Iron accumulation in tobacco plants expressing soyabean ferritin gene

High iron-content transgenic tobacco plants have been produced by transfer via Agrobacterium tumefaciens of soyabean ferritin cDNA under the control of a CaMV 35S promoter. Immunoblot analysis of protein from transgenic tobacco plants suggested mature ferritin subunits are produced by cleavage of transit peptides. The expressed ferritin was observed in the tissues of leaves and stems. The maximal iron content of transformant leaves was approximately 30% higher than leaves from non-transformants. The increased iron content of each transformant was correlated with increases in ferritin content. These results demonstrate the potential of breeding high iron content crops by introduction of the ferritin gene     

转铁蛋白基因烟草中内源铁蛋白基因的差异表达及含铁量的变化

铁蛋白是一种由24个亚基组成的高分子贮藏蛋白质,可以储存多达4500个铁原子,在动植物及微生物的新陈代谢中起着非常重要的作用。有研究表明,外源铁蛋白的大量表达可以提高植物储存铁离子的能力。为了明确外源铁蛋白基因转化植物中内源铁蛋白基因差异表达与植物含铁量的关系,本研究在成功获得2个烟草铁蛋白基因的全长cDNA克隆NtFerl（登录号：ay083924）和NtFer2（登录号：ay141105）的基础上,以烟草品种SR-1（Nicotiana tabacum cv．Petit Havana SR-1）为受体,培育了转铁蛋白基因烟草。将双元载体pBI121中的GUS基因用来自大豆的铁蛋白基因SoyFer1（登录号：m64337）置换,利用农杆菌介导法转化烟草叶盘,获得在CaMV35S启动子驱动表达的大豆铁蛋白基因转化烟草植株。Northern杂交和Western杂交分析表明外源铁蛋白基因在转基因烟草中得到了正确表达。比较转基因烟草和非转基因烟草的内源铁蛋白基因表达强度、叶片铁含量、根系铁还原酶活性、株高和鲜重表明,外源铁蛋白基因不但促进了NtFer1的表达,提高转基因植株的储存铁的能力和根系铁还原酶活性,而且促进植株的生长速度。以上结果说明,外源铁蛋白基因转化烟草中内源铁蛋白基因的表达、铁离子的还原吸收及光和作用都得到了进一步的提高。     

Differential Expression of Endogenous Ferritin Genes and Iron Homeostasis Alteration in Transgenic Tobacco Overexpressing Soybean Ferritin Gene

For studying the effects of endogenous ferritin gene expressions (NtFer1, GenBank accession number ay083924; and NtFer2, GenBank accession number ay141105) on the iron homeostasis in transgenic tobacco (Nicotiana tabacum L.) plants expressing soybean (Glycine max Merr) ferritin gene (SoyFer1, GenBank accession number m64337), the transgenic tobacco has been produced by placing soybean ferritin cDNA cassette under the control of the CaMV 35S promoter. The exogenous gene expression was examined by both Northern- and Western-blot analyses. Comparison of endogenous ferritin gene expressions between nontransformant and transgenic tobacco plants showed that the expression of NtFer1 was increased in the leaves of transgenic tobacco plants, whereas the NtFer2 expression was unchanged. The iron concentration in the leaves of transgenic tobacco plants was about 1.5-folds higher than that in nontransformant. Enhanced growth of transgenic tobacco was observed at the early development stages, resulting in plant height and fresh weights significantly greater than those in the nontransformant. These results demonstrated that exogenous ferritin expression induced increased expression of at least one of the endogenous ferritin genes in transgenic tobacco plants by enhancing the ferric chelate reductase activity and iron transport ability of the root, and improved the rate of photosynthesis.     

Subcellular Localization and Characterization of Excessive Iron in the Nicotianamine-less Tomato Mutant chloronerva

To understand the function of the Fe2+-complexing compound nicotianamine (NA) in the iron metabolism of plants we have localized iron and other elements in the NA-containing tomato wild type (Lycopersicon esculentum) and its NA-free mutant chloronerva by quantitative x-ray microanalysis. Comparison of element composition of the rhizodermal cell walls indicated that the wild type accumulated considerable amounts of iron and phosphorus in the cell wall, whereas in the mutant iron and phosphorus were detected in the cytoplasm and vacuoles of the rhizodermis. In mutant leaves containing high iron concentrations in the symplast, electron-dense inclusions were detected in chloroplasts and phloem. Such particles, consisting mainly of iron and phosphorus, were never found in the wild type and were very rarely detected in young chlorotic mutant leaves or after treatment of the mutant with NA. For further characterization the electron-dense inclusions in mutant leaves were isolated and compared by sodium dodecyl sulfate-gel electrophoresis and immunoblotting to ferritin from iron-loaded Phaseolus vulgaris leaves. Antibodies raised against purified Phaseolus leaf ferritin were used. Neither in mutant nor in wild type (iron loaded and control) was ferritin protein detected. These results suggest that the electron-dense inclusions in mutant leaves are not identical with ferritin. It is concluded that NA is necessary to complex ferrous iron in a soluble and available form within the cells. In the absence of NA the precipitation of excessive iron in the form of insoluble ferric phosphate compounds could protect the cells from iron overload.     

