Effects of specific expression of iaaL gene in tobacco tapetum on pollen embryogenesis

The indoleacetic-acid-lysine synthetase (iaaL) gene from Pseudomonas syringae subsp. savastanoi was fused to tobacco tapetum-specific expression promoter TA29, and introduced into tobacco. The expression pattern of this chimeric gene was studied, and the endogenous indoleacetic acid (IAA) levels in different organs were assayed. The results demonstrated that TA29 promoter was only able to direct the specific expression of iaaL gene in transgenic tobacco anther, and resulted in the decrease of endogenous IAA levels in transgenic tobacco anther. No significant phe-notype variation was observed among the transgenic plants at the whole plant level. However, the percentage of pollen embryogenesis was reduced to 11 % when anthers of the transgenic plants were cultured on the modified hormone-free Nistch H (NH) medium, while those of both CK1 and CK2 (see sec. 1.2.2) were more than 50% ; when the an-thers were cultured on NH medium supplemented with 0. 2 mg/L IAA, the percentage of pollen embryogenesis re-stor     

Differential expression of antisense in regenerated tobacco plants transformed with an antisense version of a tomato ACC oxidase gene

Ethylene production was measured during vegetative and reproductive development in normal tobacco plants and in transgenic tobacco plants carrying antisense genes for tomato ACC oxidase driven by the 35S CaMV promoter (Hamilton et al., 1990). When expressed in three independently derived transgenic plants, the antisense ethylene gene failed to affect ethylene production in young/mature leaves or in stems but it did inhibit ethylene production in roots by 37–58%. Ethylene production in developing flowers (i.e. from small unopened flower buds up until open flowers at anthesis) was not affected in transgenic plants but ethylene production in fruits was inhibited by 35%. The most dramatic effect on ethylene production in transgenic plants was seen immediately after wounding leaf tissue, in which case the antisense gene inhibited wound ethylene production by 72%. Thus, the antisense gene composed of a 35S CaMV promoter driving a heterologous ACC oxidase sequence had differential effects on ethylene production in tobacco plants.     

The indoleacetic acid-lysine synthetase gene of Pseudomonas syringae subsp. savastanoi induces developmental alterations in transgenic tobacco and potato plants

Summary The iaaL gene of Pseudomonas syringae subsp. savastanoi encodes an indoleacetic acid-lysine synthetase that conjugates lysine to indoleacetic acid. A chimaeric gene consisting of the iaaL coding region under the control of the 35S RNA promoter from cauliflower mosaic virus (35SiaaL) has been used to test if iaaL gene expression leads to morphological alterations in tobacco and potato. Transgenic tobacco plantlets bearing this construct have been shown to synthesize IAA-[¹⁴C]lysine when fed with [¹⁴C]lysine. In late stages of development, their leaves show an increased nastic curvature (epinasty) of the petiole and midvein, a finding suggestive of an abnormal auxin metabolism. The alteration is transmitted to progeny as a dominant Mendelian trait cosegregating with the kanamycin resistance marker. Transgenic potato plants harbouring the construct are also characterised by petiole epinasty. Moreover, 35SiaaL transgenic plants have an increased internode length in potato and decreased root growth in both tobacco and potato. An increased content of IAA-conjugates in leaf blade was found to correlate with the epinastic alterations caused by iaaL gene expression in tobacco leaves. These data provide evidence that IAA conjugation is able to modulate hormone action, suggesting that the widespread endogenous auxin-conjugating activities are of physiological importance.     

