RNAi mediated silencing of lipoxygenase gene to maintain rice grain quality and viability during storage

Lipoxygenase (LOX) is a common enzyme which catalyzes lipid peroxidation of seeds and consequently enhances seed quality deterioration and decreases seed viability. During seed storage, peroxidation of unsaturated fatty acids occur due to enhancement of LOX activity which directly leads to reduction in seed vigour and deterioration of grain nutritional quality. This study was undertaken to overcome these problem during rice seed storage by attenuating LOX activity using RNAi technology. To improve seed storage stability, we down regulated LOX gene activity by using a functional fragment of the LOX gene under the control of both constitutive (CaMV35S) and aleurone-specific (Oleosin-18) promoter separately. To understand the storage stability, RNAi–LOX seeds and non-transgenic control seeds were subjected to accelerated aging at 45 °C and 85 % relative humidity for 14 days. Our studies demonstrate that down regulation of LOX activity reduces the seed quality deterioration under storage condition. In addition GC–MS analysis revealed that reduction of fatty acid level in non-transgenic seeds during storage was higher when compared with that of transgenic rice seeds. Furthermore, the transgenic rice seeds with reduced LOX activity exhibited enhanced seed germination efficiency after storage than that of non-transgenic rice seeds. This study will have direct impact on nutritional stability of quality rice grains.     

Development and characterization of marker‐free and transgene insertion site‐defined transgenic wheat with improved grain storability and fatty acid content

Development of marker‐free and transgene insertion site‐defined (MFTID) transgenic plants is essential for safe application of transgenic crops. However, MFTID plants have not been reported for wheat (Triticum aestivum). Here, we prepared a RNAi cassette for suppressing lipoxygenase (LOX) gene expression in wheat grains using a double right border T‐DNA vector. The resultant construct was introduced into wheat genome via Agrobacterium‐mediated transformation, with four homozygous marker‐free transgenic lines (namely GLRW‐1, ‐3, ‐5 and ‐8) developed. Aided by the newly published wheat genome sequence, the T‐DNA insertion sites in GLRW‐3 and GLRW‐8 were elucidated at base‐pair resolution. While the T‐DNA in GLRW‐3 inserted in an intergenic region, that of GLRW‐8 inactivated an endogenous gene, which was thus excluded from further analysis. Compared to wild ‐type (WT) control, GLRW‐1, ‐3 and ‐5 showed decreased LOX gene expression, lower LOX activity and less lipid peroxidation in the grains; they also exhibited significantly higher germination rates and better seedling growth after artificial ageing treatment. Interestingly, the three GLRW lines also had substantially increased contents of several fatty acids (e.g., linoleic acid and linolenic acid) in their grain and flour samples than WT control. Collectively, our data suggest that suppression of grain LOX activity can be employed to improve the storability and fatty acid content of wheat seeds and that the MFTID line GLRW‐3 is likely of commercial value. Our approach may also be useful for developing the MFTID transgenic lines of other crops with enhanced grain storability and fatty acid content.     

The scutellar vascular bundle-specific promoter of the wheat HD-Zip IV transcription factor shows similar spatial and temporal activity in transgenic wheat, barley and rice

An HD‐Zip IV gene from wheat, TaGL9, was isolated using a Y1H screen of a cDNA library prepared from developing wheat grain. TaGL9 has an amino acid sequence distinct from other reported members of the HD‐Zip IV family. The 3′ untranslated region of TaGL9 was used as a probe to isolate a genomic clone of the TaGL9 homologue from a BAC library prepared from Triticum durum L. cv. Langdon. The full‐length gene containing a 3‐kb‐long promoter region was designated TdGL9H1. Spatial and temporal activity of TdGL9H1 was examined using promoter‐GUS fusion constructs in transgenic wheat, barley and rice plants. Whole‐mount and histochemical GUS staining patterns revealed grain‐specific expression of TdGL9H1. GUS expression was initially observed between 3 and 8 days after pollination (DAP) in embryos at the globular stage and adjacent to the embryo fraction of the endosperm. Expression was strongest in the outer cell layer of the embryo. In developed wheat and barley embryos, strong activity of the promoter was only detected in the main vascular bundle of the scutellum, which is known to be responsible for the uptake of nutrients from the endosperm during germination and the endosperm‐dependent phase of seedling development. Furthermore, this pattern of GUS staining was observed in dry seeds several weeks after harvesting but quickly disappeared during imbibition. The promoter of this gene could be a useful tool for engineering of early seedling vigour and protecting the endosperm to embryo axis pathway from pathogens during grain desiccation and storage.     

