Parental genome separation and elimination of cells and chromosomes revealed by AFLP and GISH analyses in a Brassica carinata x Orychophragmus violaceus cross

BACKGROUND AND AIMS: The phenomenon of parental genome separation during the mitotic divisions of hybrid cells was proposed to occur under genetic control in intergeneric hybrids between cultivated Brassica species and Orychophragmus violaceus (2n = 24). To elucidate further the cytological and molecular mechanisms behind parental genome separation, Brassica carinata (2n = 34) x O. violaceus hybrids were resynthesized and their chromosome/genomic complements analysed. METHODS: F(1) hybrids of the cross were obtained following embryo rescue, and were investigated for their cytological behaviour and subjected to genomic in situ hybridization (GISH) and amplified fragment length polymorphism (AFLP) to determine the contribution of parental genomes. KEY RESULTS: All the F(1) plants with high fertility closely resembled B. carinata in morphological attributes. These were mixoploids with 2n chromosome numbers ranging from 17 to 35; however, 34, the same number as in B. carinata, was the most frequent number of chromosomes in ovary and pollen mother cells (PMCs). GISH clearly identified 16 chromosomes of B. nigra in ovary cells and PMCs with 2n = 34 and 35. However, no O. violaceus chromosome was detected, indicating the presence of the intact B. carinata genome and elimination of the entire O. violaceus genome. However, some AFLP bands specific for O. violaceus and novel for the two parents were detected in the leaves. Cells with fewer than 34 chromosomes had lost some B. oleracea chromosomes. F(2) plants were predominantly like B. carinata, but some contained O. violaceus characters. CONCLUSIONS: The cytological mechanism for the results involves complete and partial genome separation at mitosis in embryos of F(1) plants followed by chromosome doubling, elimination of cells with O. violaceus chromosomes and some introgression of O. violaceus genetic information.     

Cytogenetic and molecular characterization of intergeneric hybrids between Brassica napus and Orychophragmus violaceus.

Twenty-two intergeneric hybrids from a cross between Brassica napus (AACC, 2n = 38) cultivar Oro and the ornamental crucifer Orychophragmus violaceus (OO, 2n = 24) were produced without embryo rescue. The plants were classified into three groups based on morphological and cytological observations and RAPD banding patterns. Plants of Group I had morphological traits of both parents and 2n = 29 chromosomes. In these plants, 62.1% of the pollen mother cells (PMCs) had the pairing configuration 1 III + 9 II + 8 I; the remaining PMCs had 10 II + 9 I. The plants possessed 97.6-98.8% B. napus specific and 9.2-11.7% O. violaceus specific RAPD fragments. Plants of Group II exhibited novel morphological traits and possessed 2n = 35, 36, or 37 chromosomes. Plants of Group III were morphologically similar to B. napus and possessed 2n = 19, 37, 38, or 39 chromosomes. Plants of Group II and Group III had 94.1-99.4% B. napus specific RAPD fragments and no O. violaceus specific RAPD fragments. Chromosome fragments were observed in PMCs of most of the F1 plants in all groups. Based on the cytological results and RAPD analysis, it is suggested that genome doubling and chromosome elimination occurred in the intergeneric hybrids of B. napus x O. violaceus.     

Alteration of chromosome behavior and synchronization of parental chromosomes after successive generations in Brassica napus x Orychophragmus violaceus hybrids.

In an earlier study, the progenies of intergeneric hybrids Brassica napus (2n = 38) x Orychophragmus violaceus (2n = 24) were investigated in successive generations (F1-F4) for the cytological phenomenon of parental genome separation during mitotic and meiotic division. In the present study, inbred lines (F5-F8) derived from 1 such hybrid were characterized for morphology, chromosome pairing behaviour, and genome composition. One F5 plant (2n = 31) with slightly yellow petals and 12:19 and 15:16 segregation ratios in its pollen mother cells (PMCs) produced F6 plants with distinct morphological characteristics and wide variations in fertility and chromosome numbers (2n = 25-38). F7 and F8 lines with distinctive morphology and wide ranges in chromsome numbers were established. In PMCs of F7 plants from 4 F6 plants, 0-12 labelled chromosomes from O. violaceus, which predominantly appeared as bivalents, were identified by genomic in situ hybridization. They behaved synchronously with B. napus chromosomes during meiotic division. The results provide molecular cytogenetic evidence of the inclusion of O. violaceus chromosomes in the original hybrids and the cytology in the hybrids documented earlier. They also show that chromosome behaviour was altered and the parental chromosomes became synchronized after successive generations.     

