Fine mapping of a recessive genic male sterility gene (Bnms3) in rapeseed (Brassica napus) with AFLP- and Arabidopsis-derived PCR markers

9012AB, a recessive genic male sterility (RGMS) line developed from spontaneous mutation in Brassica napus (Chen et al. in Acta Agron Sin 24:431-438, 1998), has been playing an increasing role in hybrid cultivar development in China. The male sterility of 9012AB is controlled by two recessive genes (designated Bnms3 and Bnms4) interacting with one recessive epistatic suppressor gene (esp). Previous study has identified seven AFLP markers, six of which were co-segregated with the Bnms3 gene in a small population (Ke et al. in Plant Breed 124:367-370, 2005). By cloning these AFLP markers and their flanking sequences, five of the six co-segregated markers were successfully converted into sequence characterized amplified region (SCAR) markers. For fine mapping of the Bnms3 gene, these SCAR markers were analyzed in a NIL population of 4,136 individuals. The Bnms3 gene was then genetically mapped to a region of 0.56 cM, with 0.15 cM from marker SEP8 and 0.41 from marker SEP4, respectively. BLAST analysis with these SCAR marker sequences identified a collinear genomic region in Arabidopsis chromosome 5, from which two specific PCR markers further narrowed the Bnms3 locus from an interval of 0.56 to 0.14 cM. These results provide additional information for map-based cloning of the Bnms3 gene and will be helpful for marker-assisted selection (MAS) of elite RGMS lines and maintainers.     

Towards map-based cloning: fine mapping of a recessive genic male-sterile gene (BnMs2) in Brassica napus L. and syntenic region identification based on the Arabidopsis thaliana genome sequences

S45AB, a recessive genic male sterile (RGMS) line, originated as a spontaneous mutant in Brassica napus cv. Oro. The genotypes of sterile (S45A) and fertile plants (S45B) are Bnms1ms1ms2ms2 and BnMs1ms1ms2ms2, respectively. In our previous studies, Yi et al. (Theor Appl Genet 113:643–650, 2006) mapped the BnMs1 locus to a region of 0.4 cM, candidates of which have been identified and genetic transformation is in progress. We describe the fine mapping of BnMs2 exploiting amplified fragment length polymorphism (AFLP) and amplified consensus genetic marker (ACGM) methodologies, and the identification of a collinear region probably containing BnMs2 orthologue in Arabidopsis thaliana. A near isogenic line (NIL) population S4516AB which segregated for BnMs2 locus was generated by crossing, allelism testing and repeated full-sib mating. From the survey of 1,024 AFLP primer combinations, 12 tightly linked AFLP markers were obtained and five of them were successfully converted into co-dominant or dominant sequence characterized amplified region (SCAR) markers. A population of 2,650 sterile plants was screened using these markers and a high-resolution map surrounding BnMs2 was constructed. The closest AFLP markers flanking BnMs2 were 0.038 and 0.075 cM away, respectively. Subsequently, an ACGM marker was developed to delimit the BnMs2 locus at an interval of 0.075 cM. We extended marker sequences to perform BlastN searches against the Arabidopsis genome and identified a collinear region containing 68 Arabidopsis genes, in which the orthologue of BnMs2 might be included. We further integrated BnMs2 linked AFLP or SCAR markers to two doubled-haploid (DH) populations derived from the crosses Tapidor × Ningyou7 (Qiu et al., Theor Appl Genet 114:67–80, 2006) and Quantum × No.2127-17 (available in our laboratory), and BnMs2 was mapped on N16. Molecular markers developed from these investigations will facilitate the marker-assisted selection (MAS) of RGMS lines, and the fine map and syntenic region identified will greatly hasten the process of positional cloning of BnMs2 gene.     

