Development of self-incompatible Brassica napus: (II) Brassica oleracea S-allele expression in B. napus

Brassica napus var. oleifera varieties have traditionally been developed as open‐pollinated varieties. The successful introduction of several high‐yielding hybrids based on cytoplasmic male sterility or transgenic pollination control systems has generated interest in the development of new hybrid systems. Self‐incompatibility could be an additional useful pollination control system for B. napus if a sufficient number of S‐alleles could be developed in this species. The S‐alleles, S2, S5, S13, S24 and S39, were identified in five hybrids of B. oleracea var. italica and subsequently transferred to B. napus. Doubled haploid lines were produced for the self‐incompatible (SI) lines in B. napus and intercrossed to produce SI heterozygotes in order to study allele interaction. There was a greater incidence of interallelic dominance in the stigmas and pollen of B. napus than was reported for the S‐alleles in B. oleracea. Allele S24 exhibited the greatest degree of dominance over the other alleles tested, while allele S2 was generally recessive or codominant with other alleles. Self‐incompatible expression was very similar in the SI homozygotes and heterozygotes, thus no weakening of the SI trait in the heterozygote was observed. The implications of S‐allele interaction for the use of SI in B. napus are discussed.     

Development of self-incompatible Brassica napus: (I) introgression of S-alleles from Brassica oleracea through interspecific hybridization

Cultivars in Brassica napus var. oleifera, a self‐pollinating, self‐compatible species, have traditionally been developed as open‐pollinated lines or populations. Significant yield gains in this species have been realized through the exploitation of heterosis. Commercial hybrid production has been possible as a result of the development of a number of pollination control systems. Self‐incompatibility was transferred from B. oleracea var. italica to B. napus var. oleifera through interspecific hybridization. The response to interspecific pollination, as measured by pod elongation and initial stages of ovule development, was genotype dependent, and two highly responsive B. napus genotypes were identified. Embryo rescue was used to produce the interspecific hybrids. Isoelectric focusing of stigma proteins was used to identify S‐alleles in the interspecific hybrids to facilitate backcrossing. Segregation of the S‐locus through a series of back‐crosses to B. napus was complicated by aneuploidy; however, the S‐locus was found to segregate as a single gene. Usefulness of B. oleracea as a source of S‐alleles for pollination control in B. napus is discussed.     

利用异源六倍体(A~rA~rA~nA~nC~nC~n)与甘蓝种间杂交合成甘蓝型油菜的新方法

利用亲本种的遗传变异是改良油菜的重要途径,本研究提出一种利用甘蓝拓宽甘蓝型油菜遗传多样性的新方法。以甘蓝型油菜(AnAnCnCn)品种中双11号为母本,与白菜型油菜(ArAr)品系SWU07杂交,经染色体加倍获得异源六倍体(ArArAnAnCnCn),再与甘蓝(CoCo)杂交,创建出具有亲本种遗传成分的新型甘蓝型油菜(ArAnCnCo)。该六倍体连续3个世代核型稳定,各世代中的自交和自由授粉结实率无显著差异,花粉育性在94.6%～98.8%之间,3个世代自交平均结实率为每角果5.47粒,自由授粉平均结实率为每角果7.93粒;各世代六倍体(ArArAnAnCnCn)与不同类型甘蓝杂交平均结实率分别为每角果0.05、0.04、0.05粒,世代间无显著差异,且六倍体与栽培、野生甘蓝杂交结实性无显著差异,可交配性不受六倍体世代及甘蓝类型的影响。尽管该六倍体与甘蓝可交配性较低,但仍可在田间条件下成功杂交,获得新型甘蓝型油菜(ArAnCnCo),表明以ArArAnAnCnCn六倍体为桥梁与甘蓝杂交,是一种有效导入甘蓝遗传成分、创建新型甘蓝型油菜的新方法。     

Self-incompatibility in Brassica napus: seed set on crossing 19 self-incompatible lines