High efficiency production and genomic<Emphasis Type="Italic">in situ</Emphasis> hybridization analysis of<Emphasis Type="Italic">Brassica</Emphasis> aneuploids and homozygous plants

Interspecific and intergeneric hybridizations have been widely used in plant genetics and breeding to construct stocks for genetic analysis and to introduce into crops the desirable traits and genes from their relatives. The intergeneric crosses between Brassica juncea (L.) Czern. & Coss., B. carinata A. Braun and Orychophragmus violaceus (L.) O. E. Schulz were made and the plants produced were subjected to genomic in situ hybridization analysis. The mixoploids from the cross with B. juncea were divided into three groups. The partially fertile mixoploids in the first group (2n = 36-42) mainly contained the somatic cells and pollen mother cells (PMCs) with the 36 chromosomes of B. juncea and additional chromosomes of O. violaceus. The mixoploids (2n = 30-36) in the second and third groups were morphologically quite similar to the mother plants B. juncea and showed nearly normal fertility. The plants in the second group produced the majority of PMCs (2n = 36) with their chromosomes paired and segregated normally, but 1-4 pairs of the O. violaceus chromosomes were included in some PMCs. The plants in the third group produced only PMCs with the 36 B. juncea chromosomes, which were paired and segregated normally. The mixoploids (2n = 29-34) from the cross with B. carinata produced the majority of PMCs (2n = 34) with normal chromosome pairing and segregation, but some plants had some PMCs with 1-3 pairs of chromosomes from O. violaceus and other plants had only PMCs with the B. carinata chromosomes. The Brassica homozygous plants and aneuploids with complete or partial chromosome complements of Brassica parents and various numbers of O. violaceus chromosomes were derived from these progeny plants. The results in this study provided the molecular cytogenetic evidence for the separation of parental genomes which was previously proposed to occur in the hybridizations of these two genera.     

High efficiency production and genomic in situ hybridization analysis of Brassica aneuploids and homozygous plants

Inplantbreedingandgeneticresearch,karyotypicallystablecrosseswhichproducehybridplantshavebeenextensivelyusedtointroduceintocropsthetargettraitsandgenesfromrelatedwildorcultivatedspeciesortoconstructstocksforgeneticanalysis(alienchromosomeadditions,substitutionsandtranslocations)[1—3].Uniparentalgenomeeliminationinkaryotypicallyunstablehybridshasbeenutilizedforhaploidproduction[2,4].Becausetheartificiallysynthesizedallopoly-ploidscannotbeusedascropsformanyreasons,onepurposeofwidehybridizations…     

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     

Unique chromosome behavior and genetic control in Brassica×Orychophragmus wide hybrids: a review

Researchers recognized early that chromosome behavior, as other morphological characters, is under genetic control and gave some cytogenetical examples such as the homoeologous chromosome pairing in wheat. In the intergeneric sexual hybrids between cultivated Brassica species and another crucifer Orychophragmus violaceus, the phenomenon of parental genome separation was found under genetic control during mitosis and meiosis. The cytogenetics of these hybrids was species-specific for Brassica parents. The different chromosome behavior of hybrids with three Brassica diploids (B. rapa, B. nigra and B. oleracea) might contribute to the different cytology of hybrids with three tetraploids (B. napus, B. juncea and B. carinata). The finding that genome-specific retention or loss of chromosomes in hybrids of O. violaceus with B. carinata and synthetic Brassica hexaploids (2n=54, AABBCC) is likely related to nucleolar dominance gives new insight into the molecular mechanisms regarding the cytology in these hybrids. It is proposed that the preferential expressions of genes for centromeric proteins from one parent (such as the well presented centromeric histone H3) are related with chromosome stability in wide hybrids and nucleolar dominance is beneficial to the production of centromere-specific proteins of the rRNAs-donor parent and to the stability of its chromosomes.     

