Production of hybrids, amphiploids and backcross progenies between a cold-tolerant wild species, Erucastrum abyssinicum and crop brassicas

Three intergeneric hybrids were produced between a cold-tolerant wild species, Erucastrum abyssinicum and three cultivated species of Brassica, B. juncea, B. carinata and B. oleracea, through ovary culture. The hybrids were characterized by morphology, cytology and DNA analysis. Amphiploidy was induced in all the F₁ hybrids through colchicine treatment. Stable amphiploids and backcross progenies were obtained from two of the crosses, E. abyssinicum x B. juncea and E. abyssinicum x B. carinata. The amphiploid, E. abyssinicum x B. juncea was successfully used as a bridge species to produce hybrids with B. napus, B. campestris and B. nigra. These hybrids and backcross progenies provide useful genetic variability for the improvement of crop brassicas.     

Intergeneric hybridization between Diplotaxis siettiana and crop brassicas for the production of alloplasmic lines

Summary Intergeneric hybrids were produced between Diplotaxis siettiana and Brassica campestris through embryo rescue. The hybrids were completely pollen sterile and backcrosses with pollen of B. campestris did not yield any seeds. Induction of colchiploidy restored pollen fertility and backcross pollinations yielded viable seeds. Cytological details of the hybrid, amphidiploid and backcross progenies were studied. Both pollen-sterile and pollen-fertile plants have been obtained in backcross 2 progeny. This hybrid (D. siettiana x B. campestris) was used as a bridge cross to transfer the cytoplasm of D. Siettiana to two other incompatible cultivars of Brassica — B. juncea and B. napus. Pollinations of the amphidiploid (D. siettiana x B. campestris, 2n = 36) with pollen of B. juncea/B. napus readily produced seeds without embryo rescue. These hybrids were grown to flowering and their cytological details were studied. Seeds have been produced from backcross pollinations of both these hybrids with the pollen of the respective cultivars. The results clearly show the feasibility of producing alloplasmic lines in all the three oilseed brassicas.     

Intergeneric hybridization between Diplotaxis siifolia,a wild species and crop brassicas

Summary Attempts were made to obtain intergeneric hybrids between Diplotaxis siifolia, a wild species, and cultivars of Brassica (B. campestris, B. juncea, and B. napus). The crosses showed unilateral incompatibility. When the wild species was used as female parent, pollen germination and pollen tube growth were normal, but hybrid seeds aborted due to post-fertilization barriers. Reciprocal crosses (cultivars as female parent) showed strong pre-fertilization barriers; although pollen grains showed germination, pollen tubes failed to enter the stigma. Hybrids were realized in two of the crosses, D. siifolia x B. juncea and D. siifolia x B. napus, through ovary culture. The hybrids were multiplied in vitro by multiplication of axillary shoots, or somatic embryogenesis. Detailed studies were carried out on the hybrid D. siifolia x B. juncea. F₁ hybrids had shrivelled anthers and were pollen sterile. Amphiploids of this hybrid showed 60% pollen fertility and produced seeds upon self-pollination as well as backcross pollination with the pollen of B. juncea.     

Transfer of Brassica tournefartii (TT) genes to allotetraploid oilseed Brassica species (B. juncea AABB, B. napus AACC, B. carinata BBCC): homoeologous pairing is more pronounced in the three-genome hybrids (TACC, TBAA, TCAA, TCBB) as compared to allodiploids (TA, TB, TC)

