Diplotaxis catholica + Brassica juncea somatic hybrids: molecular and cytogenetic characterization

Summary Intergeneric somatic hybrids Diplotaxis catholica (2n=18) + Brassica juncea (2n=36) were produced by fusing mesophyll protoplasts of the former and hypocotyl protoplasts of the latter using polyethylene glycol. Out of 52 somatic embryos, 24 produced plants of intermediate morphology. Cytological analysis of 16 plants indicated that 15 were symmetric hybrids carrying 54 chromosomes, the sum of the parental chromosome numbers. One hybrid was asymmetric with 45 chromosomes. Nuclear hybridity of five putative hybrids was confirmed by the Southern hybridization pattern of full length 18s-25s wheat nuclear rDNA probe which revealed the presence of Hind III fragments characteristic of both the parental species. The hybridization pattern of mitochondria specific gene probe cox I indicated that three of the hybrids carried B. juncea mitochondria and one carried mitochondria of D. catholica. Presence of novel 3.5 kb Hind III and 4.8 kb Bgl II fragments suggested the occurrence of mtDNA recombination in one of the hybrids. The hybrids were pollen sterile. However, seeds were obtained from most of the hybrids by back crossing with B. juncea.     

Somatic cell hybridization of ’oxy’ CMS Brassica juncea (AABB) with B. oleracea (CC) for correction of chlorosis and transfer of novel organelle combinations to allotetraploid brassicas

Alloplasmic lines of cultivated Brassica species with B. oxyrrhina cytoplasm are male-sterile and suffer from severe chlorosis. We developed male-sterile lines corrected for chlorosis by fusing protoplasts of CMS B. juncea (AABB) with ’oxy’ cytoplasm and normal B. oleracea (CC). A large number of male-sterile AABBCC somatic hybrids with desirable organelle combinations, i.e. chloroplasts of B. oleracea and mitochondria with recombinant genomes, were recovered. While no recombination was observed in the chloroplast genome, the mitochondrial genome showed extensive recombination that resulted in the appearance of totally novel banding patterns in some of the hybrids. Hybrids with a parental-type mitochondrial genome as well as recombinant patterns close to either of the parental types were also obtained. Using AABBCC somatic hybrids as bridging material, we transferred the desirable organelle combinations to B. juncea (AABB), B. napus (AACC), and B. carinata (BBCC). Many of these lines are now at advanced stages of backcrossing and show stable inheritance of the CMS character and do not suffer from chlorosis. Received: 9 August 1999 / Accepted: 14 September 1999     

Somatic hybrids with substitution type genomic configuration TCBB for the transfer of nuclear and organelle genes from Brassica tournefortii TT to allotetraploid oilseed crop B. carinata BBCC

Oilseed crop Brassica carinata BBCC is a natural allotetraploid of diploid species B. nigra BB and B. oleracea CC. To transfer the nuclear and organelle genes in a concerted manner from an alien species, B. tournefortii TT, to B. carinata, we produced somatic hybrids with genomic configuration TCBB using B. nigra and B. oleracea stocks that carried selectable marker genes. B. tournefortii TT was sexually crossed with hygromycin-resistant B. oleracea CC. Protoplasts isolated from shoot cultures of hygromycin-resistant F₁ hybrids of B. tournefortiixB. oleracea TC were fused with protoplasts of kanamycin-resistant B. nigra BB. In two different fusion experiments 80 colonies were obtained through selection on media containing both hygromycin and kanamycin. Of these, 39 colonies regenerated into plants. Analysis of 15 regenerants by random amplified polymorphic DNA (RAPD) markers showed the presence of all three genomes, thereby confirming these to be true hybrids. Restriction fragment length polymorphism (RFLP) analysis of organelle genomes with heterologous chloroplast (cp)and mitochondrial (mt) DNA probes showed that the chloroplast genome was inherited from either of the two parents while mitochondrial genomes predominantly showed novel configurations due to either rearrangements or intergenomic recombinations. We anticipate that the TCBB genomic configuration will provide a more conducive situation for recombination between the T and C genomes during meiosis than the TTCCBB or TCCBB type configurations that are usually produced for alien gene transfer. The agronomic aim of producing TCBB hybrids is to transfer mitochondrial genes conferring cytoplasmic male sterility and nuclear genes for fertility restoration from B. tournefortii to B. carinata.     