Free and Conjugated Indoleacetic Acid (IAA) Contents in Transgenic Tobacco Plants Expressing the iaaM and iaaH IAA Biosynthesis Genes from Agrobacterium tumefaciens

The Agrobacterium tumefaciens T-DNA gene iaaM was introduced by leaf-disc transformation into transgenic tobacco (Nicotiana tabacum) plants expressing the iaaH gene. Regenerated calli were screened for the presence of indole-3-acetamide (IAM), by gas chromatography-multiple ion monitoring-mass spectrometry, and IAM-containing calli were further analyzed for free and conjugated indoleacetic acid (IAA). It was found that transgenic calli on average contained twice as much free IAA and three times more conjugated IAA than calli from wild-type plants. About 40% of the transformed calli could be regenerated to plants. The distribution of free and conjugated IAA was measured in transformed plants with a normal phenotype and compared with equivalent wild-type plants. The IAA content of transgenic plants was only slightly increased, whereas IAA-conjugate levels were enhanced significantly. These data suggest that conjugation of IAA may serve as a regulatory mechanism, contributing to maintenance of steady-state IAA pool sizes during tobacco growth and development.     

Functional analysis of an <Emphasis Type="Italic">iaaM</Emphasis> gene in parthenocarpic fruit development in transgenic <Emphasis Type="Italic">Physalis pubescens</Emphasis> L. plants

An efficient somatic embryogenesis system for Physalis pubescens L. (husk tomato) was developed prior to transformation. Subsequently, cotyledonary explants of P. pubescens were transformed with a chimeric construct containing an iaaM gene from driven by the fruit-specific promoter 2A12 to develop parthenocarpic fruits. Following selection of explants on Murashige and Skoog (MS) medium containing containing 75 mg l⁻¹ kanamycin (Km), 36 km-resistant callus clusters were recovered, and these were regenerated into whole plants. Expression of the iaaM gene was detected in confirmed transgenic fruits. The 0.9-kb 2A12 promoter was capable of directing expression of the introduced iaaM gene in transgenic P. pubescens fruits, but iaaM expression was absent from both leaves and flowers. Quantitative measurements of indole-3-acetic acid (IAA) content during fruit development indicated that the IAA levels in transgenic lines increased from anthesis through young fruits and peaked at fruit maturity. On average, IAA contents in transgenic fruits were two-fold higher than those in control fruits. Under greenhouse condition, vegetative growth, morphology, and the flowering of transgenic plants were comparable to those of control plants. However, the fruits of transgenic lines ripened earlier and had fewer seeds per fruit than did control plants.     

Vascular bundle specific expression of iaaL gene affects the generation frequencies of transgenic tobacco]

A vascular bundles specific expressing vector pBAL1 with a promoter AQ630 from rice phenylalanine ammonialyase gene and a gene encoding indoleacetic-lysine synthytase from Pseudomonas syringae subsp. savastanoi was constructed. Affirmed by Southern blotting and RTPCR analysis, the AQ630-iaaL transgenic plants show increasing shoots-regeneration frequency of young stem explants on hormone-free 1/2 MS medium and lower sensibility to IAA when roots were induced from the root explants on the media containing different concentrations of IAA compared to untransformed plants.     

IaaL基因的维管束特异表达导致烟草茎和根外植体分化能力的改变

我们利用水稻苯丙氨酸解氨酶启动子(AQ630)和吲哚乙酰胺赖氨酸酯合成酶基因(iaaL)构建了维管束特异表达的植物表达载体pBAL1并导入烟草基因组中。比较了对照植株、转基因植株的幼茎和根外植体在组织培养中分化能力的变化,结果表明转基因植株茎外植体的不定芽形成明显受到促进,而转化植株根外植体在不定根发生方面对外源IAA的敏感性下降。     

