Identification of a sequence-tagged site (STS) marker linked to a restorer gene for Ogura cytoplasmic male sterility in radish (Raphanus sativus L.) by non-radioactive AFLP analysis

To identify DNA markers linked to a fertility restorer (Rf) genefor Ogura cytoplasmic male sterility in radish (Raphanus sativus L.),a non-radioactive, amplified fragment length polymorphism (AFLP) analysiswas performed on bulked DNA samples from male-sterile and male-fertileradishes. Ten male-fertile and 10 male-sterile plants selected arbitrarilyfrom an F₂ population made by selfing of F₁ plant from a crossbetween a male-sterile (`MS-Gensuke') plant and a restorer (`Comet') plantwere used as material. Using 32 AFLP primer pairs, one AFLP fragment(AFLP190) which is specific to the bulked DNA samples from male-fertileF₂ plants was identified. AFLP190 was characterized by molecularcloning and nucleotide sequencing, and was converted to a sequence-taggedsite (STS) marker, STS190. A linkage analysis performed in 126individuals of two independent F₂ populations showed tight linkageof STS190 to the Rf gene. The rate of recombination between themarker and Rf was estimated to be less than 1%, making STS1901.2 cM from the gene.     

RAPD markers linked with restorer genes for the C-source of cytoplasmic male sterility in rye (Secale cereale L.)

The study was aimed at the identification of random amplified polymorphic DNA markers linked to genes controlling male sterility in rye with the C‐source of sterility‐inducing cytoplasm. Markers of male sterility were distinguished using bulk segregant analysis, carried out on the two F₂ crosses between male sterile and male fertile inbred lines. Screening of polymorphisms revealed by 1000 arbitrary 10‐mer primers allowed the detection of 10 markers in the cross between 711‐cmsC and DS2 lines and seven markers in the cross between 544‐cmsC and Ot0‐20 lines. Five markers were common for the two crosses, which allowed comparative mapping to be performed. Ten markers were mapped on the 4RL chromosome arm where two linked quantitative trait loci (QTL) for male sterility were discovered. Additional QTL of minor effect on male fertility were detected between the two linked markers provisionally assigned to the 6RS chromosome arm. The effectiveness of the marker‐assisted selection (MAS) for male‐sterile genotypes was evaluated.     

Cytoplasmic-genetic male sterility in radish (Raphanus sativus L.). Identification of maintainers,inheritance of male sterility and effect of environmental factors

Summary Research has been carried out on identification of maintainers for cytoplasmic-genetic male sterile lines in Japanese and European radish, on the mode of inheritance of male sterility and on the effect of environmental factors on the expression of this character.In a Japanese radish population and in most early European radish populations maintainers were found in high frequency. Segregations for male sterility in full-sib families, obtained by crossing male sterile and male fertile plants, and in backcross generations, indicated that male sterility is probably determined by one dominant and two recessive independently acting genes, but also minor genes may be involved.The expression of male sterility was not affected by seasonal influences. In some populations a reversible temperature effect was found, most ms plants occurred at 10, 14 and 26°C and most mf plants at 17 and 20°C.     

Identification of male sterility maintainer lines for Ogura radish (Raphanus sativus L.)

‘Ogura radish’, a cytoplasmic genetic male sterile line, was crossed with four local and three Japanese cultivars to identify maintainer lines. Out of seven F₁ families, one cross involving a local cultivar, Aushi, produced 100% male sterile (MS) progeny. The crosses involving the other two local cultivars, Tangail Local and Kuni, produced about 90% MS progeny, indicating the presence of maintainer gene(s) for male sterility. The fourth local cultivar, Tasaki, produced 100% male fertile (MF) progeny. All three exotic cultivars appeared to possess the chromosomal gene(s) for controlling the male sterility. In BC₁, BC₂ and BC₃ generations, segregation of MS plants were more frequent when ‘Aushi’ was used as recurrent parent. The expression of male sterility was not affected by seasonal influences. Thus the local cultivar ‘Aushi’ may be used as maintainer line for ‘Ogura radish’. To produce hybrid seed, ‘Tasaki’ can be used as pollinator line as it exhibit high heterosis with ‘Aushi’. This revised version was published online in July 2006 with corrections to the Cover Date.     

