A Moricandia arvensis– based cytoplasmic male sterility and fertility restoration system in Brassica juncea

 A cytoplasmic male-sterility system has been developed in mustard (Brassica juncea) following repeated backcrossings of the somatic hybrid Moricandia arvensis (2n=28, MM)+B. juncea (2n=36, AABB), carrying mitochondria and chloroplasts from M. arvensis, to Brassica juncea. Cytoplasmic male-sterile (CMS) plants are similar to normal B. juncea; however, the leaves exhibit severe chlorosis resulting in delayed flowering. Flowers are normal with slender, non-dehiscent anthers and excellent nectaries. CMS plants show regular meiosis with pollen degeneration occurring during microsporogenesis. Female fertility was normal. Genetic information for fertility restoration was introgressed following the development of a M. arvensis monosomic addition line on CMS B. juncea. The additional chromosome paired allosyndetically with one of the B. juncea bivalents and allowed introgression. The putative restorer plant also exhibited severe chlorosis similar to CMS plants but possessed 89% and 73% pollen and seed fertility, respectively, which subsequently increased to 96% and 87% in the selfed progeny. The progeny of the cross of CMS line with the restorer line MJR-15, segregated into 1 fertile : 1 sterile. The CMS (Moricandia) B. juncea, the restorer (MJR-15), and fertility restored F₁ plants possess similar cytoplasmic organellar genomes as revealed by ‘Southern’ analysis. Received: 17 September 1997 / Accepted: 18 February 1998     

Identification of AFLP markers linked to the male fertility restorer gene of CMS (Moricandia arvensis) Brassica juncea and conversion to SCAR marker

We have developed a cytoplasmic male sterile (CMS) line of Brassica juncea through somatic hybridization with Moricandia arvensis and introgressed the fertility restorer gene into B. juncea. This fertility restorer locus is unique in that it is capable of restoring male fertility to two other alloplasmic CMS systems of B. juncea. As a first step toward cloning of this restorer gene we attempted molecular tagging of the Rf locus using the amplified fragment length polymorphism (AFLP) technique. A BC₁F₁ population segregating for male sterility/fertility was used for tagging using the bulk segregant analysis method. Out of 64 primer combinations tested in the bulks, 5 combinations gave polymorphic amplification patterns. Further testing of these primers in individual plants showed four amplicons associated with the male fertility trait. Polymorphic amplicons were cloned and used for designing SCAR primers. One of the SCAR primers generated amplicons mostly in the fertile plants. Linkage analysis using MAPMAKER showed two AFLP and one SCAR markers linked to the male fertility gene with a map distance ranging from 0.6 to 2.9 cM. All the markers are located on one side of the Rf locus.     

Male sterility caused by cytoplasm of Brassica oxyrrhina in B. campestris and B. juncea

Summary Synthetic alloploid Brassica oxyrrhina (2n = 18, OO) x B. campestris (2n = 20, AA) was repeatedly backcrossed with B. campestris to place B. campestris nucleus in the cytoplasm of B. oxyrrhina. Alloplasmic plants, obtained in BC₅ generation, were stably male sterile but mildly chlorotic during initial development. Synthetic alloploid B. oxyrrhina-campestris was also hybridized with B. juncea to transfer B. oxyrrhina cytoplasm. Segregation for green and chlorotic plants was observed in BC₁ and BC₂ generations. By selection, however, normal green male sterile B. juncea was obtained in BC₃. Pollen abortion in both B. campestris and B. juncea is post-meiotic.     

A new cytoplasmic male sterility system for hybrid seed production in Indian oilseed mustard Brassica juncea

We report a novel cytoplasmic male sterility (CMS) system in Brassica juncea (oilseed mustard) which could be used for production of hybrid seed in the crop. A male sterile plant identified in a microspore derived doubled haploid population of re-synthesized B. napus line ISN 706 was found to be a CMS as the trait was inherited from the female parent. This CMS, designated ‘126-1’, was subsequently transferred to ten different B. juncea varieties and lines through inter-specific crosses followed by recurrent backcrossing. The F₁s of inter-specific crosses were invariably partially fertile, but irrespective of the variety/line used, the recipient lines became progressively male sterile over five to seven generations and could be maintained by crossing the male sterile lines with their normal counterparts. The male sterile lines were found to be stable for the trait under both long and short day conditions. CMS lines when crossed with lines other than the respective maintainer line were restored for fertility, implying that any variety could act as a restorer for ‘126-1’ cytoplasm in B. juncea. These unique features in maintenance and restoration of CMS lines coupled with near normal floral morphology of the CMS lines have allowed the use of ‘126-1’ cytoplasm for hybrid seed production. The uniqueness of ‘126-1’ has been further established by Southern hybridization with mitochondrial DNA probes and by a histological study of the development of male sterile anthers.     

