Tissue-Dependent Expression of the Rice wx+ Gene Promoter in Transgenic Rice and Petunia

The waxy (wx) locus, which controls the amylose synthesis, isknown to be expressed specifically in the endosperm and pollen.To study the tissue-specific regulation of the wx⁺ gene, weintroduced a fusion gene that consisted of the upstream sequenceof the wx⁺ gene and the gene for rß-glucuronidase(GUS) into cells of rice (Oryza sativa L.) and petunia (Petuniahybrida L.). GUS activity was examined in the regenerated transgenicrice and petunia plants. In transgenic rice, the upstream sequenceof the wx⁺ gene was sufficient to direct the tissue-specificexpression of GUS in the endosperm and pollen, and the controlof expression was quantitative. By contrast, in transgenic petunia,the same fusion gene was expressed in pollen but not in theendosperm. These results suggest that the putative cis-actingelements that direct pollen-specific expression are common toor similar in both monocotyledonous and dicotyledonous plants,whereas ciy-elements responsible for the endosperm-specificexpression of the rice wx⁺ gene do not function in petunia,in which development of the endosperm differs from that in rice. ⁴Present address: Division of Biological Sciences, GraduateSchool of Science, Hokkaido University, Kita-ku, Sapporo, 060Japan     

Cellular localization of tyrosine decarboxylase expression in transgenic opium poppy and tobacco

Opium poppy, Papaver somniferum, is cultivated for its alkaloid-rich latex. Tyrosine decarboxylase (TyDC) is the first enzyme in poppy alkaloid biosynthesis and is encoded by a small gene family. A 2,060-bp promoter fragment of TyDC5 was translationally fused to the #-glucuronidase (GUS) reporter gene and introduced into poppy and tobacco (Nicotiana tabacum). Transgenic seedlings were stained for GUS activity which localized to the xylem parenchyma in the shoots of poppy and tobacco. Roots of both species had similar expression patterns with staining in the vascular cylinder surrounding the xylem. No staining was observed in poppy laticifers suggesting that other TyDC genes may be expressed in latex or that alkaloid precursors are supplied to laticifers by adjacent cells.     

Regulation of K+ Uptake and Transport to the Xylem in Barley Roots; K+ Distribution Determined by Electron Probe X-ray Microanalysis of Frozen-Hydrated Cells

Intact roots of young barley plants (Hordeum vulgare L. cv.Proctor) were induced to transport K⁺ to the xylem at rapidor slow rates. Roots were then rapidly frozen in liquid nitrogenand fractured in the zone 70 mm behind the root tip to givetransverse faces for electron probe microanalysis. With SEMvisualization, analyses were made over the cytoplasm and vacuole(or lumen) of 14 cells types along the root radius between theouter cortex and stele, with particular emphasis on the xylem,xylem parenchyma, and phloem. Data were recorded in the formof colour-coded maps and also quantitatively. For both typesof roots, K⁺ concentration was lower over the xylem and phloemthan in the remainder of the root. The concentration of K⁺ wasgreater in the vacuole than in the cytoplasm, while for P itwas the reverse. Significantly, in roots induced to transportK⁺ rapidly the concentration of K⁺ was low in the early maturingmetaxylem and protoxylem, and in the sieve tubes of the metaphloemand protophloem. The concentrations of K⁺ in various cell typesare discussed in relation to regulation of K⁺ loading of thexylem in long-distance ion transport. Key words: Ion transport, nutrient deficiency     

Regulation of the Osmotin Gene Promoter

By introducing a chimeric gene fusion of the osmotin promoter and [beta]-glucuronidase into tobacco by Agrobacterium-mediated transformation, we have demonstrated a very specific pattern of temporal and spatial regulation of the osmotin promoter during normal plant development and after adaptation to NaCl. We have found that the osmotin promoter has a very high natural level of activity in mature pollen grains during anther dehiscence and in pericarp tissue at the final, desiccating stages of fruit development. GUS activity was rapidly lost after pollen germination. The osmotin promoter thus appears to be unique among active pollen promoters described to date in that it is active only in dehydrated pollen. The osmotin promoter was also active in corolla tissue at the onset of senescence. Adaptation of plants to NaCl highly stimulated osmotin promoter activity in epidermal and cortex parenchyma cells in the root elongation zone; in epidermis and xylem parenchyma cells in stem internodes; and in epidermis, mesophyll, and xylem parenchyma cells in developed leaves. The spatial and temporal expression pattern of the osmotin gene appears consistent with both osmotic and pathogen defense functions of the gene.     