Summary Seed set after self-pollination confirmed that 19 lines of Brassica napus were self-incompatible. Eight lines, H, J, Q, W, X, K, P and Z, were fully cross-compatible. Line R was cross-compatible with these lines but often had a low seed set as female parent. These results are consistent with the activity of nine distinct S-alleles. Line S was cross-incompatible with K, as was V with P, and F with Z. With each of the lines A, E, B, O, G, L and M at least one reciprocal difference was found so that the number of additional distinct S-alleles could not be inferred, but there must be a minimum of seven.Pollen tube counts of intra- and inter-line pollinations using M, B and X confirmed the homozygosity of these lines with respect to self-incompatibility status and the presence of non-reciprocal compatibility between M and B.The results are interpreted in terms of the activity of both B. oleracea and B. campestris S-loci and the implications for hybrid breeding are discussed.     

Molecular characterization of novel resynthesized rapeseed (Brassica napus) lines and analysis of their genetic diversity in comparison with spring rapeseed cultivars*

Resynthesized (RS) rapeseed generated from interspecific hybridization between suitable forms of Brassica rapa L. (syn. campestris; genome AA, 2n = 20) and B. oleracea L. (CC, 2n = 18) represents a potentially important resource to expand genetic diversity in the narrow gene pool of oilseed rape (B. napus L., AACC, 2n = 38). In this study 165 RS rapeseed lines originating from crosses between an Indian Yellow Sarson (B. rapa ssp. trilocularis) and five different cauliflower (B. oleracea convar. botrytis) cultivars were studied using amplified fragment length polymorphism (AFLP) markers and their genetic diversity was compared in relationship to an assortment of 40 diverse spring oilseed and fodder rape varieties. Using three AFLP primer combinations, a total of 467 polymorphic bands were scored. Cluster analysis allowed differentiation among the different RS lines, which, as expected, were genetically highly divergent from the cultivars. The genetic diversity of the material is discussed in relation to its morphological variability with a view to the implementation of RS lines in oilseed rape breeding.     

An S-allele survey of cabbage (Brassica oleracea var. Capitata)

Summary A total of 31 S-alleles was found in a survey of 197 cabbage plants representing 11 cultivars of diverse type. Most of these S-alleles also occurred in either kale or Brussels sprouts, but five of them have not been found previously and apparently occur only in cabbage. A more detailed study of five cultivars of spring cabbage showed only 12 S-alleles in all, with 6–10 S-alleles in four older cultivars and only 3 S-alleles in the newer more highly selected cultivar. S2 was by far the commonest S-allele, as it is in B. oleracea as a whole. The highly recessive alleles S5 and S15 were not particularly common in cabbage and this may partly explain why the sib problem in F₁ hybrids is apparently less in cabbage than in Brussels sprouts. Three cases were found in which an S-allele was completely recessive in both the stigma and the pollen. The problems for the breeder created by this rather unusual situation are discussed.     

Effect of Completion of Vernalization on Generative Development of Winter Rape (Brassica napus L. var. oleifera) Plants

Germinating seeds and young plants of winter rape var. Górczañski were vernalized for 56–63 days under conditions of 9-hour day, at the temperature 2 and 5 °C and in continuous darkness at the temperature 2 °C. After vernalization the plants grew under conditions enabling to complete vernalization: in a glass-house at the temperature day/night 15/10 °C and in semi natural conditions of open vegetation hall in the period from June till August. After sub-optimal vernalization further growth of the plants at lowered temperature increased its effectiveness (completion of vernalization). Depending on the degree of the vernalization of the plants the completion of their vernalization was both obligatory, i.e. conditioning the acquisition of the ability of generative development, and facultative i.e. accelerating this development. It has been demonstrated that the population of plants of the examined variety is strongly differentiated not only with respect of vernalization requirements in the particular plants, but also what regards the effectiveness of vernalization completion. New observations have been made indicating that the mechanisms controlling the successive phases of generative development, i.e. phase of forming flower buds and the flowering phase are not identical which may be interpreted as indicating that the "flowering factor" is polymorphous.     