Recombination between chloroplast genomes of Trachystoma ballii and Brassica juncea following protoplast fusion

We document here the presence of a recombinant plastome in a cytoplasmic male sterile (CMS) line of Brassica juncea developed from the somatic hybrid Trachystoma ballii + B. juncea. Restriction endonuclease digestion of the chloroplast (cp) DNA has revealed that the recombinant plastome gives rise to novel fragments in addition to the parent-specific fragments. Analysis of the 16S rRNA region by Southern hybridization shows no variation between B. juncea, T. ballii and the CMS line. The rbcL gene region of the recombinant plastome is identical to that in T. ballii. Analysis with probes for psbA and psbD using single and double DNA digests indicates that the hybridization patterns of the recombinant plastome are identical to those of the parents in digests obtained with some restriction enzymes, while novel bands hybridize to probes in other digests. In the psbA region, a B. juncea-specific PstI site and a T. ballii-specific EcoRI site are found in the recombinant plastome. The psbD region of the recombinant plastome contains a B. juncea-specific HindIII site and T. ballii-specific BamHI and HpaII sites. These results indicate the occurrence of intergenomic recombination between the chloroplasts of T. ballii and B. juncea in the somatic hybrid from which the CMS line was developed. The recombined plastome appears to be a mosaic of fragments specific to both parents and the recombination event has occurred in the single-copy regions. These recombinational events have not caused any imbalance in the recombinant plastome in terms of chloroplast-related functions, which have remained stable over generations. Received: 3 March 1998 / Accepted: 5 August 1998     

Stable inheritance and expression of the CMS traits introduced by asymmetric protoplast fusion

The donor-recipient protoplast fusion method was used to produce cybrid plants and to transfer cytoplasmic male sterility (CMS) from two cytoplasmic male-sterile lines MTC-5A and MTC-9A into a fertile japonica cultivar, Sasanishiki. The CMS was expressed in the cybrid plants and was stably transmitted to their progenies. Only cytoplasmic traits of the male-sterile lines, especially the mitochondrial DNAs, were introduced into the cells of the fertile rice cultivar. More than 80% of the cybrid plants did not set any seeds upon selfing. Sterile cybrid plants set seeds only when they were fertilized with normal pollen by hand and yielded only sterile progenies. This maternally inherited sterility of the cybrid plants showed that they were characterized by CMS. The CMS of cybrid plants could be restored completely by crossing with MTC-10R which had the single dominant gene Rf-1 for restoring fertility. These results indicated that CMS was caused by the mitochondrial genome introduced through protoplast fusion. The introduced CMS was stably transmitted to their progenies during at least eight backcross generations. These results demonstrate that cybrids generated by the donor-recipient protoplast fusion technique can be used in hybrid rice breeding for the creation of new cytoplasmic male-sterile rice lines.     

Development of a novel Sinapis arvensis disomic addition line in Brassica napus containing the restorer gene for Nsa CMS and improved resistance to Sclerotinia sclerotiorum and pod shattering

An allo-cytoplasmic male sterile line, which was developed through somatic hybridization between Brassica napus and Sinapis arvensis (thus designated as Nsa CMS line), possesses high potential for hybrid production of rapeseed. In order to select for restorer lines, fertile plants derived from the same somatic hybridization combination were self-pollinated and testcrossed with the parental Nsa CMS line for six generations. A novel disomic alien addition line, B. napus–S. arvensis, has been successfully developed. GISH analysis showed that it contains one pair of chromosomes from S. arvensis and 19 pairs from B. napus, and retains stable and regular mitotic and meiotic processes. The addition line displays very strong restoration ability to Nsa CMS line, high resistance to Sclerotinia sclerotiorum and a low incidence of pod shattering. Because the addition line shares these very important agricultural characters, it is a valuable restorer to Nsa CMS line, and is named NR1 here (Nsa restorer no. 1).     

