Rice <Emphasis Type="Italic">NICOTIANAMINE SYNTHASE 2</Emphasis> expression improves dietary iron and zinc levels in wheat

Key message

Iron and zinc deficiencies negatively impact human health worldwide. We developed wheat lines that meet or exceed recommended dietary target levels for iron and zinc in the grains. These lines represent useful germplasm for breeding new wheat varieties that can reduce iron and zinc deficiency-associated health burdens in the affected populations.

Abstract

Micronutrient deficiencies, including iron and zinc deficiencies, have negative impacts on human health globally. Iron-deficiency; anemia affects nearly two billion people worldwide and is the cause of reduced cognitive development, fatigue and overall low productivity. Similarly, zinc deficiency causes stunted growth, decreased immunity and increased risk of respiratory infections. Biofortification of staple crops is a sustainable and effective approach to reduce the burden of health problems associated with micronutrient deficiencies. Here, we developed wheat lines expressing rice NICOTIANAMINE SYNTHASE 2 (OsNAS2) and bean FERRITIN (PvFERRITIN) as single genes as well as in combination. NAS catalyzes the biosynthesis of nicotianamine (NA), which is a precursor of the iron chelator deoxymugeneic acid (DMA) required for long distance iron translocation. FERRITIN is important for iron storage in plants because it can store up to 4500 iron ions. We obtained significant increases of iron and zinc content in wheat grains of plants expressing either OsNAS2 or PvFERRTIN, or both genes. In particular, wheat lines expressing OsNAS2 greatly surpass the HarvestPlus recommended target level of 30 % dietary estimated average requirement (EAR) for iron, and 40 % of EAR for zinc, with lines containing 93.1 µg/g of iron and 140.6 µg/g of zinc in the grains. These wheat lines with dietary significant levels of iron and zinc represent useful germplasm for breeding new wheat varieties that can reduce micronutrient deficiencies in affected populations.

     

Uptake,distribution, and remobilization of iron and zinc among various tissues of wheat–<Emphasis Type="Italic">Aegilops</Emphasis> substitution lines at different growth stages

Biofortification of wheat for higher grain iron and zinc is the most feasible and cost-effective approach for alleviating micronutrient deficiency. The non-progenitor donor Aegilops species had 2–3 times higher grain iron and zinc content than the wheat cultivars, whereas the wheat–Aegilops substitution lines mostly of group 2 and 7 chromosomes had intermediate levels of grain micronutrients. The non-progenitor Aegilops species also had the highest iron content and intermediate-to-highest zinc content in straw, lower leaves, and flag leaves at the pre-anthesis, grain-filling, and maturity growth stages. The micronutrients accumulation status is followed by wheat–Aegilops substitution lines and is the least in wheat cultivars indicating that the donor Aegilops species and their substituted chromosomes possess genes for higher iron and zinc uptake and mobilization. The grain iron content was highly positively correlated with iron content in the plant tissues. Most of the lines had much higher iron and zinc content in all tissues during grain-filling period indicating higher iron and zinc uptake from soil during this stage. Although iron and zinc contents are nearly similar in grains, there was much less zinc content in the plant tissues of all the lines suggesting that the Triticeae species take up less zinc which is mobilized to grains more effectively than iron.     

Characterisation of structural genes involved in phytic acid biosynthesis in common bean (<Emphasis Type="Italic">Phaseolus vulgaris</Emphasis> L.)