Exploiting comparative mapping among Brassica species to accelerate the physical delimitation of a genic male-sterile locus (BnRf) in Brassica napus

The recessive genic male sterility (RGMS) line 9012AB has been used as an important pollination control system for rapeseed hybrid production in China. Here, we report our study on physical mapping of one male-sterile locus (BnRf) in 9012AB by exploiting the comparative genomics among Brassica species. The genetic maps around BnRf from previous reports were integrated and enriched with markers from the Brassica A7 chromosome. Subsequent collinearity analysis of these markers contributed to the identification of a novel ancestral karyotype block F that possibly encompasses BnRf. Fourteen insertion/deletion markers were further developed from this conserved block and genotyped in three large backcross populations, leading to the construction of high-resolution local genetic maps where the BnRf locus was restricted to a less than 0.1-cM region. Moreover, it was observed that the target region in Brassica napus shares a high collinearity relationship with a region from the Brassica rapa A7 chromosome. A BnRf-cosegregated marker (AT3G23870) was then used to screen a B. napus bacterial artificial chromosome (BAC) library. From the resulting 16 positive BAC clones, one (JBnB089D05) was identified to most possibly contain the BnRf (c) allele. With the assistance of the genome sequence from the Brassica rapa homolog, the 13.8-kb DNA fragment covering both closest flanking markers from the BAC clone was isolated. Gene annotation based on the comparison of microcollinear regions among Brassica napus, B. rapa and Arabidopsis showed that five potential open reading frames reside in this fragment. These results provide a foundation for the characterization of the BnRf locus and allow a better understanding of the chromosome evolution around BnRf.     

Molecular validation of a multiple-allele recessive genic male sterility locus (BnRf) in Brassica napus L.

The recessive genic male sterility (RGMS) line 9012AB has been used successfully for rapeseed hybrid production in China. This male sterility was previously thought to be controlled by three independent genes (Bnms3, Bnms4, and BnRf). Here, we initially attempted to locate the BnMs4 locus and develop feasible molecular markers for application in practical rapeseed breeding. However, we found that three sequence characterized amplified region markers and five simple sequence repeat markers identified as linked to BnMs4 were also genetically associated with BnRf, suggesting the possible co-localization of these two loci. Moreover, we proved that four intron-based polymorphism markers tightly linked or co-segregated with BnRf could also be mapped to BnMs4 with a genetic distance ranging from 0.054 to 0.594?cM. Finally, integration of genetic maps around BnRf and BnMs4 allows for the physical restriction of both loci to a DNA fragment of about 50?kb. Systematic genetic tests also provided evidence that the candidate BnMs4 locus was allelic to the BnRf locus. These results confirmed a major modification of the sterility inheritance model in 9012A: specifically, that this male sterility was essentially controlled by two loci (BnMs3 and BnRf), whereas the previously designated BnMs4 locus (hereafter designated as BnRf ^a ) was just one allele of BnRf in addition to BnRf ^b (the allele from 9012A) and BnRf ^c (the allele from temporary maintainer), with a dominance relationship of BnRf ^a ?>?BnRf ^b ?>?BnRf ^c . This inheritance model will simplify the breeding process involved with this RGMS line, especially with the BnRf allele-specific molecular markers identified here.     

Molecular mapping of the reverse thermo-sensitive genic male-sterile gene (rtms1) in rice

TGMS (thermo-sensitive genic male-sterile) rice is widely used in hybrid rice production. Because of a specific temperature requirement, it can be used only in a narrow rice-growing zone in Asia. A newly discovered reverse thermo-sensitive genic male-sterile line, J207S, has an opposite phynotype compared to the normal TGMS lines. J207S is completely sterile when the temperature is lower than 31°C. Thus, it can be widely used in a larger area. Genetic analysis indicated that the sterility of J207S was controlled by a single recessive gene which was first named as rtms1. An F₂ population from the cross between J207S and E921 was developed and used for molecular mapping of the rtms1 gene. The AFLP (amplified fragment length polymorphism) technique, combined with BSA (bulked segregant analysis), was used to screen markers linked to the target gene, and eight polymorphic AFLP loci were identified. Co-segregating analysis using the F₂ population showed that two of them, Rev1 and Rev7, were closely linked to the target gene with a recombinant rate of 3.8% and 7.7%, respectively. Both Rev1 and Rev7 were found to be single-copy sequences through Southern analysis. Rev1 was subsequently mapped on chromosome 10 with a doubled-haploid mapping populations derived from the cross CT9993 × IR62266 available at Texas Tech University. RM222 and RG257 were linked to Rev1 at a distance of 11.8 cM and 4.6 cM, respectively. Additional SSR markers from the rice map of Cornell University, RFLP markers from the map of RGP in Japan and the map of Texas Tech University were selected from the region surrounding Rev1 on chromosome 10 to conduct the fine-mapping of the rtms1 gene. Presently, rtms1 was mapped between RM239 and RG257 with genetic distance of 3.6 cM and 4.0 cM, respectively. The most-closely linked AFLP marker, Rev1, 4.2 cM from the rtms1 gene, was sequenced and converted into a SCAR (sequence characterized amplified region) marker which could facilitate marker-assisted selection of the rtms1 gene. Received: 2 November 2000 / Accepted: 21 November 2000     