甘蓝型油菜与诸葛菜属间杂种无性系的变异研究

从形态及细胞学两方面对甘蓝型油菜与诸葛菜属间杂种无性系的变异进行了研究。经过长期继代培养后,杂种在形态上越来越偏向母本甘蓝型油菜,而表现出较少的父本诸葛菜性状,但表现出对等双分枝的新性状。经细胞学观察表明,杂种体内杂种细胞比例下降,而甘蓝型油菜细胞比例大幅度上升并远高于核质杂种细胞（具有油菜细胞质与诸葛菜细胞核）的比例,以至较多的甘蓝型油菜染色体组被遗传下去。在该杂种继代培养中还观察到杂种细胞内的染色体消除及体细胞配对现象。     

Generation of B. nigra-B. rapa chromosome addition stocks: cytology and microsatellite markers (SSRs) based characterization

To improve Brassica nigra, the B-genome donor for Brassica juncea through selective introgression of useful variation from A-genome chromosomes, B. nigra-B. rapa chromosome addition stocks were successfully synthesized for the first time. Resynthesized B. juncea was used as B-genome donor species and A-genome addition stocks were developed by hybridizing sesquidiploid plant (ABB) as female and using B. nigra as the male parent. Various cycles of backcrossing and/or selfing were utilized to isolate plants carrying addition of three A-genome chromosomes in the background of B. nigra. These chromosome addition stocks were characterized by chromosome counts, pollen and seed fertility and chromosome specific microsatellite (SSRs) markers. The chromosome number in different backcross/self generations ranged between 2n=26 and 2n=19 with relatively high frequency of univalents (8-10I) at in meiotic configurations observed, suggesting the role of preferential transmission of A-genome chromosomes. SSRs analysis revealed that B. rapa chromosomes 3 and 4 were the first to get eliminated followed by chromosome 10. Remaining chromosomes were maintained till BC(1)F(4). However, second cycle of backcrossing (BC(2)) led to the elimination of chromosome numbers 1 and 2. BC(2)F(2) plants carried the chromosome numbers 6, 7, 8 and 9. Generation BC(3) having plants with 2n=19 carried chromosome numbers 6, 7 and 8. It is possible that chromosomes 6, 7 and 8 had higher transmission frequency and these were better tolerated by the B. nigra genome.     

Synthesis of intergeneric hybrids and establishment of genomic affinity between <Emphasis Type="Italic">Diplotaxis catholica</Emphasis> and crop <Emphasis Type="Italic">Brassica</Emphasis> species

Intergeneric hybrids of the wild crucifer Diplotaxis catholica (2n = 18, D(C)D(C)) as female with two crop Brassica species, namely Brassica rapa (2n = 20; AA) and Brassica juncea (2n = 36; AABB) as male, were developed, using ovary and sequential culture. Reciprocal crosses were not successful, suggesting unilateral cross incompatibility. Morphologically, the hybrid plants resembled the crop brassica parents, but were nearly male- as well as female-sterile. Induction of amphiploidy helped to improve pollen fertility for the D. catholica x B. rapa cross (73%), but less so for the D. catholica x B. juncea cross (35-40%). Female fertility was also higher in both the amphiploids. Cytological analysis of the F(1) hybrids revealed aberrant meiosis with predominant occurrence of the univalents. Partial genomic homoeology between the A genome of B. rapa and the D(C) genome of D. catholica was indicated by the presence of up to five bivalents in 14.7% of the PMCs in the D. catholica x B. rapa hybrid, and 1-2 trivalents or a quadrivalent in nearly 44% of the PMCs in the derived amphiploid. In the second cross, D. catholica x B. juncea, up to six bivalents and one trivalent were observed indicating homoeology between the A/B genomes of B. juncea and the D(C) genome of D. catholica. The possibility of introgression of desirable genes from D. catholica into crop Brassica species exists in view of significant affinity between the D(C) and A/B genomes.     

Conserved patterns of chromosome pairing and recombination in Brassica napus crosses.