Phytate (myo-inositol hexakisphosphate), the major form of phosphorous storage in plant seeds, is an inositol phosphate compound poorly digested by humans and monogastric animals. A major goal for grain crop improvement is the reduction of its content in the seed to improve micronutrient bioavailability and phosphorus utilisation by humans and non-ruminant animals, respectively. We are interested in lowering phytic acid in common bean seed and to this goal we have undertaken a two-strategy approach: the isolation of mutants from an EMS mutagenised population (Campion et al. 2009) and the identification of genes coding for candidate enzymes involved in inositol phosphate metabolism for future targeted mutant isolation and/or study. In this paper we report data referred to the second approach and concerning the isolation and genomic organisation of Phaseolus vulgaris genes coding for myo-inositol 1-phosphate synthase (PvMIPSs and PvMIPSv), inositol monophosphatase (PvIMP), myo-inositol kinase (PvMIK), inositol 1,4,5-tris-phosphate kinase (PvIPK2), inositol 1,3,4-triphosphate 5/6-kinase (PvITPKα and PvITPKβ) and inositol 1,3,4,5,6 pentakisphosphate 2-kinase (PvIPK1). All these genes have been mapped on the common bean reference genetic map of McClean (NDSU) 2007 using a virtual mapping strategy. Bean markers, presumably associated to each gene of the phytic acid pathway, have also been identified. In addition, we provide a picture of the expression, during seed development, of the genes involved in phytic acid synthesis, including those such as MIK, IMP and IPK2, for which this information was lacking.     

Endosperm-Specific Co-Expression of Recombinant Soybean Ferritin and <Emphasis Type="Italic">Aspergillus</Emphasis> Phytase in Maize Results in Significant Increases in the Levels of Bioavailable Iron

We have generated transgenic maize plants expressing Aspergillus phytase either alone or in combination with the iron-binding protein ferritin. Our aim was to produce grains with increased amounts of bioavailable iron in the endosperm. Maize seeds expressing recombinant phytase showed enzymatic activities of up to 3 IU per gram of seed. In flour paste prepared from these seeds, up to 95% of the endogenous phytic acid was degraded, with a concomitant increase in the amount of available phosphate. In seeds expressing ferritin in addition to phytase, the total iron content was significantly increased. To evaluate the impact of the recombinant proteins on iron absorption in the human gut, we used an in vitro digestion/Caco-2 cell model. We found that phytase in the maize seeds was associated with increased cellular iron uptake, and that the rate of iron uptake correlated with the level of phytase expression regardless of the total iron content of the seeds. We also investigated iron bioavailability under more complex meal conditions by adding ascorbic acid, which promotes iron uptake, to all samples. This resulted in a further increase in iron absorption, but the effects of phytase and ascorbic acid were not additive. We conclude that the expression of recombinant ferritin and phytase could help to increase iron availability and enhance the absorption of iron, particularly in cereal-based diets that lack other nutritional components.     

Expression of apoplast-targeted plant defensin <Emphasis Type="Italic">MtDef4.2</Emphasis> confers resistance to leaf rust pathogen <Emphasis Type="Italic">Puccinia triticina</Emphasis> but does not affect mycorrhizal symbiosis in transgenic wheat

Rust fungi of the order Pucciniales are destructive pathogens of wheat worldwide. Leaf rust caused by the obligate, biotrophic basidiomycete fungus Puccinia triticina (Pt) is an economically important disease capable of causing up to 50 % yield losses. Historically, resistant wheat cultivars have been used to control leaf rust, but genetic resistance is ephemeral and breaks down with the emergence of new virulent Pt races. There is a need to develop alternative measures for control of leaf rust in wheat. Development of transgenic wheat expressing an antifungal defensin offers a promising approach to complement the endogenous resistance genes within the wheat germplasm for durable resistance to Pt. To that end, two different wheat genotypes, Bobwhite and Xin Chun 9 were transformed with a chimeric gene encoding an apoplast-targeted antifungal plant defensin MtDEF4.2 from Medicago truncatula. Transgenic lines from four independent events were further characterized. Homozygous transgenic wheat lines expressing MtDEF4.2 displayed resistance to Pt race MCPSS relative to the non-transgenic controls in growth chamber bioassays. Histopathological analysis suggested the presence of both pre- and posthaustorial resistance to leaf rust in these transgenic lines. MtDEF4.2 did not, however, affect the root colonization of a beneficial arbuscular mycorrhizal fungus Rhizophagus irregularis. This study demonstrates that the expression of apoplast-targeted plant defensin MtDEF4.2 can provide substantial resistance to an economically important leaf rust disease in transgenic wheat without negatively impacting its symbiotic relationship with the beneficial mycorrhizal fungus.     