Fine mapping of a dominant thermo-sensitive genic male sterility gene (BntsMs) in rapeseed (Brassica napus) with AFLP- and Brassica rapa-derived PCR markers

Key message

A new thermo-sensitive dominant genic male sterility (TSDGMS) line of Brassica napus was found and mapped in this paper. Our result will greatly accelerate the map-based cloning of the BntsMs gene.

Abstract

TE5A is a thermo-sensitive dominant genic male sterility line originating from spontaneous mutation of the inbred line TE5 in Brassica napus and provides a promising system for the development of hybrid cultivars. Genetic analysis has revealed that the BntsMs mutant is controlled by a single, dominant gene. Here, we describe the fine mapping of BntsMs using amplified fragment length polymorphism (AFLP) and intron polymorphism (IP) methodologies. We screened 1,024 primer combinations and then identified five AFLP markers linked to the BntsMs gene, two of which were successfully converted into sequence-characterised amplified region (SCAR) markers. The linkage of the markers was identified by analysing a large BC₂ population of 700 recessive-fertility individuals. Two SCAR markers were found in the flanking region of the BntsMs gene at distance of 3.5 and 4.8 cm. Based on sequence information from the previously screened AFLP markers and on genome organisation comparisons of the A genome of Brassica rapa and Arabidopsis, seven IP markers linked to the BntsMs gene were developed. By analysing the 700 recessive-fertility individuals, two IP markers, IP004 and IP470, were localised to the flanking region of the BntsMs gene at a distance of 0.3 and 0.2 cm, respectively. A comparison of the B. rapa and Arabidopsis genomes revealed 27 genes of B. rapa in the flanking region of these two IP markers. It is likely that the molecular markers developed from these investigations will greatly accelerate the positional cloning of the BntsMs gene.     

Fine mapping of the recessive genic male sterility gene (<Emphasis Type="Italic">Bnms3</Emphasis>) in <Emphasis Type="Italic">Brassica napus</Emphasis> L.

The Brassica napus oilseed rape line, 7-7365AB, is a recessive epistatic genic male sterile (RGMS) two-type line system. The sterility is controlled by two pairs of recessive duplicate genes (Bnms3 and Bnms4) and one pair of recessive epistatic inhibitor gene (Bnrf). Homozygosity at the Bnrf locus (Bnrfrf) inhibits the expression of the two recessive male sterility genes in homozygous Bnms3ms3ms4ms4 plants and produces a male fertile phenotype. This line has a good potential for heterosis utilization but it is difficult to breed heterotic hybrids without molecular markers. To develop markers linked to the BnMs3 gene, amplified fragment length polymorphism (AFLP) technology was applied to screen the bulks of sterile and fertile individuals selected randomly from a population of near-isogenic lines (NIL) consisting of 2,000 plants. From a survey of 1,024 primer combinations, we identified 17 AFLP markers linked to the BnMs3 gene. By integrating the previous markers linked to the BnMs3 gene into the genetic map of the NIL population, two markers, EA01MC12 and EA09P06, were located on either side of the BnMs3 gene at a distance of 0.1 and 0.3 cM, respectively. In order to use the markers for male sterile line breeding, five AFLP markers, P05MG05, P03MG04, P11MG02, P05MC11₂₅₀, and EA09P06, were successfully converted into sequence characterized amplified region (SCAR) markers. Two of these, P06MG04 and sR12384, were subsequently mapped on to linkage group N19 using two doubled-haploid mapping populations available at our laboratory derived from the crosses Tapidor × Ningyou7 and Quantum × No2127-17. The markers found in the present study should improve our knowledge of recessive genic male sterility (RGMS), and accelerate the development of male sterile line breeding and map-based cloning.     

