Successful backcrosses of somatic hybrids between Sinapis alba and Brassica oleracea with the Brassica oleracea parent

Somatic hybrids between Sinapis alba (2n= 24) and Brassica oleracea (2n= 18) have been backcrossed with the B. oleracea parent. Whereas backcrosses with the diploid B. oleracea parent were unsuccessful, 344 BC₁ seeds could be obtained from inter-valence crosses with tetraploid B. oleracea (2n= 4x= 36). The investigated 96 BC₁ plants segregated for morphological traits and for fertility. They were backcrossed with diploid B. oleracea or self-pollinated, depending on their male fertility. The BC₁F₂ and BC₂ progenies segregated well for the morphological traits. Disturbances were observed especially in the generative phase (flower development and pollen fertility). Both male fertile and male sterile BC₁F₂ and BC₂ plants were obtained and backcrossed or self-pollinated with the B. oleracea parent. The presence of either one of the parental or the cybrid organelle genomes was detected. In the progenies, a stable maternal inheritance of the organelle genome patterns was observed. Isozyme analyses revealed polymorphism for the leucine aminopeptidase (LAP) which was used for the identification of S. alba genes in the progenies. Cytological investigations showed a clear differentiation between the BC₁F₂ and BC₂ plants. Whereas the BC₁F₂ plants possess large numbers of chromosomes ranging from 34 to 40, the BC₂ material was strongly reduced to chromosome numbers ranging from 20 to 22. Preliminary investigation of the meiosis suggests the possibility of introgressions of S. alba-DNA into the B. oleracea genome.     

Hybridization of Sinapis alba L. and Brassica napus L. via Embryo Rescue

Embryo rescue techniques were used to obtain hybrids between Sinapis alba L. (white mustard) and Brassica napus L. (oilseed rape) with the goal of improving the disease tolerance of oilseed rape. Hybrid plants with 31 or 43 chromosomes were only recovered, when S. alba, was used as the female parent. One hybrid was obtained from the cross S. alba L. cv. ‘Kirby’×B. napus L. cv. ‘Topas’, while 26 hybrids were obtained, when various S. alba L. cultivars were pollinated with the rapid cycling B. napus line CrGC 5006. All F₁, hybrid plants were male sterile; however, the first generation backcross to B. napus L., also obtained by embryo rescue, produced plants with 50 chromosomes and 61–84 % pollen viability. Second backcross generation seed was produced by normal sexual crossing. Preliminary cytological analyses of pollen mother cells of hybrid plants suggests the possibility of genetic exchange between the two species.     

Pod shatter resistance evaluation in cultivars and breeding lines of Brassica napus, B. juncea and Sinapis alba

Pod shatter susceptibility was investigated in Brassica napus germplasm and shatter resistant species of B. juncea and Sinapis alba. The comparisons were made by measuring seed yield in field plots, detached pod rupture energy (RE) and the half‐life of pod‐opening. Pod shatter resistance was significantly greater in B. napus lines derived from interspecific hybridizations of B. napus with B. rapa, B. carinata and B. juncea, than common B. napus cultivars. While these lines exhibited no significant difference in resistance to pod shatter than B. juncea, an entry of S. alba had no yield loss caused by pod shatter. Resistance to pod shatter was characterized in the field as little or no yield loss after full maturity, delayed shattering in time, and stable yield performance under variable climatic conditions during pod maturity. Yield loss caused by pod shatter ranged from a low of 4% for the B. juncea cv. ‘AC Vulcan’ to a high of 61% for the black seeded B. napus line DH12075 in 2‐year field trials after 1 month maturity. Pod shatter resistance was not significantly associated with specific plant and pod morphological traits, except pod length (P = 0.005) in tested materials. Field visual scores of pod shatter through inspections of average pod shatter per plant within plots were highly correlated with plot yield loss. Indoor quantitative evaluations of pod strength using a pendulum machine to measure pod RE and random impact test to measure half‐life of pod‐opening resistance were highly correlated with field yield loss. Multiple evaluations of pod shatter in method and in time after pod maturity are recommended for reliable evaluation of pod shatter resistance.     