Organelle analysis of symmetric and asymmetric hybrids between Lycopersicon peruvianum and Lycopersicon esculentum

Summary The organelles of somatic hybrids obtained from symmetric and asymmetric fusions between the Lycopersicon species L. peruvianum and L. esculentum were analyzed by DNA hybridization methods. In the asymmetric fusions the L. peruvianum protoplasts were gamma-irradiated at a dose of 50, 300 and 1,000 Gy. The organelles were characterized using the Petunia chloroplast probe pPCY64 and the mitochondrial EcoRI-SalI fragment of the Pcf gene. In all symmetric and asymmetric hybrid plants, a total of 73 being analyzed, only one of the parental chloroplast genomes was present, except for one hybrid plant which harbored both parental chloroplast genomes. No recombination and/or rearrangement in the chloroplast genome could be identified with the pPCY64 probe. Irradiation of the L. peruvianum protoplasts did not significantly reduce the fraction of asymmetric hybrids with L. peruvianum chloroplasts. A novel mitochondrial restriction pattern was present in 5 out of 24 hybrids tested. In 9 hybrids novel combinations of chloroplasts and mitochondria were found, indicating that both organelle types sorted out independently.     

Interspecific hybridization between Brassica juncea and B. spinescens through protoplast fusion

Hypocotyl derived protoplasts of B. juncea cv. RLM-198 were fused with mesophyll protoplasts of B. spinescens using polyethylene glycol to produce interspecific hybrids. Fusion products could be microscopically identified by characteristics of the protoplasts of both parents in the hybrid cells; they are colourless and vacuolated like the hypocotyl protoplasts and possess chloroplasts of the mesophyll protoplasts. The heterokaryotic fusion frequency was around 5%. However, the frequency of calli regenerating hybrid shoots was more than 10% of the regenerating calli. Putative somatic hybrids had morphological features characteristic of both the parents. Twelve plants analysed cytologically, possessed 52 chromosomes (26_II) at meiosis representing the complete genomes of B. juncea (18_II) and B. spinescens (8_II). For esterase isozymes, the hybrids had bands of Doth the parents. Hybrid nature of some of the plants was confirmed by their close resemblance to B. juncea, chromosome number and isozyme bands of B. spinescens as in Rsp-19. Somatic hybrids had rudimentary, non-dehiscent anthers and completely sterile pollen. However, on back crossing with B. juncea, 10 out of 12 plants produced seeds and about 100 plants were realized.Abbreviations PEG Polyethylene glycol     

Differential transmission of the Cucumis organellar genomes

 Although plants generally show maternal transmission of the organellar genomes, previous research has demonstrated that the mitochondrial (mt) genome of cucumber is paternally transmitted. In this study, we identified RFLPs in the organellar genomes of melon, squash, and watermelon to establish organellar DNA transmission. Serial dilutions of DNA demonstrated that our hybridizations revealed the presence of a polymorphic cytoplasm when it represented at least 1% of the DNA sample. At this level of sensitivity, the chloroplast genomes of melon, squash, and watermelon were maternally transmitted. The mitochondrial genomes of squash and watermelon were maternally transmitted; however, melon, like cucumber, showed paternal transmission of the mitochondrial genome. Because most angiosperms and the related genera Cucurbita and Citrullus show maternal transmission of the mtDNA, paternal transmission in Cucumis is likely the derived state. The Cucumis mitochondrial genomes are several-fold larger than those of other cucurbits. Based on 55 probe-enzyme combinations, mtDNA size differences could not be explained by duplication of the entire genome or partial duplication of regions hybridizing with the mitochondrial probes. Because the chloroplast, mitochondrial, and nuclear genomes of Cucumis are differentially transmitted, this genus is an excellent system to study the role of intergenomic transfer in the evolution of extremely large mitochondrial genomes. Received: 20 November 1997 / Accepted: 30 December 1997     

Differential fate of plastid and mitochondrial genomes in Petunia somatic hybrids

