导入LPAAT和KCS基因对油菜种子芥酸含量的影响

采用农杆菌介导法,以下胚轴为转化受体,将溶血性磷脂酸酰基转移酶（LPAAT）和酮脂酰辅酶A合成酶（KCS）基因导入2种不同基因型（“Drakkar”和“Maplus”）的甘蓝型油菜,共获得247株再生植株,其再生频率分别为15.1%和2.0%。PCR检测和Southern杂交分析证实,外源基因已整合到油菜基因组中,转化频率分别为3.6%和0.7%。种子中芥酸含量因外源基因的导入使零芥酸油菜“Drakkar”提高到10.5%,高芥酸品种“Maplus”提高了5.0%,最高达62.8%。     

Transforming the plastome: genetic markers and DNA delivery systems

Summary Stable chloroplast transformants were first obtained following particle bombardment of tobacco leaves, and later by PEG-mediated uptake of DNA by protoplasts. The transforming DNA in these studies was itself of plastid origin and carried double (streptomycin, spectinomycin) antibiotic resistance which was used to select transformants. Integration was by homologous recombination, and both donor and recipient were Nicotiana species. Recent characterisation of plastid mutants of Solanum nigrum has allowed the extension of this gene replacement approach to include Nicotiana:Solanum combinations.The introduction of functional heterologous genes into the plastome is an alternative approach based on the use of constructs in which a bacterial resistance gene is flanked by sequences homologous to a region of the recipient plastome. Thus homologous recombination in the flanking sequences allows introduction of a foreign gene. A large number of putative transformants can be generated by the method, but this apparent attraction is partly offset by the need for repeated cycles of re-selection to obtain homoplasmic plants. In contrast, homoplasmy can be accomplished in a single selection step using plastome-encoded antibiotic resistance markers.The plastome is an attractive target for the introduction of useful genes into crop plants, as maternal inheritance acts as an insurance against unwanted spread of the foreign gene, and the large plastome copy number ensures immediate gene amplification and may influence levels of expression. Specific characters encoded on the plastid DNA, including components of photosynthesis and other aspects of metabolism, will also become open to manipulation as a consequence of developments in plastid transformation.     

The Introduction of Transgenes to Control Blackheart in Pineapple (Ananas Comosus L.) cv. Smooth Cayenne by Microprojectile Bombardment

Summary A transformation technique for the introduction of transgenes to control blackheart by particle bombardment has been developed for pineapple cv. Smooth Cayenne. Leaf callus cultures capable of high frequency organogenesis with a short regeneration time were used as explant material. Gus and gfp reporter genes were used to observe and determine transient and stable expression. The ppo gene, isolated from pineapple, was introduced to control blackheart. Co-transformation occurred with constructs containing the nptII gene conferring geneticin resistance. We have recovered 15 independent transgenic gus and gfp lines each from 8 separate experiments and 22 ppo lines from 11 experiments. Gus, gfp, ppo and nptII positive plants have been regenerated, which have been shown by Southern blot analysis to be stable transgenics containing multiple copies of the introduced genes. These results show that biolistic gene delivery in pineapple can be successfully achieved at an acceptable efficiency of 0.21–1.5% for genetic improvement of ’Smooth Cayenne’, the industry standard throughout the world.     

Transgenic apples display stable gene expression in the fruit and Mendelian segregation of the transgenes in the R1 progeny

Summary The transfer of genes via Agrobacterium to a perennial tree crop such as apple, requires monitoring of the stability of the genes in the target tissues such as the fruit and leaves. If the same genes are required for introgression into a conventional breeding programme, their expression also needs to be stable and their inheritance should follow a normal Mendelian pattern. In the following report we show, for the first time, the stable expression and Mendelian segregation of transgenes in a tree species. We have evidence for a 1:1 segregation of the nos and nptII genes among R1 progeny from a transgenic apple parent. In addition, we present evidence for stable gene expression of both nos and the co-transferred gene nptII in the flesh of apple fruit 7 years after the initial transformation.Abbreviations nos nopaline synthase - nptII neomycin phosphotransferase - ACC 1-aminocyclopropane carboxylic acid - PVP polyvinylpyrrolidone - PCR polymerase chain reaction - EFE ethylene forming enzyme - B.t. Bacillus thuringiensis     

Transformation of modified cowpea trypsin inhibitor gene and anti-bacterial peptide gene in Brassica pekinensis protoplasts mediated by Agrobacterium tumefaciens