For the transfer of genes from B. tournefortii (TT) to the allotetraploid oilseed brassicas, B. juncea AABB, B. carinata BBCC and B. napus AACC, B. tournefortii was first crossed with the three basic diploid species, B. campestris (AA), B. nigra (BE) and B. oleracea (CC), to produce the allodiploids TA, TB and TC. These were tetraploidized by colchicine treatment to produce the allotetraploids TTAA, TTBB and TTCC, which were further crossed with B. juncea and B. napus to produce three-genome hybrids with substitution-type genomic configurations: TACC, TBAA and TCAA. These hybrids along with another hybrid TCBB produced earlier, the three allodiploids, their allotetraploids and the four diploid parent species were studied for their male meiotic behaviour. The diploid parent and the allotetraploids (TTAA, TTBB and TTCC) showed regular meiosis although the pollen viability was generally low in the allotetraploids. In the allodiploids (TA, TB and TC) only some end-to-end associations were observed without any clearly discernible chiasmata or exchange points. Chromosomes involved in end-to-end associations were randomly distributed at the metaphase/anaphase-I stages. In contrast, the three-genome hybrids (TACC, TBAA, TCAA and TCBB) showed normal bivalents whose number exceeded the expected bivalent values. Bivalents arising out of homoeologous pairing were indistinguishable from normal pairs by their disjunction pattern but could be distinguished on the basis of the heteromorphy of the homoeologous chromosomes. The three-genome hybrids could be backcrossed to allotetraploid oilseed brassicas as they had some fertility. In contrast, the allodiploids could neither be selfed nor back-crossed. On the basis of their meiotic stability, in terms of more pronounced homoeologous pairing and fertility for backcrossing, the three-genome configurations provide the best possible situation for the introgression of alien genes from the secondary gene pool to the allotetraploid oilseed crops B. juncea, B. napus and B. carinata.     

Production of wide hybrids and backcross progenies between Diplotaxis erucoides and crop brassicas

Intergeneric hybrids were produced between D. erucoides (), a wild species, and four cultivated species of Brassica, B. campestris, B. juncea, B. napus and B. oleracea, through embryo rescue. The hybrid nature of these plants was confirmed through morphological and cytological studies. Backcross pollinations with the pollen of the respective cultivars yielded BC progenies in the hybrids D. erucoides x B. juncea and D. erucoides x B. napus but not in D. erucoides x B. campestris and D. erucoides x B. oleracea. The hybrid D. erucoides x B. campestris was also used as a bridge species and crossed with B. juncea to raise the hybrid and backcross progenies. F₂ progenies were more amenable than f₁ hybrids for raising backcross progenies. Although D. erucoides is considered to be a close relative of B. campestris and B. oleracea, incompatibility barriers of this species with different cultivars do not reflect this relationship.     

Diploid Brassica napus somatic hybrids: characterization of nuclear and organellar DNA

Summary Five somatic hybrids between Brassica campestris and B. oleracea were obtained. Molecular, morphological and cytological information all suggest that the resynthesized B. napus plants were hybrids. All five plants were diploid (2n=38) and had mainly bivalents at meiosis. Seedset was low after selfing but normal after crossing with B. napus. Molecular proof of the hybrid nature of these plants was obtained by hybridization of a rDNA repeat to total DNA. Analysis of chloroplast DNA restriction patterns revealed that all hybrids had chloroplasts identical to the B. oleracea parent. The analysis of mitochondrial DNA indicated that three hybrids had restriction patterns identical to those of B. campestris, and the other two had restriction patterns similar to those of B. oleracea. The 11.3 kb plasmid present in mitochondria of the B. campestris parent was also found in mitochondria of all five hybrids. This suggests that the plasmid from a B. campestris type of mitochondria was transferred into mitochondria of a B. oleracea type.     

