The promoter of aBrassica napus polygalacturonase gene directs pollen expression ofβ-glucuronidase in transgenicBrassica plants

A 647-bp 5-flanking fragment obtained from genomic clone Sta 44G(2) belonging to a family of polygalacturonase genes expressed inBrassica napus pollen was fused to the-glucuronidase (GUS) marker gene. This fusion construct was introduced intoB. napus plants viaAgrobacterium tumefaciens transformation. Analysis of the transgenicB. napus plants revealed that this promoter fragment is sufficient to direct GUS expression specifically in the anther and that GUS activity increases in pollen during maturation.Abbreviation GUS -Glucuronidase     

An efficient method for flow cytometric analysis of pollen and detection of 2n nuclei in Brassica napus pollen

A simple and reliable method was developed for isolating pollen nuclei from Brassica napus and Triticum aestivum for DNA analysis using flow cytometry. The nuclei were released from pollen by ultrasonic treatment. The isolated nuclei following filtration through nylon mesh and a purification procedure were suitable for flow cytometric analysis as well as for isolating genomic DNA. Ultrasonic treatment time was optimized for B. napus pollen at different developmental stages. The method is effective and suitable for the preparation of many samples. We analyzed the nuclear DNA levels in pollen of B. napus at three major developmental stages as well as in mature wheat pollen. Only a single 1C peak representing the haploid DNA level was detected in the nuclei isolated from Brassica uninucleate microspores as well as in mature Triticum pollen. Interestingly, diploid nuclei were detected in both binucleate and mature pollen of B. napus. The possible origins of the diploid nuclei are discussed.Abbreviations DAPI 4,6-Diamidino-2-phenylindole - NIB Nuclear isolation buffer     

An analysis of the relative activities of a number of promoter constructs from genes which are expressed during late pollen development as determined by particle bombardment

Summary The promoters of a tobacco actin gene, a tobacco pectate lyase, a tobacco and maize polygalacturonase and aBrassica S-locus related gene have been fused to the-glucuronidase reporter gene and their activities determined by biolistic transient assay in tobacco pollen. In stably transformed tobacco all the transgenes with the exception of Cauliflower Mosaic Virus-35S--glucuronidase appear to express efficiently in maturing pollen. Transient assay analysis showed that the tobacco pectate lyase and the polygalacturonase constructs were 8x more active than the tobacco actin construct, and that the tobacco polygalacturonase construct was some 33x more active than the maize polygalacturonase construct. Constructional manipulations that altered the lengths of the 5-untranslated leaders including one which resulted in the removal of a 490 bp leader intron had little effect on the observed level of expression. However, the alteration of the context of the ATG from A/TnnATGG to CnnATGT resulting in a 70% reduction in the observed levels of activity, was obtained with the pectate lyase and polygalacturonase promoters. An identical reductional was also observed in transgenic plant populations transformed with the polygalacturonase transgenes.Abbreviations GUS -glucuronidase - LUC luciferase - NosTer nopaline synthase terminator - CaMV Cauliflower Mosaic Virus - UTL untranslated leader - PCR polymerase chain reaction - PG polygalacturonase - Npg tobacco polygalacturonase - Pl pectate lyase - Ac actin     

Pea Lectin Expressed Transgenically in Oilseed Rape Reduces Growth Rate of Pollen Beetle Larvae

In several studies plant lectins have shown promise as transgenic resistance factors against various insect pests. We have here shown that pea seed lectin is a potential candidate for use against pollen beetle, a serious pest of Brassica oilseeds. In feeding assays where pollen beetle larvae were fed oilseed rape anthers soaked in a 1% solution of pea lectin there was a reduction in survival of 84% compared to larvae on control treatment and the weight of surviving larvae was reduced by 79%. When a 10% solution of pea lectin was used all larvae were dead after 4 days of testing. To further evaluate the potential use of pea lectin, transgenic plants of oilseed rape (Brassica napus cv. Westar) were produced in which the pea lectin gene under control of the pollen-specific promoter Sta44-4 was introduced. In 11 out of 20 tested plants of the T₀-generation there was a significant reduction in larval weight, which ranged up to 46% compared to the control. A small but significant reduction in larval survival rate was also observed. In the T₂-generation significant weight reductions, with a maximum of 32%, were obtained in 10 out of 33 comparisons between transgenic plants and their controls. Pea lectin concentrations in anthers of transgenic T₂-plants ranged up to 1.5% of total soluble protein. There was a negative correlation between lectin concentration and larval growth. Plants from test groups with significant differences in larval weights had a significantly higher mean pea lectin concentration, 0.64% compared to 0.15% for plants from test groups without effect on larval weight. These results support the conclusion that pea lectin is a promising resistance factor for use in Brassica oilseeds against pollen beetles.     