Effects of the maize C<Subscript>4</Subscript> phosphoenolpyruvate carboxylase (<Emphasis Type="Italic">ZmPEPC</Emphasis>) gene on nitrogen assimilation in transgenic wheat

Nitrogen (N) is the primary limiting factor for crop growth, development, and productivity. Transgenic technology is a straightforward strategy for improving N assimilation in crops. The present study assessed the effects of maize C₄ phosphoenolpyruvate carboxylase (ZmPEPC) gene overexpression on N assimilation in three independent transgenic lines and wild-type (WT) wheat (Triticum aestivum L.). The transgenic wheat lines depicted ZmPEPC overexpression and higher PEPC enzyme activity relative to that in the WT. The leaves of the transgenic wheat lines subjected to low N treatment showed an increase in ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO) expression, content, and carboxylase activity. The transgenic wheat lines also depicted an upregulation of genes associated with the anaplerotic pathway for the TCA cycle, suggesting that more carbon (C) skeleton material is being allocated for N assimilation under low N conditions. Furthermore, ZmPEPC expression in transgenic wheat lines induced the upregulated of genes associated primary N metabolism, including TaNR, TaGS2, TaGOGAT, TaAspAT, and TaASN1. The average total free amino acid content in the transgenic wheat lines was 48.18% higher than that in the WT, and asparagine (Asn), glutamine (Gln), aspartic acid (Asp), and serine (Ser) were also markedly enhanced. In addition, elementary analysis showed that N and C content, and the biomass of the transgenic wheat lines increased with low N treatment. Yield trait analysis indicated that ZmPEPC overexpression improved grain yield by increasing 1000-grain weight. In conclusion, ZmPEPC overexpression in wheat could modulate C metabolism, significantly improve N assimilation, enhances growth, and improves yield under low N conditions.     

Does the combination of citrate and phytase exudation in <Emphasis Type="Italic">Nicotiana tabacum</Emphasis> promote the acquisition of endogenous soil organic phosphorus?

Background and Aims

Plant acquisition of endogenous forms of soil phosphorus (P) could reduce external P requirements in agricultural systems. This study investigated the interaction of citrate and phytase exudation in controlling the accumulation of P and depletion of soil organic P by transgenic Nicotiana tabacum plants.

Methods

N. tabacum plant lines including wild-type, vector controls, transgenic plants with single-trait expression of a citrate transporter (A. thaliana frd3) or fungal phytases (phyA: A. niger, P. lycii) and crossed plant lines expressing both traits, were characterized for citrate efflux and phytase exudation. Monocultures and intercropped combinations of single-trait plants were grown in a low available P soil (12 weeks). Plant biomass, shoot P accumulation, rhizosphere soil pH and citrate-extractable-P fractions were determined. Land Equivalent Ratio and complementarity effect was determined in intercropped treatments and multiple-linear-regression was used to predict shoot P accumulation based on plant exudation and soil P depletion.

Results

Crossed plant lines with co-expression of citrate and phytase accumulated more shoot P than single-trait and intercropped plant treatments. Shoot P accumulation was predicted based on phytase-labile soil P, citrate efflux, and phytase activity (Rsq=0.58, P < .0001). Positive complementarity occurred between intercropped citrate- and phytase-exuding plants, with the greatest gains in shoot P occurring in plant treatments with A. niger phyA expression.

Conclusions

We show for the first time that trait synergism associated with the exudation of citrate and phytase by tobacco can be linked to the improved acquisition of P and the depletion of soil organic P.

     

A strong root-specific expression system for stable transgene expression in bread wheat

Key message

A strong, stable and root-specific expression system was developed from a rice root-specific GLYCINE - RICH PROTEIN 7 promoter for use as an enabling technology for genetic manipulation of wheat root traits.