AFLP and SCAR markers linked to the suppressor gene (Rf) of a dominant genetic male sterility in rapeseed (Brassica napus L.)

Rs1046AB is a line which is true breeding for a dominant genetic male sterility gene (Ms) but which is a mixture of male fertile and sterile individuals (a two-type line) because it is segregating for a dominant suppressor gene (Rf). This system provides a promising alternative to the CMS system for hybrid breeding in Brassica napus. In order to identify molecular markers linked to the rf gene, a near-isogenic line (NIL) population from the cross between a sterile individual (MsMsrfrf) and a fertile individual (MsMsRfrf) in Rs1046AB was subjected to amplified fragment length polymorphism (AFLP) analysis, with a combination of comparing near isogenic lines (NILs) and bulked segregant analysis (BSA). From 2,816 pairs of AFLP primers, six fragments showing polymorphism between the fertile and sterile bulks as well as the individuals of the bulks were identified. Linkage analysis indicated that the six AFLP markers are tightly linked to the Rf gene and all are distributed on the same side. The minimum genetic distance between the Rf gene and a marker was 0.7 cM. Since the AFLP markers are not suitable for large-scale application in MAS (marker-assisted selection), our objective was to develop a fast, cheap and reliable PCR-based assay. Consequently, three of the four closest AFLP markers were converted directly to sequence characterized amplified region (SCAR) markers. For the other marker a corresponding SCAR marker was successfully obtained after isolating the adjacent sequences by PCR Walking. The available SCAR markers of the Rf gene will greatly facilitate future breeding programs using dominant GMS to produce hybrid varieties.     

Breeding for low nitrate content in radish (Raphanus sativus L.)

Summary To study prospects of reducing nitrate content of radish roots by breeding, plants with varying nitrate content were selected from four populations of the diploid cultivar Robijn (two populations with a low, one with an intermediate and one with a high nitrate content) and from two tetraploid cultivar, Boy and Oscar, with low nitrate contents.Correlation coefficients between nitrate contents of parent plants and their I₁'s were generally significant, but rather small (between 0.48 and 0.78), as were the parent-offspring regression coefficients (between 0.18 and 0.54). Significant differences in nitrate content occurred between I₁'s of each of the parent populations, I₁'s were also present with significantly higher or lower nitrate contents than the corresponding parent populations. Genetic variation for nitrate content was still present within I₁'s. I₂'s could be selected with a significantly lower or higher nitrate content than their I₁'s.It is possible to select radish cultivars with less than 2.0 mg nitrate per gram fresh weight of root under low light conditions in winter. As appeared from crosses with cytoplasmic-genetic male sterile plants, their was no relationship between cytoplasmic-genetic male sterility and nitrate content, indicating that hybrid cultivars with low nitrate contents can also be selected.     

Identification of AFLP fragments linked to one recessive genic male sterility (RGMS) in rapeseed (Brassica napus L.) and conversion to SCAR markers for marker-aided selection

117AB is a recessive genic male sterility (RGMS) line in which the sterility is controlled by a duplicate recessive gene named ms, located at two separate loci. In the RGMS line, the genotype of the sterile plant (117A) is msmsmsms, and that of the fertile plant (117B) is Msmsmsms. The present study was aimed to identify DNA markers linked to the ms locus by amplified fragment length polymorphism (AFLP). From the survey of 512 AFLP primer combinations, 6 AFLP fragments (y1, k1, k2, k3, k4, k5) were identified as being tightly linked to the Ms locus. The genetic distances between the markers and the Ms locus were all less than 8 cM, among which two fragments, designated as k2 and k3, co-segregated with the target gene in the tested population. Fragment k2 was successfully converted into a sequence characterized amplified region (SCAR) marker. The markers detected could be valuable in marker-assisted breeding of RGMS in Brassica napus.     