Genetic analysis,molecular tagging and mapping of the thermo-sensitive genic male-sterile gene (wtms1) in wheat

A thermo-sensitive genic male-sterile (TGMS) wheat line ( Triticum aestivum L.) BNY-S was obtained from the spontaneous mutant of BNY-F. Its fertility was decided by the temperature during the differentiation stage of the spikelets. BNY-S was completely sterile when the temperature was lower than 10 degrees C during the differentiation stage of the spikelets, but fertile when the temperature was higher than 10 degrees C. Genetic analysis indicated that the sterility of BNY-S was controlled by a single recessive gene, which was named as wtms1. An F(2) population, consisting of 3,000 individuals from the cross between BNY-S and Lankao 52-24, was used for genetic analysis and statistical analysis of the TGMS and, out of them, 158 sterile and 93 fertile extremes were present for molecular tagging and mapping of the wtms1 gene. SSR (simple sequence repeat) and AFLP (amplified fragment length polymorphism) techniques combined with BSA (bulked segregant analysis) were used to screen markers linked to the target gene. As a result, wtms1 was preliminarily mapped on chromosome 2B according to SSR analysis. In AFLP analysis, 14 polymorphic AFLP loci were identified with a linkage relation to the wtms1 gene. Then linkage analysis using the F(2) population showed that three of them, E: AAG/M: CTA(163), E: AGG/M: CTC(220) and E: ACA/M: CTA(160), were linked to the wtms1 gene relatively close to a genetic distance of 6.9 cM, 6.9 cM and 13.9 cM, respectively. Finally, the wtms1 gene was mapped between the SSR marker Xgwm 374 and the AFLP marker E: AAG/M: CTA(163) with the distance of 4.8 cM and 6.9 cM, respectively. A partial linkage map was constructed according the SSR and AFLP data.     

Tagging and mapping the thermo-sensitive genic male-sterile gene in rice (Oryza sativa L.) with molecular markers

The thermo-sensititve genic male-sterile (TGMS) gene in rice can alter fertility in response to temperature and is useful in the two-line system of hybrid rice production. However, little is known about the TGMS gene at the molecular level. The objective of this study was to identify molecular markers tightly linked with the TGMS gene and to map the gene onto a specific rice chromosome. Bulked segregant analysis of an F₂ population from 5460s (a TGMS mutant line) x Hong Wan 52 was used to identify RAPD markers linked to the rice TGMS gene. Four hundred RAPD primers were screened for polymorphisms between the parents and between two bulks representing fertile and sterile plants; of these, 4 primers produced polymorphic products. Most of the polymorphic fragments contained repetitive sequences. Only one singlecopy sequence fragment was found, a 1.2-kb fragment amplified by primer OPB-19 and subsequently named TGMS1.2. TGMS1.2 was mapped on chromosome 8 with a RIL population and confirmed by remapping with a DHL population. Segregation analysis using TGMS1.2 as a probe indicated that TGMS1.2 both consegregated and was lined with the TGMS gene in this population. It is located about 6.7 cM from the TGMS gene. As TGMS1.2 is linked to the TGMS gene, the TGMS gene must be located on chromosome 8.This research was supported by the Rockefeller Foundation and China National High-Tech Research and Development Program. The first author is a Rockefeller Career Fellow at Texas Tech University     

Fine mapping and candidate gene analysis of the nuclear restorer gene Rfp for pol CMS in rapeseed (Brassica napus L.)

The Polima (pol) system of cytoplasmic male sterility (CMS) in rapeseed is widely used in China for commercial hybrid seed production. Genetic studies have shown that its fertility restorer gene (Rfp) is monogenic dominant. For fine mapping of the Rfp gene, a near isogenic line comprising 3,662 individuals of BC(14)F(1) generation segregating for the Rfp gene was created. Based on the sequences of two SCAR markers, SCAP0612ST and SCAP0612EM2, developed by Zhao et al. (Genes Genom 30(3):191-196, 2008) and the synteny region of Brassica napus and other Brassica species, 13 markers strongly linked with the Rfp gene were identified. By integrating three of these markers to the published linkage map, the Rfp gene was mapped on linkage group N9 of B. napus. Using these markers, the Rfp locus was narrowed down to a 29.2-kb genomic region of Brassica rapa. Seven open reading frames (ORFs) were predicted in the target region, of these, ORF2, encoding a PPR protein, was the most likely candidate gene of Rfp. These results lay a solid foundation for map-based cloning of the Rfp gene and will be helpful for marker-assisted selection of elite CMS restorer lines.     