Fertility and chromosome stability in Brassica napus resynthesised by protoplast fusion

Summary Fertile somatic hybrids between Brassica campestris and B. oleracea have been produced by protoplast fusion. Fusion products were identified by their intermediate protoplast morphology. Heterokaryons were isolated either with micropipettes using a micromanipulator or by flow sorting. About 2% of the obtained calli differentiated to shoots. Of the shoots obtained from manually selected heterokaryons, 100% were true hybrids as confirmed by isozyme analysis while 87% of the flow sorted ones showed a hybrid pattern. Ploidy level of the hybrid plants was determined by chromosome counting and relative DNA-content analysis. The sum of the chromosome number (38) from the two fusion partners were found in 30% of the hybrids; 9% had fewer and 61% had more chromosomes. Pollen viability and seed set varied with ploidy level. Compared to natural B. napus, a pollen viability of 52%–93% and a fertility of 1%–40% was found for the somatic hybrids with normal chromosome number. Restriction enzyme analysis of chloroplast-DNA showed that either B. campestris or B. oleracea chloroplasts were present in the somatic hybrid plants. Of 11 hybrid plants 5 had the campestris and 6 had the oleracea type (11 ratio).     

Analysis of chloroplast and mitochondrial segregation in three different combinations of somatic hybrids produced within Brassicaceae

Summary Mitochondrial and chloroplast DNA were characterized in three different combinations of somatic hybrids produced between different species within Brassicaceae. The fusions were made between B. campestris and B. oleracea, B. napus and B. nigra and between B. napus and Eruca sativa. The combinations represent interspecific hybridizations, but the phylogenetic distance between the species used in each instance is different. Whereas the B. campestris (+) B. oleracea and the B. napus (+)B. nigra hybrids are both examples of intrageneric hybrids, B. campestris is more closely related to B. oleracea than B. napus is to B. nigra. The fusion of B. napus and E. sativa represents an intergeneric hybridization. Since hybrids were produced with reproducible and uniform fusion and culture methods, a comparison of chloroplast and mitochondrial segregation and mitochondrial DNA (mt-DNA) rearrangements could be made between the combinations. The segregation of both chloroplasts and mitochondria was biased in the B. napus (+)B. nigra and the B. napus (+)E. sativa combination. The nonrandom segregation of chloroplasts and mitochondria could be due to the different ploidy levels of the fusion partners and/or reflect differences in organelle replication rate. Furthermore, segregation of mitochondria was correlated to the differences in phylogenetic distance between the species used in the fusions. However, mitochondrial segregation, in contrast to chloroplast segregation, could in all combinations also have been affected by the cell type used as protoplast source in the fusions. All different chloroplast types could be established within each combination. Hybrids containing chloroplast from one parent together with mitochondria from the other parent were found in two of the combinations, although the majority of the hybrids had mt-DNA that was altered compared to the parental species. The rearranged mt-DNA found in most hybrids was an effect of the heteroplasmic state following protoplast fusion rather than of the tissue culture methods, since no mt-DNA rearrangements were found in B. napus plants regenerated from protoplast culture. The mtDNA restriction patterns of the hybrids with rearranged mt-DNA indicated that specific regions of the mt-DNA were involved in the rearrangements following protoplast fusion.     

Introgression in Brassica napus for adaptation to the growing conditions in Bangladesh

Summary Among the oleiferous Brassicas, B. napus has the highest seed and oil productivity. As it is a species adapted to the temperate regions, its spring type is either unable to flower or flowers too late in the short — day winter (rabi) season of the subtropics. B. napus (genome AACC) is an amphidiploid between B. campestris (AA) and B. oleracea (CC), and shares one genome with the other allotetraploids B. juncea (AABB) and B. carinata (BBCC). While B. napus lacks ecotypes adapted to the subtropics, the other four species are well represented in this climatic zone. Reciprocal crosses with or without one direct backcross to B. napus have been carried out with the intention of transfering short-day adaptability. The aim was to introgress the A genome of carefully selected early representatives of B. campestris and B. juncea with the corresponding genome in B. napus, and similary the C genome from B. oleracea and B. carinata with the analogous genome in B. napus. B. campestris, B. juncea and the clearly later species, B. oleracea var alboglabra and B. carinata, seem to be almost equally effective in introgressing the appropriate earliness necessary for growth in Bangladesh. One backcross sligthly delayed segregation of early types. Convergent crosses did not result in the transgression of earliness, which was unexpected since the inheritance of flowering and maturity indicated a polygenic regulation. This result is partly explained by assuming dominant oligogenic control of the photoperiodic response. Introgression of earliness with the C genome doesn't seem to be necessarily related with the earliness of the donor species. Intergenomic interactions may be important. Interesting new lines were selected with high yield. Thus there is a good probability that Bangladesh will have a new oil crop. As these lines were observed to be early in Sweden as well, they could potentially push rapseed cultivation further north in temperate regions where the growing period is limited by short summers.This article forms part of the author's Ph.D. thesis     