Isolation and characterization of a Pinus radiata lignin biosynthesis-related O-methyltransferase promoter

A putative promoter fragment of a Pinus radiata gene encoding a multi-functional O-methyltransferase (AEOMT) was isolated from genomic DNA. Sequence analysis revealed a number of putative cis elements, including AC-rich motifs common in promoters of genes related to the phenylpropanoid pathway. The isolated promoter was fused to the GUS reporter gene and its expression profile analyzed in transgenic tobacco and in transient transformation experiments with P. radiata embryogenic and xylogenic tissue. The promoter conferred weak expression in embryogenic tissue but caused strong GUS activity in both ray parenchyma cells and developing tracheary elements of xylem strips. Histochemical analysis in transgenic tobacco plants revealed that the AEOMT promoter induced GUS expression in cell types associated with lignification, such as developing vessels, phloem and wood fibers and xylem parenchyma as well as in non-lignifying phloem parenchyma. The isolated promoter was activated by challenge of the tissue with a fungal pathogen. Our results also indicate that the control of lignin-related gene expression is conserved and can be compared in evolutionarily distant species such as tobacco and pine.     

Expression of BifunctionaI Caffeoyl-CoA 3-O-Methyltransferase in Stress Compensation and Lignification

Abstract: Caffeate and caffeoyl-CoA O-methyltransferases (COMTs and CCoAOMTs) catalyze the formation of ferulic acid and feruloyl-CoA, respectively, in many plants, and their physiological significance is under investigation. CCoAOMT was proposed to play a pivotal role in cell wall reinforcement during the induced disease resistance response, as exemplified in elici-tor-treated parsley cells, as well as in the formation of guaiacyl-and syringyl-type lignins. This requires selective substrate and tissue specificities. Parsley CCoAOMT expressed in E. coli methylated caffeoyl- or 5-hydroxyferuloyl-CoA to feruloyl- and sinap-oyl-CoA, whereas neither caffeate nor 5-hydroxyferulate was accepted. Tissue print hybridizations of parsley stem and root sections revealed, furthermore, that CCoAOMT mRNA is consti-tutively associated with the vascular tissues, but is also expressed in the surface cell layers upon wounding. In order to study the promoter activity of the parsley CCoAOMT gene, tobacco plantlets were transformed with parsley CCoAOMT promoter-GUS reporter gene constructs; these transformants, at the very young stage, expressed GUS activity in a narrow subapical root zone only extending later to the vascular tissue at the onset of xylem differentiation. GUS activity of the mature transgenic tobacco plants was observed exclusively in the parenchyma lining the differentiated xylem elements and xylem ray cells of root, stem or leaf tissues. Thus, parsley CCoAOMT is a bifunctional enzyme which appears to serve in both stress compensation and lignification. This was supported by the ontogenetic activity profile of tobacco endogeneous CCoAOMT, which correlated closely with the GUS expression under the control of parsley CCoAOMT promoter, while the proportion of CCoAOMT vs. COMT activities varied substantially during growth of the transgenic tobacco plants.     

Different Sets of cis-Elements Contribute to the Expression of a Catalase Gene from Castor Bean during Seed Formation and Postembryonic Development in Transgenic Tobacco

Deletion analysis of the promoter region of a gene for catalase,cat2, from castor bean (Ricinus communis) was performed to identifythe cis-regulatory elements responsible for the expression ofa rß-glucuronidase (GUS) fusion gene during seed formationand postembryonic development in transgenic tobacco. The analysisshowed that multiple cis-elements contribute to the activityof the cat2 promoter during seed formation and postembryonicdevelopment. The 5'-upstream regions from –1,241 to –816bp, from –720 to –682 bp, and from –632 to–535 bp, relative to the site of initiation of translationof cat2, contributed positively to the activity of the cat2promoter during both stages. By contrast, the region from –816to –720 bp had a negative effect at both stages. The regionfrom –682 to –632 bp contributed positively to theactivity during seed formation but negatively during postembyonicdevelopment. Histochemical analysis revealed that the multiplecis-elements determined not only the level of expression ofthe chimeric gene but also the tissue-specificity of such expression.For example, the region from –1,241 to –816 bp allowedexpression of the chimeric gene in the axis of the embryo ofthe dry seed, as well as in the cortex of the middle part ofthe hypocotyl and at the base of epicotyl in the young seedling. ¹Present address: Department of Plant Molecular and Cell Biology,University of Florida, Gainesville, Florida 32611-0511, U.S.A. ²Present address: Center for Molecular Biology and Genetics,Mie University, 1515 Kamihama, Tsu, Mie, 519 Japan ³Present address: Faculty of Biotechnology, Fukui PrefecturalUniversity, 4-1-1 Kenjojima, Matsuoka-cho, Yoshida-gun, Fukui,910-11 Japan     

Developmental and environmental regulation of tissue- and cell-specific expression for a pea protein farnesyltransferase gene in transgenic plants

