Analysis of an ABA-responsive rice gene promoter in transgenic tobacco

We have analyzed in transgenic tobacco the expression of a chimeric gene containing 5 sequences of the rice rab-16B gene fused to the -glucuronidase (GUS) reporter gene. This construct, a translational fusion (–482 to +184) including 14 amino acids of the RAB-16B protein, is expressed only in zygotic and pollen-derived embryos. In zygotic embryos, GUS activity begins to accumulate 10 days after flowering (daf), and increases until seed maturation at 25 daf. Immunological measurements of endogenous abscisic acid (ABA) accumulation in these seeds showed a close parallel between hormone levels and GUS activity. However, GUS activity could not be reproducibly induced by treatment of immature embryos with ABA (10 M). Neither GUS activity nor GUS mRNA could be detected in leaves of transgenic tobacco even after ABA treatment. In contrast, GUS activity could be induced to high levels in pollen-derived embryos by treatment with ABA. Our results show that 482 bp of 5 sequences of the rice rab-16B promoter can confer in transgenic tobacco developmentally regulated expression in embryos but not ABA-responsive expression in vegetative tissues.     

Expression of the rice Osgrp1 promoter-Gus reporter gene is specifically associated with cell elongation/expansion and differentiation

To study the expression and regulation of a rice glycine-rich cell wall protein gene, Osgrpl, transgenic rice plants were regenerated that contain the Osgrpl promoter or its 5 deletions fused with the bacterial -glucuronidase (GUS) reporter gene. We report here a detailed histochemical analysis of the Osgrpl-Gus expression patterns in transgenic rice plants. In roots of transgenic rice plants, GUS expression was specifically located in cell elongation and differentiation regions, and no GUS expression was detectable in the apical meristem and the mature region. In shoots, GUS activity was expressed only in young leaves or in the growing basal parts of developing leaves, and little GUS activity was expressed in mature leaves or mature parts of developing leaves. In shoot apices, GUS activity was detected only in those leaf cells which were starting to expand and differentiate, and GUS expression was not detected in the apical meristem and the young meristematic leaf primordia. GUS activity was highly expressed in the young stem tissue, particularly in the developing vascular bundles and epidermis. Thus, the expression of the Osgrpl gene is closely associated with cell elongation/expansion during the post-mitotic cell differentiation process. The Osgrpl-Gus gene was also expressed in response to wounding and down-regulated by water-stress conditions in the elongation region of roots. Promoter deletion analysis indicates that both positive and negative mechanisms are involved in regulating the specific expression patterns. We propose a simple model for the developmental regulation of the Osgrpl gene expression.     

Tapetum-specific expression of theOsg6B promoter-β-glucuronidase gene in transgenic rice

The promoter of an anther tapetum-specific gene,Osg6B, was fused to a-glucuronidase (GUS) gene and introduced into rice byAgrobacterium-mediated gene transfer. Fluorometric and histochemical GUS assay showed that GUS was expressed exclusively within the tapetum of anthers from the uninucleate microspore stage (7 days before anthesis) to the tricellular pollen stage (3 days before anthesis). This is the first demonstration of an anther-specific promoter directing tapetum-specific expression in rice.Abbreviations GUS ßGlucuronidase     

Characterization of a rice gene family encoding root-specific proteins

Two cDNA clones (RCc2 and RCc3) corresponding to mRNAs highly expressed only in root tissues of rice (Oryza sativa L.) seedlings were characterized. Respectively, they encode polypeptides of 146 (14.5 kDa) and 133 amino acids (13.4 kDa) that share high (<70%) sequence similarity with a polypeptide encoded by a cDNA (ZRP3) encoding an mRNA preferentially expressed in young maize roots. Genomic DNA blot analysis revealed that they are members of a small gene family and RCg2, the gene corresponding to RCc2, was isolated. A 1656 bp 5-upstream sequence of RCg2 was translationally fused to a -glucuronidase (GUS) reporter gene and stable introduction of the chimeric construct into rice was confirmed by PCR and genomic DNA blot analyses. Histochemical analysis of transgenic rice plants containing the full-length chimeric gene showed high levels of GUS activity in mature cells and the elongation and maturation zones of primary and secondary roots, and in the root caps, but no GUS activity was detected in root meristematic regions. Surprisingly, high GUS activity was also detected in leaves of the same plants. This raises the possibility that the RCg2 5-upstream element may not be sufficient for the proper spatial control of root specificity in transgenic rice.     