Random chloroplast segregation and mitochondrial genome recombination in somatic hybrid plants of Diplotaxis catholica+Brassica juncea

Detailed molecular analysis of the somatic hybrid plants of Diplotaxis catholica+B. juncea indicated random chloroplast segregation. One of the five hybrid plants analyzed derived its chloroplasts from D. catholica and two hybrids had chloroplasts of B. juncea origin. Two hybrid plants maintained mixed population of chloroplasts. The mitochondrial (mt) genomes of the fusion partners had undergone recombinations. Occurrence of fragments specific to both the parents in HindIII digestion followed by atp 9 probing, as in hybrid DJ5, provided evidence for intergenomic mitochondrial recombination between D. catholica and B. juncea. Similar mt genome organization in two hybrids (DJ3 and DJ6) suggested that intergenomic recombination may be preferred at specific sites. Hybrid DJ1 had about 70% similarity to D. catholica in mt genome organization. mt genomes of hybrids DJ2, 3, 5, and 6 differed from B. juncea by 14.3–28%. The significance of these novel mt genome organizations in developing novel male sterility systems is discussed. Received: 4 April 1997 / Revision received: 19 December 1997 / Accepted: 28 March 1998     

Characterization of a partial male fertility derived from Ogura-cms in progeny of a resynthesized Brassica napus

Summary The inheritance of a partial male fertile phenotype in somatic hybrid B. napus plants that carried novel mtDNA was investigated over five backcross generations to B. napus Triton. The recurrent parent and the original somatic hybrid both contained chloroplasts resistant to atrazine. The F₁ population contained mainly plants that were partial fertile, and some of the plants differed in mtDNA. The partial fertility predominated in the progeny of each backcross generation, but fully male sterile and fertile plants were also obtained. However, the sterility/fertility of these latter plants was not stable; both the fully male sterile and the male fertile plants produced progeny that were again predominantly partial male fertile. This pattern of predominant partial fertility but occasional sterile and fertile plants persisted in different nuclear backgrounds. Neither the male sterility nor the male fertility could be fixed and made stable. Test crosses indicated that restorer genes were probably not associated with appearance of male fertile plants. The evidence indicates that the behavior of the partial male fertility is cytoplasmic, and probably controlled by the chondriome.     

Alloplasmic male-sterile <Emphasis Type="Italic">Brassica juncea</Emphasis> with <Emphasis Type="Italic">Enarthrocarpus lyratus</Emphasis> cytoplasm and the introgression of gene(s) for fertility restoration from cytoplasm donor species

A new cytoplasmic male sterility (CMS) source in Brassica juncea (2n = 36; AABB) was developed by substituting its nucleus into the cytoplasm of Enarthrocarpus lyratus (2n = 20; E(l)E(l)). Male sterility was complete, stable and manifested in either petaloid- or rudimentary-anthers which were devoid of fertile pollen grains. Male sterile plants resembled the euplasmic B. juncea except for slight leaf yellowing and delayed maturity. Leaf yellowing was due mainly to higher level of carotenoids rather than a reduction in chlorophyll pigments. Female fertility in male-sterile plants varied; it was normal in lines having rudimentary anthers but poor in those with petaloid anthers. Each of the 62 evaluated germplasm lines of B. juncea was a functional maintainer of male sterility. The gene(s) for male-fertility restoration ( Rf) were introgressed from the cytoplasm donor species through homoeologous pairing between A and E(l) chromosomes in monosomic addition plants (2n = 18II+1E(l)). The percent pollen fertility of restored F(1) ( lyr CMS x putative restorer) plants ranged from 60 to 80%. This, however, was sufficient to ensure complete seed set upon by bag selfing. The CMS ( lyr) B. juncea compared favourably with the existing CMS systems for various productivity related characteristics. However, the reduced transmission frequency of the Rf gene(s) through pollen grains, which was evident from the sporadic occurrence of male-sterile plants in restored F(1) hybrids, remains a limitation.     