The patterns of chromosome pairing and recombination in two contrasting Brassica napus F1 hybrids were deduced. One hybrid was from a winter oilseed rape (WOSR) x spring oilseed rape cross, the other from a resynthesized B. napus x WOSR cross. Segregation at 211 equivalent loci assayed in the population derived from each hybrid produced two collinear genetic maps. Alignment of the maps indicated that B. napus chromosomes behaved reproducibly as 19 homologous pairs and that the 19 distinct chromosomes of B. napus each recombined with unique chromosomes from the interspecific hybrid between Brassica rapa and Brassica oleracea. This result indicated that the genomes of the diploid progenitors of amphidiploid B. napus have remained essentially unaltered since the formation of the species and that the progenitor genomes were similar to those of modern-day B. rapa and B. oleracea. The frequency and distribution of crossovers were almost indistinguishable in the two populations, suggesting that the recombination machinery of B. napus could cope easily with different degrees of genetic divergence between homologous chromosomes. Efficient recombination in wide crosses will facilitate the introgression of novel alleles into oilseed rape from B. rapa and B. oleracea (via resynthesized B. napus) and reduce linkage drag.     

通过白菜型油菜和埃塞俄比亚芥的Ar和Cc基因组导入创造甘蓝型油菜新材料

油菜是目前我国主要种植的油料作物之一,但现有的种质资源限制了产量的进一步提高。本研究采取了一种新的育种方式来增加甘蓝型油菜的种质资源,即通过远缘杂交结合分子标记辅助选择的方式将白菜型油菜的Ar基因组和埃塞俄比亚芥的Cc对现有的甘蓝型油菜品种的基因组(AnAnCnCn)进行部分替换。通过对五倍体杂交后代(ArAnBcCcCn)进行染色体选择,找到了染色体数目为38的材料。为了和现有的甘蓝型油菜进行区分,得到的新材料被认定为甘蓝型油菜新材料。实验结果表明,得到的部分甘蓝型油菜新材料具有基本正常的减数分裂过程、正常的花粉萌发以及胚囊发育过程,这说明甘蓝型油菜新材料达到了遗传平衡。分子标记分析表明:甘蓝型油菜新材料的约50%的基因组被白菜型油菜的Ar基因组和埃塞俄比亚芥的Cc替换,并且这些甘蓝型油菜新材料之间具有丰富的遗传多样性。因此,白菜型油菜的Ar基因组和埃塞俄比亚芥的Cc基因组导入对于丰富现有的甘蓝型油菜种质资源具有明显的效果。     

Molecular-genetic analysis of wheat (T. aestivum L.) genome with introgression of Ae. cylindrica Host genetic elements

Wheat-aegilops hybrid plants Triticum aestivum L. (2n = 42) x Aegilops cylindrica Host (2n = 28) were investigated with using microsatellite markers. In two BC1F9 lines some genome modifications connected with losing DNA fragments of initial variety or appearing of Aegilops genome elements were detected. In some investigated hybrids new amplicons lacking in parental plants were found. Substitution of wheat chromosomes for aegilops chromosomes was not revealed. Analysis of microsatellite loci in BC2F5 plants showed stable introgression of aegilops genetic elements into wheat; elimination of some transferred aegilops DNA fragments in the course of backcrossing; decreasing size of introgressive elements after backcrossing. Introgressive lines were classified according to genome changes.     

Production and cytogenetics of intergeneric hybrids between the three cultivated Brassica diploids and Orychophragmusviolaceus

It has been proposed that both complete and partial separation of the parental genomes during mitosis and meiosis occurs in the intergeneric hybrids between Orychophragmus violaceus (2n=24) and the three cultivated Brassica tetraploids (B. napus, B. carinata and B. juncea). The hypothesis has been that this and the variations in chromosome numbers of these hybrids and their progenies result from the different roles of the A, B and C genomes originating from Brassica. To test this hypothesis, we produced hybrids between O. violaceus and the cultivated Brassica diploids. The hybrids with B. oleracea (2n=18, CC) had an intermediate morphology, but their petals were purple like those of O. violaceus. They were sterile and had the expected chromosome number (2n=21) in their mitotic and meiotic cells. The hybrid with B. campestris (2n=20, AA) was morphologically intermediate, except for its partial fertility and its yellow petals, which were similar to those of B. campestris. It was mixoploid (2n=23–42), and cells with 2n=34 were most frequent. Partial separation of parental genomes during mitosis, leading to the addition of O. violaceus chromosomes to the B. campestris complement, was proposed to explain the findings in the mitotic and meiotic cells of the hybrid and its progeny. In crosses with B. nigra (2n=16, BB), the majority of the F₁ plants were of the maternal type (2n=16), a small fraction had B. nigra morphology but were mixoploids (2n=16–18), predominantly with 2n=16 cells and three plants, each with a specific morphology, were mixoploids consisting of cells with varying ranges of chromosome numbers (2n=17–26, 11–17 and 14–17). The origin of these different types of plants was inferred to be a result of the complete and partial separation of parental genomes and the loss of O. violaceus chromosomes. Our findings in the three crosses suggest that the A genome was more influential than the C genome with respect to complete genome separation during mitosis and meiosis of the hybrids with B. napus. Possible complete and partial genome separation during mitotic divisions of the hybrids with B. carinata was mainly attributed to the role of the B genome. The combined roles of the A and B genomes would thus contribute to the most variable chromosome numbers of mitotic and meiotic cells in the hybrids with B. juncea and their progenies. The possible cytological mechanisms pertaining to these hybrids and the potential of genome separation in the production of Brassica aneuploids and homozygous plants are discussed. Received: 8 February 1998 / Accepted: 12 March 1999     