Genetic analysis of four self-incompatible lines in Brassica napus

Reciprocal hybridization between four self-incompatible lines of Brassica napus: 271, 181, 184 and ‘White Flower’, revealed incompatibility. The reciprocal F₁s obtained by bud pollination showed self-incompatible reactions, and no segregation for self-incompatibility was observed in all the reciprocal F₂ populations, indicating that lines 271, 181, 184 and ‘White Flower’ were genetically identical with regard to self-incompatibility. Observations of self-incompatibility in 17 hybrids from crosses between line 271 and 17 varieties of B. napus showed 10 of the F₁ hybrids to be self-compatible, while four were partially self-compatible and three were self-incompatible. Genetic analysis based on F₂ and BC₁ populations from five self-compatible F₁ hybrids and two self-incompatible F₁ hybrids suggested the existence of at least two loci controlling the self-incompatibility of line 271: one is the S locus, with dominant and recessive relationships between the S alleles, and the other is the suppressor (sp) of the S locus. The sp locus is genetically different from the S locus, and also shows dominant and recessive relationships between the sp alleles.     

Assessment of transgene escape from Brassica rapa (B. campestris) into B. nigra or Sinapis arvensis

The possibility of gene transfer between Brassica rapa and the two weedy species B. nigra and Sinapis arvensis was evaluated with the special concern on transgene escape from B. rapa to these two weedy species. B. rapa cultivar Tobin was reciprocally crossed to five and four strains of B. nigra and S. arvensis, respectively, using controlled cross. A single interspecific hybrid was obtained from the cross B. rapa×B. nigra, but no other cross was successful. The fertility of this hybrid on open pollination, selfing and backcrosses was investigated. The data of the present study and the information available to date indicate that gene transfer between B. rapa and B. nigra is possible. The chance of transgene escape from B. rapa to B. nigra depends essentially on whether natural cross can occur between these two species. Gene transfer between B. rapa and S. arvensis is at the most difficult, whereas trans-gene escape directly from B. rapa to S. arvensis appears very unlikely.     

The transfer of characters from Brassica campestris L. to Brassica napus L.: Production of clubroot-resistant oil-seed rape (B. napus ssp oleifera)

Summary Four oil-seed rape lines were crossed with a clubroot resistant Brassica campestris line from the European Clubroot Differential sct. The allotriploid hybrids were backcrossed to the rape lines to introgress clubroot resistance into oil-seed rape. Using a combination of screening for disease resistance and chromosome number, a high proportion of 38-chromosome, clubroot resistant selections were obtained.     

人工合成甘蓝型油菜抗旱性及DNA甲基化水平分析

甘蓝型油菜是具有重要经济价值的多倍体物种,是优质食用植物油和饲料蛋白质的重要来源之一。但是其驯化历史较短,遗传背景狭窄,且在整个生命周期中都对干旱胁迫敏感,因此培育高产耐旱品种是甘蓝型油菜的重要育种目标之一。本文用15%PEG-6000模拟干旱胁迫,对人工合成甘蓝型油菜不同世代(S1～S4)及其二倍体亲本进行不同时间的胁迫处理,并结合表型观察,以及叶片中丙二醛(MDA)、可溶性蛋白含量、过氧化物酶(POD)、超氧化物歧化酶(SOD)等生理指标的测定,初步了解上述材料的抗旱性差异。结合表型观察和叶片中相对含水量分析,发现人工合成甘蓝型油菜S1～S4及其亲本的抗旱性表现为甘蓝 Bn-S3 Bn-S4 Bn-S1 Bn-S2白菜型油菜。干旱胁迫后Bn-S3、Bn-S4的POD及SOD活性较高,MDA含量较低,表明Bn-S3和Bn-S4能更加有效地清除活性氧(ROS),对过氧化损伤的防御能力更强。通过HPLC分析发现所有材料的甲基化水平在胁迫12 h时最高,其中亲本白菜型油菜Br的甲基化水平最高, Bn-S1和Bn-S4介于两亲本之间,而Bn-S2和Bn-S3低于两亲本。甲基化敏感多态性分析也显示人工合成甘蓝型油菜在干旱胁迫后,甲基化和去甲基化水平均发生了明显的变化,表明植物的甲基化变化可能有利于提高其抗旱能力。     