Iron Fortification of Banana by the Expression of Soybean Ferritin

Iron deficiency anemia is one of the serious ailments related to nutrition in the developing countries. Fruit and vegetable crops favor the bioavailability of iron. Banana is consumed as a staple food in the tropics. Iron-fortified bananas provide an effective means of controlling the iron deficiency. Embryogenic cells of banana cv. Rasthali (AAB) were transformed with soybean ferritin cDNA using two different expression cassettes pSF and pEFE-SF to express ferritin. Transgenic nature of the regenerated plants was confirmed by PCR. Transgenic plants were regenerated and analyzed through PCR and PCR-Southern analysis. The expression of ferritin was confirmed by RT-PCR. Iron and zinc levels in the transgenic and control plants were estimated by atomic absorption spectroscopy. A 6.32-fold increase in iron accumulation and a 4.58-fold increase in the zinc levels were noted in the leaves of transgenic plants. Thus, iron- and zinc-fortified bananas could be developed as a functional food to overcome the malnutrition-related iron deficiency. This is the first report on the iron and zinc fortification of banana.     

An MYB Transcription Factor from Malus xiaojinensis Has a Potential Role in Iron Nutrition

Regulation of iron uptake and use is critical for plant survival and growth. We isolated an MYB gene from Malus xiaojinensis named MxMYB1, which is induced under Fe-deficient conditions. Expression of MxMYB1 was upregulated by Fe starvation in the roots but not in leaves, suggesting that MxMYB1 might play a role in iron nutrition in roots. Transgenic Arabidopsis plants expressing MxMYB1 exhibited lower iron content as compared with wild type plants under both Fe-normal (40 Μm) and Fe-deflcient conditions (Fe omitted and Ferrozine 300 Μm). However, the contents of Cu, Zn and Mn were not changed in these transgenic plants. Gene chip and real-time polymerase chain reaction analyses indicated that the expression of two Fe-related genes encoding an iron transporter AtIRT1 and an iron storage protein ferritin AtFER1 might be negatively regulated by MxMYB1 as the expression levels of these genes were lower in MxMYB1 expressing transgenic Arabidopsls plants as compared with wild type plants under both Fe-normal and Fe-deficient conditions. These results suggest that MxMYB1 may function as a negative regulator of iron uptake and storage In plants.     

Iron accumulation and enhanced growth in transgenic lettuce plants expressing the iron- binding protein ferritin

We have produced transgenic lettuce plants accumulating the iron storage protein ferritin. The integration of the ferritin gene and expression levels in leaves were examined by Southern- and Western-blot analysis, respectively. It was shown that transgenic lettuce plants contained iron levels ranging from 1.2 to 1.7 times that of the control plants, however, the manganese content in transgenic lettuce plants was similar to that in the control. Enhanced growth of transgenic lettuces was observed at the early developmental stages, resulting in weights 27–42% greater than those of control plants. Transgenic lettuce had photosynthesis rates superior to those of the controls, and grew larger and faster compared with the controls during the period of 3 months from germination. These results demonstrate the possibility of producing lettuce plants with high yield, high iron content and rapid growth rate. Received: 21 March 1999 / Accepted: 14 September 1999     

Plants ectopically expressing the iron-binding protein, ferritin, are tolerant to oxidative damage and pathogens

Transgenic tobacco plants that synthesize alfalfa ferritin in vegetative tissues--either in its processed form in chloroplasts or in the cytoplasmic nonprocessed form--retained photosynthetic function upon free radical toxicity generated by iron excess or paraquat treatment. Progeny of transgenic plants accumulating ferritin in their leaves exhibited tolerance to necrotic damage caused by viral (tobacco necrosis virus) and fungal (Alternaria alternata, Botrytis cinerea) infections. These transformants exhibited normal photosynthetic function and chlorophyll content under greenhouse conditions. We propose that by sequestering intracellular iron involved in generation of the very reactive hydroxyl radicals through a Fenton reaction, ferritin protects plant cells from oxidative damage induced by a wide range of stresses.     