白芥和甘蓝型油菜属间杂种后代种子结构比较

白芥具有很多优良的农艺性状,从白芥和甘蓝型油菜属间体细胞杂种后代中筛选出多个具有黄籽或趋向黄籽性状的株系,利用光学显微镜和电子显微镜技术观察它们种子的结构。回交后代种皮解剖结构与甘蓝型油菜相似,而与白芥相差较远。种皮色素主要分布在栅栏层,甘蓝型油菜和部分后代株系中有色素分布,而白芥和部分黄籽后代株系中没有色素分布。栅栏层在甘蓝型油菜中最厚,在白芥中最薄,而后代介于两者之间。回交后代和甘蓝型油菜种皮表面纹饰为网-穴状,白芥为沟槽状或水疱状。胚子叶细胞面积以白芥最小,甘蓝型油菜最大,后代介于两者之间;而蛋白体面积指数以白芥最大,甘蓝型油菜最小,后代介于两者之间。超微结构观察表明,亲本和后代蛋白体均为球状晶体蛋白体,油体有大、小两种,其大小在亲本和后代间有差异。上述结果表明,回交后代株系种子解剖结构与甘蓝型油菜相近,种皮颜色、色泽深浅和栅栏层厚度,以及胚子叶细胞大小、油体和蛋白体等受亲本白芥的影响而发生变化。     

通过甘蓝型油菜和白芥属间杂种后代的小孢子培养获得二体异附加系

对3株甘蓝型油菜-白芥单体异附加系（2n=39）进行小孢子培养,共获得15株单倍体植株。经GISH鉴定,其中11株n=19,4株附加有一条白芥染色体（n=20）。经秋水仙素加倍处理,获得了二体异附加系(2n=40),这为远缘杂交后代外源基因的保存、纯合和利用提供了一条新的途径。     

Cytogenetic analysis of F1, F2 and BC1 plants from intergeneric sexual hybridization between Sinapis alba and Brassica oleracea by genomic in situ hybridization

By intergeneric sexual hybridization between Sinapis alba and Brassica oleracea , F₁, F₂ and BC₁ progeny plants were produced. S. alba plants (genome SS, 2n = 24) were pollinated with B. oleracea (genome CC, 2n = 18), and the fertile F₁ plants were pollinated with B. oleracea to obtain BC₁ plants. GISH analysis showed that 10 out of 12 F₁ plants had 12 S. alba chromosomes (one full S chromosome set) and nine B. oleracea chromosomes (one C chromosome sets), representing the expected hybrids. However, two F₁ plants had 12 S chromosomes and 18 C chromosomes (two C chromosome sets), indicating unexpected hybrids. A maximum of three trivalents between C and S chromosomes were identified at metaphase I of semi-fertile F₁ pollen mother cells (PMCs), which indicates homology and chromosome pairing between these two genomes. The C genome had obviously been doubled in two F₂ plants from selfed semi-fertile F₁ plants. BC₁ plants consisted of 18 C chromosomes and different numbers of one, five and six additional S chromosomes, respectively. Monosomic alien addition lines developed in the present study can be used for B. oleracea breeding and Sinapis alba gene mapping.     

Production of intergeneric hybrids between Brassica and Sinapis species by means of embryo rescue techniques

Reciprocal crosses were made to produce intergeneric hybrids among seven species of Brassica and three species of Sinapis with the aid of embryo rescue techniques. Ovule culture showed better responses in terms of hybrid plant development. Altogether, hybrids from 8 different combinations were obtained from the crosses between B. campestris var. trilocularis × S. turgida, B. campestris var. pekinensis × S. arvensis, S. arvensis × B. campestris var. pekinensis, B. oleracea var. alboglabra × S. alba, B. oleracea var. alboglabra × S. turgida, B. carinata × S. alba, B. carinata × S. arvensis, and B. carinata × S. turgida. Reciprocal crosses yielded no hybrid except in the combination of S. arvensis × B. campestris var. pekinensis. Among them hybrids from 6 combinations were established in the glass house. The hybridity of the plants was confirmed by morphological characters, pollen stainability, chromosome number and by isozyme analysis. Hybrids of four combinations out of six turned out as true hybrids, one as sesquidiploids and the another one as false hybrid plant. This revised version was published online in August 2006 with corrections to the Cover Date.     