Somatic hybridization between Brassica juncea and Moricandia arvensis by protoplast fusion

Intergeneric somatic hybrids have been produced between Brassica juncea (2n=36, AABB) cv. RLM-198 and Moricandia arvensis (2n=28, MM) by protoplast fusion. Hypocotyl protoplasts of B. juncea were fused with mesophyll protoplasts of M. arvensis using polyethylene glycol. Fusion frequency, estimated on the basis of differential morphological characterstics of parental protoplasts was about 5%. Of the 156 calli obtained, four calli produced shoots intermediate in morphology between the parents. Hybrid nature of the plants was confirmed using wheat nuclear rDNA probe. Hybridization of total DNA with a mitochondrial DNA probe carrying 5s–18s rRNA genes of maize showed that the mitochondria of the somatic hybrids were derived from the wild species M. arvensis. Meiosis in the only hybrid that produced normal flowers revealed the occurrence of 64 chromosomes, the sum of chromosomes of parental species. Inspite of complete pollen sterility, siliquas were produced in this hybrid by back-crossing with B. juncea. These siliquas on in vitro culture produced 12 seeds.     

The effect of genotype on pollen transmission of mitochondria in rapeseed (Brassica napus)

Summary Crossing experiments were conducted to determine whether parental genotype affected the rate of transmission of paternal mitochondria to progeny in rapeseed (Brassica napus). Progeny were screened either by RFLP analysis of mitochondrial (mt) DNA or by means of a mt marker that causes male sterility. To date we have transferred paternal mitochondria to progeny in only cross, i.e. a specific female line crossed to a specific male line. The male line carries the polima cytoplasm, the mitochondria of which confer a characteristic malesterile flower morphology when in a napus nuclear background. This line is male fertile due to a restorer gene carried on an extra chromosome from a closely related species, Brassica juncea. The female line has a Brassica campestris cytoplasm with a chloroplast mutation conferring resistance to triazine herbicides. Progeny with mixtures of parental mtDNA display a range of plant phenotype from complete male fertility through varying proportions of male-sterile sectors to complete male sterility. The male sterility or fertility of flowers on a sector of a plant reflects the mt population of that sector, and such sectors will give rise to stably fertile or sterile progeny. These experiments suggest that maternal inheritance of mitochondria in higher plants is due to genes active in both the pollen parent and the egg parent.     

Genetic characterization of a new cytoplasmic male sterility system (<Emphasis Type="Italic">hau</Emphasis>) in <Emphasis Type="Italic">Brassica </Emphasis><Emphasis Type="Italic">juncea</Emphasis> and its transfer to <Emphasis Type="Italic">B. napus</Emphasis>

A novel cytoplasmic male sterility (CMS) was identified in Brassica juncea, named as hau CMS (00-6-102A). Subsequently, the male sterility was transferred to B. napus by interspecific hybridization. The hau CMS has stable male sterility. Flowers on the A line are absolutely male sterile, and seeds harvested from the line following pollinations with the maintainer gave rise to 100% sterile progeny. The anthers in CMS plants are replaced by thickened petal-like structures and pollen grains were not detected. In contrast, in other CMS systems viz. pol, nap, tour, and ogu, anthers are formed but do not produce viable pollen. The sterility of hau CMS initiates at the stage of stamen primordium polarization, which is much earlier compared with the other four CMS systems. We have successfully transferred hau CMS from B. juncea to B. napus. Restorer lines for pol, ogu, nap, and tour CMS systems were found to be ineffective to restore fertility in hau CMS. Sixteen out of 40 combinations of mitochondrial probe/enzyme used for RFLP analysis distinguished the hau CMS system from the other four systems. Among these sixteen combinations, five ones alone could distinguish the five CMS systems from each other. The evidence from genetic, morphological, cytological and molecular studies confirmed that the hau CMS system is a novel CMS system. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Recombination between chloroplast genomes of Trachystoma ballii and Brassica juncea following protoplast fusion