Farnesylation mediates membrane targeting and in vivo activities of several key regulatory proteins such as Ras and Ras-related GTPases and protein kinases in yeast and mammals, and is implicated in cell cycle control and abscisic acid (ABA) signaling in plants. In this study, the developmental expression of a pea protein farnesyl-transferase (FTase) gene was examined using transgenic expression of the β-glucuronidase (GUS) gene fused to a 3.2 kb 5′ upstream sequence of the gene encoding the pea FTase β subunit. Coordinate expression of the GUS transgene and endogenous tobacco FTase β subunit gene in tobacco cell lines suggests that the 3.2 kb region contains the key FTase promoter elements. In transgenic tobacco plants, GUS expression is most prominent in meristematic tissues such as root tips, lateral root primordia and the shoot apex, supporting a role for FTase in the control of the cell cycle in plants. GUS activity was also detected in mature embryos and imbibed embryos, in accordance with a role for FTase in ABA signaling that modulates seed dormancy and germination. In addition, GUS activity was detected in regions that border two organs, e.g. junctions between stems and leaf petioles, cotyledons and hypocotyls, roots and hypocotyls, and primary and secondary roots. GUS is expressed in phloem complexes that are adjacent to actively growing tissues such as young leaves, roots of light-grown seedlings, and hypocotyls of dark-grown seedlings. Both light and sugar (e.g. sucrose) treatments repressed GUS expression in dark-grown seedlings. These expression patterns suggest a potential involvement of FTase in the regulation of nutrient allocation into actively growing tissues.     

The Promoter of the Gene for Plastidic Glutamine Synthetase (GS2) fromRice Is Developmentally Regulated and Exhibits Substrate-Induced Expression in Transgenic Tobacco Plants

A 1.3-kb fragment from the 5'-flanking region of the RGS-38gene, which encodes the plastidic glutamine synthetase in Oryzasativa L., was fused to a ß-glucuronidase (GUS) reportergene and introduced into Nicotiana tabacum by Agrobacterium-mediatedtransformation. The promoter directed GUS expression, both inleaves and in roots, and the expression of GUS was regulatedby light. The GUS activity was high in the mature leaves ofthe transgenic tobacco plants, in marked contrast to the activityof the GS1 promoter. The GS2 promoter also responded to externallyapplied ammonia, as is the case for the GS1 promoter. Theseresults suggest that the cis-acting regulatory elements thatcontrol the response to ammonia, a substrate for glutamine synthetase,are located within a 1.3-kb region of the promoter. (Received October 1, 1991; Accepted January 20, 1992)     

The Promoter of a Pine Photosynthetic Gene Allows Expression of a {beta}-Glucuronidase Reporter Gene in Transgenic Rice Plants in a Light-Independent but Tissue-Specific Manner

In angiosperms, the expression of the cab gene that encodesthe chlorophyll a/b-binding protein of PSII is light-regulated.However, the pine cab gene is expressed in a light-independentbut cell-type-specific manner. In the present study, the cab-6promoter (1.7 kbp) from pine was fused to a -glucuronidase (GUS)reporter gene and the chimeric gene was introduced into riceprotoplasts by electroporation. The GUS expression was studiedin the resultant transgenic rice plants. Expression of GUS ata substantial level was confirmed in primary leaves of dark-germinatedrice seedlings, and no obvious effect of light on the GUS activitywas observed. The expression of GUS was restricted to photosynthetictissues. The pine cab-6 promoter is, thus, sufficient for inductionof light-independent but cell-type-specific expression in cellsof a monocot, as is the case in the original pine cells. (Received December 17, 1993; Accepted April 22, 1994)     

Isolation and characterization of the 4-coumarate:coenzyme A ligase (4CL1) promoter from <Emphasis Type="Italic">Eucalyptus camaldulensis</Emphasis>

The most important enzyme of the phenylpropanoid pathway, 4-coumarate:coenzyme A ligase (4CL), is encoded by several homologous genes including 4CL1. The 4CL1 promoter is a tissue-specific gene expression element, particularly active in the secondary xylem or older stems. In this study, the 1127 bp 5′- upstream region of the 4CL1 coding sequence from Eucalyptus camaldulensis, Euc4CL1, was isolated and characterized. Essential putative cis-elements in the Euc4CL1 promoter included: a TATA-box at ?22/?28 position, two CCAAT-boxes at ?256/?260 and ?277/?281 positions, respectively, an AC-element at ?328/?336 and A-boxes at ?115/?120 and ?990/?995 positions. To investigate the effect of the Euc4CL1 promoter on gene expression, a plant transformation vector, pEuc4CL1p, containing the reporter gene for β-glucuronidase (GUS) under the control of Euc4CL1 promoter was constructed based on the pBI101 backbone and introduced in tobacco plants. Stable expression of the GUS gene in transgenic lines was analysed by a histochemical GUS assay. The results indicated the specific expression of the GUS gene in the stem xylem cells of transgenic tobacco lines was controlled by the Euc4CL1 promoter. The observations suggest the isolated Euc4CL1 promoter is a potential candidate for driving the expression of a foreign gene in plant xylem tissues.