Abstract

Root systems play an important role in wheat productivity. Genetic manipulation of wheat root traits often requires a root-specific or root-predominant expression system as an essential enabling technology. In this study, we investigated promoters from rice root-specific or root-predominant expressed genes for development of a root expression system in bread wheat. Transient expression analysis using a GREEN FLUORESCENT PROTEIN (GFP) reporter gene driven by rice promoters identified six promoters that were strongly expressed in wheat roots. Extensive organ specificity analysis of three rice promoters in transgenic wheat revealed that the promoter of rice GLYCINE-RICH PROTEIN 7 (OsGRP7) gene conferred a root-specific expression pattern in wheat. Strong GFP fluorescence in the seminal and branch roots of wheat expressing GFP reporter driven by the OsGRP7 promoter was detected in epidermal, cortical and endodermal cells in mature parts of the root. The GFP reporter driven by the promoter of rice METALLOTHIONEIN-LIKE PROTEIN 1 (OsMTL1) gene was mainly expressed in the roots with essentially no expression in the leaf, stem or seed. However, it was also expressed in floral organs including glume, lemma, palea and awn. In contrast, strong expression of rice RCg2 promoter-driven GFP was found in many tissues. The GFP expression driven by these three rice promoters was stable in transgenic wheat plants through three generations (T1–T3) examined. These data suggest that the OsGRP7 promoter can provide a strong, stable and root-specific expression system for use as an enabling technology for genetic manipulation of wheat root traits.

     

Characterization of grain protein content gene (<Emphasis Type="Italic">GPC</Emphasis>-<Emphasis Type="Italic">B1</Emphasis>) introgression lines and its potential use in breeding for enhanced grain zinc and iron concentration in spring wheat

At least two billion people around the world suffer from micronutrient deficiency, or hidden hunger, which is characterized by iron-deficiency anemia, vitamin A and zinc deficiency. As a key staple food crop, wheat provides 20% of the world’s dietary energy and protein, therefore wheat is an ideal vehicle for biofortification. Developing biofortified wheat varieties with genetically enhanced levels of grain zinc (Zn) and iron (Fe) concentrations, and protein content provides a cost-effective and sustainable solution to the resource-poor wheat consumers. Large genetic variation for Fe and Zn were found in the primitive and wild relatives of wheat, the potential high Zn and Fe containing genetic resources were used as progenitors to breed high-yielding biofortified wheat varieties with 30–40% higher Zn content. Grain protein content (GPC) determines processing and end-use quality of wheat for making diverse food products. The GPC-B1 allele from Triticum turgidum L. var. dicoccoides have been well characterized for the increase in GPC and the associated pleiotropic effect on grain Zn and Fe concentrations in wheat. In this study effect of GPC-B1 allele on grain Zn and Fe concentrations in wheat were measured in different genetic backgrounds and two different agronomic management practices (with- and without foliar Zn fertilization). Six pairs of near-isogenic lines differing for GPC-B1 gene evaluated at CIMMYT, Mexico showed that GPC-B1 influenced marginal increase for grain Zn, Fe concentrations, grain protein content and slight reduction in kernel weight and grain yield. However, the magnitude of GPC and grain Zn and Fe reductions varied depending on the genetic background. Introgression of GPC-B1 functional allele in combination with normal or delayed maturity alleles in the CIMMYT elite wheat germplasm has the potential to improve GPC and grain Zn and Fe concentrations without the negative effect on grain yield due to early senescence and accelerated maturity.     

Elucidating the interactions and phytotoxicity of zinc oxide nanoparticles with agriculturally beneficial bacteria and selected crop plants

There is a growing interest in the use of bioinoculants to assist mineral fertilizers in improving crop production and yield. Azotobacter and Pseudomonas are two agriculturally relevant strains of bacteria which have been established as efficient bioinoculants. An experiment involving addition of graded concentrations of zinc oxide (ZnO) nanoparticles was undertaken using log phase cultures of Azotobacter and Pseudomonas. Growth kinetics revealed a clear trend of gradual decrease with Pseudomonas; however, Azotobacter exhibited a twofold enhancement in growth with increase in the concentration of ZnO concentration. Scanning electron microscopy (SEM), supported by energy-dispersive X-ray (EDX) analyses, illustrated the significant effect of ZnO nanoparticles on Azotobacter by the enhancement in the abundance of globular biofilm-like structures and the intracellular presence of ZnO, with the increase in its concentration. It can be surmised that extracellular mucilage production in Azotobacter may be providing a barrier to the nanoparticles. Further experiments with Azotobacter by inoculation of wheat and tomato seeds with ZnO nanoparticles alone or bacteria grown on ZnO-infused growth medium revealed interesting results. Vigour index of wheat seeds reduced by 40–50% in the presence of different concentrations of ZnO nanoparticles alone, which was alleviated by 15–20%, when ZnO and Azotobacter were present together. However, a drastic 50–60% decrease in vigour indices of tomato seeds was recorded, irrespective of Azotobacter inoculation.     