Map-based cloning of a recessive genic male sterility locus in Brassica napus L. and development of its functional marker

We previously mapped one male-sterile gene (Bnms3) from an extensively used recessive genic male sterility line (9012AB) in Brassica napus to a 0.14-cM genomic region. In this study, two highly homologous BAC contigs possibly containing the candidate BnMs3 gene were identified using a map-based cloning strategy. A BnMs3-linked SCAR marker (DM1) capable of differentiating the subgenomes between B. rapa and the B. oleracea aided mapping of BnMs3 on the contig derived from the B. napus chromosome C9. One representative BAC clone was sequenced from each of the two contigs and resulted in a larger number of markers according to the sequence difference between the two clones. To isolate BnMs3, these markers were then analyzed in another two BC(1) populations with different genetic backgrounds. This assay allowed for a delimitation of the mutated functional region of BnMs3 to a 9.3-kb DNA fragment. Gene prediction suggested that one complete open reading frame (ORF, ORF2) and partial CDS fragments of ORF1 and ORF3 reside in this fragment. Sequence comparison and genetic transformation eventually indicated that ORF1 (designated as BnaC9.Tic40), an analogue of the Arabidopsis gene AT5G16620 which encodes a translocon of the inner envelope of chloroplasts 40 (Tic40), is the only candidate gene of BnMs3. Furthermore, two distinct mutation types in ORF1 both causing the male-sterile phenotype were individually revealed from 9012A and the temporary maintainer line T45. The molecular mechanism of this male sterility as well as the application of BnMs3-associated functional and cosegregated markers in true breeding programs was also discussed.     

Analysis of RFLP mapping inaccuracy in Brassica napus L.

 We identified sources of mapping inaccuracy during the construction of RFLP linkage maps from one F₂ population and two F₁ microspore-derived populations from the same cross of oilseed Brassica napus. The genetic maps were compared using a total of 145 RFLP marker loci including 82 loci common to all three populations. In the process, we identified a series of mapping events that could lead to ambigous conclusions. Superimposed restriction fragments could be mistaken as a single dominant restriction fragment in a F₂ population and, when analyzed as such, would yield inaccurate linkage information. Residual heterozygosity in parental lines resulted in complicated allelic assignment and yielded subsequent difficulties in linkage determination. Loose and spurious linkages occurred during mapping and were identified by comparing maps derived from different populations. LOD scores and χ² test of independence were compared for their capacity to detect loose linkages or generate spurious ones. Extreme segregation distortions towards the same parental allele also contributed to an additional source of spurious linkage. Small but significant segregation distortions resulted in reduced estimates of the recombination fraction. The use of the same ‘probe× enzyme’ combinations in doubled haploid populations allowed the identification of the correct allele assignment as well as loose and spurious linkages. A translocation between two homoeologous linkage groups was observed. The consequences of such a chromosomal event as a source of error in mapping applications are discussed. Received: 7 September 1996/Accepted: 25 October 1996     

Molecular validation of multiple allele inheritance for dominant genic male sterility gene in Brassica napus L