Constitutive Expression of Soybean Ferritin cDNA Intransgenic Wheat and Rice Results in Increased Iron Levels in Vegetative Tissues but not in Seeds

We used particle bombardment to produce transgenic wheat and rice plants expressing recombinant soybean ferritin, a protein that can store large amounts of iron. The cDNA sequence was isolated from soybean by RT-PCR and expressed using the constitutive maize ubiquitin-1 promoter. The presence of ferritin mRNA and protein was confirmed in the vegetative tissues and seeds of transgenic wheat and rice plants by northern and western blot analysis, respectively. The levels of ferritin mRNA were similar in the vegetative tissues of both species, but ferritin protein levels were higher in rice. Both ferritin mRNA and protein levels were lower in wheat and rice seeds. ICAP spectrometry showed that iron levels increased only in vegetative tissues of transgenic plants, and not in the seeds. These data indicate that recombinant ferritin expression under the control of the maize ubiquitin promoter significantly increases iron levels invegetative tissues, but that the levels of recombinant ferritin in seeds are not sufficient to increase iron levels significantly over those in the seeds of non-transgenic plants.     

Bacterial siderophores efficiently provide iron to iron-starved tomato plants in hydroponics culture

Iron is one of the essential elements for a proper plant development. Providing plants with an accessible form of iron is crucial when it is scant or unavailable in soils. Chemical chelates are the only current alternative and are highly stable in soils, therefore, posing a threat to drinking water. The aim of this investigation was to quantify siderophores produced by two bacterial strains and to determine if these bacterial siderophores would palliate chlorotic symptoms of iron-starved tomato plants. For this purpose, siderophore production in MM9 medium by two selected bacterial strains was quantified, and the best was used for biological assay. Bacterial culture media free of bacteria (S) and with bacterial cells (BS), both supplemented with Fe were delivered to 12-week-old plants grown under iron starvation in hydroponic conditions; controls with full Hoagland solution, iron-free Hoagland solution and water were also conducted. Treatments were applied twice along the experiment, with a week in between. At harvest, plant yield, chlorophyll content and nutritional status in leaves were measured. Both the bacterial siderophore treatments significantly increased plant yield, chlorophyll and iron content over the positive controls with full Hoagland solution, indicating that siderophores are effective in providing Fe to the plant, either with or without the presence of bacteria. In summary, siderophores from strain Chryseobacterium C138 are effective in supplying Fe to iron-starved tomato plants by the roots, either with or without the presence of bacteria. Based on the amount of siderophores produced, an effective and economically feasible organic Fe chelator could be developed.     

亚洲玉米螟与欧洲玉米螟混生区的研究

生殖隔离试验、形态鉴定、网室内性信息素活性反应和食性试验的结果表明 :张家口苍耳中的玉米螟与新疆伊宁的欧洲玉米螟同种 ,而为害玉米的优势种与广东阳山的亚洲玉米螟同种。张家口为害玉米的种群中 ,有部分雄蛾对欧洲玉米螟性信息素及苍耳中的雌处女蛾具有反应。苍耳和玉米中的种群在玉米、谷子、高梁、苍耳、草和大马蓼等 6种寄主上均可产卵和取食为害 ,并能正常完成生活史。研究结果证实张家口为亚洲玉米螟和欧洲玉米螟混生区 ,而且在玉米中很可能有少量欧洲玉米螟与亚洲玉米螟混生。     

Stomatal Behavior and CO(2) Exchange Characteristics in Amphistomatous Leaves

The possibility that differences in stomatal conductance between upper and lower surfaces of amphistomatous leaves are adaptations to differences in CO₂ exchange characteristics for the two surfaces was investigated. The ratio of upper to lower stomatal conductance was found to change little in response to light and humidity for well-watered sunflower (Helianthus annuus L.) plants. Stressing the plants (ψ = −17 bars) and rewatering 1 day before gas exchange measurements reduced upper conductance more severely than lower in both indoor- and outdoor-grown plants, and caused small changes in conductance ratio with light and humidity. A similar pattern was found using outdoor grown sunflower and cocklebur (Xanthium strumarium L.) plants. Calculated intercellular CO₂ concentrations for upper and lower surfaces were always close to identical for a particular set of environmental conditions for both sunflower and cocklebur, indicating that no differences in CO₂ exchange characteristics exist between the two surfaces. By artificially creating a CO₂ gradient across the leaf, the resistance to CO₂ diffusion through the mesophyll was estimated and found to be so low that despite possible nonhomogeneity of the mesophyll, differences in CO₂ exchange characteristics for the two surfaces are unlikely. It is concluded that differences in conductance between upper and lower stomates are not adaptations to differences in CO₂ exchange characteristics.     