Overexpression of wheat <Emphasis Type="Italic">TaNCED</Emphasis> gene in <Emphasis Type="Italic">Arabidopsis</Emphasis> enhances tolerance to drought stress and delays seed germination

Abscisic acid (ABA) regulates various plant physiological processes, especially participates in the plant responses to harsh environments. The 9-cis-epoxycarotenoid dioxygenase (NCED) is a key enzyme in ABA biosynthesis pathway. Here, a TaNCED with an 1 887-bp open reading frame was cloned from wheat, which encodes a peptide of 628 amino acids. A chloroplast transit peptide sequence was found at the N-terminus of the TaNCED protein. Multiple sequence alignments indicate that the TaNCED protein shared high similarities with other NCEDs from different species. Real-time quantitative PCR analysis shows that expression of TaNCED was strongly up-regulated by treatments with ABA, polyethylene glycol, and drought stress, and it was down-regulated during germination of the wheat seeds. Ectopic overexpression of the TaNCED gene in Arabidopsis resulted in an increase of endogenous ABA and free proline content. A lower water loss rate and stomatal conductance of leaves were found in the transgenic plants in comparison with the wild type. Subsequently, the transgenic plants displayed an enhanced tolerance to drought stress but delayed seed germination. These data provide evidence that the TaNCED might play a primary role in regulation of ABA content during water stress and seed dormancy.     

Cloning of fatty acid desaturase-coding sequence (<Emphasis Type="Italic">Lufad3</Emphasis>) from flax and its functional validation in rice

Flax contains very high levels of alpha-linolenic acid (57%) and a fatty acid desaturase 3-coding sequence (Lufad3) of flax has been amplified from the RNA isolated from developing seeds. The deduced amino acid sequence of LuFAD3 showed the presence of three histidine motifs, six membrane spanning domains and an endoplasmic reticulum (ER) retention signal KSK, indicating its plausible localization into the ER. Flax is not amenable for genetic transformation and not suitable for functional validation of Lufad3 gene. Hence, rice with well-developed genetic transformation has been selected as heterologous host system. Coding sequence of Lufad3 driven by maize Ubi1 promoter has been introduced into indica rice by Agrobacterium tumefaciens-mediated genetic transformation. Southern analysis of putative transformants (T ₀) revealed signals at variable lengths at >5 kbp indicating random integration of transgene into the genomes of different transformants. The Mendelian segregation observed for selectable marker gene hyg in both T₁ and T₂ generations confirmed stable inheritance and single-site integration of transgenes. As compared to untransformed control (UC), homozygous transgenic rice expressing Lufad3 showed higher levels of essential α-linolenic acid in leaves and seeds validating its functionality.     

Enhancement of syringin contents in soybean seeds with seed-specific expression of a chimeric <Emphasis Type="Italic">UGT72E3</Emphasis>/<Emphasis Type="Italic">E2</Emphasis> gene

Syringin, sinapyl alcohol 4-O-glucoside, is well known as a plant-derived bioactive monolignol glucoside. In Arabidopsis, recombinant chimeric protein UGT72E3/2 has been previously reported to lead to significantly higher syringin production than the parental enzymes UGT72E2 and UGT72E3. To enhance syringin content in Korean soybean (Glycine max L. ‘Kwangan’), we cloned the UGT72E3/2 gene under the control of the β-conglycinin or CaMV-35S promoter to generate β-UGT72E3/2 and 35S-UGT72E3/2 constructs, respectively, and then transformed them into soybean to obtain transgenic plants using the modified half-seed method. Real-time semi-quantitative PCR (RT-PCR) analysis showed that the UGT72E3/2 gene was expressed in the leaves of the β-UGT72E3/2 and 35S-UGT72E3/2 transgenic lines. HPLC analysis of the seeds and mature tissues of the T2 generation plants revealed that the β-UGT72E3/2 transgenic seeds accumulated 0.15 µmol/g DW of total syringin and 0.29 µmol/g DW of total coniferin, whereas coniferin and syringin were not detected in non-transgenic seeds. Moreover, coniferin and syringin also accumulated at high levels in non-seed tissues, particularly the leaves of β-UGT72E3/2 transgenic lines. In contrast, 35S-UGT72E3/2 lines showed no differences in the contents of coniferin and syringin between transgenic and non-transgenic soybean plants. Thus, the seed-specific β-conglycinin promoter might be an effective tool to apply to the nutritional enhancement of soybean crops through increased syringin production.     

