Structure and expression of the barley lipid transfer protein gene Ltp1

We have characterized a gene (Ltp1) encoding a barley lipid transfer protein. Northern blot analysis showed that Ltp1 mRNA accumulates specifically in the aleurone layer of developing and germinating seeds. Southern blot analysis indicated that LTP1 protein is encoded by a single gene in barley. Sequence analysis of Ltp1 showed that it contains an open reading frame of 351 bp interrupted by a single intron of 133 bp. Transient expression assays indicated that 702 bp of the 5 upstream region of Ltp1 is sufficient to direct aleurone-specific expression during late seed development and early germination.     

A novel endosperm transfer cell-containing region-specific gene and its promoter in rice

The endosperm of cereal grains is an important resource for both food and feed. It contains three major types of tissue: starchy endosperm, the aleurone layer, and transfer cells. To improve grain quality and quantity using molecular methods, control of transgene expression directed by distinct temporal and spatial promoter activity is necessary. To identify aleurone layer-specific and/or transfer cell-specific promoters in rice, microarray analyses were performed, comparing the aleurone layer containing transfer cells and the other reproductive and vegetative tissues. After confirmation by RT-PCR analysis, we identified two putative aleurone layer and/or transfer cell-specific genes, AL1 and AL2. The promoter regions of these genes and β-glucuronidase (GUS) fusion constructs were stably transformed into rice. The GUS expression patterns indicated that the AL1 promoter was active exclusively in the dorsal aleurone layer adjacent to the main vascular bundle. In rice, transfer cells are differentiated in this region. Therefore, the promoter of the AL1 gene exhibits transfer cell-containing region-specific activity. The AL1 gene encodes a putative anthranilate N-hydroxycinnamoyl/benzoyltransferase. The promoter of this gene will be useful for enhancing uptake of nutrients from the mother cells and protecting filial seeds from pathogen attack.     

Dehydration-Stress-Regulated Transgene Expression in Stably Transformed Rice Plants

To confer abscisic acid (ABA) and/or stress-inducible gene expression, an ABA-response complex (ABRC1) from the barley (Hordeum vulgare L.) HVA22 gene was fused to four different lengths of the 5′ region from the rice (Oryza sativa L.) Act1 gene. Transient assay of β-glucuronidase (GUS) activity in barley aleurone cells shows that, coupled with ABRC1, the shortest minimal promoter (Act1–100P) gives both the greatest induction and the highest level of absolute activity following ABA treatment. Two plasmids with one or four copies of ABRC1 combined with the same Act1–100P and HVA22(I) of barley HVA22 were constructed and used for stable expression of uidA in transgenic rice plants. Three Southern blot-positive lines with the correct hybridization pattern for each construct were obtained. Northern analysis indicated that uidA expression is induced by ABA, water-deficit, and NaCl treatments. GUS activity assays in the transgenic plants confirmed that the induction of GUS activity varies from 3- to 8-fold with different treatments or in different rice tissues, and that transgenic rice plants harboring four copies of ABRC1 show 50% to 200% higher absolute GUS activity both before and after treatments than those with one copy of ABRC1.     

Cloning and promoter analysis of the cotton lipid transfer protein gene Ltp3

A cotton Ltp3 gene and its 5′ and 3′ flanking regions have been cloned with a PCR-based genomic DNA walking method. The amplified 2.6 kb DNA fragment contains sequences corresponding to GH3 cDNA which has been shown to encode a lipid transfer protein (LTP3). The gene has an intron of 80 bp which is located in the region corresponding to the C-terminus of LTP3. The Ltp3 promoter was systematically analyzed in transgenic tobacco plants by employing the Escherichia coli β-glucuronidase gene (GUS) as a reporter. The results of histochemical and fluorogenic GUS assays indicate that the 5′ flanking region of the Ltp3 gene contains cis-elements conferring the trichome specific activity of Ltp3 promoter.     

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.     

Transient gene expression in aleurone protoplasts isolated from developing caryopses of barley and wheat

Methods have been developed for the isolation of aleurone protoplasts from developing caryopses of Hordeum vulgare and Triticum aestivum in order to study transient expression of introduced genes. Chimaeric gene constructs were introduced into aleurone protoplasts by polyethylene glycol (PEG). Transient expression directed by the 35S promoter from cauliflower mosaic virus (CaMV) of the reporter gene encoding chloramphenicol acetyl transferase (CAT) was detected in aleurone protoplasts from developing barley and wheat grains. Using a similar construct, CAT activity increased when the alcohol dehydrogenase intron 1 fragment from maize was ligated between the 35S promoter and the CAT coding region. The demonstration of transient expression in protoplasts from developing aleurone layers indicates that they may be useful for investigating tissue and developmental control of genes coding for cereal seed proteins.     

A plant-based expression system for matching cDNA clones and isozymes

Isozymes of barley α-amylase were matched to cDNAs that encode them using transient expression in oat aleurone layers. Four cDNAs, including two that are previously unpublished, were inserted into oat aleurone cells by microparticle bombardment. The cDNAs were under the control of theAct1 promoter of rice. Expression levels were sufficient for in-gel detection of enzyme activity following isoelectric focusing of aleurone homogenates. The system has also proved useful in characterizing a hybrid β-glucanase gene.     

Tissue specificity of the sugarcane bacilliform virus promoter in oat,barley and wheat

The tissue-specificity of the sugarcane bacilliform virus (SCBV) promoter was investigated in oat, barley, and wheat to determine whether its expression pattern in one species was predictive of promoter specificity in the other closely related Gramineae species. Progeny of transgenic plants produced using constructs containing the SCBV promoter driving gusA were sampled at different stages of plant development and stained for GUS activity using a histochemical assay. Overall, the GUS staining patterns were most similar between oat and barley. In all three species, similar GUS staining patterns were observed in mature endosperms, leaves, and floral bracts of developing infloresences. No GUS staining was detected in oat embryos whereas the entire barley embryo was stained, and GUS staining was confined to the scutellum of wheat embryos. Oat and barley stems exhibited GUS staining whereas no GUS staining was observed in stems of the transgenic wheat plants. The SCBV promoter conferred strong GUS staining intensity in most tissues of oat and barley but was generally weaker in wheat. These differences in SCBV promoter specificity indicate that promoter evaluation should be conducted in the target species of interest rather than by extrapolation from expression patterns in other species.