Molecular mapping of a fertility restorer gene for cytoplasmic male sterility in soybean

In this study, we report the mapping of the Rf locus in soybean by microsatellite simple sequence repeat (SSR) genetic markers. A cross was made between cytoplasmic male sterility (CMS) line JLCMS82A and restorer line JIHUI 1 based on the DNA polymorphisms revealed by 109 SSR markers. A F₂ population derived from a single F₁ plant containing 103 individuals was used for mapping the Rf locus. The Rf gene of JIHUI 1 gametophytically restores male fertility to JLCMS82A. Fertile and semi-fertile DNA bulks and parental DNAs were screened with 219 SSR markers, and Satt215 which was previously mapped to soybean LG J, was found linked to the Rf gene. Five additional polymorphic SSR markers from LG J were used for analysis and a regional linkage map around the Rf locus was established. SSR markers, Sctt011 and Satt547, flanked the Rf locus at 3.6 cM and 5.4 cM, respectively. The availability of these SSR markers will facilitate the selection of restorer lines in hybrid soybean breeding.     

Diversity among sources of cytoplasmic male sterility in sunflower (Helianthus annuus L.)

Summary Ten cytoplasmic male sterile (CMS) sunflower (Helianthus annuus L.) lines were crossed with nine maintainer or male fertility restorer lines in a diallel crossing scheme. Based on fertility restoration of the F₁ generation, CMS lines were divided into four groups. At least two new sources of CMS, CMS PET2 and CMS GIG1, were found to be potentially useful for commercial production of hybrids. Environment had an influence on fertility restoration of one CMS line, CMS MAX1. Effective restoration of male fertility for CMS RIG1, CMS ANN2, and CMS ANN3 was not found.     

Development and primary genetic analysis of a fertility temperature-sensitive polima cytoplasmic male sterility restorer in Brassica napus

Over the past decade, the polima cytoplasmic male sterility ( pol CMS) three-line and two-line systems have been developed for the production of hybrid seed in Brassica napus oilseed rape in China. The discovery of the novel pol CMS restorer line FL-204 is described here. It restores male fertility of hybrid plants in the pol CMS system, but hybrid seed production can only be carried out under autumn sowing in Wuhan in south China under moderate temperatures at flowering. The restorer cannot be used as a male for hybrid seed production in northwestern China (Gansu) under spring sowing conditions, because there it is more or less male sterile due to high temperatures at flowering. Because of this behaviour, it is referred to as a fertility temperature-sensitive restorer (FTSR) in this paper. F₂, BC₁ as well as double haploid populations were constructed to determine the inheritance of fertility restoration of FL-204 in the autumn at Wuhan and under spring sowing conditions at Gansu, respectively. Deviations from Mendelian genetics were observed. It was hypothesized that the change of fertility was the result of the interaction between nuclear genes [restoring gene ( Rf ) and temperature-sensitive genes ( ts )] and the cytoplasm. The Rf gene in FL-204 was incapable of restoring male fertility of pol CMS lines under spring sowing conditions at Gansu where it is inactivated by the recessive ts gene present in FL-204. However, the ts gene(s) could be non-functional under moderate temperature conditions at flowering at Wuhan which allows full expression of male fertility in FL-204. The recessive ts gene(s) can only be expressed in plants containing the pol sterile cytoplasm. A method for the utilization of the FTSR pol CMS restorer FL-204 for the production of hybrid seed in B. napus oilseed rape is proposed.     

SSR and SCAR markers linked to the fertility-restoring gene for a D2-type cytoplasmic male-sterile line in wheat

‘Yi 4060’ is an elite restorer line of a non‐photoperiod‐sensitive D²‐type cytoplasmic male‐sterile (CMS) line of wheat. Random amplified polymorphic DNA (RAPD) and simple sequence repeat (SSR) markers were employed to map one major fertility‐restoring gene (D²Rf₁) in ‘Yi 4060′. The sterile and fertile DNA pools were established from individuals in BC₆, based on bulked segregant analysis. One RAPD marker E09, linked to D²Rf₁, was converted to a SCAR marker and designated as E09‐SCAR₈₆₅. The genetic distance between E09‐SCAR₈₆₅ and D²Rf₁ is 9.5 cM. Two SSR markers, Xgwm11 and Xgwm18, were also linked to a D²Rf₁ and co‐segregated with E09‐SCAR₈₆₅. The three molecular markers are useful in marker‐assisted breeding of the elite restorer lines for D² ‐type CMS lines in wheat.     