Summary A transformation system for Chinese cabbage protoplasts was developed using Agrobacterium tumefaciens strain LBA4404 (harbouring the plasmid pBinΩSCK and the plasmid pMOG 411 respectively). The plasmid pBinΩSCK contains a 415 bp insert derived from the Cowpea trypsin proteinase inhibitor gene and The plasmid pMOG 411 contains a 870 bp fragment which codes an anti-bacterial peptide gene. Freshly isolated protoplasts of Chinese cabbage (Brassica campestris L.ssp.pekinensis) lines were pre-treated at 4 ^∘C for 1 h, then incubated at 25 ^∘C for 2–3 days in the dark. 3 drops of A. tumefaciens solution in log-phase were added to 10 ml protoplasts and cocultivated for 48 h at 25 ^∘C. Some kanamycin-resistant plants and a number of kanamycin-resistant calli were obtained. Southern blot hybridization analysis demonstrated the presence of the CpTI gene and the anti-bacterial peptide gene in the Chinese cabbage genome. Northern blot analysis of the kanamycin-resistant plantlets and calli confirmed the accumulation of the CpTI and the anti-bacterial peptide mRNAs.     

Genetic transformation of Eustoma grandiflorum Griseb. by microprojectile bombardment

Summary Foreign DNA was introduced into cell suspension cultures and leaf tissue of Eustoma grandiflorum Griseb. (lisianthus) by microprojectile bombardment. For this purpose a low-cost bombardment device that uses a helium flux to accelerate microprojectiles was built. When cell suspensions were used, an average of 4.1 Kan resistant calli were recovered per shot after 4 months' cultivation on selective medium. Most of the Kan resistant plants regenerated from calli were positive to GUS assay. Both the nptII and gus genes were successfully amplified from alkali-treated leaves of putative transgenic plants by PCR analysis. Transgenic plants were not recovered from bombarded leaves. Considering the host range specificity of Agrobacterium, and the response of the species to plant regeneration from suspension culture, microprojectile bombardment is, at present, the most efficient procedure for genetic transformation of lisianthus.Abbreviations BA 6-benzyladenine - Cx cefotaxime - 2,4 D (2,4-dichlorophenoxy) acetic acid - FDA fluorescein diacetate - gus -glucuronidase - IAA indole-3-acetic acid - IBA indole-3-butyric acid - 2iP (2-isopentenyl) adenine - Kan kanamycin - nptII neomycin phosphotransferase II - PCR polymerase chain reaction     

Agrobacterium-mediated genetic transformation and production of semilooper resistant transgenic castor (Ricinus communis L.)

Summary Semilooper resistant transgenic castor plants were produced through Agrobacterium-mediated genetic transformation method. Two castor cultivars, Jyothi and VP1 were transformed using the super-binary vector pTOK233 carrying gus A and hpt genes. Putative transformants were regenerated following selection on the hygromycin containing medium. GUS positive primary transformants, when subjected to Southern analysis, revealed stable integration of gus A into their genomes. In the T₁ generation, a monogenic segregation ratio of 3 GUS positive: 1 GUS negative plants was observed. Furthermore, transformation experiments were carried out with the Agrobacterium pSB111 super-binary vector carrying a synthetic delta endotoxin gene cryIAb and the herbicide resistance gene bar both driven by cauliflower mosaic virus 35S promoter. Putative transformants were regenerated through selection on the phosphinothricin containing medium and Basta tolerant transformants were subjected to molecular analysis. PCR analysis revealed the presence of both bar and cryIAb genes in the Basta tolerant primary transformants. Southern analysis of PCR positive plants with cryIAb probe showed a 3 Kb band upon HindIII digestion and a > 6 Kb band with BamHI digestion, thus suggesting stable integration of cryIAb intact expression cassette and independent nature of the transformants. The primary transformants subjected to ELISA disclosed varied levels of Cry protein. These transgenics expressing cryIAb – when bioassayed against freshly hatched semilooper larvae – induced substantial (> 88%) insect mortality. Southern analysis of 2T₁ plants revealed the presence of cryIAb gene, indicating stable inheritance of the transgene into the next generation. In T₁, all the Southern-positive plants for cryIAb invariably exhibited tolerance to Basta, denoting co-segregation of both bar and cryIAb genes. Transgenics, expressing cryIAb exhibited ample resistance against the castor semilooper.     