Targeting intracellular transport combined with efficient uptake and storage significantly increases grain iron and zinc levels in rice

Rice, a staple food for more than half of the world population, is an important target for iron and zinc biofortification. Current strategies mainly focus on the expression of genes for efficient uptake, long‐distance transport and storage. Targeting intracellular iron mobilization to increase grain iron levels has not been reported. Vacuole is an important cell compartment for iron storage and the NATURAL RESISTANCE ASSOCIATED MACROPHAGE PROTEIN (NRAMP) family of transporters export iron from vacuoles to cytosol when needed. We developed transgenic Nipponbare rice lines expressing AtNRAMP3 under the control of the UBIQUITIN or rice embryo/aleurone‐specific 18‐kDa Oleosin (Ole18) promoter together with NICOTIANAMINE SYNTHASE (AtNAS1) and FERRITIN (PvFER), or expressing only AtNRAMP3 and PvFER together. Iron and zinc were increased close to recommended levels in polished grains of the transformed lines, with maximum levels when AtNRAMP3, AtNAS1 and PvFER were expressed together (12.67 μg/g DW iron and 45.60 μg/g DW zinc in polished grains of line NFON16). Similar high iron and zinc levels were obtained in transgenic Indica IR64 lines expressing the AtNRAMP3, AtNAS1 and PvFER cassette (13.65 μg/g DW iron and 48.18 μg/g DW zinc in polished grains of line IR64_1), equalling more than 90% of the recommended iron increase in rice endosperm. Our results demonstrate that targeting intracellular iron stores in combination with iron and zinc transport and endosperm storage is an effective strategy for iron biofortification. The increases achieved in polished IR64 grains are of dietary relevance for human health and a valuable nutrition trait for breeding programmes.     

Field Performance of Transgenic indica Hybrid Rice with Improved Cooking and Eating Quality by Down-regulation of Wx Gene Expression

High amylose content (AC) in rice endosperm is correlated with poor grain quality, particularly in indica hybrid rice. We have generated several homozygous transgenic parent lines of indica hybrid rice carrying an antisense Waxy (Wx) gene and demonstrated that the AC in seeds of these lines decreased dramatically. Two transgenic maintainer lines (L25B and L18B), derived from one of the key maintainer parents of an indica hybrid rice in China, Long-te-fu B (LTF-B), were selected and the antisense Wx gene was subsequently introgressed into the male-sterile counterpart, LTF-A, with the aim to generate improved indica hybrids. The indica hybrids derived from the selected transgenic male-sterile lines and restorer lines were tested for quality and agronomic performance under normal field conditions. Our results demonstrated that the reduction of AC in the homozygous transgenic maintainer lines stably passed down in five successive generations and the improved quality was also found in their relevant transgenic hybrids produced. The other two key characters of rice cooking and eating quality, the gel consistence (GC) and gelatinization temperature (GT), were also improved in the grains of both the transgenic maintainer lines and their relevant hybrids. In addition, no change was observed for most of the agronomic characters of the transgenic maintainer lines and the relevant transgenic hybrids. Although the grain weight of the transgenic line was reduced, the grain yield of the homozygous transgenic parent lines and the transgenic hybrids was similar when compared with that of the wild-type controls. These results suggest that transgenic approaches are an effective way to obtain rice lines with both improved qualities and high yield, especially for indica hybrid rice.     

The endoplasmic reticulum stress induced by highly expressed OsrAAT reduces seed size via pre-mature programmed cell death

The high accumulation of a recombinant protein in rice endosperm causes endoplasmic reticulum (ER) stress and in turn dramatically affects endogenous storage protein expression, protein body morphology and seed phenotype. To elucidate the molecular mechanisms underlying these changes in transgenic rice seeds, we analyzed the expression profiles of endogenous storage proteins, ER stress-related and programmed cell death (PCD)-related genes in transgenic lines with different levels of Oryza sativa recombinant alpha antitrypsin (OsrAAT) expression. The results indicated that OsrAAT expression induced the ER stress and that the strength of the ER stress was dependent on OsrAAT expression levels. It in turn induced upregulation of the expression of the ER stress response genes and downregulation of the expression of the endogenous storage protein genes in rice endosperm. Further experiments showed that the ER stress response upregulated the expression of PCD-related genes to disturb the rice endosperm development and induced pre-mature PCD. As consequence, it resulted in decrease of grain weight and size. The mechanisms for the detriment seed phenotype in transgenic lines with high accumulation of the recombinant protein were elucidated.     