Obtaining and analysis of intergeneric somatic hybrids between Brassica napus and "albino" line of Orychophragmus violaceus

The Orychophragmus violaceus chlorophylldefective line of "albino" type has been obtained by spectinomycin treatment. Somatic hybridization between Orychophragmus violaceus and Brassica napus was performed by fusion of green mesophyll protoplasts of rape and callus protoplasts of the O. violaceus "albino" line. Near two hundred of regenerant plants were selected according to the regeneration type and ability to become green, and were determined as hybrids. Chloroplast DNA in selected hybrids was identical to rape chlDNA, which was confirmed by the PCR-RFLP analysis of plastid DNA fragments. Fragments of hybrid mitochondrial DNA analyzed by the PCR-RFLP analysis were identical to fragments of O. violaceus. The nuclear genome of the majority of hybrids was represented by the O. violaceus genome, which was demonstrated by analyses of isoenzymes, DNA telomeric sequences, ribosomal and satellite DNAs, and the RAPD analysis. The cytogenetic analysis of a number of lines has shown variability in the number of chromosomes in the obtained lines.     

Stable progeny production of the amphidiploid resynthesized Brassica napus cv. Hanakkori, a newly bred vegetable

Resynthesized Brassica napus cv. Hanakkori (AACC, 2n?=?38) was produced by cross-hybridization between B. rapa (AA, 2n?=?20) and B. oleracea (CC, 2n?=?18) as a new vegetative crop. Many studies have provided evidences for the instability and close relationship between A and C genome in the resynthesized B. napus cultivars. In fact, seed produced to obtain progeny in Hanakkori had unstable morphological characters and generated many off-type plants. In this study, we investigated the pollen fertility, chromosome number, structure, and behavior linked to various Hanakkori phenotypes to define factors of unstable phenotypic expression in the progeny. Hanakkori phenotypes were categorized into five types. The results of pollen fertility, chromosome number, and fluorescence in situ hybridization analysis for somatic mitosis cells indicated that the off-type plants had lower pollen fertility, aberrant chromosome number, and structures with small chromosome fragments. Observation of chromosomes at meiosis showed that the meiotic division in off-type plants led to appreciably higher abnormalities than in on-type plants. However, polyvalent chromosomes were observed frequently in both on- and off-type plants in diplotene stage of meiosis. We assume that the unstable morphological characters in resynthesized progeny were the result of abnormal division in meiosis. It results as important that the plants of normal phenotype, chromosome structure and minimized abnormal meiosis are selected to stabilize progeny.     

Cytogenetic characterization and fae1 gene variation in progenies from asymmetric somatic hybrids between Brassica napus and Crambe abyssinica.

Sexual progenies of asymmetric somatic hybrids between Brassica napus and Crambe abyssinica were analyzed with respect to chromosomal behavior, fae1 gene introgression, fertility, and fatty-acid composition of the seed. Among 24 progeny plants investigated, 11 plants had 38 chromosomes and were characterized by the occurrence of normal meiosis with 19 bivalents. The other 13 plants had more than 38 chromosomes, constituting a complete chromosomal set from B. napus plus different numbers of additional chromosomes from C. abyssinica. The chromosomes of B. napus and C. abyssinica origin could be clearly discriminated by genomic in situ hybridization (GISH) in mitotic and meiotic cells. Furthermore, meiotic GISH enabled identification of intergenomic chromatin bridges and of asynchrony between the B. napus and C. abyssinca meiotic cycles. Lagging, bridging and late disjunction of univalents derived from C. abyssinica were observed. Analysis of cleaved amplified polymorphic sequence (CAPS) markers derived from the fae1 gene showed novel patterns different from the B. napus recipient in some hybrid offspring. Most of the progeny plants had a high pollen fertility and seed set, and some contained significantly greater amounts of seed erucic acid than the B. napus parent. This study demonstrates that a part of the C. abyssinica genome can be transferred into B. napus via asymmetric hybridization and maintained in sexual progenies of the hybrids. Furthermore, it confirms that UV irradiation improves the fertility of the hybrid and of its sexual progeny via chromosomal elimination and facilitates the introgression of exotic genetic material into crop species.     