We document here the presence of a recombinant plastome in a cytoplasmic male sterile (CMS) line of Brassica juncea developed from the somatic hybrid Trachystoma ballii?+?B. juncea. Restriction endonuclease digestion of the chloroplast (cp) DNA has revealed that the recombinant plastome gives rise to novel fragments in addition to the parent-specific fragments. Analysis of the 16S rRNA region by Southern hybridization shows no variation between B. juncea, T. ballii and the CMS line. The rbcL gene region of the recombinant plastome is identical to that in T. ballii. Analysis with probes for psbA and psbD using single and double DNA digests indicates that the hybridization patterns of the recombinant plastome are identical to those of the parents in digests obtained with some restriction enzymes, while novel bands hybridize to probes in other digests. In the psbA region, a B. juncea-specific PstI site and a T. ballii-specific EcoRI site are found in the recombinant plastome. The psbD region of the recombinant plastome contains a B. juncea-specific HindIII site and T. ballii-specific BamHI and HpaII sites. These results indicate the occurrence of intergenomic recombination between the chloroplasts of T. ballii and B. juncea in the somatic hybrid from which the CMS line was developed. The recombined plastome appears to be a mosaic of fragments specific to both parents and the recombination event has occurred in the single-copy regions. These recombinational events have not caused any imbalance in the recombinant plastome in terms of chloroplast-related functions, which have remained stable over generations.     

Restoration of fertility in cytoplasmic male sterile (CMS) Nicotiana Sylvestris by fusion with X-irradiated N. tabacum protoplasts

Summary Restoration of male fertility was achieved by fusing protoplasts from male sterile (CMS) Nicotiana sylvestris plants with X-irradiated protoplasts derived from fertile N. tabacum plants. The CMS N. sylvestris plants were derived from a previous somatic hybridization experiment and contained alien (Line 92) cytoplasm. About one quarter of the regenerated plants were found to be cybrids. i.e. they consisted of N. sylvestris nuclei combined with all or some components of N. tabacum cytoplasm. In one half of these cybrids male fertility was restored to different levels. The chloroplasts of the two parental donors differ in respect to tentoxin sensitivity: chloroplasts of CMS N. sylvestris are sensitive while those of N. tabacum are insensitive. It could therefore be demonstrated that there was an independent segregation of chloroplast type and male fertility/sterility: several somatic cybrids were male fertile but tentoxin sensitive and others were tentoxin insensitive yet they were male sterile. Only in about one half of the somatic cybrids was male fertility restored together with restoration to tentoxin insensitivity.     

Protoplast fusion-derived Ogura male sterile cauliflower with cold tolerance

Cauliflower (Brassica oleracea L. ssp. botrytis) protoplasts with Ogura male sterile and fertile B. oleracea cytoplasms were fused, producing plants with an array of organellar types. Plants with Ogura mitochondria were male sterile; those with B. oleracea chloroplasts were cold tolerant. In some fusions, unfused parental protoplasts were eliminated by double inactivation with iodoacetate and gamma-irradiation; in others, fused protoplasts were physically isolated by micromanipulation or by cell sorting. Double inactivation fusions produced the most plants, including many which were male sterile, female fertile, cold tolerant and diploid.Abbreviations IA iodoacetate - FDA fluorescein diacetate - CMS cytoplasmic male sterility - mtDNA mitochondrial DNA     

Production of new CMS Brassica oleracea by transfer of `Anand' cytoplasm from B. rapa through protoplast fusion

New types of cytoplasmic male sterility (CMS) in Brassica oleracea would be useful for F₁ hybrid seed production. The `Anand' cytoplasm derives from the wild species B. tournefortii. Rapid cycling stocks of B. rapa and B. oleracea were used in cybridization experiments as donor and recipient of `Anand' (=`tour') CMS, respectively. Prior to fusion with PEG, donor protoplasts were inactivated with 30 krad γ-rays and recipient ones with 3 mM iodoacetate, respectively. No calli were obtained from the pre-treated protoplasts. The frequency of shoot regeneration was 21–43% in untreated B. oleracea controls, but only 0–0.5% in `Anand' B. rapa. Putative cybrids were regenerated from about 3% of the calli from fused protoplasts. Regenerated plants were analyzed for nuclear DNA content, plant and flower morphology, pollen production, female fertility, cold tolerance, and organelle composition. Eighty-one percent of the regenerated controls and 63% of fusion-derived plants were diploid. The rest showed DNA contents corresponding to 2x–4x, 4x, or higher ploidy levels, presumably due to somatic doubling in vitro and/or fusions in which the donor nucleus was not completely eliminated. Sixty-four percent of the cybrids had stamens and petals varying in size and shape and were male-sterile, with indehiscent anthers. Their phenotype was otherwise similar to that of B. oleracea. The remaining plants had normal flowers and were male-fertile. Data from crosses with fertile pollinators indicated good female fertility in some of the sterile lines, both after hand and insect pollinations in cages. Mitochondrial (mt) segregation in the cybrids was slightly biased towards `Anand' mitochondria, and the presence of `Anand' mtDNA fragments was strongly associated with male sterility. Evidence of mtDNA rearrangements was obtained in some cybrids. Segregation of chloroplasts was slightly biased towards B. oleracea. The presence of `Anand' chloroplasts with a B. oleracea nucleus did not result in cold temperature chlorosis, as seen in `Ogura' CMS plants. Received: 22 February 1996 / Accepted: 10 May 1996     