Summary The chloroplast (cp) and mitochondrial (mt) DNAs of Petunia somatic hybrid plants, which were derived from the fusion of wild-type P. parodii protoplasts with albino P. inflata protoplasts, were analyzed by endonuclease restriction and Southern blot hybridization. Using ³²P-labelled probes that distinguished the two parental cpDNAs at a BamH1 site and at a HpaII site, only the P. parodii chloroplast genome was detected in the 10 somatic hybrid plants analyzed. To examine whether cytoplasmic mixing had resulted in rearrangement of the mitochondrial genome in the somatic hybrids, restriction patterns of purified somatic hybrid and parental mtDNAs were analyzed. Approximately 87% of those restriction fragments which distinguish the two parental genomes are P. inflata-specific. Restriction patterns of the somatic hybrid mtDNAs differ both from the parental patterns and from each other, suggesting that an interaction occurred between the parental mitochondrial genomes in the somatic fusion products which resulted in generation of the novel mtDNA patterns. Southern blot hybridization substantiates this conclusion. In addition, somatic hybrid lines derived from the same fusion product were observed to differ in mtDNA restriction pattern, reflecting a differential sorting-out of mitochondrial genomes at the time the plants were regenerated.     

Morphological and molecular characterization of fertile tetraploid somatic hybrids produced by protoplast electrofusion and PEG-induced fusion between Lycopersicon esculentum Mill. and Lycopersicon peruvianum Mill.

Summary Mesophyl protoplasts of two genotypes of cultivated tomato (Lycopersicon esculentum Mill.) and one of its wild relative species (Lycopersicon peruvianum Mill.) were fused by using electrofusion and polyethyleneglycol-induced fusion. Forty-three fertile tetraploid somatic hybrid plants, each deriving from separate calli, were recovered from both fusion procedures. Electrofusion appeared more efficient than chemical fusion for the production of somatic hybrids. These plants appeared morphologically similar, whatever the fusion procedure and tomato genotype. They had intermediate leaf, inflorescence, and flower morphology. After self-pollination, the hybrids set fruit of intermediate size and color. The hybrid nature of these plants was confirmed by isoelectric focusing of the Rubisco small subunits used as nuclear markers. L. esculentum and L. peruvianum were distinguished by means of two chloroplast markers: CF1-ATPase subunit as analyzed by isoelectro-focusing and ct DNA restriction patterns. All hybrids displayed both ct markers of only one parent with no biased transmission. Mitochondrial (mt) DNAs were prepared from flower buds by using miniaturized CsCl gradients. Preliminary analysis indicated that mt genomes from the hybrids all differed from those of both parents. mt DNA Sall restriction enzyme analysis revealed that all but two hybrids contained one novel fragment of 13.5 kb. Gene mapping experiments showed that the mt apocytochrome b and ATPase subunit 9 homologies in the somatic hybrid mt DNA resembled L. esculentum and L. peruvianum, respectively; the mt nad5 probe distinguished at least four distinct patterns in the hybrids. These results indicated that mt DNA rearrangements involving intergenomic recombinations occurred through protoplast fusion. A greater mt DNA polymorphism was induced with chemical fusion than with electrofusion.     

Genomic in situ hybridization in Brassica amphidiploids and interspecific hybrids

Genomic in situ hybridization (GISH) methods were used to detect different genome components within Brassica amphidiploid species and to identify donor chromatin in hybrids between Brassica napus and Raphanus sativus. In Brassica juncea and Brassica carinata the respective diploid donor genomes could be reliably distinguished by GISH, as could all R-genome chromosomes in the intergeneric hybrids. The A- and C-genome components in B. napus could not be clearly distinguished from one another using GISH, confirming the considerable homoeology between these genomes. GISH methods will be extremely beneficial for monitoring chromatin transfer and introgression in interspecific Brassica hybrids. Received: 20 May 1997 / Accepted: 28 July 1997     

Biparental inheritance of plastidial and mitochondrial DNA and hybrid variegation in <Emphasis Type="Italic">Pelargonium</Emphasis>