Combination of resistance to Verticillium longisporum from zero erucic acid Brassica oleracea and oilseed Brassica rapa genotypes in resynthesized rapeseed (Brassica napus) lines

Resynthesized (RS) forms of rapeseed (Brassica napus L.; genome AACC, 2n = 38) generated from interspecific hybridization between suitable genotypes of its diploid progenitors Brassica rapa L. (syn. campestris; genome AA, 2n = 20) and Brassica oleracea L. (CC, 2n = 18) represent a potentially useful resource to introduce resistance against the fungal pathogen Verticillium longisporum into the gene pool of oilseed rape. Numerous cabbage (B. oleracea) accessions are known with resistance to V. longisporum; however, B. oleracea generally has high levels of erucic acid and glucosinolates in the seed, which reduces the suitability of resulting RS rapeseed lines for oilseed rape breeding. In this study resistance against V. longisporum was identified in the cabbage accession Kashirka 202 (B. oleracea convar. capitata), a zero erucic acid mutant, and RS rapeseed lines were generated by crossing the resistant genotype with two spring turnip rape accessions (B. rapa ssp. olerifera) with zero erucic acid. One of the resulting zero erucic acid RS rapeseed lines was found to have a high level of resistance to V. longisporum compared with both parental accessions and with B. napus controls. A number of other zero erucic acid RS lines showed resistance levels comparable to the parental accessions. In the most resistant RS lines the resistance and zero erucic acid traits were combined with variable seed glucosinolate contents. Erucic acid‐free RS rapeseed with moderate seed glucosinolate content represents an ideal basic material for introgression of quantitative V. longisporum resistance derived from B. oleracea and B. rapa into elite oilseed rape breeding lines.     

Induction of Generative Development of Winter Rape (Brassica napus L. var. oleifera) in Relation to Vernalization Conditions and Age of Vernalized Plants

Germinating seeds and young winter rape plants were vernalized 56–63 days at 5 or 2°C under nine-hour days or in darkness. The highest percentage of generative plants and the most rapid flowering were obtained following the vernalization of young seedlings and germinating seed under conditions of nine-hour day, at 5°C. The least effective induction of generative development followed the vernalization at 2°C in continuous darkness. The vegetation period from the end of vernalization till the beginning of flowering was the shortest when four-week-old plants were vernalized under conditions of nine-hour day, yet the vegetation period from the beginning of germination to flowering was the shortest when seed germinating under conditions of nine-hour day were vernalized. The period was extending as older plants were being vernalized. Data indicating that the optimal temperature for vernalization of older plants is higher than for germinating seed and young seedlings were obtained.     

Genes for race-specific resistance against blackleg disease in Brassica napus L.

Specificity of interaction at the cotyledon stage was recently demonstrated between the blackleg pathogen, Leptosphaeria maculans, and Brassica napus. Three pathogenicity groups were distinguished, PG2 avirulent towards ‘Quinta’ and ‘Glacier’, PG3 avirulent towards ‘Quinta’, and PG4 virulent on the two cultivars. The genetic control of the interactions was investigated on both the pathogen and the plant. Tetrad analysis was performed following PG3 × PG4 and PG2 × PG4 crosses.‘Quinta’ and ‘Glacier’ were crossed with the susceptible winter oilseed rape cultivar ‘Score’. The analysis of F₁, F₂ and testcross populations suggested that the incompatible interaction between ‘Quinta’ and PG3 isolates is conditioned by the presence of the dominant single resistance allele Rlml in ‘Quinta’ and the matching avirulence gene AvrLml in L. maculans. Race-specific resistance of ‘Glacier’ to PG2 isolates was conditioned by the matching gene pair Rlm2/AvrLm2. Finally, the data suggest that two avirulence genes matching two dominant loci control the ‘Quinta’-PG2 interaction. The consequences of the occurrence of race-specific resistance in B. napus are discussed with respect to future breeding for blackleg resistance.     