转基因水稻胚乳中表达铁结合蛋白提高稻米铁含量

为提高我国稻米的铁含量,通过农杆菌介导将自行克隆的菜豆(Phaseolus limensis)铁结合蛋白(Ferritin)基因导入了一个高产粳稻(Oryaz sativa L.ssp．japonuica)品种中,获得17个独立的转基因水稻株系。分子检测证明,外源基因在多数转基因水稻植株基因组中有1～3个整合位点,并可稳定遗传。在水稻种子贮存蛋白谷蛋白基因GluB-1启动子的控制下,铁结合蛋白基因可在转基因水稻的种子中高效特异地表达,不同转化子中的表达量有明显不同。在转基因水稻种子中表达铁结合蛋白后对提高精米中的铁含量有明显的效果,相对于未转化对照最多可提高64％,而锌的含量并无明显变化。     

The role of ferritin in developing primary bean leaves under various light conditions

Ferritin and ferritin-iron in the primary leaves of Phaseolus vulgaris L. were determined during growth in the dark, in the light, and during de-etiolation. The ratio ferritin protein/total protein appeared to be rather constant. In dark-grown leaves maximally 50% of the total extractable iron was found to be present in ferritin. This percentage was lower in deetiolating and light-grown leaves. In ten-day-old green leaves no ferritin-iron could be measured. The translocation of iron from cotyledons to the developing plant appears to be related to the need for iron in the leaves. These results suggest that ferritin acts as a buffer molecule for iron in plants.     

Growth schedule of Xanthium canadense: Does it optimize the timing of reproduction?

Summary The effects of nutrition on the timing of reproductive initiation of a short-day annual plant Xanthium canadense (cocklebur) were examined with the following hypotheses in mind: If the plant always follows an optimal growth schedule, low-nutrient plants will initiate reproductive growth earlier than high-nutrient plants. On the other hand, if the plant flowers in response to photoperiodic stimuli, both plants will initiate reproductive growth on the same day. The sand-culture experiment showed that high-nutrient plants flowered earlier than the low-nutrient plants, leading to rejection of the first hypothesis. The predicted optimal flowering time is 2 days later than the actual flowering time in high-nutrient plants and 10 days earlier in low-nutrient plants. These deviations from the optimal times reduced the reproductive yield by 0.1% and 2.3%, respectively. The ratio of the final reproductive yield to the vegetative mass at flower initiation was 1.10 in high-nutrient plants and 0.63 in low-nutrient plants. Since the expected ratio for the optimal growth schedule is 1.0, high-nutrient plants followed the opitmal growth schedule more closely than the low-nutrient plants. Cocklebur is a fast-growing annual which is common in relatively nutrient-rich environments. This study suggests that cocklebur adapts itself to such environments through its photoperiodic response.     

Utilization of iron complexes in an animal cell

The ciliate protozoan Tetrahymena thermophila was grown in synthetic nutrient medium in the absence of the iron chelator citrate. Utilization and toxicity of various iron compounds or complexes in iron-starved cells were assessed from the number of cell doublings obtained within a standard time. The compounds tested included complexes formed between ortho-phosphates and two forms of ferric hydroxides, native and cationized ferritin, and tris-acetylacetonato Fe(III). The ferric hydroxo ortho-phosphate particles are toxic and can be removed from the medium by Millipore filtration. Uptake of ferritin and tris-acetylacetonato-Fe(III) is independent of food vacuole formation and seems to occur by micropinocytosis and by plasma membrane translocation, respectively.     

Lack of Cross-Resistance of Imazaquin-Resistant Xanthium strumarium Acetolactate Synthase to Flumetsulam and Chlorimuron

Acetolactate synthase (ALS) was isolated from a field population of cocklebur (Xanthium strumarium) that developed resistance to the herbicide Scepter following three consecutive years of application. The active ingredient of Scepter, imazaquin, gave an inhibitor concentration required to produce 50% inhibition of the enzyme activity that was more than 300 times greater for the resistant enzyme than for the wild-type cocklebur ALS. Tests with flumetsulam and chlorimuron show that the resistant ALS was not cross-resistant to these two other classes of ALS inhibitors.