the rice genome. Expression analysis and immunoblot analysis suggested that the OsPPR1 was accumulated mainly in rice leaf. Antisense transgenic strategy was used to suppress the expression of OsPPR1 and the resulted transgenic rice showed the typical phenotypes of chlorophyll-deficient mutants; albinism and lethality. Cytological observation using microscopy revealed that the antisense transgenic plant contained a significant defect in the chloroplast development. Taken together, the results suggest that the OsPPR1 is a nuclear gene of rice, encoding the PPR protein that might play a role in the chloroplast biogenesis. This is the first report on the PPR protein required for the chloroplast biogenesis in rice.     

Macro- and microcolinearity between the genomic region of wheat chromosome 5B containing the Tsn1 gene and the rice genome

The Tsn1 gene in wheat confers sensitivity to a proteinaceous host-selective toxin (Ptr ToxA) produced by the tan spot fungus (Pyrenophora tritici-repentis) and lies within a gene-rich region of chromosome 5B. To use the rice genome sequence information for the map-based cloning of Tsn1, colinearity between the wheat genomic region containing Tsn1 and the rice genome was determined at the macro- and microlevels. Macrocolinearity was determined by testing 28 expressed sequence markers (ESMs) spanning a 25.5-cM segment and encompassing Tsn1 for similarity to rice sequences. Twelve ESMs had no similarity to rice sequences, and 16 had similarity to sequences on seven different rice chromosomes. Segments of colinearity with rice chromosomes 3 and 9 were identified, but frequent rearrangements and disruptions occurred. Microcolinearity was determined by testing the sequences of 26 putative genes identified from BAC contigs of 205 and 548 kb in length and flanking Tsn1 for similarity to rice genomic sequences. Fourteen of the predicted genes detected orthologous sequences on six different rice chromosomes, whereas the remaining 12 had no similarity with rice sequences. Four genes were colinear on rice chromosome 9, but multiple disruptions, rearrangements, and duplications were observed in wheat relative to rice. The data reported provide a detailed analysis of a region of wheat chromosome 5B that is highly rearranged relative to rice.     

A microcolinearity study at the earliness per se gene Eps-A m 1 region reveals an ancient duplication that preceded the wheat–rice divergence

Wheat flowering is controlled by numerous genes, which respond to environmental signals such as photoperiod and vernalization. Earliness per se (Eps) genes control flowering time independently of these environmental cues and are responsible for the fine tuning of flowering time. We recently mapped the Eps-A ^m 1 gene on the end of Triticum monococcum chromosome arm 1A^mL. As a part of our efforts to clone Eps-A ^m 1 we developed PCR markers flanking this gene within a 2.7 cM interval. We screened more than one thousand gametes with these markers and identified 27 lines with recombination between them. Recombinant lines were used to generate a high-density map and to investigate the microcolinearity between wheat and rice in this region. We mapped ten genes from a 149 kb region located at the distal part of rice chromosome 5 (cdo393 – Ndk3) on a 3.7 cM region on wheat chromosome one. This region is part of an ancient duplication between rice chromosomes 5 and 1. Genes present in both rice chromosomes were less similar to each other than to the closest wheat orthologues, suggesting that this duplication preceded the divergence between wheat and rice. This hypothesis was supported by the presence of 18 loci duplicated both in rice chromosomes 5 and 1 and in the colinear wheat chromosomes from homoeologous groups 1 and 3. Independent gene deletions in wheat and rice lineages explain the alternations of colinearity between rice chromosome 5 and wheat chromosomes 1 and 3. Colinearity between the end of rice chromosome 5 and wheat chromosome 1 was also interrupted by a small inversion, and several non-colinear genes. These results suggest that the distal region of the long arm of wheat chromosome 1 was involved in numerous changes that differentiated wheat and rice genomes. This comparative study provided sufficient markers to saturate the Eps-A ^m 1 gene region and to precisely map this gene within a 0.9 cM interval flanked by the VatpC and Smp loci. Sequences obtained in this study: DQ196178, DQ196179, DQ196180, DQ196181, DQ196182, DQ196183, DQ196184, DQ196185, DQ196186, DQ196187, DQ196488, DQ198537, DQ308530, DQ308531, DQ308532, DQ308533, DQ308534, DQ308535, DQ308536, DQ308537, DQ308538, DQ308539, DQ308540     

Positional cloning of <Emphasis Type="Italic">ds1</Emphasis>, the target leaf spot resistance gene against <Emphasis Type="Italic">Bipolaris sorghicola</Emphasis> in sorghum