Plastidial (pt) and mitochondrial (mt) genes usually show maternal inheritance. Non-Mendelian, biparental inheritance of plastids was first described by Baur (Z Indukt Abstamm Vererbungslehre 1:330–351, 1909) for crosses between Pelargonium cultivars. We have analyzed the inheritance of pt and mtDNA by examining the progeny from reciprocal crosses of Pelargonium zonale and P. inquinans using nucleotide sequence polymorphisms of selected pt and mt genes. Sequence analysis of the progeny revealed biparental inheritance of both pt and mtDNA. Hybrid plants exhibited variegation: our data demonstrate that the inquinans chloroplasts, but not the zonale chloroplasts bleach out, presumably due to incompatibility of the former with the hybrid nuclear genome. Different distribution of maternal and paternal sequences could be observed in different sectors of the same leaf, in different leaves of the same plant, and in different plants indicating random segregation and sorting-out of maternal and paternal plastids and mitochondria in the hybrids. The substantial transmission of both maternal and paternal mitochondria to the progeny turns Pelargonium into a particular interesting subject for studies on the inheritance, segregation and recombination of mt genes.     

Mitochondrial DNA polymorphism induced by protoplast fusion in Cruciferae

Summary The mitochondrial genomes of five rapeseed somatic hybrid plants, which combine in a first experimentBrassica napus chloroplasts and a cytoplasmic male sterility trait coming fromRaphanus sativus, and in a second experiment chloroplasts of a triazine resistantB. compestris and a cytoplasmic male sterility trait fromR. sativus, were analyzed by restriction endonucleases. Restriction fragment patterns indicate that these genomes differ from each other and from both parents. The presence of new bands in the somatic hybrid mitochondrial DNA restriction patterns is evidence of mitochondrial recombination in somatic hybrid cells. In both parental and somatic hybrid plants large quantitative variations in a mitochondrial plasmid-like DNA have been observed. Our results suggest that the cytoplasmic support for male sterility is located in the chromosomal mitochondrial DNA instead of the plasmid-like DNA.     

Production and cytogenetics of the intergeneric hybrids Brassica juncea×Orychophragmus violaceus and B. carinata×O. violaceus

 Intergeneric hybrids between Brassica juncea (2n=36), B. carinata (2n=34) and Orychophragmus violaceus (2n=24) were produced when B. juncea and B. carinata cultivars were used as female parents. The hybrids between B. juncea and O. violaceus had an intermediate morphology except for petal colour and were partially fertile. The hybrids between B. carinata and O. violaceus had a matroclinous morphology and were nearly fertile. Cytological analysis of the hybrids and their progenies gave the following results. (1) In the hybrids between B. juncea and O. violaceus, the somatic tissues of the roots, leaves and styles were mixoploid (2n=12–42), and cells with 24, 30 or 36 chromosomes were the most frequent. Based on the recorded numbers and behaviour of the mitotic and meiotic chromosomes, complete and partial separation of the parental genomes was proposed to have occurred during mitosis. This resulted in the occurrence of cells with possibly complete and incomplete complements of the parental species and cells with parental complements and some additional chromosomes from the other parent. (2)  Pollen mother cells (PMCs) possibly with both parental chromosome complements, only B. juncea chromosomes or a complete B. juncea complement with additional O. violaceus chromosomes were more competitive in entering meiosis. The majority of fertile gametes were deduced to have been produced by PMCs with a B. juncea complement with or without additional O. violaceus chromosomes. (3) The progeny plants from selfed hybrids between B. juncea and O. violaceus were morphologically either of a B. juncea, hybrid or variable type. Cytologically they were grouped into six types according to the frequencies of cells with various chromosome numbers. All of the plants except 2 which constituted two types, were mixoploids, composed of cells with various chromosome numbers, mainly in a certain serial range. (4) The hybrid plants between B. carinata and O. violaceus were mixoploids with chromosome numbers in the range of 12–34, and cells with 2n=34 were the most frequent. The main categories of PMCs with 17 bivalents at metaphase I and 17 : 17 segregations at anaphase I contributed to the high fertility of the hybrids and the fact that their progeny after selfing were mainly plants with 2n=34. Somatic and meiotic separation of the parental genomes was proposed to have occurred in the hybrids between B. carinata and O. violaceus. (5) Mitotic and meiotic elimination of what could be O. violaceus chromosomes might also have contributed to the observed mitotic and meiotic cell types in the two kinds of hybrids studied. Finally, the possible mechanisms behind these cytological observations and their potential in the production of Brassica aneuploids were discussed. Received: 4 February 1997/Accepted: 29 July 1997     

Synthesis of Brassica oleracea/Brassica napus somatic hybrid plants with novel organeile DNA compositions