Temperature related instability of a naturally induced cytoplasmic male sterility in industrial chicory (Cichorium intybus L.)

Natural alloplasmic cytoplasmic male sterile (CMS) clones of industrial chicory were obtained after crossing wild chicory with selected breeding lines. We investigated the CMS stability of 10 clones in various environmental growing conditions. CMS was stable under cool growing conditions in most of them. Fertility restoration, based on pollen production scores, was observed in all clones after a period of hot temperatures. The early flower bud stage was sensitive, resulting in fertile flowers 12–17 days after exposure to high temperatures. Experiments under controlled growing conditions at 15°C demonstrated that a heat shock of 2 days at 25 or 30°C was sufficient to restore fertility. Sterile flowers were formed when plants were again grown at lower temperatures. Significant differences between individual clones were observed, indicating the potential of genetic selection to obtain stable CMS parent lines.     

Transfer of cytoplasmic male sterility by spontaneous androgenesis in tobacco (Nicotiana tabacum L.)

Summary Five cytoplasmic male sterile lines of Nicotiana tabacum homozygous for a dominant rootless mutation [Rac^-] were used as female parents in crosses with three male fertile varieties. Androgenetic haploids were selected by their ability to form plantlets with a normal root system, whereas hybrid plantlets failed to grow. High frequencies of androgenetic haploid plants were obtained with N. debneyi cytoplasm, and with one paternal genotype. Chromosome doubling was performed using three different methods (pollination, in vitro culture, acenaphthen) and cytoplasmic male sterile doubled haploid plants have been obtained. The results demonstrate the efficiency of this method for a rapid cytoplasm transfer in Nicotiana tabacum; the integrity of the cytoplasm is conserved. For the first time, we possess a counter selectable marker universally usable for Nicotiana tabacum and closely related species.     

Hybridization of radish (Raphanus sativus L.) and oilseed rape (Brassica napus L.) through a flower-culture method

Summary Hybridization between radish and oilseed rape has been cumbersome, requiring elaborate embryo rescue techniques. With a modified flower culture method, we have achieved successful hybridization between radish and (transgenic) oilseed rape without the laborious and technically demandingin vitro ovule or embryo rescue techniques.The hybrid nature of the intergeneric hybrids was demonstrated using morphological traits, and DNA analyses. The described method will facilitate the generation ofRaphanobrassica hybrids useful for biosafety studies of the potential for transgenes to spread in weedyCruciferae as well as for breeding programs aimed at introducing useful radish genes, e.g. nematode resistance genes, into oilseed rape.     

Cytoplasmic male sterility in Brassicaceae crops

Brassicaceae crops display strong hybrid vigor, and have long been subject to F₁ hybrid breeding. Because the most reliable system of F₁ seed production is based on cytoplasmic male sterility (CMS), various types of CMS have been developed and adopted in practice to breed Brassicaceae oil seed and vegetable crops. CMS is a maternally inherited trait encoded in the mitochondrial genome, and the male sterile phenotype arises as a result of interaction of a mitochondrial CMS gene and a nuclear fertility restoring (Rf) gene. Therefore, CMS has been intensively investigated for gaining basic insights into molecular aspects of nuclear-mitochondrial genome interactions and for practical applications in plant breeding. Several CMS genes have been identified by molecular genetic studies, including Ogura CMS from Japanese radish, which is the most extensively studied and most widely used. In this review, we discuss Ogura CMS, and other CMS systems, and the causal mitochondrial genes for CMS. Studies on nuclear Rf genes and the cytoplasmic effects of alien cytoplasm on general crop performance are also reviewed. Finally, some of the unresolved questions about CMS are highlighted.     

Development of genomic and EST-SSR markers in radish (Raphanus sativus L.)