Target leaf spot is one of the major sorghum diseases in southern Japan and caused by a necrotrophic fungus, Bipolaris sorghicola. Sorghum resistance to target leaf spot is controlled by a single recessive gene (ds1). A high-density genetic map of the ds1 locus was constructed with simple sequence repeat markers using progeny from crosses between a sensitive variety, bmr-6, and a resistant one, SIL-05, which allowed the ds1 gene to be genetically located within a 26-kb region on the short arm of sorghum chromosome 5. The sorghum genome annotation database for BTx623, for which the whole genome sequence was recently published, indicated a candidate gene from the Leucine-Rich Repeat Receptor Kinase family in this region. The candidate protein kinase gene was expressed in susceptible plants but was not expressed or was severely reduced in resistant plants. The expression patterns of ds1 gene and the phenotype of target leaf spot resistance were clearly correlated. Genomic sequences of this region in parental varieties showed a deletion in the promoter region of SIL-05 that could cause reduction of gene expression. We also found two ds1 alleles for resistant phenotypes with a stop codon in the coding region. The results shown here strongly suggest that the loss of function or suppression of the ds1 protein kinase gene leads to resistance to target leaf spot in sorghum.     

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.     

Fine physical mapping of the rice stripe resistance gene locus, Stvb-i

The Stvb-i gene confers stripe disease resistance to rice. For positional cloning, we constructed a physical map spanning 1.8-cM distance between flanking markers, consisting of 18 bacterial artificial chromosome (BAC) clones, around the Stvb-i locus on rice chromosome 11. The 18 clones were isolated by screening a BAC library derived from a japonica cultivar, Shimokita, with three Stvb-i-linked RFLP markers and DraI-digested DNAs of a yeast artificial chromosome (YAC) clone. The results of Southern hybridization and restriction enzyme analyses indicated that these BAC clones are contiguous and cover about a 700-kb region containing the Stvb-i allele. Utilizing end and internal fragments of the BAC insert DNAs, 33 molecular markers were generated within a small chromosomal region including the Stvb-i locus. Genotyping analysis with these markers for a resistant cultivar and four nearby recombinants selected from 120 F₂ individuals indicated that Stvb-i is contained within an approximately 286-kb region covered with two overlapping BAC clones. Received: 25 August 1999 / Accepted: 16 November 1999     

The Pik m gene, conferring stable resistance to isolates of Magnaporthe oryzae , was finely mapped in a crossover-cold region on rice chromosome 11

The Pik ^m gene in rice confers a high and stable resistance to many isolates of Magnaporthe oryzae collected from southern China. This gene locus was roughly mapped to the long arm of rice chromosome 11 with restriction fragment length polymorphic (RFLP) markers in the previous study. To effectively utilize the resistance, a linkage analysis was performed in a mapping population consisting of 659 highly susceptible plants collected from four F₂ populations using the publicly available simple sequence repeat (SSR) markers. The result showed that the locus was linked to the six SSR markers and defined by RM254 and RM144 with ≈13.4 and ≈1.2 cM, respectively. To fine map this locus, additional 10 PCR-based markers were developed in a region flanked by RM254 and RM144 through bioinformatics analysis (BIA) using the reference sequence of cv. Nipponbare. The linkage analysis with these 10 markers showed that the locus was further delimited to a 0.3-cM region flanked by K34 and K10, in which three markers, K27, K28, and K33, completely co-segregated with the locus. To physically map the locus, the Pik ^m -linked markers were anchored to bacterial artificial chromosome clones of the reference cv. Nipponbare by BIA. A physical map spanning ≈278 kb in length was constructed by alignment of sequences of the clones anchored by BIA, in which only six candidate genes having the R gene conserved structure, protein kinase, were further identified in an 84-kb segment.     

Comprehensive molecular cytogenetic analysis of sorghum genome architecture: distribution of euchromatin, heterochromatin, genes and recombination in comparison to rice

Cytogenetic maps of sorghum chromosomes 3-7, 9, and 10 were constructed on the basis of the fluorescence in situ hybridization (FISH) of approximately 18-30 BAC probes mapped across each of these chromosomes. Distal regions of euchromatin and pericentromeric regions of heterochromatin were delimited for all 10 sorghum chromosomes and their DNA content quantified. Euchromatic DNA spans approximately 50% of the sorghum genome, ranging from approximately 60% of chromosome 1 (SBI-01) to approximately 33% of chromosome 7 (SBI-07). This portion of the sorghum genome is predicted to encode approximately 70% of the sorghum genes ( approximately 1 gene model/12.3 kbp), assuming that rice and sorghum encode a similar number of genes. Heterochromatin spans approximately 411 Mbp of the sorghum genome, a region characterized by a approximately 34-fold lower rate of recombination and approximately 3-fold lower gene density compared to euchromatic DNA. The sorghum and rice genomes exhibit a high degree of macrocolinearity; however, the sorghum genome is approximately 2-fold larger than the rice genome. The distal euchromatic regions of sorghum chromosomes 3-7 and 10 are approximately 1.8-fold larger overall and exhibit an approximately 1.5-fold lower average rate of recombination than the colinear regions of the homeologous rice chromosomes. By contrast, the pericentromeric heterochromatic regions of these chromosomes are on average approximately 3.6-fold larger in sorghum and recombination is suppressed approximately 15-fold compared to the colinear regions of rice chromosomes.     