Development of interspecific somatic hybrid cell lines in cultivated jute and their early characterization using jute chloroplast RFLP marker

A strong sexual incompatibility barrier that exists between the two cultivated jute species, Corchorus capsularis and Corchorus olitorius, limits the scope for improvement through genetic introgression. Protoplast fusion was carried out to generate interspecific hybrid cell lines. Cotyledonary cell protoplasts of C. capsularis and anthocyaninpigmented hypocotyl protoplasts of C. olitorius were used in the fusion experiments, which appeared to be visually useful in the early selection of the fused products. A chloroplast DNA (cpDNA) marker was developed in jute, which showed species‐specific hybridization patterns with EcoRI‐digested total genomic DNA of C. capsularis and C. olitorius. This cpDNA marker was used in the characterization of the somatic hybrid cell lines at their early stages of growth. Evidence for the presence of both types of cpDNA in the hybrid cell lines was obtained when the total genomic DNA of 4‐ to 7‐month‐old hybrid cell lines was challenged with the chloroplast DNA marker through Southern analysis. It was shown that the early segregation of the parental chloroplasts did not occur in jute, although this is common in other plant species. The hybrid nature of the fused cell lines could also be identified through peroxidase isozyme analysis. Isozyme banding patterns were complex and varied among the hybrid cell lines.     

Transgenic barley by particle bombardment. Inheritance of the transferred gene and characteristics of transgenic barley plants

Summary Transgenic barley plants (Hordeum vulgare L. cv. Kymppi) were obtained by particle bombardment of various tissues. Immature embryos and microspore-derived cultures were bombarded with gold particles coated with plasmid DNA carrying the gene coding for neomycin phosphotransferase II (NPTII), together with plasmid DNA containing the gene for -glucuronidase (GUS).Bombarded immature embryos were grown to plants without selection and NPTII activity was screened in small plantlets. One plant proved to be transgenic (T₀). This chimeric plant passed the transferred nptII gene to its T₁ progeny. The presence of the nptII gene was demonstrated by the PCR technique and enzyme activity was analyzed by an NPTII gel assay. Four T₀ spikes and 15 T₁ offspring were transgenic. The integration and inheritance was confirmed by Southern blot hybridization. Transgenic T₂ and T₃ plants were produced by isolating embryos from green grains of transgenic T₁ and T₂ plants, respectively and growing them to plants. After selfing, the ratio of transgenic to non-transgenic T₂ offspring was shown to follow the rule of Mendelian inheritance. The general performance of transgenic plants was normal and no reduction in fertility was observed.Microspore-derived cultures were bombarded one and four weeks after microspore isolation. After bombardment, cultures were grown either with or without antibiotic selection (geneticin ^R or kanamycin). When cultures were grown without selection and regenerated plants were transferred to kanamycin selection in rooting phase, one out of a total of about 1500 plants survived. This plant both carried and expressed the transferred nptII gene. The integration was confirmed by Southern blot hybridization. This plant was not fertile.     

High-efficiency transformation of Gossypium hirsutum embryogenic calli mediated by Agrobacterium tumefaciens and regeneration of insect-resistant plants

A simple protocol of transformation of cotton (Gossypium hirsutum L.) at a high frequency has been developed via Agrobacterium mediation, coupled with the use of embryogenic calli as explants. Embryogenic calli derived from only one to two somatic embryogenic calli lines of two Chinese cotton cultivars, the cvs. Ekang 9 and Jihe 321 which have low embryogenic potency were first inoculated with the A. tumefaciens strain LBA4404 harbouring binary vector pBin438 carrying a synthetic Bacillus thuringiensis‐active Cry1Ac and API‐B chimeric gene. Infected embryogenic calli were co‐cultivated for 48 h and were then moved on to the selection medium with kanamycin (100 mg/l) for 7‐8 weeks. Then, the kanamycin‐resistant calli (Km¹) subcultured in proliferation medium would re‐differentiate to form somatic embryos in 30 days. Cotyledon embryos were transferred to 100‐ml Erlenmeyer flasks for germination and regeneration. Putative transformants were confirmed by polymerase chain reaction and Southern blot analysis. Forty‐five regenerated plants were successfully transferred to soil, of which 12 proved to have the active Cry1Ac and API‐B chimeric gene. Insect resistance was tested by bioassay. The transgenic plants were highly resistant to cotton bollworm (Heliothis armigera) larvae, with mortality (insect resistance) ranging from 95.8 to 100%. In comparison with the methods used in Agrobacterium‐mediated transformation of cotton hypocotyls or cotyledons, about 6 months are saved by using the method presented in this paper to obtain a large number of transgenic plants.     

