Combinatorial interactions between positive and negative cis-acting elements control spatial patterns of 4CL-1 expression in transgenic tobacco

The phenylpropanoid enzyme 4-coumarate:coenzyme A ligase (4CL) plays a key role in linking general phenylpropanoid metabolism to end-product specific biosynthetic pathways. During vascular system and floral organ differentiation, the parsley 4CL-1 gene is expressed in a restricted set of tissues and cell types where 4CL activity is required to supply precursors for the synthesis of diverse phenylpropanoid-derived products such as lignin and flavonoids. In order to localize cis -acting elements which specify complex patterns of 4CL-1 expression, we analyzed the expression of internally deleted promoter fragment— GUS fusions in tobacco plants and parsley protoplasts. Elements located between −244 and −78 were required for most aspects of developmentally regulated expression. Within this region, three separate promoter domains containing partially redundant cis -elements directed vascular-specific expression when combined with a TATA-proximal domain. A negative cis -acting element which represses phloem expression was revealed in one of the domains and appears to be responsible for restricting vascular expression to the xylem. Distinct but overlapping promoter domain combinations were required for expression in floral organs, suggesting that different combinations of cis -acting elements may direct expression in different organs. Gel retardation assays were used to demonstrate the formation of DNA-protein complexes between factors present in nuclear extracts of parsley tissue culture cells and various tobacco organs and a 4CL-1 promoter fragment. Competition experiments showed that complex formation required the presence of a 42 bp promoter domain shown to be critical for 4CL-1 expression in vascular and floral tissues. The results are discussed in light of the coordinate expression of 4CL and other phenylpropanoid genes.     

Influence of bacterial strain genotype on transient expression of plasmid DNA in plant protoplasts

It is demonstrated that transient expression of plasmid DNA in plant protoplasts can be strongly influenced by the bacterial strain used for plasmid propagation. Four different promoter constructs containing two light-responsive and two fungal elicitor-responsive parsley promoters translationally fused to the reporter gene, β-glucuronidase (GUS), were amplified in bacterial strains MC1061, DH5α or GM2163 and tested individually. Marked differences in basal expression levels and in fold inducibilities were observed upon transfection of parsley protoplasts. Low levels of basal expression and strong light or elicitor inducibilities were observed only with plasmid DNA derived from the methylation-deficient GM2163 strain. In vitro methylation of DNA prior to transformation also drastically increased basal expression levels. The results suggest that DNA methylation may be partly responsible for deregulating promoter activity in the transient expression system.     

cis-regulatory elements involved in ultraviolet light regulation and plant defense.

An elicitor-regulated transient expression system was established in soybean protoplasts that allowed the identification of cis-regulatory elements involved in plant defense. The 5' region of an ultraviolet (UV) light-inducible and elicitor-inducible chs gene (chs1) of soybean was subjected to deletion analysis with the help of chimeric chs-nptII/gus gene constructs. This analysis delimited the sequences necessary for elicitor inducibility to -175 and -134 of the chs1 promoter. The same soybean sequences were able to direct elicitor inducibility in parsley protoplasts, suggesting a conserved function of cis-acting elements involved in plant defense. In addition, this region of the soybean promoter also promotes UV light inducibility in parsley protoplasts. However, in contrast to the elicitor induction, correct regulation was not observed after UV light induction when sequences downstream of -75 were replaced by a heterologous minimal promoter. This result indicates that at least two cis-acting elements are involved in UV light induction.     

A parsley 4CL-1 promoter fragment specifies complex expression patterns in transgenic tobacco.

The 4CL-1 gene is one of two highly homologous parsley genes encoding 4-coumarate:coenzyme A ligase, a key enzyme of general phenylpropanoid metabolism. Expression of these genes is essential for the biosynthesis of both defense-related and developmentally required phenylpropanoid derivatives. We examined the developmental regulation of the 4CL-1 promoter by analyzing the expression of 4CL-1-beta-glucuronidase fusions in transgenic tobacco plants. A 597-base pair 4CL-1 promoter fragment specified histochemically detectable expression in a complex array of vegetative and floral tissues and cell types. The activity of a series of 5' deleted promoter fragments was analyzed in parsley protoplasts and transgenic tobacco plants. Deletions past -210 base pairs led to a drastic decline in beta-glucuronidase activity in protoplasts and loss of tissue-specific expression in transgenic tobacco. These results were put into the context of potential protein-DNA interactions by in vivo footprint analysis of the 4CL-1 promoter in parsley cells. Loss of promoter activity in parsley protoplasts and transgenic tobacco was correlated with the deletion or disruption of the distal portion of a large (100-base pair) footprinted region within the first 200 base pairs of the 4CL-1 promoter.     