Fine mapping of a fertility restoring gene for a new CMS hybrid rice system

The Fujian Abortion cytoplasmic male sterility (CMS-FA) system, a new type of sporophytic CMS system in indica rice (Oryza sativa L.), was developed using the cytoplasm and the corresponding fertility-restoring gene from a wild rice (O. rufipogon L.), which originated from Fujian Province, China. Previous studies in combination with several years of production practice demonstrated that CMS-FA hybrid rice was superior to CMS-WA hybrid rice, a prevailing hybrid rice worldwide, and that the male fertility restoration was controlled by a pair of dominant alleles. We tentatively designated the fertility restoration gene as Rf(fa). The analysis of the polymorphism between the fertile and sterile pool DNAs from a mapping segregation population (BC1F1) indicated that Rf(fa) was located on rice chromosome 10. We further delimited the Rf(fa) locus to a 121.1-kb region flanked by RM6100 and MM2023, which were approximately 0.26 cM and 0.18 cM away from Rf(fa), respectively, by simple sequence repeat molecular marker linkage genetic analysis. These results would facilitate the map-based cloning of Rf(fa), the elucidation of a novel molecular mechanism underlying cytoplasm–nucleus interaction in the CMS-FA system, and the production application of this hybrid rice.     

Genomic targeting and mapping of tiller inhibition gene (<Emphasis Type="Italic">tin3</Emphasis>) of wheat using ESTs and synteny with rice

Changes in plant architecture have been central to the domestication of wild species. Tillering or the degree of branching determines shoot architecture and is a key component of grain yield and/or biomass. Previously, a tiller inhibition mutant with monoculm phenotype was isolated and the mutant gene (tin3) was mapped in the distal region of chromosome arm 3A^mL of Triticum monococcum. As a first step towards isolating a candidate gene for tin3, the gene was mapped in relation to physically mapped expressed sequence tags (ESTs) and sequence tag site (STS) markers developed based on synteny with rice. In addition, we investigated the relationship of the wheat region containing tin3 with the corresponding region in rice by comparative genomic analysis. Wheat ESTs that had been previously mapped to deletion bins provided a useful framework to identify closely related rice sequences and to establish the most likely syntenous region in rice for the wheat tin3 region. The tin3 gene was mapped to a 324-kb region spanned by two overlapping bacterial artificial chromosomes (BACs) of rice chromosome arm 1L. Wheat–rice synteny was exceptionally high at the tin3 region despite being located in the high-recombination, gene-rich region of wheat. Identification of tightly linked flanking EST and STS markers to the tin3 gene and its localization to highly syntenic rice BACs will assist in the future development of a high-resolution map and map-based cloning of the tin3 gene. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Physical mapping of a rice lesion mimic gene,<Emphasis Type="Italic"> Spl1</Emphasis> , to a 70-kb segment of rice chromosome 12

The rice lesion mimic mutant spotted leaf 1 ( spl1) was first identified in the rice ( Oryza sativa) cultivar Asahi in 1965. This mutant displayed spontaneous disease-like lesions in the absence of any pathogen, and was found to confer resistance to multiple isolates of rice blast. We employed a map-based cloning strategy to localize the Spl1 gene. A total of ten cleaved amplified polymorphic sequence (CAPS) markers linked to the Spl1 gene were identified and mapped to an 8.5-cM region on chromosome 12. A high-resolution genetic map was developed using these ten CAPS markers and a segregating population consisting of 3202 individuals. A BAC contig containing four BAC clones was constructed, and Spl1 was localized to a 423-kb region. Seven spl1 mutants were obtained from the IR64 deletion mutant collection, and molecular analysis using these mutants delimited the Spl1 gene to a 70-kb interval, covered by two BAC clones. These results provide the basis for cloning this gene, which is involved in cell death and disease resistance in rice.Communicated by R. HagemannThe first two authors contributed equally to the work