Analysis of self-incompatibility interactions in 30 resynthesized Brassica napus lines. I. Fluorescence microscopic studies

Thirty Brassica napus lines have been developed through interspecific hybridization of B. oleracea and B. campestris lines with defined S-allele constitutions. These lines, which represent 29 different S-allele combinations, were tested in a diallel of test-pollinations to determine the activity of the introgressed S-alleles and intergenomic dominance relationships. Some consistent trends were observed: B. oleracea S-alleles high in the dominance series (e.g. S₈, S₁₄, S₂₉) were always active in the resynthesized B. napus lines, whereas recessive S-alleles (S₂, S₁₅) lost their activity in some test combinations. The B. campestris S-alleles were active in most cases, although 2 alleles were partially inactivated by the recessive B. oleracea allele S₁₅.     

Inheritance of rapeseed (Brassica napus)-specific RAPD markers and a transgene in the cross B. juncea x (B. juncea x B. napus)

We have examined the inheritance of 20 rapeseed (Brassica napus)-specific RAPD (randomly amplified polymorphic DNA) markers from transgenic, herbicide-tolerant rapeseed in 54 plants of the BC₁ generation from the cross B. junceax(B. junceaxB. napus). Hybridization between B. juncea and B. napus, with B. juncea as the female parent, was successful both in controlled crosses and spontaneously in the field. The controlled backcrossing of selected hybrids to B. juncea, again with B. juncea as the female parent, also resulted in many seeds. The BC₁ plants contained from 0 to 20 of the rapeseed RAPD markers, and the frequency of inheritance of individual RAPD markers ranged from 19% to 93%. The transgene was found in 52% of the plants analyzed. Five synteny groups of RAPD markers were identified. In the hybrids pollen fertility was 0–28%. The hybrids with the highest pollen fertility were selected as male parents for backcrossing, and pollen fertility in the BC₁ plants was improved (24–90%) compared to that of the hybrids.     

Analysis of self-incompatibility interactions in 30 resynthesized Brassica napus lines. II. Expression of S-locus glycoproteins (SLGs)

Thirty resynthesized Brassica napus lines with defined S-allele constitution and the ancestral B. oleracea and B. campestris lines were used for the analysis of S- locus glycoproteins (SLGs). The aim of this study was to investigate (1) whether the S-specific glycoproteins of the diploid ancestor lines were also expressed in the amphidiploid hybrids and (2) whether the occurrence of SLG bands was correlated with the activity of the respective S-alleles, which had been tested by means of diallele pollination tests in a previous study. Stigma proteins were separated by isoelectric focusing (IEF)-gel electrophoresis, and glycoprotein bands were identified by Western blotting and Con-A/peroxidase reaction. The SLG bands of the B. campestris parent could be detected in all 30 resynthesized B. napus lines. In contrast, B. oleracea SLG bands could only be detected in 12 resynthesized B. napus lines. Only B. napus lines which carried the dominant B. oleracea S-alleles S₈ and S₂₉ showed respective SLG bands in all cases. Nine B. napus lines showed only glycoprotein bands of the B. campestris parent, although the biological functioning of the B. oleracea S-alleles was demonstrated by test-pollinations. New SLG bands different from those of the B. oleracea and B. campestris parents occurred in 16 B. napus lines. The expression level of the SLGs in B. napus was not correlated with the self-incompatibility phenotype, not only in the case of recessive S-alleles (S₂, S₁₅), but also for dominant alleles (e.g. S₁₄, S₃₂, S₄₅). Received: 22 January 1999 / Accepted: 30 January 1999     