Rice endosperm is cost‐effective for the production of recombinant griffithsin with potent activity against HIV

Protein microbicides containing neutralizing antibodies and antiviral lectins may help to reduce the rate of infection with human immunodeficiency virus (HIV) if it is possible to manufacture the components in large quantities at a cost affordable in HIV‐endemic regions such as sub‐Saharan Africa. We expressed the antiviral lectin griffithsin (GRFT), which shows potent neutralizing activity against HIV, in the endosperm of transgenic rice plants (Oryza sativa), to determine whether rice can be used to produce inexpensive GRFT as a microbicide ingredient. The yield of ^OSGRFT in the best‐performing plants was 223 μg/g dry seed weight. We also established a one‐step purification protocol, achieving a recovery of 74% and a purity of 80%, which potentially could be developed into a larger‐scale process to facilitate inexpensive downstream processing. ^OSGRFT bound to HIV glycans with similar efficiency to GRFT produced in Escherichia coli. Whole‐cell assays using purified ^OSGRFT and infectivity assays using crude extracts of transgenic rice endosperm confirmed that both crude and pure ^OSGRFT showed potent activity against HIV and the crude extracts were not toxic towards human cell lines, suggesting they could be administered as a microbicide with only minimal processing. A freedom‐to‐operate analysis confirmed that GRFT produced in rice is suitable for commercial development, and an economic evaluation suggested that 1.8 kg/ha of pure GRFT could be produced from rice seeds. Our data therefore indicate that rice could be developed as an inexpensive production platform for GRFT as a microbicide component.     

Transgenic rice as bioreactor for production of the Candida antarctica lipase B

Candida antarctica lipase B (CALB) is a versatile biocatalyst used for a wide range of biotransformation. Methods for low cost production of this enzyme are highly desirable. Here, we report a mass production method of CALB using transgenic rice seeds as the bioreactor. The transgenic rice transformed with the CALB gene under the control of the promoter of the rice seed storage protein GT1 was found to have accumulated a large quantity of CALB in seeds. The transgenic line with the highest lipolytic activity reached to 85 units per gram of dry seeds. One unit is defined as the amount of lipase necessary to liberate 1 μmol p‐nitrophenol from p‐nitrophenyl butyrate in 1 min. The rice recombinant lipase (rOsCALB) from this line represents 40% of the total soluble proteins in the crude seed extracts. The enzyme purified from the rice seeds had an optimal temperature of 40 °C, and optimal pH of 8.5, similar to that of the fermentation products. Test of its conversion ability as a biocatalyst for biodiesel production suggested that rOsCALB is functionally identical to the fermentation products in its industrial application.     

The suppression of the glutelin storage protein gene in transgenic rice seeds results in a higher yield of recombinant protein

Glutelin is a major seed storage protein, accounting for 60?C80?% of the total endosperm protein content in rice. To test whether we could augment the expression of an introduced recombinant protein in rice by suppressing the glutelin gene, we generated transgenic glutelin RNAi (glu RNAi) rice seeds. RNA gel blot analyses confirmed that the endogenous glutelin gene was severely suppressed in these transgenic rice lines. RT-PCR analysis further revealed that all the members of glutelin multigene family were downregulated. Transgenic glu RNAi rice seeds expressing a recombinant red fluorescent protein (RFP) showed stronger fluorescence than seeds transformed with the RFP gene only. Western blot analysis further revealed that the relative accumulation of RFP in glu RNAi seeds was twofold higher than that in the RFP-only transgenic seeds. These results suggest that RNAi targeting of an endogenous storage protein could be of great utility in obtaining higher transgene expression in genetically engineered rice and other plant lines.     