Dominant genic male sterility (DGMS) has been playing an increasingly important role, not only as a tool for assisting in recurrent selection but also as an alternative approach for efficient production of hybrids. Previous studies indicate that fertility restoration of DGMS is the action of another unlinked dominant gene. Recently, through classical genetic analysis with various test populations we have verified that in a DGMS line 609AB the trait is inherited in a multiple allelic pattern. In this study, we applied molecular marker technology to provide further validation of the results. Eight amplified fragment length polymorphism (AFLP) markers tightly linked to the male sterility allele (Ms) were identified in a BC₁ population from a cross between 609A (a sterile plant in 609AB) and a temporary maintainer GS2467 as recurrent parent. Four out of the eight markers reproduced the same polymorphism in a larger BC₁ population generated with microspore-derived doubled haploid (DH) parents (S148 and S467). The two nearest AFLP markers SA12MG14 and P05MG15, flanking the Ms locus at respective distances of 0.3 centiMorgan (cM) and 1.6 cM, were converted into sequence characterized amplified region (SCAR) markers designated SC6 and SC9. Based on the sequence difference of the marker P05MG15 between S148 and a DH restorer line S103, we further developed a SCAR marker SC9f that is specific to the restorer allele (Mf). The map distance between SC9f and Mf was consistent with that between SC9 and Ms allele. Therefore, successful conversion of the marker tightly linked to Ms into a marker tightly linked to Mf suggested that the restoration for DGMS in 609AB is controlled by an allele at the Ms locus or a tightly linked gene (regarded as an allele in practical application). The Ms and Mf-specific markers developed here will facilitate the breeding for new elite homozygous sterile lines and allow further research on map-based cloning of the Ms gene.     

甘蓝型油菜花瓣缺失基因的图谱定位

在无花瓣品系APT02和正常有花瓣品种中双4号构建的的F2分离群体中,运用AFLP和SRAP两种标记技术对甘蓝型油菜花瓣缺失基因进行分子标记和图谱定位。在两亲本间筛选20对AFLP引物和170对SRAP 引物,进一步通过BSA法筛选,获得了与甘蓝型油菜花瓣缺失基因WHB连锁的1个SRAP标记e8m3_4（600bp）和1个AFLP标记E3247_15（150bp）,标记与基因WHB之间的遗传距离分别为5 cM和13.5cM;构建了一个甘蓝型油菜(Brassica napus.L )的分子标记遗传连锁图谱,该图谱共包含213个AFLP标记、56个SRAP标记和1个形态标记,分布于17个主要连锁群、两个三联体和4个连锁对中,遗传图距总长2487.1cM,标记间平均距离为10.09 cM。通过图谱定位,控制花瓣缺失性状的基因WHB被定位到第4连锁群(LG4)上。     

SSR and SCAR mapping of a multiple-allele male-sterile gene in Chinese cabbage (Brassica rapa L.)

The genic multiple-allele inherited male-sterile gene Ms in Chinese cabbage (Brassica rapa L.) was identified as a spontaneous mutation. Applying this gene to hybrid seed production, several B. rapa cultivars have been successfully bred in China. A BC₁ population (244 plants) was constructed for mapping the Ms gene. Screening 268 simple sequence repeat (SSR) markers which cover the entire genome of Chinese cabbage was performed with bulked segregant analysis (BSA). On the basis of linkage analysis, the Ms gene was located on linkage group R07. In addition, through the amplified fragment length polymorphism (AFLP) and the sequence-characterized amplified region (SCAR) techniques combining BSA, two SCAR markers which were converted from corresponding AFLP markers flanked the Ms gene. Finally, a genetic map of the Ms gene was constructed covering a total interval of 9.0 cM. Two SCAR markers, syau_scr01 and syau_scr04, flanked the Ms gene at distances of 0.8 and 2.5 cM, respectively. All the SSR markers (cnu_m273, cnu_m030, cnu_m295, and syau_m13) were mapped on the same side of the gene as syau_scr04, the nearest one of which, syau_m13, was mapped at a distance of 3.3 cM. These SSR and SCAR markers may be useful in marker-assisted selection and map-based cloning. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Melliferous potential of Brassica napus L. subsp. napus (Cruciferae)

Morphophysiological characteristics of oilseed rape flowers, such as features of the nectaries, nectar production, and observations on honey bee visits and honey and seed yield were studied with the aim to evaluate the melliferous potential of this crop as well as its attractiveness to pollinators. Calculation of the theoretical maximal honey yield revealed that the actual amount of extracted honey was much lower than the potential yield, indicating that this bee pasture is underutilized. We found that honey bee pollination increased oilseed rape yield, i.e., seed production, by 12 % compared with the treatment in which pollinators were excluded.     