Effects of parental ploidy level and genetic divergence on chromosome elimination and chloroplast segregation in somatic hybrids within Brassicaceae

Summary Chromosome and organelle segregation after the somatic hybridization of related species with different degrees of genetic divergence were studied by comparing the interspecific somatic hybrids Brassica oleracea (CC) (+) B. campestris (AA), B. napus (AACC) (+) B. oleracea (CC) B. napus (AACC) (+) B. nigra (BB) and B. napus (AACC) (+) B. juncea (AABB) with the intergeneric somatic hybrids B. napus (AACC) (+) Raphanus sativus (RR) and B. napus (AACC) (+) Eruca sativa (EE). Within each combination, some hybrids were found whose DNA content was equal to the sum of parental chromosomes, others had a relatively higher DNA content and in most of the cases, some had a relatively lower content. However, the frequency distribution in these three classes differed significantly between the combinations. A positive correlation between the frequency of hybrids with eliminated chromosomes and the genetic distance between the species in each combination was found. Furthermore, by combining species with different ploidy levels we found a significantly higher degree of chromosome elimination compared to combinations of species with the same ploidy level. In the B. napus (+) B. Nigra, B. napus (+) R. sativus and B. napus (+) E. sativa combinations chromosomes from the B, R and E genomes appeared to be preferentially sorted out, as indicated by the fact that some of the nuclear markers from these genomes were missing in 7–46% of the plants, whereas no plants were lacking B. napus nuclear markers. Fertile hybrids were found in all but the B. napus (+) R. sativus fusion combination; the latter hybrids were male sterile, but female fertile. Hybrids between the A and C genomes were more fertile than hybrids obtained between the distantly related AC and B, R or E genomes, respectively. Analysis of the chloroplast RFLP pattern revealed that chloroplasts in the B. oleracea (+) B. campestris hybrids segregated randomly. A slightly biased segregation, favouring B. napus chloroplasts, was found in the B. napus (+) B. oleracea combination, whereas B. napus chloroplasts were strongly selected for in the B. napus (+) B. juncea, B. napus (+) B. nigra, B. napus (+) R. sativus and B. napus (+) E. sativa somatic hybrids.     

A high frequency of intergenomic mitochondrial recombination and an overall biased segregation of B. campestris or recombined B. campestris mitochondria were found in somatic hybrids made within Brassicaceae

Mitochondrial segregation and rearrangements were studied in regenerated somatic hybrids from seven different species combinations produced using reproducible and uniform methods. The interspecific hybridizations were made between closely or more distantly related species within the Brassicaceae and were exemplified by three intrageneric, two intergeneric and two intertribal species combinations. The intrageneric combinations were represented by Brassica campestris (+) B. oleracea, B. napus (+) B. nigra and B. napus (+) B. juncea (tournefortii) hybrids, the intergeneric combinations by B. napus (+) Raphanus sativus and B. napus (+) Eruca sativa hybrids, and the intertribal combinations by B. napus (+) Thlaspi perfoliatum and B. napus (+) Arabidopsis thaliana hybrids. In each species combination, one of the two mitochondrial genotypes was B. campestris since the B. napus cultivar used in the fusions contained this cytoplasm. Mitochondrial DNA (mtDNA) analyses were performed using DNA hybridization with nine different mitochondrial genes as probes. Among the various species combinations, 43–95% of the hybrids demonstrated mtDNA rearrangements. All examined B. campestris mtDNA regions could undergo intergenomic recombination since hybrid-specific fragments were found for all of the mtDNA probes analysed. Furthermore, hybrids with identical hybrid-specific fragments were found for all probes except cox II and rrn18/rrn5, supporting the suggestion that intergenomic recombination can involve specific sequences. A strong bias of hybrids having new atp A-or atp9-associated fragments observed in the intra- and intergeneric combinations could imply that these regions contain sequences that have a high reiteration number, which gives them a higher probability of recombining. A biased segregation of B. campestris-or B. campestris-like mitochondria was found in all combinations. A different degree of phylogenetic relatedness between the fusion partners did not have a significant influence on mitochondrial segregation in the hybrids in this study.     