Cloning and characterization of the rice CatA catalase gene, a homologue of the maize Cat3 gene

We isolated and sequenced a genomic clone (CatA) encoding CAT-A catalase, a homologue of the maize catalase isozyme 3 (CAT-3) from rice (Oryza sativa L.). The 5-upstream non-coding region had very low similarity with the maize Cat3 gene and possible cis elements and sequence motifs in the maize Cat3 gene were not evident, except for TATA and CAAT motifs. Several sequence motifs found in the promoters of plant seed-specific genes were identified in the 5-upstream non-coding region of the CatA gene. Northern blotting showed that the CatA gene is expressed at high levels in seeds during early development and also in young seedlings. Methyl viologen (paraquat) resulted in the 3-fold induction of the CatA gene in the leaves of young seedlings, whereas abscisic acid, wounding, salicylic acid, and hydrogen peroxide had no or only slight effects.The 1.9 kb 5-upstream fragment (–1559 to +342) of the CatA gene was fused with the Escherichia coli -glucuronidase (GUS) gene and introduced by electroporation into protoplasts prepared from rice suspension-cultured cells, then the transient expression of the GUS gene was examined. Deletion analysis of this chimeric gene suggested that a weak silencer is located in the region between –1564 to –699. Abscisic acid (ABA) at a final concentration of 10^–6 M doubled GUS activity in protoplasts electroporated with the chimeric DNAs having 1.9 to 1.2 kb 5-upstream regions. A sequence highly similar to the Sph box, a motif found in genes modulated by ABA, was found at –266 to –254. Deletion of this region however, did not eliminate the responsiveness to ABA. Expression of the chimeric gene in the protoplasts was not enhanced by stress such as low and high temperature, hydrogen peroxide, methyl viologen, salicylic acid, elicitor, and UV light.The chimeric CatA-GUS plasmid DNAs amplified in the methylation-positive strain, E. coli DH5, showed GUS gene activities, whereas all the chimeric DNAs amplified in the methylation-deficient E. coli JM 110 were completely inactive in the presence or absence of ABA in the culture medium. DNA methylation, especially of either one or both of the deoxyadenosines at the two GATC motifs (one in the first exon and the other in the first intron of the rice CatA gene), appeared to be responsible for the CatA promoter activity identified in the transient assay.author for corresondenceThe nucleotide sequence data reported will appear in the DDBJ EMBL and GenBank Nucleotide Sequence Databases under the accession number D29966.     

Expression of CaMV35S-GUS gene in transgenic rice plants

Summary To understand the properties of the cauliflower mosaic virus (CaMV) 35S promoter in a monocotyledonous plant, rice (Oryza sativa L.), a transgenic plant and its progeny expressing the CaMV35S-GUS gene were examined by histochemical and fluorometric assays. The histochemical study showed that -glucuronidase (GUS) activity was primarily localized at or around the vascular tissue in leaf, root and flower organs. The activity was also detected in the embryo and endosperm of dormant and germinating seeds. The fluorometric assay of various organs showed that GUS activity in transgenic rice plants was comparable to the reported GUS activity in transgenic tobacco plants expressing the CaMV35S-GUS gene. The results indicate that the level of expression of the CaMV 35S promoter in rice is similar to that in tobacco, a dicotyledonous plant, suggesting that it is useful for expression of a variety of foreign genes in rice plants.     

Tissue-specific expression of the rolC promoter of the Ri plasmid in transgenic rice plants

Summary Transgenic rice plants were obtained from protoplasts treated with two plasmids by electroporation. Primary transformants were selected on the basis of resistance to hygromycin, conferred by one of the co-transferred plasmids. Out of 26 hygromycin-resistant plants 2 showed the reporter gene activity due to another plasmid possessing a chimeric gene consisting of the promoter (about 900 by upstream non-coding region) of the ORF12 gene (roIC of the Ri plasmid and the coding region for -glucuronidase (GUS). Using a colorimetric reaction, the GUS enzyme was found to be localized in vascular tissues, demonstrating the similar expression of the roIC gene promoter in monocots and dicots (Sugaya et al. 1989; Schmülling et al. 1989).     

The rice metallothionein gene promoter does not direct foreign gene expression in seed endosperm

We generated transgenic tobacco and rice plants harboring a chimeric gene consisting of the 5-upstream sequence of the rice metallothionein gene (ricMT) fused to the -glucuronidase (GUS) gene. The activity and tissue-specific expression of the ricMT promoter were demonstrated in these transgenic plants. In the transgenic rice plants, despite substantial levels of GUS activity in the shoot and root, almost no GUS signal was detected in the endosperm. Thus, the ricMT promoter could be useful in avoiding accumulation of undesired proteins in the seed endosperm.     