A stable cytoplasmic male-sterile line of Brassica juncea carrying restructured organelle genomes from the somatic hybrid Trachystoma ballii+B. juncea

A cytoplasmic male-sterile (CMS) line of Brassica juncea has been developed by combining the cytoplasm originating from the somatic hybrid Trachystoma ballii+B. juncea, and the nucleus of B. juncea cv. Pusa Bold by repeated backcrossing. Male-sterile plants closely resembled the normal fertile B. juncea in general morphology, but had delayed flowering (5–7 days) when compared with fertile ‘Pusa Bold’ which flowered in 45 days. Stamens of the male-sterile line were transformed into petaloid structures. Pollen abortion occurred after tetrad formation. Female fertility of the male-sterile line was normal. Molecular analysis of organelle genomes indicated extensive mitochondrial DNA recombinations in the CMS line. Preliminary analysis of the chloroplast genome of the CMS line also indicated chloroplast DNA recombination.     

Cytogenetics of Brassica juncea×Brassica rapa hybrids and patterns of variation in the hybrid derivatives

Interspecific hybridization is an important tool to elucidate intergenomic relationships, transfer characters across species and develop synthetic amphidiploids, and it has been widely applied for improving Brassicas. The objective of the present study was to create genetic variability in Brassica through interspecific hybridization. Crosses between Brassica juncea (AABB, 2n= 36), and Brassica rapa (AA, 2n = 20) vars toria, yellow sarson, and brown sarson were attempted, and the hybrid derivatives were advanced to the F4 generation. Hybrids were obtained from the crosses B. juncea× toria and B. juncea× yellow sarson. The F₁ plants were vigorous and intermediate to the parents in many morphological traits. The meiotic study of AAB hybrids showed 10 II + 8 I in the majority (71.8%) of cells analysed. A maximum of 12 and a minimum of seven bivalents were also observed in a few cells. The occurrence of multivalent associations (trivalents to pentavalents) at diakinesis/metaphase I and a bridge‐fragment configuration at anaphase I were attributed to homoeology between A and B genomes. A high percentage of plants resembling B. juncea was observed in the F₂ generation. Transgressive segregation in both directions was found for plant height, primary branches, main raceme length, siliquae on main raceme, siliqua intensity, seeds per siliqua and seed yield. There were significant differences for the 14 characters in the F₄ derivatives. Moderate to high estimates of phenotypic and genotypic coefficients of variation, broad‐sense heritability, and expected genetic advance were found for seed yield, 1000‐seed weight, siliquae per plant, seeds per siliqua and days to flowering. Intergenomic recombination, reflected as wide variation in the hybrid progenies, permitted the selection of some useful derivatives.     

甘蓝型油菜和芥菜型油菜杂种小孢子培养获得再生植株

利用分离小孢子培养首次从甘蓝型油菜和芥菜型油莱种间杂种(甘芥杂种)中获得了胚和再生植株。所用的培养程序是,将甘芥杂种小孢子在蔗糖浓度为13％的液体NLN培养基中32℃下暗培养2天,转入25℃暗培养3周,再在光照条件下振荡培养一周后转入再生培养基(B_5)。供试的8个正反交甘芥杂种,有4个对培养有反应,其中3个均为以甘蓝型油菜为母本的杂种。杂种911186(甘蓝型)×851336(芥菜型)的胚产量明显高于其他杂种,未发现杂种花粉育性与小孢子胚产量存在显著相关。多数再生植株形态上介乎两个亲本之间,已开花的植株多为不育类型。讨论了亲本基因型对杂种小孢子胚胎发生的影响和小孢子衍生植株的可能用途。     