The EPSPS gene flow from glyphosate-resistant Brassica napus to untransgene B. napus and wild relative species Orychophragmus violaceus

Gene flow from transgenic plants to compatible wild relatives is one of the major impediments to the development of the culture of genetically engineered crop plants. In this work, the flow of EPSPS (conferring resistance to glyphosate) gene of transgene Brassica napus toward the untransgene B. napus and wild relative species Orychophragmus violaceus in an open field (1 ha) was studied. The data related to only the 2004 and 2005 autumn season on one location of southwest of China. Pollen dispersal and fertilization of the target plants were favored and a detailed analysis of the hybrid offspring was performed. In field, the data studied show that the gene flow frequency was 0.16% between GM and non-GM B. napus at a distance of 1 m from the transgenic donor area. The crosspollination frequency was 0.05% between GM and non-GM B. napus at a distance of 5 m from the transgenic donor area. At a distance of 10 m, no crosspollination was observed. According to the results of this study, B. napus transgene flow was low. However, the wild relative species O. violaceus could not be fertilized by the transgenic pollen of B. napus, no matter what the distance was.     

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

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

Introduction of a gene from fertility restored radish (Raphanus sativus) into Brassica napus by fusion of X-irradiated protoplasts from a radish restorer line and iodacetoamide-treated protoplasts from a cytoplasmic male-sterile cybrid of B. napus

To establish a cytoplasmic male-sterile/restored fertility (cms-Rf) system for F₁ seed production in Brassica napus, we transferred a gene from fertillity restored radish to B. napus by protoplast fusion. X-irradiated protoplasts, isolated from shoots of Raphanus sativus cv Kosena (Rf line), were fused with iodoacetamide-treated protoplasts of a B. napus cms cybrid. Among 300 regenerated plants, six were male-fertile. The fertile plants were characterized for petal color, chromosome number and the percentage of viable pollen grains. Three fertile plants had aneuploid chromosome numbers and white or cream petals, which is a dominant marker in radish. Of these three plants, one which had 2n = 47 chromosomes and white petals was used for further backcrosses. After two backcrosses, chromosome number and petal color became identical to that of B. napus. No female sterility was observed in the BC₃ generations.     

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

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

Immunocytochemical distribution of polygalacturonase and pectins in styles of distylous and homostylous Turneraceae

Distyly is a plant breeding system in which two self-incompatible, but cross-compatible, floral morphs occur within populations. The morphs differ in having a reciprocal arrangement of styles and anthers. Little or nothing is known of the proteins involved in self-incompatibility for any distylous species. Here we show that a 35 kDa putative polygalacturonase is specific to the transmitting tissue of short-styled plants of five species in series Turnera. The polygalacturonase was not detected in styles of long-styled plants, or in styles of five homostylous self-compatible species in this series of the genus. It is also absent from two X-ray generated mutants and a spontaneous somatic homostylous mutant that arose on a short-styled plant and whose style does possess this polygalacturonase. Three more distantly related species in the Turneraceae were investigated. Turnera weddelliana (series Salicifoliae) does possess the polygalacturonase; however, T. diffusa (series Microphyllae), and Piriqueta caroliniana, showed no evidence of possessing this polygalacturonase using immunocytochemistry. Polygalacturonase assays revealed activity in styles of long- and short-styled plants, but showed no activity of the 35 kDa style polygalacturonase. The distribution of pectins in styles and pollen tubes revealed no difference between the long- and short-styled morphs. Methyl-esterified pectins occur throughout the style tissues, except in the transmitting tissue. The transmitting tissue possesses unesterified pectins that could provide a substrate for polygalacturonase activity. We propose that the style polygalacturonase might act in a complementary manner, allowing pollen of long-styled plants to grow through short styles or, alternatively, oligogalacturonide products of polygalacturonase activity might play a role in signalling compatible responses.     

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

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

Molecular characterization of two Brassica napus genes related to oleosins which are highly expressed in the tapetum

Two highly homologous Brassica napus flower cDNA clones, Sta 41-2 and Sta 41-9, were isolated and characterized. These clones were shown to correspond to genes expressed in the tapetum from the early uninucleate microspore stage to the dinucleate stage. The predicted Sta 41-2 and Sta 41-9 proteins possessed characteristics similar to oleosins such as a polar N-terminal domain, a large relatively conserved hydrophobic domain and a long C-terminal domain which consisted of four different groups of repeats. In addition, like oleosins, the Sta 41-2 and Sta 41-9 proteins have a basic pl, lack a signal peptide and are found in a tissue which accumulates lipids in small lipid bodies.     