Production and molecular characterization of Citrus intergeneric somatic hybrids between red tangerine and citrange

Somatic hybridization has been an effective and successful technique for plant improvement. In this paper, embryogenic callus protoplasts of red tangerine (Citrus reticulata Blanco) were electrically fused with mesophyll protoplasts from citrange (C. sinensis × P. trifoliata, a Chinese local strain) in an effort to produce complementary tetraploid citrus rootstocks. Regenerated embryoids grew slowly and were vulnerable to browning. Twelve plants were finally regenerated, rooted and transplanted into a greenhouse. Root‐tip chromosome counting of five randomly‐selected plants revealed most cells were tetraploid (2n = 4x = 36), but aneuploid cells also existed. Flow cytometry analysis further confirmed their tetraploid nature. Nuclear simple sequence repeat (SSR) analysis verified their hybridity. Further mitochondrial genome analysis by restriction fragment length polymorphism and cleaved amplified polymorphic sequence revealed their mtDNA banding pattern was identical to that of red tangerine, the embryogenic callus parent; while their chloroplast DNA inheritance was random as revealed by chloroplast SSR analysis, in addition to cpDNA co‐existence detected in one plant. Cytological and molecular analysis indicated that somatic hybrid plants between red tangerine and citrange had been successfully obtained.     

Development of yellow-seeded Brassica napus of double low quality

Two yellow‐seeded white‐petalled Brassica napus F₇ inbred lines, developed from interspecific crosses, containing 26–28% emcic acid and more than 40 μmol glucosinolates (GLS)/g seed were crossed with two black/dark brown seeded B. napus varieties of double low quality and 287 doubled haploid (DH) lines were produced. The segregation in the DH lines indicated that three to four gene loci are involved in the determination of seed colour, and yellow seeds are formed when all alleles in all loci are in the homozygous recessive state. A dominant gene governed white petal colour and is linked with an erucic acid allele that, in the homozygous condition, produces 26–28% erucic acid. Four gene loci are involved in the control of total GLS content where low GLS was due to the presence of recessive alleles in the homozygous condition in all loci. From the DH breeding population a yellow‐seeded, yellow‐petalled, zero erucic acid line was obtained. This line was further crossed with conventional B. napus varieties of double low quality and, following pedigree selection, a yellow seeded B. napus of double low quality was obtained. The yellow seeds had higher oil plus protein content and lower fibre content than black seeds. A reduction of the concentration of chromogenic substances was found in the transparent seed coat of the yellow‐seeded B. napus.     

Further Characterization of rollC Transgenic Tetraploid Potato Clones, and Influence of Daylength and Level of rolC Expression on Yield Parameters

Tetraploid rolC transformants have been analyzed considering the level of rolC expression and yield parameters. In rolC transformants a maximum of five integrated copies of the gene were detected by Southern analysis. A relation between copy number of the rolC gene, phenotypic rolC expression and intensity of morphological alterations was established. Three experiments were performed to assess the differential effect of the rolC gene on yield and its interaction with growth factors. In the first experiment, the influence of day length on plant morphological and physiological characters was studied. The phenotype of the transgenic plants with a low rolC expression was like the control under the two day-regimes tested, while the intermediate expressing genotype showed a different reaction. In the second and third experiment, tuber yield, tuber number and weight per tuber were recorded under short and long day conditions. When grown in smaller pots of 1.15 1 volume, the control plants had the highest yield of tubers under both day lengths tested. Yield decreased with increasing rolC expression. Tuber number revealed to be genotype dependent: it was higher for low rolC expressing plants and lower for intermediate rolC transformants (Experiment 2). In the third experiment the influence of variable pot size and shape was analyzed for one clone with intermediate and two with low level of rolC expression. Remarkable differences between pots and flat boxes of the same volume were noted for tuber yield and number: Under the two conditions the control clone and the low rolC expressing genotypes gave similar tuber yield and number in both growth containers, whereas the rolC intermediate genotype yielded significantly more in flat boxes. The effect of variable hormonal levels induced in transgenic plants through prokaryotic genes are discussed with the existence of non-predictable genotype in relation to environmental interactions. It is concluded that at least the agronomic performance of potatoes transformed with these genes cannot be predicted on the basis of simple linear relationships among the expression of the gene and of the traits.     