Introgression of genes into cultivated Brassica napus through resynthesis of B. napus via ovule culture and the accompanying change in fatty acid composition

Fifteen lines of Brassica napus were resynthesized via ovule culture through 24 interspecific crosses between four Brassica oleracea and three Brassica campestris accessions. The degree of success in the interspecific crosses was significantly influenced by maternal genotypes. The interspecific hybrid production rate (HPR) varied with combinations from 0 to 76.9%, with a mean HPR of 24.7% for the crosses with B. campestris as the female parent and 6.9% for the crosses with B. oleracea as female parent. Twenty‐four crosses between seven natural and six resynthesized B. napus gave, on average, 10.3 seeds per pod, and ranged from 1.2 to 22.0 seeds per pod, depending on genotypes of both parents. Resynthesized lines of B. napus showed high erucic acid content and variable content of linolenic acid, ranging from 3.4% to 9.9%. The fatty acid composition in hybrid seeds between natural and resynthesized B. napus was dominated by the embryo genotypes; an additive mode was shown for erucic acid and positive over‐dominance for linolenic acid content.     

利用野生甘蓝抗性遗传资源获得高抗菌核病甘蓝型油菜的抗性与分子标记初步分析

茵核病是甘蓝型油菜最严重的病害之一,自身抗性低,而甘蓝野生资源中存在高抗遗传资源.以部分抗性的甘蓝型油菜中双9号和高抗性的甘蓝野生资源为亲本杂交得到F1 (ACC),F1连续用中双9号回交6代,得到育性基本恢复正常植株自交,培育成了高抗茵核病材料,命名为F6.染色体计数显示,F6有38条染色体,和甘蓝型油菜(AACC,2 n=38)一致.茵核病抗性鉴定实验结果说明F6对茵核病的抗性高于中双9号而弱于甘蓝.通过在亲本和子代间比较229个分布于甘蓝型油菜19个遗传连锁群的SSR分子标记以及16个与甘蓝抗茵核病特异性位点有关的SSR分子标记,发现甘蓝抗茵核病主要特异性区段9号连锁群已渗入甘蓝型油菜基因组中.     

A cytogenetic study of the progenies of hybrids between Brassica napus and Brassica oleracea, Brassica bourgeaui, Brassica cretica and Brassica montana

In this cytogenetic study the progeny of all crosses were investigated in F₁, F₂ and backcross (BC₁) hybrids. Brassica napus and F₁ hybrids between B. napus and B. oleracea, and between B. napus and three wild relatives of B. oleracea (B. bourgeaui, B. cretica and B. montana). Each of the wild relatives has 18 somatic chromosomes. Interspecific F₁ hybrids were obtained through ovary culture mean. These had 28 and 37 chromosomes and their mean pollen fertility was 10.7% and 93.0%, respectively. Many F₂ and BC₁ seeds were harvested from the F₁ hybrids with 37 chromosomes after self‐pollination and open pollination of the F₁ hybrids, and backcrossing with B. napus. Many aneuploids were obtained in the F₂ and BC₁ plants. It is evident from these investigations that the F₁ hybrids may serve as bridge plants to improve B. napus and other Brassica crops.     

Self-incompatibility as a pollination control mechanism for spring oilseed rape,Brassica napus L.

Summary Self-incompatibility was shown to be an effective method of pollination control in spring rapeseed (B. napus L. ssp. oleifera (Metzg.)) by comparing the yield of a Westar-Topas syn-1 produced by crossing two SI lines with the yield of the corresponding syn-1 produced by hand pollination. Although the trial showed high-parent heterosis in the syn-1s, there was insufficient replication to determine the level of heterosis.Abbreviations SI self-incompatible - SC self-compatible