Summary Broccoli (Brassica oleracea L. italica) hypocotyl protoplasts were fused with mesophyll protoplasts of two B. napus lines, one carrying the Ogura (ogu) cms cytoplasm, and the other carrying a hybrid cytoplasm consisting of ogu mitochondria combined with triazine-tolerance-conferring chloroplasts from ctr cytoplasm. Two male-sterile somatic hybrids were recovered from the fusion of broccoli protoplasts with those of ogu/ctr cybrid B. napus. The ogu mtDNAs and ctr cpDNAs were not altered in these hybrids. Four male-sterile plants were recovered from the somatic hybridization of broccoli with ogu cms B. napus. Three of these possessed mitochondrial genomes that appeared to have resulted from recombination between the ogu and normal B. oleracea (ole) mtDNAs, while the fourth possessed an unrearranged ogu mtDNA. All four of these plants had B. oleracea cpDNA, and none displayed the seedling chlorosis associated with ogu chloroplasts. Most of the plants recovered from these fusions had the chromosome number expected of B. oleracea + B. napus hybrids (2n = 56). The novel cytoplasms may prove to be useful for the molecular analysis of Brassica cms and for the production of hybrid Brassica.     

Interspecific somatic hybridization between Brassica napus and Brassica hirta (Sinapis alba L.)

Summary Somatic hybridization between Brassica napus and B. hirta (or Sinapis alba) is described. No cybrid plant with B. napus nucleus exhibiting cytoplasmic male sterility was recovered. Somatic hybrids were identified morphologically and, for some of them, by cytological observations. They were also characterised by Southern hybridization of nuclear rDNA. Chloroplast and mitochondrial DNA restriction analysis showed that 2 plants out of 14 have B. hirta ctDNA, one the B. napus mtDNA and the other a hybrid. Nine possess B. napus ctDNA with a hybrid mtDNA. For six of them, mtDNA patterns present novel bands, suggesting intergenomic recombination during fusion. These hybrids will be included in the breeding program.     

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     

Somatic hybrids between Brassica juncea (L). Czern. and Diplotaxis harra (Forsk.) Boiss and the generation of backcross progenies

An attempt to transfer genes from droughttolerant Diplotaxis harra, a wild relative of Brassica species, to an elite oil-yielding cultivar, B-85, of mustard (Brassica juncea) was made through protoplast fusion, as the two plant systems are sexually incompatible. By following the standard protocol for PEG-mediated protoplast fusion followed by high pH, high Ca⁺⁺, DMSO treatment and appropriate cell-culture technique, 16 presumptive somatic hybrid plants could be regenerated. Chromosomal analysis of four such somatic hybrids revealed that three of them were asymmetric. Analysis of morphological characters, meiotic chromosomes, and esterase isoenzyme pattern revealed that all the somatic hybrids were different from each other. Furthermore four chromosomes of each genome could undergo homoeologous pairing at meiosis indicating the possibilities for genetic recombination and chromosomal rearrangements. Irregular distribution of chromosomes at anaphase-II at meiosis has been a consistent feature of these plants. Eventually, pollen of all the somatic hybrids showed complete infertility preventing the recovery of any selfed seed. Nevertheless, ovule fertility of one somatic hybrid was not totally impaired as it had set some seeds upon backcrossing with the B. juncea parent. The esterase isoenzyme banding pattern of 24 individual progeny plants of this backcross provided evidence for their recombinant nature. It was thus confirmed that a transfer of genetic traits from Diplotaxis harra to B. juncea had indeed taken place. Furthermore, it was conceptualised that a transfer of alien genes through the protoplast-fusion technique is primarily possible in situations where meiotic pairing of the chromosomes of the two participating genomes generates recombinant gametocytes which can pass through subsequent filial generations.     