光敏启动子控制的酵母Hem1基因在烟草中表达

拟南芥hemA1基因启动子是一种光响应型启动子,它控制着植物体内5-氨基乙酰丙酸(ALA)昼夜节律型合成.将该启动子与酿酒酵母Hem1基因构建的二价载体转入烟草中,获得转基因植株.以转二价基因的烟草T0代种子为材料,用不同浓度卡那霉素(Km)溶液浸种,结果显示,种子发芽率和子叶绿化率随着Km浓度升高而降低.将1 000 mg·L-1Km溶液中长出的162株抗性植株移植至盆钵中培养,GUS检测出的阳性比率为92%.用特异引物PCR法检测Km抗性-GUS阳性植株,发现含有拟南芥HemA1基因启动子的比率为92.5%,含有酿酒酵母Hem1基因的比率为88%,含有二价重组基因的比率为84.2%.RT-PCR检测表明,Hem1基因在黑暗中的表达量明显低于光照下,证明光敏启动子有效地控制了结构基因Hem1的表达.生理指标分析表明,与野生型相比,转基因植株ALA合成速率、叶绿素含量明显增加,叶绿素b/a比值提高.野生型植株基部叶片SPAD值显著降低,而转基因植株基部叶片SPAD值保持较高水平.以上结果说明,外源二价基因已经成功整合到烟草基因组中,并且能够在光照条件下过量表达,合成过量ALA.     

Fruit-specific overexpression of wound-induced tap1 under E8 promoter in tomato confers resistance to fungal pathogens at ripening stage

Based on high economic importance and nutritious value of tomato fruits and as previous studies employed E8 promoter in fruit ripening-specific gene expression, we have developed transgenic tomato plants overexpressing tomato anionic peroxidase cDNA (tap1) under E8 promoter. Stable transgene integration was confirmed by polymerase chain reaction (PCR) and Southern analysis for nptII. Northern blotting confirmed elevated tap1 levels in the breaker- and red-ripe stages of T(1) transgenic fruits, whereas wild-type (WT) plants did not show tap1 expression in these developmental stages. Further, tap1 expression levels were significantly enhanced in response to wounding in breaker- and red-ripe stages of transgenic fruits, whereas wound-induced expression of tap1 was not detected in WT fruits. Confocal microscopy revealed high accumulation of phenolic compounds at the wound site in transgenic fruits suggesting a role of tap1 in wound-induced phenolic polymerization. Total peroxidase activity has increased remarkably in transgenic pericarp tissues in response to wounding, while very less or minimal levels were recorded in WT pericarp tissues. Transgenic fruits also displayed reduced post-harvest decay and increased resistance toward Alternaria alternata and Fusarium solani infection with noticeable inhibition in lesion formation. Conidiospore germination and mycelial growth of F. solani were severely inhibited when treated with E8-tap1 fruit extracts compared to WT fruits. 3-(4,5-Dimethylthiazol-2-yl)-2, 5-diphenyltetrazolium bromide assay showed reduced spore viability when incubated in E8-tap1 fruit extracts. Thus, fruit-specific expression of tap1 using E8 promoter is associated with enhanced total peroxidase activity and high phenolic accumulation in fruits with minimized post-harvest deterioration caused by wounding and fungal attack in tomato fruits.     

Prevention of flower formation in dicotyledons

Prevention of flower formation is important, for example for preventing the spread of transgenes from genetically modified plants or the spread of non-native species, for increasing vegetative growth or preventing the formation of allergenic pollen. The aim of this study was to determine whether flowering of dicotyledonous plants can be prevented by genetic manipulation without harmful effects on vegetative growth. Here we describe isolation of the BpMADS1 gene (similar to SEP3, formerly AGL9) from birch and show that it is expressed only in the inflorescences. In tobacco and Arabidopsis, the expression of BpMADS1::GUS was also virtually inflorescence-specific. Transgenic tobacco and Arabidopsis containing a BpMADS1::BARNASE construct grew well. In one tobacco line the formation of the inflorescence was completely prevented; in several other lines the flowers lacked stamens and carpels and therefore were sterile. The final dry weights of the shoots of the sterile tobacco lines were 140–200% of those of controls. In Arabidopsis, some of the transgenic lines containing the BpMADS1::BARNASE construct formed inflorescences. Some of these lines formed never flowers and some others formed occasionally single fertile flowers. Some other lines did not form inflorescences, but formed up to about one hundred leaves, even in long-day conditions. These results suggest that formation of flowers or inflorescences in widely different dicotyledonous plants could be prevented using the BpMADS1::BARNASE construct and that prevention of flowering may lead to increased vegetative mass.