The morphology, cytology, and C-banded karyotypes of Brassica campestris, B. oleracea, and B. napus plants regenerated from protoplasts

The behaviour of Brassica campestris (2n=20, AA), B. oleracea (2n=18, CC), and B. napus (2n=38, AACC) were studied during a tissue-culturing process. Hypocotyl-protoplasts were cultivated into calli from which new plants were regenerated. The regenerated plants were compared, and mitotic root-tip cells were C-banded and karyotyped. A majority of the plants were tetraploid. The meioses were studied in the PMCs. A number of abberations were observed, mainly due to faulty spindle function. There was a difference between the three species in that B. campestris performed the most poorly with many fewer regenerated plants. These plants were more morphologically disturbed and had more problems during pollen production than B. oleracea and B. napus plants.     

Accessing and exploiting genes of breeding value of distant relatives of crop Brassicas

The Brassicas are an important group of crops in India yielding edible oils and many vegetables. For improving cultivated Brassicas, the wild relatives are of considerable value. The Brassica group of seed oil and vegetables comprises six cultivated species, out of which three are diploids and three are digenomic tetraploids. Brassica juncea is the major seed oil crop in India which can be improved for several traits by incorporating genes from its distant relatives. The early work in India relating to genome manipulation consisted of synthesis of B. juncea by crossing B. campestris with B. nigra, experimental resynthesis of Brassica species and non-homologous pairing and genetic exchange at the interspecific level. The alloploid species B. napus and B. carinata have not been successful in India due to agrometereological limitations. However, synthetic forms of B. napus have been produced which have a desirable maturity period with good yield potential. Also, through non-homologous pairing, pod shatter resistant B. napus has been obtained, B. napus ordinarily suffers from pod shattering. Similarly, synthetic forms of B. carinata have been derived from reciprocal crosses between morphotypes of B. oleracea and B. nigra and also through protoplast fusion of B. nigra with B. oleracea. Molecular analysis has revealed that one of the somatic hybrids had a novel cytoplasmic combination which carried B. nigra mitochondrial and B. oleracea chloroplast genomes. A range of wild and weedy species related to crop Brassicas possess extensive genetic variability. Work for utilizing this variability included hybridization between wild and crop species, analysis of chromosome pairing and induction of alloploidy. Among Brassicas of interest to India, protoplast culture and regeneration has been successful in the case of B. oleracea, B. juncea, B. nigra and B. carinata (cultivated species) and Eruca sativa and Diplotaxis muralis (related wild species). Polyethylene glycol mediated protoplast fusion has been the most commonly used method in India for producing somatic hybrids involving Brassicas. The eight somatic hybrids produced and studied showed that in the majority of cases the fusions led to symmetric hybrids combining the complete genomes of the donor species. For developing suitable male sterile lines, B. juncea, B. campestris and B. napus nuclei have been combined with the cytoplasm of six wild species and stable male steriles have been developed. Protoplast fusion methodology has been used extensively for improving these CMS by manipulating cytoplasmic organelles, including production of new combinations of cp and mt.     