Analysis of the plastome and chondriome origin in plants regenerated after asymmetric Solanum ssp. protoplast fusions

Protoplasts from potato cultivars used as recipient parents were fused with irradiated protoplasts from wild Solanum donor species. Regenerated plants were analysed by RAPDs to identify hybrids. Irradiation of donor protoplasts with ionizing irradiation induced a broad range of donor nuclear DNA elimination in the asymmetric hybrids. Usage of chloroplast (cp)- and mitochondrial (mt)-specific PCR markers made it possible to trace the different origins of the cp genome in seven fusion combinations, as well as the mt genomes in two fusion combinations. Regenerated plants with recipient nucleus and plastome markers from the donors were found in six of the seven analysed fusion combinations. Protoplast fusion has generated novel mt genome combinations consisting of different portions of the mt genomes from the fusion partners. Selection of heterofusion products based on fluorescence markers is an efficient method to obtain asymmetric Solanum hybrids and cy- brids from most fusion combinations. Possible models for cybrid formation are discussed. Received: 7 October 1999 / Accepted: 3 December 1999     

A novel intergeneric hybrid in the Triticeae: Triticum aestivum x Psathyrost achys juncea

Summary Two hybrid embryos of intergeneric origin between Triticum aestivum cv Fukuho (2n=6x=42, AABBDD) and Psathyrostachys juncea (2n=2x=14, NN) were successfully rescued. One hybrid plant had the expected chromosome number of 28 (ABDN), whereas the second plant had 35 chromosomes. The average meiotic chromosome pairing in the 35-chromosome hybrid was 21.87 univalents + 6.38 bivalents + 0.11 trivalents + 0.009 quadrivalents, which indicates that two copies of the N genome were present. Chromosome pairing in the 28-chromosome hybrid was low (1.35 bivalents), and pointed out the lack of homology between the wheat genomes and the P. juncea genome. These new hybrids showed some necrosis and chlorosis, which caused severe floral abortion in the plant that had 35 chromosomes. These problems became gradually less severe after 18 months.Contrib. no. 372     

Chloroplast substitution overcomes leaf chlorosis in a Moricandia arvensis-based cytoplasmic male sterile Brassica juncea

 A male sterile Brassica juncea line based on Moricandia arvensis cytoplasm was developed previously by backcrossing the somatic hybrid M. arvensis+B. juncea, and the gene for restoring fertility was introgressed. The CMS line is very severely chlorotic because of the presence of alien chloroplasts and flowering is delayed by 30–40 days, making it unsuitable for the exploitation of heterosis. We have resorted to another cycle of protoplast fusion between green fertile B. juncea and chlorotic male sterile B. juncea, and developed green male-sterile plants. Molecular analysis revealed that in green male-sterile plants chloroplasts of M. arvensis origin were substituted by those from B. juncea, giving rise to intergeneric cytoplasmic hybrids with mitochondria of M. arvensis origin. With the development of dark-green male-sterile plants, the CMS fertility restoration system is suitable for the production of hybrid mustard. Received: 23 February 1998 / Accepted: 12 May 1998     

Development of synthetic Brassica amphidiploids by reciprocal hybridization and comparison to natural amphidiploids

In a previous study we proposed that cytoplasmic genomes have played an important role in the evolution of Brassica amphidiploid species. Based on this and other studies, we hypothesized that interactions between the maternal cytoplasmic genomes and the paternal nuclear genome may cause alterations in genome structure and/or gene expression of a newly synthesized amphidiploid, which may play an important role in the evolution of natural amphidiploid species. To test this hypothesis, a series of synthetic amphidiploids, including all three analogs of the natural amphidiploids B. napus, B. juncea, and B. Carinata and their reciprocal forms, were developed. These synthetic amphidiploids were characterized for morphological traits, chromosome number, and RFLPs revealed by chloroplast, mitochondrial, and nuclear DNA clones. The maternal transmission of chloroplast and mitochondrial genomes was observed in all of the F₁ hybrids examined except one hybrid plant derived from the B. rapa x B. oleracea combination, which showed a biparental transmission of organelles. However, the paternal chloroplast and mitochondrial genomes were not observed in the F₂ progeny. Nuclear genomes of synthetic amphidiploids had combined RFLP patterns of their parental species for all of the nuclear DNA clones examined. A variation in fertility was observed among self-pollinated progenies of single amphidiploids that had completely homozygous genome constitutions. Comparisons between natural and synthetic amphidiploids based on restriction fragment length polymorphism (RFLP) patterns indicated that natural amphidiploids are considerably more distant from the progenitor diploid species than the synthetic amphidiploids. The utility of these synthetic amphidiploids for investigating the evolution of amphidiploidy is discussed.