Comparative analysis of mitochondrial genomes between the hau cytoplasmic male sterility (CMS) line and its iso-nuclear maintainer line in Brassica juncea to reveal the origin of the CMS-associated gene orf288

Background

Cytoplasmic male sterility (CMS) is not only important for exploiting heterosis in crop plants, but also as a model for investigating nuclear-cytoplasmic interaction. CMS may be caused by mutations, rearrangement or recombination in the mitochondrial genome. Understanding the mitochondrial genome is often the first and key step in unraveling the molecular and genetic basis of CMS in plants. Comparative analysis of the mitochondrial genome of the hau CMS line and its maintainer line in B. juneca (Brassica juncea) may help show the origin of the CMS-associated gene orf288.

Results

Through next-generation sequencing, the B. juncea hau CMS mitochondrial genome was assembled into a single, circular-mapping molecule that is 247,903 bp in size and 45.08% in GC content. In addition to the CMS associated gene orf288, the genome contains 35 protein-encoding genes, 3 rRNAs, 25 tRNA genes and 29 ORFs of unknown function. The mitochondrial genome sizes of the maintainer line and another normal type line “J163-4” are both 219,863 bp and with GC content at 45.23%. The maintainer line has 36 genes with protein products, 3 rRNAs, 22 tRNA genes and 31 unidentified ORFs. Comparative analysis the mitochondrial genomes of the hau CMS line and its maintainer line allowed us to develop specific markers to separate the two lines at the seedling stage. We also confirmed that different mitotypes coexist substoichiometrically in hau CMS lines and its maintainer lines in B. juncea. The number of repeats larger than 100 bp in the hau CMS line (16 repeats) are nearly twice of those found in the maintainer line (9 repeats). Phylogenetic analysis of the CMS-associated gene orf288 and four other homologous sequences in Brassicaceae show that orf288 was clearly different from orf263 in Brassica tournefortii despite of strong similarity.

Conclusion

The hau CMS mitochondrial genome was highly rearranged when compared with its iso-nuclear maintainer line mitochondrial genome. This study may be useful for studying the mechanism of natural CMS in B. juncea, performing comparative analysis on sequenced mitochondrial genomes in Brassicas, and uncovering the origin of the hau CMS mitotype and structural and evolutionary differences between different mitotypes.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-322) contains supplementary material, which is available to authorized users.     

Transfer of Ogu cytoplasmic male sterility to Brassica juncea and improvement of the male sterile line through somatic cell fusion

Male sterility conferred by ogu cytoplasm of Raphanus sativus has been transferred to Brassica juncea cv RLM 198 from male-sterile B. napus through repeated backcrossing and selection. The male-sterile B. juncea is, however, highly chlorotic and late. It has low female (seed) fertility and small contorted pods. To rectify these defects, protoplasts of the male sterile were fused with normal RLM 198 (green, self fertile). Four dark green, completely male-sterile plants were obtained and identified as putative cybrids. All the plants were backcrossed three times with RLM 198. Mitochondrial and chloroplast DNA analysis of backcross progeny confirmed hybridity of the cytoplasm. The restriction pattern of the chloroplast DNA of progeny plants of three cybrids (Og 1, Og 2, Og 3) was similar to that of the green self-fertile RLM 198 and indicated that the correction of chlorosis resulted from chloroplast substitution. The chloroplast DNA of the lone progeny plant of the fourth cybrid (Og 10) could not be analyzed because the plant was stunted and had only a few leaves. When total cellular DNA was probed with mitochondrial probes coxI and atpA it was found that the cybrids had recombinant mitochondria. The chlorosis-corrected plants were early flowering and had vastly improved seed fertility.