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

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

Production and cytogenetic characterization of intertribal somatic hybrids between <Emphasis Type="Italic">Brassica napus</Emphasis> and <Emphasis Type="Italic">Isatis indigotica</Emphasis> and backcross progenies

Intertribal somatic hybrids between Brassica napus (2n = 38, AACC) and a dye and medicinal plant Isatis indigotica (2n = 14, II) were obtained by fusions of mesophyll protoplasts. From a total of 237 calli, only one symmetric hybrid (S2) and five asymmetric hybrids (As1, As4, As6, As7 and As12) were established in the field. These hybrids showed some morphological variations and had very low pollen fertility. Hybrids S2 and As1 possessed 2n = 52 (AACCII), the sum of the parental chromosomes, and As12 had 2n = 66 (possibly AACCIIII). Hybrids As4, As6 and As7 were mixoploids (2n = 48–62). Genomic in situ hybridization analysis revealed that pollen mother cells at diakinesis of As1 contained 26 bivalents comprising 19 from B. napus and 7 from I. indigotica and mainly showed the segregation 26:26 at anaphase I (AI) with 7 I. indigotica chromosomes in each polar group. Four BC₁ plants from As1 after pollinated by B. napus resembled mainly B. napus in morphology but also exhibited some characteristics from I. indigotica. These plants produced some seeds on selfing or pollination by B. napus. They had 2n = 45 (AACCI) and underwent pairing among the I. indigotica chromosomes and/or between the chromosomes of two parents at diakinesis. All hybrids mainly had the AFLP banding patterns from the addition of two parents plus some alterations. B. napus contributed chloroplast genomes in majority of the hybrids but some also had from I. indigotica. Production of B. napus–I. indigotica additions would be of considerable importance for genome analysis and breeding.     

Scanning electron microscopy of microspore embryogenesis inBrassica spp.

Scanning electron microscopy was employed to study and compare microspore embryogenesis in vitro with pollen development in planta inBrassica napus andB. oleracea. An exine with its specific pattern had already been formed, when microspores were released from tetrads. During subsequent pollen development, microspores increased in size and continued to strengthen the exine. Upon in vitro culture, all microspores, i.e., embryogenic and nonembryogenic, initially showed the same morphological features. After 24 h in culture, the microspores had increased in size. Thereafter, embryogenesis was indicated in some microspores by two different morphological changes. One featured an expansion in volume of the cell cluster around the germination aperture (type I), the other showed cell cluster volume expansion over the entire microspore surface (type II). Two-thirds of embryogenic microspores in bothB. napus andB. oleracea demonstrated type I development. When followed by fluorescence microscopy, in vitro culture of microspores revealed cultures with a high embryo frequency were those with a high frequency of symmetrical division.Abbreviations SEM Scanning electron microscopy - TEM Transmission electron microscopy     

Transforming petals into sepaloid organs in<Emphasis Type="Italic"> Arabidopsis</Emphasis> and oilseed rape: implementation of the hairpin RNA-mediated gene silencing technology in an organ-specific manner

Oilseed rape (Brassica napus L.) genotypes with no or small petals are thought to have advantages in photosynthetic activity. The flowers of field-grown oilseed rape form a bright-yellow canopy that reflects and absorbs nearly 60% of the photosynthetically active radiation (PAR), causing a severe yield penalty. Reducing the size of the petals and/or removing the reflecting colour will improve the transmission of PAR to the leaves and is expected to increase the crop productivity. In this study the hairpin RNA-mediated (hpRNA) gene silencing technology was implemented in Arabidopsis thaliana (L.) Heynh. and B. napus to silence B-type MADS-box floral organ identity genes in a second-whorl-specific manner. In Arabidopsis, silencing of B-type MADS-box genes was obtained by expressing B. napus APETALA3 (BAP3) or PISTILLATA (BPI) homologous self-complementary hpRNA constructs under control of the Arabidopsis A-type MADS-box gene APETALA1 (AP1) promoter. In B. napus, silencing of the BPI gene family was achieved by expressing a similar hpRNA construct as used in Arabidopsis under the control of a chimeric promoter consisting of a modified petal-specific Arabidopsis AP3 promoter fragment fused to the AP1 promoter. In this way, transgenic plants were generated producing male fertile flowers in which the petals were converted into sepals (Arabidopsis) or into sepaloid petals (B. napus). These novel flower phenotypes were stable and heritable in both species.Abbreviations PAR photosynthetically active radiation - ST-LS1 potato light-inducible tissue-specific ST-LS1 gene - GUS -glucuronidase     

