The pea ferredoxin I gene exhibits different light responses in pea and tobacco

Ectopically expressed sweet pepper ferredoxin PFLP enhances disease resistance to Pectobacterium carotovorum subsp. carotovorum affected by harpin and protease-mediated hypersensitive response in Arabidopsis

Plant ferredoxin-like protein (PFLP) is a photosynthesis-type ferredoxin (Fd) found in sweet pepper. It contains an iron-sulphur cluster that receives and delivers electrons between enzymes involved in many fundamental metabolic processes. It has been demonstrated that transgenic plants overexpressing PFLP show a high resistance to many bacterial pathogens, although the mechanism remains unclear. In this investigation, the PFLP gene was transferred into Arabidopsis and its defective derivatives, such as npr1 (nonexpresser of pathogenesis-related gene 1) and eds1 (enhanced disease susceptibility 1) mutants and NAHG-transgenic plants. These transgenic plants were then infected with the soft-rot bacterial pathogen Pectobacterium carotovorum subsp. carotovorum (Erwinia carotovora ssp. carotovora, ECC) to investigate the mechanism behind PFLP-mediated resistance. The results revealed that, instead of showing soft-rot symptoms, ECC activated hypersensitive response (HR)-associated events, such as the accumulation of hydrogen peroxide (H2 O2 ), electrical conductivity leakage and expression of the HR marker genes (ATHSR2 and ATHSR3) in PFLP-transgenic Arabidopsis. This PFLP-mediated resistance could be abolished by inhibitors, such as diphenylene iodonium (DPI), 1-l-trans-epoxysuccinyl-leucylamido-(4-guanidino)-butane (E64) and benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone (z-VAD-fmk), but not by myriocin and fumonisin. The PFLP-transgenic plants were resistant to ECC, but not to its harpin mutant strain ECCAC5082. In the npr1 mutant and NAHG-transgenic Arabidopsis, but not in the eds1 mutant, overexpression of the PFLP gene increased resistance to ECC. Based on these results, we suggest that transgenic Arabidopsis contains high levels of ectopic PFLP; this may lead to the recognition of the harpin and to the activation of the HR and other resistance mechanisms, and is dependent on the protease-mediated pathway.

Analysis of trans-silencing interactions using transcriptional silencers of varying strength and targets with and without flanking nuclear matrix attachment regions

We investigated the effect of the Rb7 matrix attachment region (MAR) on trans-silencing in tobacco plants, comparing the effects of three transgene silencer loci on ten target loci. Two of the silencer loci, C40 and C190, contain complex and rearranged transgene arrays consisting of 35S:GUS or NOS:NPTII containing plasmids. The third silencer locus, V271, was previously characterized as a complex locus containing rearranged 35S:RiN sequences. Each of these silencers can reduce 35S promoter-driven expression at other loci, albeit with varying efficiencies. The presence of MARs at a target locus does not prevent trans-silencing by the V271 silencer. However, four of seven MAR-containing loci were at least partially resistant to silencing by the C40 and C190 loci. One MAR locus was unaffected by C40, our weakest silencer, and three were silenced only when the silencer locus was maternally inherited. Silencing is progressive in the F1 and F2 generations; two days after germination there is little or no difference between seedlings derived from crosses to silencing or control lines, but seedlings containing silencer loci slowly lose expression during subsequent development. These observations are compatible with the hypothesis that a product of the silencer locus must accumulate before unlinked loci can be affected. However, our silencer loci are themselves silenced for GUS transcription, and coding region homology is not required for their effects on target loci. Our results are consistent with a model in which transcriptional silencing is triggered by transcription of sequences during the early stages of embryo or seedling development.