芥菜型油菜与甘蓝型油菜嫁接嵌合体的性状表现

以芥菜型油菜(B. juncea)作砧木,以甘蓝型油菜(B. napus)作接穗,形成嫁接嵌合体（以下简称“甘+芥”嫁接嵌合体）,对其植物学性状、农艺性状和32P标记的难溶性磷矿粉的吸收能力进行了研究。结果表明,“甘+芥”嫁接嵌合体除叶片出现紫色性状外,其他性状与甘蓝型油菜没有差异,但其农艺性状明显优于甘蓝型油菜和芥菜型油菜。其根系对肥料中难溶性磷吸收能力强,而且多数转移到地上部分,在体内分布较合理。     

A Simple Method of Inducing Somatic Embryogenesis in Brassica juncea (L.) Czern & Coss.

A single-step method for the induction and development of somatic embryoids from hypocotyls explains of Brassica juncea is reported. On modified MS medium containing 2 % sucrose, 0.25 mgl ¹ 2,4-D, 0.5 mgl ¹ each of NAA and BaP-R, each explant calluses at both of and at its best, 31% of explants produce embryoids. In the variety RLM-198, the number of embryoids ranges from 8–21 per culture. Each embryoid, upon proliferation, developed up to the 25 shoots. The method is rapid; the time La ken from inoculation to the development of intact plantlets is 8–10 weeks. Regenerated plants have flowered normally and have set seed. The system can profitably be used for in vitro mutant selection and early bulking in mustard.     

Macro-nutrient Status of Brassica napus and Brassica juncea Grown Under Swedish Conditions

Concentrations and amounts of macro-nutrients (N, P, K, Ca, Mg, S) in shoots, vegetative and generative plant parts in B. napus and B. juncea and nutrient inflow per unit root length in B. napus were studied in a field experiment at Uppsala, Sweden. Concentrations in vegetative plant parts were, except for Ca in B. napus, highest at the beginning of the season, and N and K were higher in B. napus than in B. juncea. The higher N concentration in vegetative parts (leaves, stems and pods) in B. napus was probably due to differences in growth pattern between the species. Seed concentrations of N, P, Ca, Mg and, most pronounced of all, S were higher in B. juncea. Nutrient amounts were, with the exception of K, throughout the season higher in B. juncea than in B. napus due to a higher dry matter production. Nutrient inflow per unit root length in B. napus was highest during the rosette stage for all nutrients. During flowering, the inflow decreased for N and K and increased for P and Ca. After root growth had stopped, no net inflow of K and S was found and inflow rates of other nutrients were at very low levels.     

Hybridizations among Brassica napus, B. rapa and B. juncea and their two weedy relatives B. nigra and Sinapis arvensis under open pollination conditions in the field

The rate of natural crosses occurring among the cultivated Brassica species B. napus, B. rapa, and B. juncea and their two weedy relatives B. nigra and Sinapis arvensis was studied in co-cultivation experiments under field conditions in Saskatchewan, Canada, with special reference to evaluation of the possibility of transgene escape from the cultivated to the weedy species. Natural crosses occurred among B. napus, B. rapa, and B. juncea, indicating that hybridizations among these three species do occur under field conditions. On the other hand, no natural crosses occurred between the cultivated species and B. nigra or S. arvensis. It is concluded that the crosses between the cultivated and weedy species are practically impossible under field conditions in Saskatchewan, and that the escape of transgenes from transgenic cultivars of B. napus, B. rapa and B. juncea into B. nigra and S. arvensis is basically zero in this region.     