Transgenic rice seed synthesizing diverse flavonoids at high levels: a new platform for flavonoid production with associated health benefits

Flavonoids possess diverse health‐promoting benefits but are nearly absent from rice, because most of the genes encoding enzymes for flavonoid biosynthesis are not expressed in rice seeds. In the present study, a transgenic rice plant producing several classes of flavonoids in seeds was developed by introducing multiple genes encoding enzymes involved in flavonoid synthesis, from phenylalanine to the target flavonoids, into rice. Rice accumulating naringenin was developed by introducing phenylalanine ammonia lyase (PAL) and chalcone synthase (CHS) genes. Rice producing other classes of flavonoids, kaempferol, genistein, and apigenin, was developed by introducing, together with PAL and CHS, genes encoding flavonol synthase/flavanone‐3‐hydroxylase, isoflavone synthase, and flavone synthases, respectively. The endosperm‐specific GluB‐1 promoter or embryo‐ and aleurone‐specific 18‐kDa oleosin promoters were used to express these biosynthetic genes in seed. The target flavonoids of naringenin, kaempferol, genistein, and apigenin were highly accumulated in each transgenic rice, respectively. Furthermore, tricin was accumulated by introducing hydroxylase and methyltransferase, demonstrating that modification to flavonoid backbones can be also well manipulated in rice seeds. The flavonoids accumulated as both aglycones and several types of glycosides, and flavonoids in the endosperm were deposited into PB‐II‐type protein bodies. Therefore, these rice seeds provide an ideal platform for the production of particular flavonoids due to efficient glycosylation, the presence of appropriate organelles for flavonoid accumulation, and the small effect of endogenous enzymes on the production of flavonoids by exogenous enzymes.     

Transgenic barley expressing a fungal xylanase gene in the endosperm of the developing grains

The feasibility of producing plant cell wall polysaccharide-hydrolysing feed enzymes in the endosperm of barley grain was investigated. The coding region of a modified xylanase gene (xynA) from the rumen fungus, Neocallimastix patriciarum, linked with an endosperm-specific promoter from cereal storage protein genes was introduced into barley by Agrobacterium-mediated transformation. Twenty-four independently transformed barley lines with the xylanase gene were produced and analysed. The fungal xylanase was produced in the developing endosperm under the control of either the rice glutelin B-1 (GluB-1) or barley B1 hordein (Hor2-4) promoter. The rice GluB-1 promoter provided an apparently higher expression level of recombinant proteins in barley grain than the barley Hor2-4 promoter in both transient and stable expression experiments. In particular, the mean value for the fungal xylanase activity driven by the GluB-1 promoter in the mature grains of transgenic barley was more than twice that with the Hor2-4 promoter. Expression of the xylanase transgene under these endosperm-specific promoters was not observed in the leaf, stem and root tissues. Accumulation of the fungal xylanase in the developing grains of transgenic barley followed the pattern of storage protein deposition. The xylanase was stably maintained in the grain during grain maturation and desiccation and post-harvest storage. These results indicate that the cereal grain expression system may provide an economic means for large scale production of feed enzymes in the future.     

Ectopic expression of a novel OsExtensin‐like gene consistently enhances plant lodging resistance by regulating cell elongation and cell wall thickening in rice

Plant lodging resistance is an important integrative agronomic trait of grain yield and quality in crops. Although extensin proteins are tightly associated with plant cell growth and cell wall construction, little has yet been reported about their impacts on plant lodging resistance. In this study, we isolated a novel extensin‐like (OsEXTL) gene in rice, and selected transgenic rice plants that expressed OsEXTL under driven with two distinct promoters. Despite different OsEXTL expression levels, two‐promoter‐driven OsEXTL‐transgenic plants, compared to a rice cultivar and an empty vector, exhibited significantly reduced cell elongation in stem internodes, leading to relatively shorter plant heights by 7%–10%. Meanwhile, the OsEXTL‐transgenic plants showed remarkably thickened secondary cell walls with higher cellulose levels in the mature plants, resulting in significantly increased detectable mechanical strength (extension and pushing forces) in the mature transgenic plants. Due to reduced plant height and increased plant mechanical strength, the OsEXTL‐transgenic plants were detected with largely enhanced lodging resistances in 3 years field experiments, compared to those of the rice cultivar ZH11. In addition, despite relatively short plant heights, the OsEXTL‐transgenic plants maintain normal grain yields and biomass production, owing to their increased cellulose levels and thickened cell walls. Hence, this study demonstrates a largely improved lodging resistance in the OsEXTL‐transgenic rice plants, and provides insights into novel extensin functions in plant cell growth and development, cell wall network construction and wall structural remodelling.     