Characterization of a rice pollen-specific gene and its expression

Pollen development requires a large number of genes expressed in both sporophytic and gametophytic tissues. We have isolated a pollen-specific gene, PS1, from rice. PS1 is a unique gene in the rice genome and encodes a 164 amino acid long protein. RNA blot analysis shows that PS1 mRNAs accumulate specifically in rice anthers. When introduced into rice tissues by microprojectile bombardment, the PS1 promoter drives expression of a marker gene, β-glucuronidase, specifically in rice pollen. The PS1 gene and the deduced amino acid sequence of the PS1 protein share significant levels of homology with another monocot pollen-specific gene—the maize Zm-13 gene and its deduced protein, respectively. PS1 also shows some homology with the dicot tomato anther-specific gene LAT-52. Interestingly, the structure of the PS1 gene is more similar to that of the LAT-52 gene than to Zm-13. The coding regions of both PS1 and LAT-52 are interrupted by a single intron, and the positions of the introns are conserved in these genes. Moreover, there is considerable sequence homology in the introns of the PS1 and LAT-52 genes in regions immediately upstream of the 3' splice sites. The upstream regulatory sequences of the PS1 gene show several regions of homology with other pollen- or anther-specific genes from a number of plant species. The conservation of coding sequences of PS1 from rice, Zm-I3 from maize, and LAT-52 from tomato suggests a functional conservation of their gene products. Similarities in the regulatory regions of PS1 and other anther- or pollen-specific genes among monocotyledonous and dicotyledonous species indicate that at least some regulatory features controlling gene expression in male reproductive tissues are conserved. This is supported by the preservation of pollen-specific expression from the rice PS1 promoter when it is introduced into tobacco plants by Agrobacterium Ti plasmid-mediated transformation.     

Development and characterization of a chimaeric tissue-specific promoter in wheat and rice endosperm

The recently achieved significant improvement of cereal transformation protocols provides facilities to alter the protein composition of the endosperm, for example, to increase or decrease the quantity of one of its protein components or to express foreign molecules. To achieve this goal, strong endosperm-specific promoters have to be available. The aim of our work was to develop a more efficient tissue-specific promoter which is currently used. A chimaeric promoter was assembled using the 5′ UTR (1,900 bp) of the gene coding for the 1Bx17 HMW glutenin subunit protein, responsible for tissue-specific expression and the first intron of the rice actin gene (act1). The sequence around of the translation initial codon was optimized. The effect of the intron and promoter regulatory sequences, using different lengths of 1Bx17 HMW-GS promoter, were studied on the expression of uidA gene. The function of promoter elements, promoter length, and the first intron of the rice actin gene were tested by a transient expression assay in immature wheat endosperm and in stable transgenic rice plants. Results showed that insertion of the rice act1 first intron increased GUS expression by four times in transient assay. The shortest 1Bx17 HMW-GS promoter fragment (173 bp) linked to the intron and GUS reporter gene provided almost the same expression level than the intronless long 1Bx17 HMW-GS promoter. Analysis of the stable transformant plants revealed that 173 nucleotides were sufficient for endosperm-specific expression of the uidA gene, despite 13 nucleotides missing from the HMW enhancer sequence, a relevant regulatory element in the promoter region.     

Pollen-Specific Expression of <Emphasis Type="Italic">Oryza sativa Indica</Emphasis> Pollen Allergen Gene (<Emphasis Type="Italic">OSIPA</Emphasis>) Promoter in Rice and <Emphasis Type="Italic">Arabidopsis</Emphasis> Transgenic Systems

Earlier, a pollen-specific Oryza sativa indica pollen allergen gene (OSIPA), coding for expansins/pollen allergens, was isolated from rice, and its promoter—upon expression in tobacco and Arabidopsis—was found active during the late stages of pollen development. In this investigation, to analyze the effects of different putative regulatory motifs of OSIPA promoter, a series of 5′ deletions were fused to β-glucuronidase gene (GUS) which were stably introduced into rice and Arabidopsis. Histochemical GUS analysis of the transgenic plants revealed that a 1631 bp promoter fragment mediates maximum GUS expression at different stages of anther/pollen development. Promoter deletions to −1272, −966, −617, and −199 bp did not change the expression profile of the pollen specificity. However, the activity of promoter was reduced as the length of promoter decreased. The region between −1567 and −199 bp was found adequate to confer pollen-specific expression in both rice and Arabidopsis systems. An approximate 4-fold increase in the GUS activity was observed in the pollen of rice when compared to that of Arabidopsis. As such, the OSIPA promoter seems promising for generation of stable male-sterile lines required for the production of hybrids in rice and other crop plants.