Wide somatic hybrids of Citrus with its related genera and their potential in genetic improvement

Citrus wild relatives are an untapped germplasm reservoir, which possesses many elite resistance traits. Genetic introgression into Citrus by conventional methods has been greatly hindered by polyembryony, pollen / ovule sterility, sexual / graft incompatibility, long juvenility etc. Somatic hybridization via protoplast fusion may make it possible to transfer genes from wild relatives to Citrus. To date, more than sixty sexually compatible or incompatible intergeneric somatic hybrids between Citrus and its various related wild genera have been produced by PEG - orelectrically - induced fusion. These wide somatic hybrids were identified by morphology, cytology, isozyme, RAPD and RFLP analyses. Genetic variation or recombination was also revealed in some of them. Several sexually compatible combinations have flowered and set fruits. The agronomic performance of these wide somatic hybrids is diverse, and the current results are not conclusive. Somatic hybrids are being tested as rootstocks. The prospects of wide somatic hybridization of Citrus with its wild relatives are discussed. This revised version was published online in July 2006 with corrections to the Cover Date.     

Synthesis and cytogenetic characterization of intergeneric hybrids of Diplotaxis siifolia with Brassica rapa and B. juncea

Intergeneric hybrids involving a wild crucifer, Diplotaxis siifolia (2n = 20; D^sD^s), and two crop Brassica species, namely Brassica rapa (2n = 20; AA) and B. juncea (2n = 36; AABB), were developed through sequential ovary/ovule culture. Hybridization was successful only when D. siifolia was used as the female parent, indicating unilateral cross incompatibility. Hybrids were intermediate between the parents for morphological characteristics but had low male as well as female fertility. Meiotic studies of hybrids revealed partial homoeology between D^s and A/B genomes.     

Cytogenetic analysis of two interspecific Citrus allotetraploid somatic hybrids and their diploid fusion parents

Microsporogenesis of two interspecific allotetraploid somatic hybrids, i.e.‘Hamlin’ sweet orange +‘Rough Lemon’ (HR) and ‘Key’ lime +‘Valencia’ sweet orange (KV), was examined and compared with their corresponding diploid fusion parents. Meiotic analysis revealed that only 13.2 and 18.0% of the meiocytes exhibited normal tetrad formation in HR and KV somatic hybrid plants, respectively, and irregular chromosome behaviour with univalent or multivalent pairing occurred. Moreover, meiotic abnormalities such as chromosome bridges, chromosomes orientated away from the equatorial plate, especially lagging chromosomes, which resulted in different sizes of pollen grain, were frequently observed in both somatic hybrids. As expected, the percentage of chromosome abnormalities was much lower in their corresponding diploid fusion parents. HR and KV had 15.4 and 7.2% pollen germinability, respectively, intermediate between their corresponding fusion parents. The meiotic behaviour of these somatic hybrids provided valuable information for their practical utilization in a citrus breeding programme.     

Analysis of chromosome, mtDNA and cpDNA patterns in five somatic hybrids between Brassica alboglabra Bailey and Brassica campestris L.

Summary Somatic hybrids between Brassica alboglabra (CC) and B. campestris (AA) were produced through protoplast fusion. Hybrids of this combination have already been produced through sexual crosses and among other traits in the offspring, a CMS of ogura type was discovered. The reason for generating somatic hybrids was to create new nuclear-cytoplasmic combinations and/or cytoplasmic variants, which could be exploited in combination with the sexual hybrids. Mitosis and meiosis were studied and all hybrids were found to be of the AACCCC genomic constitution. The fusion of somatic cells resulted in altered cytoplasmic genomes.     

Inheritance of siliqua locule number and seed coat colour in Brassica juncea

The inheritance of siliqua locule number and seed coat colour in Brassica juncea was investigated, using three lines each of tetralocular brown seeded and bilocular yellow seeded. Three crosses of tetralocular brown seeded × bilocular yellow seeded lines were attempted and their F₁, F₂ and backcross generations were examined for segregation of these two traits. Brown seed colour and bilocular siliqua characters were found to be dominant over yellow seed and tetralocular siliqua, respectively. Chi‐square tests indicated that each trait is controlled by different sets of duplicate pairs of genes. Bilocular siliquae or brown seeds can result from the presence of either of two dominant alleles, whereas tetralocular siliquae or yellow seeds are produced when alleles at both loci are recessive. A joint segregation analysis of F₂ data indicated that the genes governing siliqua locule number and seed colour were inherited independently.