甘蓝型油菜与诸葛菜属间杂种的减数分裂观察

在甘蓝型油莱与诸葛菜属间杂种细胞减数分裂中,观察到两种类型的染色体分离方式。第一种,细胞内的３１条染色体呈两组分离,其中１９条染色体至细胞一极,１２条染色体至另一极;且在两极的染色体进行分裂,产生４个核,两个具有１９条染色体,另两个具有１２条染色体。故杂种细胞通过这种染色体分离方式,可同时产生具有１９与１２条染色体的两类配子。杂种细胞内发生的这种染色体行为,极有可能与来自两个亲本种的染色体组相关;即在细胞两极的１９与１２条染色体分别来自甘蓝型油菜与诸葛菜。第二种,在后期Ｉ至末期Ｉ,花粉母细胞内以６个二价体形式出现的１２条染色体被落后在赤道板附近,而被排斥在末期核之外。这些落后二价体很有可能来自诸葛菜。因此,在杂种细胞减数分裂中,来自两个亲本种的染色体组被分开。文中还对染色体组分开的遗传意义等进行了讨论。     

Analysis of B-genome chromosome introgression in interspecific hybrids of Brassica napus × B. carinata

Brassica carinata, an allotetraploid with B and C genomes, has a number of traits that would be valuable to introgress into B. napus. Interspecific hybrids were created between B. carinata (BBCC) and B. napus (AACC), using an advanced backcross approach to identify and introgress traits of agronomic interest from the B. carinata genome and to study the genetic changes that occur during the introgression process. We mapped the B and C genomes of B. carinata with SSR markers and observed their introgression into B. napus through a number of backcross generations, focusing on a BC(3) and BC(3)S(1) sibling family. There was close colinearity between the C genomes of B. carinata and B. napus and we provide evidence that B. carinata C chromosomes pair and recombine normally with those of B. napus, suggesting that similar to other Brassica allotetraploids no major chromosomal rearrangements have taken place since the formation of B. carinata. There was no evidence of introgression of the B chromosomes into the A or C chromosomes of B. napus; instead they were inherited as whole linkage groups with the occasional loss of terminal segments and several of the B-genome chromosomes were retained across generations. Several BC(3)S(1) families were analyzed using SSR markers, genomic in situ hybridization (GISH) assays, and chromosome counts to study the inheritance of the B-genome chromosome(s) and their association with morphological traits. Our work provides an analysis of the behavior of chromosomes in an interspecific cross and reinforces the challenges of introgressing novel traits into crop plants.     

Progressive introgression between Brassica napus (oilseed rape) and B. rapa

We have earlier shown extensive introgression between oilseed rape (Brassica napus) and B. rapa in a weedy population using AFLP markers specific for the nuclear genomes. In order to describe the progress of this introgression, we examined 117 offspring from 12 maternal plants from the introgressed population with the same AFLP-markers; AFLP data were supported by chromosome counting. We also analysed the offspring with a species-specific chloroplast marker and finally evaluated the reproductive system in selected maternal plants. Our results indicated a high outcrossing rate of the introgressed maternal plants. It seemed that B. rapa most often functioned as the maternal plant in the introgression process and that the amount of oilseed rape DNA was highly diminished in the offspring compared to their introgressed maternal plants. However, our analysis of plants from the weedy population indicated that introgression can lead to both (1) exchange of chloroplast DNA between species producing B. rapa-like plants with B. napus chloroplasts and (2) incorporation of B. napus C-genome DNA into the B. rapa genome. Therefore, we question whether it can be regarded as containment to position transgenes in the chloroplast or in specific parts of the nuclear genome of B. napus.