Transfer of hygromycin resistance into Brassica napus using total DNA of a transgenic B. nigra line

The successful transfer of a marker gene (hpt gene) from Brassica nigra into B. napus via direct gene transfer was demonstrated. Total DNA was isolated from a hygromycin-resistant callus line, which contained three to five copies of the hpt gene. This line had been produced via direct gene transfer with the hygromycin resistance-conferring plasmid pGL2. The treatment of B. napus protoplasts with genomic DNA of B. nigra (Hyg^R) resulted in relative transformation frequencies of 0.1–0.4%. Similar transformation rates were obtained in direct gene transfer experiments using B. napus protoplasts and plasmid pGL2.     

Production and cytogenetics of intergeneric hybrids between Brassica napus and Orychophragmus violaceus

The intergeneric hybrid between Brassica napus and Orychophragmus violaceus was obtained by means of embryo culture technique with the latter as the pollen parent. The hybrid was morphologically intermediate between its parents, but could produce a lot of seeds when selfed. Somatic separation of the genomes from the two parental species was observed during the mitotic divisions of some of the hybrid cells. Thus, the hybrid became the mixoploid in nature, consisting of haploid and diploid cells of B. napus, and a nuclear — cytoplasmic hybrid, with the cytoplasm of B. napus and the nuclei of O. violaceus, and the hybrid cells. Pollen mother cells with 19, 12 and 6 bivalents, respectively, were produced by the hybrid. From the selfed progeny of the hybrid, mainly two kinds of plants, B. napus and the hybrid, were found. The hybrid plants of the selfed progeny again produced two kinds of plants, B. napus and the hybrid.     

Isolation and Characterization of an Anther-Specific Polygalacturonase Gene, BcMF16, in Brassica campestris ssp. chinensis

Many genes in the genic male sterile A/B line (Bajh97-01A/B) of Chinese cabbage pak choi (Brassica campestris L. subsp. chinensis Makino) are expressed differentially, and some play critical roles in the formation of pollen walls. In this study, one of these genes, Brassica campestris Male Fertility 16 (BcMF16), has been isolated and characterized. The BcMF16 gene shares approximately 85% nucleotide sequence homology with two exopolygalacturonase (EC3.2.1.67) genes of Arabidopsis thaliana. Cluster analysis of polygalacturonase peptides indicate that BcMF16 belongs to the pollen polygalacturonase clade. Quantitative real-time PCR analysis has revealed that BcMF16 is specifically expressed in reproductive tissues of the fertile line of genic male sterile A/B line of Chinese cabbage pak choi, and that expression levels dramatically increased during later stages of pollen development. In situ hybridization has demonstrated that BcMF16 is specifically and transiently expressed in both tapetum and pollen following microspore separation at the tetrad stage.     

Mitochondrial DNA decreases during pollen development in rapeseed (Brassica napus L.), but mitochondrial linear-plasmid-encoded RNA polymerase persists in mature pollen

Summary. Mitochondrial DNA in the male reproductive cells of rapeseed (Brassica napus L.) was monitored by fluorescence microscopy of Technovit 7100 resin sections double-stained with 4,6-diamidino-2-phenylindole and 3,3-dihexyloxacarbocyanine iodide. Mitochondrial DNA progressively decreased during pollen development and disappeared in mature pollen. This result corresponds well with the maternal inheritance of mitochondria in rapeseed determined by previous genetic analyses. To better characterize the mode of inheritance of the mitochondrial linear plasmid in rapeseed, which is transmitted through pollen, we analyzed by indirect immunofluorescence microscopy the expression and localization of ORF6 protein, a putative RNA polymerase encoded by the plasmid. ORF6 protein was expressed in mature pollen and specifically localized in the cytoplasm of sperm cells in the mature pollen. This suggests that the genes encoded by the plasmid DNA are transcribed in the mature pollen by its own RNA polymerase (ORF6 protein) and that the gene expression in the generative cells may be needed for transmission of plasmid DNA through the pollen.Present address: Laboratory of Plant Molecular Biology, Nara Institute of Science and Technology, Ikoma, Nara, Japan.Correspondence and reprints: Department of Plant Biotechnology, National Institute of Agrobiological Sciences, 2-1-2 Kan-non-dai, Tsukuba 305-8602, Japan.