Prospecting endophytes from different Fe or Zn accumulating wheat genotypes for their influence as inoculants on plant growth,yield, and micronutrient content

The plant microbiome is known to play a significant role in improving plant productivity and quality of produce, and the endophytic component was explored toward developing inoculants for enhancing micronutrient concentration in grains. A set of 213 endophytes (201 bacteria and 12 fungi) were isolated, from a set of 13 wheat genotypes, identified through preliminary screening as low and high iron and zinc accumulating genotypes. A pot experiment, with two low accumulator genotypes and eight selected endophytes, was undertaken, followed by field evaluation with both high and low Zn or Fe accumulator genotypes. Screening of these endophytes identified 11 bacteria and 2 fungi as being efficient for zinc solubilization, while 10 bacteria and 2 fungi were promising siderophore producers. Zinc and iron uptake were enhanced by one to several folds over the recommended dose of NPK (RDF) in the pot experiment. Two sets of promising endophytes, identified as Bacillus subtilis (DS-178) and Arthrobacter sp. (DS-179) for zinc accumulation, and Arthrobacter sulfonivorans (DS-68) and Enterococcus hirae (DS-163) for iron acquisition in grains, were selected. Significant increase of 14–20% in plant growth and yield was recorded in field experiment, with 75% increase, over RDF, in terms of Fe or Zn accumulation in wheat grains. Phytic acid, an anti-nutritional factor, was significantly lower in grains from endophyte inoculated treatments in the wheat genotypes evaluated. This illustrated the promise of these endophytes in improving both the translocation of micronutrients and enhancing the quality of wheat grains.     

Establishment of <Emphasis Type="Italic">Miscanthus sinensis</Emphasis> with decreased lignin biosynthesis by <Emphasis Type="Italic">Agrobacterium</Emphasis>–mediated transformation using antisense <Emphasis Type="Italic">COMT</Emphasis> gene

This study was to determine a transformation system for Miscanthus sinensis, and to optimize factors and conditions required for expression of an antisense caffeic acid O-methyltransferase gene in the M. sinensis (MsCOMT-AS). Transformation of callus derived from seeds and immature inflorescences of M. sinensis was established by using Agrobacterium tumefaciens strain LBA4404 harboring a binary vector pMBP1. In order to establish the stable transformation system, several transformation factors such as explant type, strain, co-culture periods, acetosyringone concentration, and selective markers were assessed. In this study, seven putative transgenic plants were obtained from callus transformation and plantlet regeneration. Various tests including PCR analysis and RT-PCR were used to detect the transgenic insert. The transgenic plants were also characterized for their agronomic and morphological characteristics, expression of MsCOMT-AS gene, and variation in lignocellulosic content. Biomass related traits such as plant height, number of leaves, length of leaf, stem diameter, fresh weight, dry weight, and cell size of the control plants were superior to transgenic plants. Total lignin content of transgenic plants was lower than that of the control plant due to reduced caffeic acid O-methyltransferase (COMT) gene expression related to lignin production. Cellulose and hemicellulose content in transgenic plants were not increased. Variation in cellulose and hemicellulose content had no correlation with variation in lignin content of transgenic plants. In conclusion, transgenic M. sinensis was obtained with down-regulated COMT gene. Lignin synthesis was decreased what offers possibility of crop modification for facilitated biofuel production.     