Radish (Raphanus sativus L.) belongs to Brassicaceae family and is a close relative of Brassica. This species shows a wide morphological diversity, and is an important vegetable especially in Asia. However, molecular research of radish is behind compared to that of Brassica. For example, reports on SSR (simple sequence repeat) markers are limited. Here, we designed 417 radish SSR markers from SSR-enriched genomic libraries and the cDNA data. Of the 256 SSR markers succeeded in PCR, 130 showed clear polymorphisms between two radish lines; a rat-tail radish and a Japanese cultivar, ‘Harufuku’. As a test case for evaluation of the present SSRs, we conducted two studies. First, we selected 16 SSRs to calculate polymorphism information contents (PICs) using 16 radish cultivars and four other Brassicaceae species. These markers detected 3–15 alleles (average = 9.6). PIC values ranged from 0.54 to 0.92 (average = 0.78). Second, part of the present SSRs were tested for mapping using our previously-examined mapping population. The map spanned 672.7 cM with nine linkage groups (LGs). The 21 radish SSR markers were distributed throughout the LGs. The SSR markers developed here would be informative and useful for genetic analysis in radish and its related species.     

Conversion of the genic male sterility (GMS) system of bell pepper (Capsicum annuum L.) to cytoplasmic male sterility (CMS)

Non‐pungent bell pepper (Capsicum annuum L.) lacks the cytoplasmic male sterility (CMS) nuclear restorer allele, Rf, and CMS cannot be employed in its F₁ hybrid seed production. To demonstrate that the genic male sterility (GMS) system in non‐pungent bell pepper can be converted to the CMS male sterility system, the conversion of GMS to CMS for non‐pungent bell pepper line GC3 was conducted by introgression of S‐type cytoplasm and the Rf allele from tropical pungent donors. After morphological traits were evaluated, two lines from BC₁F₁ containing S‐type cytoplasm and four lines from BC₂F₂ containing Rf allele, phenotypically similar to GC3, were obtained and could be employed as CMS male sterile lines and restorer lines for non‐pungent bell pepper. Four molecular markers potentially linked to traits of interest were also evaluated in BC₁F₁ and BC₁F₂ populations. This is the first time that GMS has been successfully converted to CMS in bell pepper, a significant contribution for bell pepper hybrid seed production.     

PPR‐B‐31: a new maintainer allele in the male‐fertility restorer gene of radish (Raphanus sativus) Ogura cytoplasm

The PPR‐B gene is responsible for male‐fertility restoration of the Ogura‐type male‐sterile radish plants, and it is located in the complex Rfo locus in the vicinity of similar PPR‐A gene and PPR‐C pseudogene. The aim of this study was to identify PPR‐B alleles and understand the structure of the Rfo locus in radish breeding lines. Five lines of radish with normal male‐fertile cytoplasm were tested. The entire PPR‐B gene was amplified, sequenced and allelic PPR‐B sequences were identified. The results indicated that the maintainer lines 7, 15 and 21 contained a non‐restoring form of PPR‐B protein. A unique PPR‐B was found in lines 24/15 and 31 that are restorer and maintainer lines, respectively. The substitutions might be responsible for the loss of a restoring function of the PPR‐B‐31 allele. Amplification of the PPR‐A/PPR‐B and PPR‐B/PPR‐C intergenic regions allowed to identify rearrangements within Rfo locus. Obtained results confirm the wide allelic variation within the Rfo locus, as well as high genetic complexity of the fertility restoration mechanism in radish.     

Molecular and biological studies on male sterile cytoplasm in Cruciferae. II. The origin of Ogura male sterile cytoplasm inferred from the segregation pattern of male sterility in the F1 progeny of wild and cultivated radishes (Raphanus sativus L.)

Summary To determine the origin of Ogura male sterile cytoplasm in radish (Raphanus sativus L.), wild and cultivated radishes were crossed. Three types of progeny resulted from the F₁ hybrids between the wild radish from Kushikino with Ogura-type mtDNA and the cultivars (Uchiki-Gensuke or Comet). The segregation patterns of the male sterility were compared with those of Ogura cytoplasm. The male sterility induced in the F₁ hybrid was maintained by crossing with Uchiki-Gensuke, that maintains Ogura male sterility. In the two types of progeny, in which Comet (a restorer of Ogura cytoplasm) was used as one of the parents, both fertile and sterile plants segregated at the predicted ratio on the assumption that a single dominant fertility restoring gene exists in the restorer. From these results, we concluded that the Ogura cytoplasm is identical to that of the wild radish, and the former originated in a population of Japanese wild radish.