Erucic acid heredity in Brassica juncea - some additional information

Genetic studies were undertaken to reassess erucic acid heredity in Brassica juncea. Analysis of segregation in F₂ and BC₁ generations from two zero × high erucic acid crosses indicated that higher erucic acid in B. juncea was controlled by two dominant genes with additive effects, whereas segregation in a cross involving ‘CCWF 16′, a genotype having intermediate erucic acid (25.6%), and a zero erucic acid strain, indicated monogenic dominant control for intermediate erucic acid content. The B. juncea strain ‘CCWF 16’ was developed by hybridizing high‐erucic acid B. juncea cv.‘WF‐1’ with a ‘0’ erucic B. rapa cv.‘Candle’ followed by backcrossing with ‘WF‐1’ and half‐seed selection for low erucic acid in each backcross generation. This strategy resulted in substitution of the high erucic acid allele present in the A genome of B. juncea (AABB) by the zero erucic acid allele associated with ‘A’ genome of ‘Candle’. The intermediate erucic acid content in ‘CCWF 16’ was thus attributed to a gene present in the ‘BB’ genome. Experimental data clearly suggested that the gene (E₂) associated with the A genome had a greater contribution to the total erucic acid content in B. juncea than the gene (E₁) located on the B genome. This provided experimental evidence for a previous suggestion of unequal contributions of two dominant genes (E₁= 12%, E₂= 20%) to high erucic acid content in conventional digenomic Brassica species.     

Mapping of male sterility gene ms10 in chilli pepper (Capsicum annuum L.)

Most of the hybrid seed in chilli are produced manually, but the use of male sterility (MS) can reduce the cost of hybrid seed production. MS‐12, a nuclear male‐sterile (NMS) line developed at Punjab Agricultural University, Ludhiana (India), has been utilized to develop commercial F₁ hybrids. A recessive gene, designated as ms10, governs MS in MS‐12. Due to recessive gene control, development of new NMS lines incorporating ms10 gene is tedious and time‐consuming. We identified SSR markers AVRDC‐PP12 and AVRDC_MD997* linked to the ms10 gene. A total of 558 primer pairs were screened following bulked segregant analysis (BSA). Linkage analysis in 210 F₂ plants indicated that the two SSR markers were linked to the ms10 gene and the marker AVRDC‐PP12 was closest to the gene at 7.2 cM distance. The marker was mapped to chromosome 1 at genome position 175 694 513 to 175 694 644. Until more closely linked markers are developed, the marker AVRDC‐PP12 would facilitate transfer of ms10 gene through marker‐assisted selection (MAS). Fine mapping would lead to cloning of the ms10 gene.     

Modification of oilseed rape to produce oils for industrial use by means of applied tissue culture methodology

Summary A programme of research was designed to investigate methods for the modification of the fatty acid profiles of high performance lines of oilseed rape (Brassica napus L.) in an attempt to produce lines with enhanced levels of industrially useful fatty acids. The methodology employed to achieve these objectives was based on the exploitation of somaclonal or protoclonal variation, and targeted somatic hybridization using wild cruciferous germplasm as fusion partners.A range of somaclonal lines was produced from shoot regeneration protocols. These lines underwent replicated, randomised glasshouse trials for morphological assessment followed by gas chromatographic analysis to monitor any changes in fatty acid profile. It was found that a small number of lines exhibited potentially useful changes in oleic acid and polyunsaturated fatty acid content. Protoplast regeneration and electrofusion protocols for a range of winter oilseed rape lines were developed, and methods for the isolation and fusion of protoplasts of the wild crucifer Lunaria annua (chosen for its high nervonic acid content) established.Abbreviations GC Gas Chromatography     

Effect of ethylene on Agrobacterium tumefaciens-mediated gene transfer to melon

The effect of ethylene on gene transfer mediated by an Agrobacterium tumefaciens harbouring a binary vector with the β‐glucuronidase (uid A) gene was investigated in melon, Cucumis melo L. Explants excised from melon cotyledons produced ethylene, the production of which was increased by the addition of 1‐aminocyclopropane‐1‐carboxylic acid (ACC, 20 or 200 μM), and inhibited by the addition of aminoethoxy‐vinylglycin (AVG, 10 μM). Agrobacterium inoculation of explants increased ethylene production, while application of AVG during inoculation reduced it. After 4 days of co‐cultivation with Agrobacterium, gene transfer in the explants was assayed by transient uid A expression. Application of ACC to the co‐cultivation medium reduced Agrobacterium‐mediated gene transfer to explants and that of AVG increased it. These results suggest that ethylene affects the A. tumefaciens‐mediated gene transfer to the explants excised from melon cotyledons, and the efficiency of Agrobacterium‐mediated gene transfer can be improved by inhibiting ethylene production from the explants.