Rheological and breadmaking properties of wheat samples infected with<Emphasis Type="Italic">Fusarium spp.</Emphasis>

Rheological and breadmaking properties of untreated and suboptimally stored wheat samples (grain moisture: 20%, temperature: 20°C) and also of wheat which was inoculated withFusarium spp. were investigated. The deoxynivalenol (DON) content of the stored and inoculated wheat samples ranged between 820–12,000 μg/kg. Gluten proteins were isolated with different extraction solutions and the fractions obtained were analysed by means of RP-HPLC. Microextension tests and micro-baking tests were used for the determination of dough properties (maximum resistance (MR) and extensibility (EX)) and bread volume, respectively. In spite of the extremely high DON concentrations of some wheat samples contaminated withFusarium spp. they showed only a slight decrease of the amount of gluten proteins. Extension tests of dough led to a slight decrease of MR, bread volumes stayed almost the same compared with the non-contaminated grain. The contamination of wheat withAspergillus andPenicillium led to a high decrease of gluten proteins, which resulted in an extremely decreased MR of the dough and a very low bread volume.     

The iron-chelate transporter OsYSL9 plays a role in iron distribution in developing rice grains

Key message

Rice OsYSL9 is a novel transporter for Fe(II)-nicotianamine and Fe(III)-deoxymugineic acid that is responsible for internal iron transport, especially from endosperm to embryo in developing seeds.

Abstract

Metal chelators are essential for safe and efficient metal translocation in plants. Graminaceous plants utilize specific ferric iron chelators, mugineic acid family phytosiderophores, to take up sparingly soluble iron from the soil. Yellow Stripe 1-Like (YSL) family transporters are responsible for transport of metal-phytosiderophores and structurally similar metal-nicotianamine complexes. Among the rice YSL family members (OsYSL) whose functions have not yet been clarified, OsYSL9 belongs to an uncharacterized subgroup containing highly conserved homologs in graminaceous species. In the present report, we showed that OsYSL9 localizes mainly to the plasma membrane and transports both iron(II)-nicotianamine and iron(III)-deoxymugineic acid into the cell. Expression of OsYSL9 was induced in the roots but repressed in the nonjuvenile leaves in response to iron deficiency. In iron-deficient roots, OsYSL9 was induced in the vascular cylinder but not in epidermal cells. Although OsYSL9-knockdown plants did not show a growth defect under iron-sufficient conditions, these plants were more sensitive to iron deficiency in the nonjuvenile stage compared with non-transgenic plants. At the grain-filling stage, OsYSL9 expression was strongly and transiently induced in the scutellum of the embryo and in endosperm cells surrounding the embryo. The iron concentration was decreased in embryos of OsYSL9-knockdown plants but was increased in residual parts of brown seeds. These results suggested that OsYSL9 is involved in iron translocation within plant parts and particularly iron translocation from endosperm to embryo in developing seeds.

     

Functional Analysis of Wheat <Emphasis Type="Italic">TaPaO1</Emphasis> Gene Conferring Pollen Sterility Under Low Temperature

Thermosensitive male sterility plays an important role in wheat fertility and production. As a key enzyme for chlorophyll degradation, pheophorbide a oxygenase (PaO) can suppress cell death in plants. We cloned the wheat gene TaPaO1 from the thermosensitive genetic male sterile (TGMS) line BS366; it encodes a typical PaO protein, containing a conserved Rieske [2Fe-2S] iron–sulphur motif, a mononuclear non-heme iron-binding motif, and a C-terminal CxxC motif. TaPaO1 was expressed in all tissues and was upregulated during the meiosis stage of BS366 anthers under low temperature. Subcellular localization of TaPaO1 specifically labelled the surrounding of chloroplasts. TaPaO1 regulated by RD29A promoter which responded to low temperature led to pollen sterility in transgenic tobacco. Expression analysis showed that TaPaO1 exhibited a higher level of expression in the anther than in other tissues in transgenic tobacco plants during low temperature treatment. We propose that the higher senescence-related activity of TaPaO1 may lead to the cell death of anthers, which happens at an early developmental stage under low temperature. These results provide new insights into the function of PaO during the early developmental stage of anthers. PaO is closely related to cell death regardless of whether it exhibits increased activity or inactive.