Fine mapping of BrWax1, a gene controlling cuticular wax biosynthesis in Chinese cabbage (Brassica rapa L. ssp. pekinensis)

The surface of plants is covered with a cuticular wax, which contains a mixture of very-long-chain fatty acid derivatives. This wax layer provides a hydrophobic barrier which reduces non-stomatal water loss and prevents pathogen attack. The biosynthesis pathway of cuticular wax in Arabidopsis is well studied; however, little is known about the synthesis of cuticular wax in Brassica rapa. Genetic analyses indicated that the waxy characteristic is controlled by a single dominant gene. In the present study, preliminary mapping results from an F2 population consisting of 308 recessive individuals showed that the BrWax1 (Brassica Wax) gene is located on linkage group A01. We developed a set of new markers closely linked to the target gene, and used another population of 1,020 recessive F2 individuals to fine-map the BrWax1 gene to a genomic DNA fragment of approximately 86.4 kb. Fifteen genes were identified in this target region. Based on gene annotation, the Bra013809 gene was the candidate for the BrWax1 gene. Quantitative real-time PCR analysis and expression pattern of the two parents showed that the expression level of Bra013809 was much higher in the waxy phenotype than in the glossy phenotype. This result should provide not only important information for functional studies of the BrWax1 gene, but also the starting point for studying the pathway of cuticular wax biosynthesis in Brassica rapa.     

Characterization and genetic mapping of a novel recessive genic male sterile gene in sesame (Sesamum indicum L.)

Male sterile mutants play a very important role in the utilization of crop heterosis. A recessive genic male sterile (RGMS) two-type line 95ms-5AB was derived from a male sterile mutant of common white sesame (Sesamum indicum L.) cultivar Yuzhi 4 by treatment with gamma rays from ⁶⁰Co. Male sterile 95ms-5A plants did not show any other obvious differences from the male fertile 95ms-5B plants, except for having greenish, shriveled and slim anthers with few, small and degenerative pollens. Genetic analysis indicated that the male sterility of 95ms-5A was controlled by a single RGMS gene, Sims1 (Sesamum indicum male sterility 1). An allelic test with a previously identified RGMS mutant, ms86-1, confirmed that Sims1 in 95ms-5A is different from Sims2 in ms86-1. Amplified fragment length polymorphism markers linked to SiMs1 were screened using bulked segregant analysis. A genetic linkage map of the SiMs1 gene was constructed using 237 plants derived from the sib-mating between the near-isogenic lines 95ms-5A and 95ms-5B. The SiMs1 gene was found to be located in a region of 8.0 cM, at a distance of 1.2 cM from P06MG04 and 6.8 cM from P12EA14. In this genetic region, another marker P01MC08 was identified to be co-segregated with SiMs1. The linkage map constructed in this study will be very useful for marker-assisted selection and map-based cloning of SiMs1 as well as for hybrid breeding in sesame crop.     

Genetic characterization and fine mapping of a novel thermo-sensitive genic male-sterile gene tms6 in rice (Oryza sativa L.)

The application of genetic male sterility in hybrid rice production has great potential to revolutionize hybrid seed production methodology. The two-line breeding system by using thermo-sensitive genic male sterility (TGMS) has been discovered and successfully developed as a breeding strategy in rice. One TGMS gene was investigated by a spontaneous rice mutant line, Sokcho-MS, originated from a Korean japonica variety. It was shown that Sokcho-MS is completely sterile at a temperature higher than 27°C and/or lower than 25°C during the development of spikelets, but fertile at the temperature ranging from 25 to 27°C regardless of the levels of day-length. Genetic analysis and molecular mapping based on SSR, STS and EST markers revealed that a single recessive gene locus involved the control of genic male sterility in Sokcho-MS. By using an F₂ mapping population derived from a cross between Sokcho-MS and a fertile indica variety Neda, the new TGMS gene, designated as tms6, was mapped primarily to the long arm of chromosome 5 of Oryza sativa at the interval between markers E60663 (2.0 cM) and RM440 (5.8 cM). Subsequently, tms6 was fine mapped to the interval between markers RM3351 (0.1 cM) and E60663 (1.9 cM). As tms6 appeared to be independent of other mapped TGMS genes in rice, the genetic basis of Sokcho-MS was further discussed.