Osmotin gene expression is controlled by elicitor synergism

Arachidonic acid (AA), a fatty-acid fungal elicitor, and a cellulase preparation from Aspergillus niger , a protein-type fungal elicitor, induced osmotin gene expression. Both elicitors activated the osmotin promoter fused to a β-glucuronidase (GUS) reporter gene in a tissue-specific manner in tobacco seedlings ( Nicotiana tabacum L. cv. Wisconsin 38). The cellulase preparation was more effective than AA at the concentrations tested and, unlike AA, also induced the accumulation of osmotin mRNA and protein. Combinations of AA and the cellulase preparation had a greater than additive effect on the activation of the osmotin promoter and the accumulation of osmotin mRNA and protein. Both AA and the cellulase preparation, when applied separately, were virtually ineffective in the induction of the osmotin promoter in cotyledon tissues. However, together they were able to induce synergistically GUS fused to the osmotin promoter. Increases in osmotin-promoter-driven GUS activity and accumulation of osmotin mRNA induced by AA, the cellulase preparation or their combination were reversed by norbornadiene, an ethylene action inhibitor, indicating that ethylene is involved in the induction of the osmotin gene by these elicitors.     

Stress induction and developmental regulation of a rice chitinase promoter in transgenic tobacco

A 1.5 kb promoter fragment from the rice (Oryza sativa L.) RCH10 gene, which encodes a basic endochitinase inducible by wounding and fungal elicitor, was translationally fused to the β-glucuronidase (GUS) reporter gene and transferred to tobacco by Agrobacterium tumefaciens-mediated leaf disc transformation. Wounding of leaves induced GUS activity from low basal levels, and addition of fungal elicitor to the wounded tissue caused a further marked activation of the gene fusion. During vegetative development high levels of GUS activity were observed in roots and moderate levels in stems. Histochemical analysis indicated that the promoter was active in vascular and epidermal tissue, and the root apical tip. In flowers, high levels of GUS activity were observed in stigmas, ovaries and pollen-containing anthers, but only low levels in sepals and petals. The promoter 5′-deleted to ?160 exhibited the same patterns of expression in floral organs, and was also strongly induced by wounding and elicitor, but GUS activity was markedly reduced in vegetative organs. More detailed 5′ deletions showed that a cis-element required for floral expression was located between ?160 and ?74, and a cis element sufficient for stress induction was located 3′ of ?74. This proximal region 3′ of ?74 was also sufficient for expression in transfected rice protoplasts derived from suspension cultured cells. These data indicate that the complex developmental and environmental regulation of RCH10 promoter activity involves several distinct cis-elements for vegetative expression, floral expression and stress induction, and that signal pathways for wound and elicitor induction are conserved between monocotyledonous and dicotyledonous plants.     

A/T-rich sequences act as quantitative enhancers of gene expression in transgenic tobacco and potato plants

The role of an A/T-rich positive regulatory region (P268, -444 to -177 from the translation start site) of the pea plastocyanin gene (PetE) promoter has been investigated in transgenic plants containing chimeric promoters fused to the -glucuronidase (GUS) reporter gene. This region enhanced GUS expression in leaves of transgenic tobacco plants when fused in either orientation to a minimal pea PetE promoter (-176 to +4) and in roots when fused in either orientation upstream or downstream of a minimal cauliflower mosaic virus 35S promoter (-90 to +5). The region was also able to enhance GUS expression in microtubers of transgenic potato plants when placed in either orientation upstream of a minimal class I patatin promoter (-332 to +14). Dissection of P268 revealed that cis elements responsible for enhancing GUS expression from the minimal PetE promoter were distributed throughout P268. Multiple copies of a 31 bp A/T-rich sequence from within P268 and of a 26 bp random A/T sequence were able to enhance GUS expression from the minimal PetE promoter, indicating that A/T-rich sequences are able to act as quantitative, non-tissue-specific enhancer elements in higher plants. Abbreviations: CaMV, cauliflower mosaic virus; GUS, -glucuronidase; HMG, high-mobility group; MAR, matrix-associated region; MU, methylumbelliferone; SAR, scaffold-associated region.     

Analysis of the essential DNA region for OsEBP-89 promoter in response to methyl jasmonic acid

In rice, the characterization of OsEBP-89 is inducible by various stress- or hormone-stimuli, including ethylene, abscisic acid (ABA), jasmonate acid (JA), drought and cold. Here, we report the investigation of essential DNA region within OsEBP-89 promoter for methyl jasmonic acid (MeJA) induction. PLACE analysis indicates that this promoter sequence contains multiple potential elements in response to various stimuli. First, we fused this promoter with GUS gene and analyzed its expression under MeJA treatment through Agrobacterium infiltration mediating transient expression in tobacco leaves. Our results revealed that this chimeric gene could be inducible by MeJA in tobacco leaves. To further de- termine the crucial sequences responsible for MeJA induction, we generated a series of deletion pro- moters which were fused with GUS reporter gene respectively. The results of transient expression of GUS gene driven by these mutant promoters show that the essential region for MeJA induction is po- sitioned in the region between -1200 and -800 in OsEBP-89 promoter containing a G-box (?1127), which is distinct from the essential region containing ERE (?562) for ACC induction. In all, our finding is helpful in understanding the molecular mechanism of OsEBP-89 expression under different stimuli.     

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)