Transfer of resistance to Xanthomonas campestris pv campestris into Brassica oleracea L. by protoplast fusion

Black rot caused by the bacterium Xanthomonas campestris pv campestris is one of the most serious diseases of Brassica oleracea. Since sources of resistance to the disease within B. oleracea are insufficient and control means are limited, the development of resistant breeding lines is extremely desirable. Certain lines of B. napus contain very high resistance controlled by a dominant gene, but crossing the two species sexually is very difficult. Therefore, somatic hybrids were produced by protoplast fusion between rapid cycling B. oleracea and a B. napus line highly resistant to X. campestris pv campestris. Hybrid identity was confirmed by morphological studies, flow cytometric estimation of nuclear DNA content, and analysis of random amplified polymorphic DNA (RAPD). Inoculations with the pathogen identified four somatic hybrids with high resistance. The resistant hybrid plants were fertile and set seed when selfed or crossed reciprocally to the bridge line 15 (Quazi 1988). Direct crosses to B. oleracea were unsuccessful, but embryo rescue facilitated the production of a first-backcross generation. The BC₁ plants were resistant to the pathogen. Progeny from the crosses to line 15 were all susceptible. Embryo rescue techniques were not obligatory for the development of a second-backcross generation, and several resistant BC₂ plants were obtained.     

Intergeneric hybridization between Brassica napus and Sinapis pubescens,and the cytology and crossability of their progenies

The cytological possibility of gene transfer from Sinapis pubescens to Brassica napus was investigated. Intergeneric hybrids between Brassica napus (2n = 38) and Sinapis pubescens (2n = 18) were produced through ovary culture. The F₁ hybrids were dihaploid and the chromosome configurations were (0–1) _III + (2–11) _II + (5–24) _I . One F₂ plant with 38 chromosomes was obtained from open pollination of the F₁ hybrid. Thirty-one seeds were obtained from the backcross of the F₂ plant with B. napus. Five out of seven plants had 38 chromosomes, and the pollen stainability ranged from 0% to 81.4%. In the B₂ plants obtained from the backcross of B₁ plants with B. napus, 66.7% of the plants examined had 38 chromosomes. S. pubescens may become a gene source for the improvement of B. napus.     

Analysis of organelle genomes in a somatic hybrid derived from cytoplasmic male-sterile Brassica oleracea and atrazine-resistant B. campestris

Summary An atrazine-resistant, male-fertile Brassica napus plant was synthesized by fusion of protoplasts from the diploid species B. oleracea and B. campestris. Leaf protoplasts from B. oleracea var. italica carrying the Ogura male-sterile cytoplasm derived from Raphanus sativus were fused with etiolated hypocotyl protoplasts of atrazine-resistant B. campestris. The selection procedure was based on the inability of B. campestris protoplasts to regenerate in the media used, and the reduction of light-induced growth of B. oleracea tissue by atrazine. A somatic hybrid plant that differed in morphology from both B. oleracea and B. campestris was regenerated on medium containing 50 M atrazine. Its chromosome number was 36–38, approximately that of B. napus. Furthermore, nuclear ribosomal DNA from this hybrid was a mixture of both parental rDNAs. Southern blot analyses of chloroplast DNA and an assay involving tetrazolium blue indicated that the hybrid contained atrazine-resistant B. campestris chloroplasts. The hybrid's mitochondrial genome was recombinant, containing fragments unique to each parent, as well as novel fragments carrying putative crossover points. Although the plant was female-sterile, it was successfully used to pollinate B. napus.     

RFLP analyses of severalBrassica representatives

Molecular variability was determined between, 17Brassica napus cultivars, 8 new selections 4 F₁ hybrids, 5 cultivars ofB. oleracea, B. campestris andB. peruvianum with 4 rDNA probes fromLycopersicon esculentum, 3 probes from a PstI library ofB. oleracea, 3 probes from EcoRI libraries ofB. napus andB. oleracea and the acetolactatsynthase gene fromNicotiana tabacum. Sporadic interspecific and rare intraspecific variability was detected. Contribution presented to the 5^th Czechoslovak Seminar “Plant Gene Engineering”, organized by the Institute of Plant Molecular Biology in České Budějovice, 2–13 September 1991.