Improvement of Human lysozyme Expression in Transgenic Rice Grain by Combining Wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis>) <Emphasis Type="Italic">puroindoline b</Emphasis> and Rice <Emphasis Type="Italic">(Oryza sativa)</Emphasis> Gt1 Promoters and Signal Peptides

Heterologous protein expression levels in transgenic plants are of critical importance in the production of plant-made pharmaceuticals (PMPs). We studied a puroindoline b promoter and signal peptide (Tapur) driving human lysozyme expression in rice endosperm. The results demonstrated that human lysozyme expressed under the control of the Tapur cassette is seed-specific, readily extractable, active, and properly processed. Immuno-electron microscopy indicated that lysozyme expressed from this cassette is localized in protein bodies I and II in rice endosperm cells, demonstrating that this non-storage promoter and signal peptide can be used for targeting human lysozyme to rice protein bodies. We successfully employed a strategy to improve the expression of human lysozyme in transgenic rice grain by combining the Tapur cassette with our well established Gt1 expression system. The results demonstrated that when the two expression cassettes were combined, the expression level of human lysozyme increased from 5.24 ± 0.34 mg⁻¹ g flour for the best single cassette line to 9.24 ± 0.06 mg⁻¹ g flour in the best double cassette line, indicating an additive effect on expression of human lysozyme in rice grain.     

Down‐regulation of OsSPX1 caused semi‐male sterility,resulting in reduction of grain yield in rice

OsSPX1, a rice SPX domain gene, involved in the phosphate (Pi)‐sensing mechanism plays an essential role in the Pi‐signalling network through interaction with OsPHR2. In this study, we focused on the potential function of OsSPX1 during rice reproductive phase. Based on investigation of OsSPX1 antisense and sense transgenic rice lines in the paddy fields, we discovered that the down‐regulation of OsSPX1 caused reduction of seed‐setting rate and filled grain number. Through examination of anthers and pollens of the transgenic and wild‐type plants by microscopy, we found that the antisense of OsSPX1 gene led to semi‐male sterility, with lacking of mature pollen grains and phenotypes with a disordered surface of anthers and pollens. We further conducted rice whole‐genome GeneChip analysis to elucidate the possible molecular mechanism underlying why the down‐regulation of OsSPX1 caused deficiencies in anthers and pollens and lower seed‐setting rate in rice. The down‐regulation of OsSPX1 significantly affected expression of genes involved in carbohydrate metabolism and sugar transport, anther development, cell cycle, etc. These genes may be related to pollen fertility and male gametophyte development. Our study demonstrated that down‐regulation of OsSPX1 disrupted rice normal anther and pollen development by affecting carbohydrate metabolism and sugar transport, leading to semi‐male sterility, and ultimately resulted in low seed‐setting rate and grain yield.     

Over‐expression of mutated ZmDA1 or ZmDAR1 gene improves maize kernel yield by enhancing starch synthesis

Grain weight and grain number are important crop yield determinants. DA1 and DAR1 are the ubiquitin receptors that function as the negative regulators of cell proliferation during development in Arabidopsis. An arginine to lysine mutant at amino acid site 358 could lead to the da1‐1 phenotype, which results in an increased organ size and larger seeds. In this study, the mutated ZmDA1 (Zmda1) and mutated ZmDAR1 (Zmdar1) driven by the maize ubiquitin promoter were separately introduced into maize elite inbred line DH4866. The grain yield of the transgenic plants was 15% greater than that of the wild‐type in 3 years of field trials due to improvements in the grain number, weight and starch content. Interestingly, the over‐expression of Zmda1 and Zmdar1 promoted kernel development, resulting in a more developed basal endosperm transfer cell layer (BETL) than WT and enhanced expression of starch synthase genes. This study suggests that the over‐expression of the mutated ZmDA1 or ZmDAR1 genes improves the sugar imports into the sink organ and starch synthesis in maize kernels.