Post-transcriptional light regulation of nuclear-encoded genes

A significant number of studies have detected a post-transcriptional component in the light responses of nuclear genes. As yet there are few in-depth studies of the mechanism(s) involved, and it seems likely some additional examples have been missed. For instance, transcriptional responses have sometimes been inferred on the basis of experiments with translational fusions containing both the promoter and 5' UTR of the test gene, but we now know that elements within the 5' UTR can mediate post-transcriptional light responses. Similarly, because of possible changes in translation rates and protein turnover, the common assumption that mRNA levels directly dictate protein levels is tenuous at best. It is no longer permissible to assume that the biological effect of a gene is a simple function of its transcription. Thus it is likely that with careful experimental design, reports of nuclear-encoded post-transcriptional gene regulation will become increasingly prevalent.

Developmental, circadian and light regulation of wheat ferredoxin gene expression

A genomic clone encoding the precursor of wheat leaf ferredoxin has been isolated and characterised. The uninterrupted PetF gene encodes a polypeptide of 143 amino acid residues, consisting of an N-terminal presequence of 46 amino acid residues and a mature polypeptide of 97 amino acid residues. Southern blot analysis suggests that six copies of the PetF gene are present in the wheat haploid genome. Northern blot analysis has shown that the genes are both developmentally and light regulated in wheat seedlings and provides evidence that a circadian rhythm regulates the steady-state levels of ferredoxin transcripts. The intact wheat gene and several chimeric constructs, containing portions of the 5'-upstream region fused to the beta-glucuronidase reporter gene, have been introduced into tobacco plants, but levels of beta-glucuronidase activity above background were not detected, suggesting that the 5'-upstream region is unable to function as a promoter in tobacco plants.

Promoters from genes for plastid proteins possess regions with different sensitivities toward red and blue light

The light-regulated expression of eight nuclear-encoded genes for plastid proteins from spinach (Spinacia oleracea) (RBCS-1 and CAB-1; ATPC and ATPD, encoding the subunits gamma and delta of the ATP synthase; PC and FNR; PSAD and PSAF, encoding the subunits II and III of photosystem I reaction center) was analyzed with promoter/beta-glucuronidase (GUS) gene fusions in transgenic tobacco (Nicotiana tabacum and Nicotiana plumbaginifolia) seedlings and mature plants under standardized light and growth conditions. Unique response patterns were found for each of these promoters. GUS activities differed more than 30-fold. Strong promoters were found for the PC and PSAD genes. On the other hand, the ATPC promoter was relatively weak. Expression of the CAB/GUS gene fusion in etiolated material was at the detection limit; all other chimeric genes were expressed in the dark as well. Light stimulation of GUS activities ranged from 3- (FNR promoter) to more than 100-fold (CAB-1 promoter). The FNR promoter responded only to red light (RL) and not significantly to blue light (BL), whereas the PC promoter contained regions with different sensitivities toward RL and BL. Furthermore, different RNA accumulation kinetics were observed for the PSAF, CAB, FNR, and PC promoter/GUS gene fusions during de-etiolation, which, at least in the case of the PSAF gene, differed from the regulation of the corresponding endogenous genes in spinach and tobacco. The results suggest either that not all cis elements determining light-regulated and quantitative expression are present on the spinach promoter fragments used or that the spinach cis-regulatory elements respond differently to the host (tobacco) regulatory pathway(s). Furthermore, as in tobacco, but not in spinach, the trans-gene hardly responds to single light pulses that operate through phytochrome. Taken together, the results suggest that the genes have been independently translocated from the organelle to the nucleus during phylogeny. Furthermore, each gene seems to have acquired a unique set of regulatory elements.

Light-regulated expression of the Arabidopsis thaliana ferredoxin A gene involves both transcriptional and post-transcriptional processes

Ferredoxin is part of the photosynthetic apparatus of the chloroplast and is encoded in the nucleus. In Arabidopsis thaliana expression of the ferredoxin A gene is influenced by both the presence of chloroplasts and light. Tobacco plants transformed with a ferredoxin promoter-GUS fusion gene showed a tissue-specific and light-dependent expression pattern. The effect of light on the expression of the fusion gene in transgenic seedlings was only two- to fourfold, which is less pronounced than the 20-fold effect in Arabidopsis itself. Run-on transcription assays with nuclei isolated from Arabidopsis revealed a twofold modulation of transcriptional activity of the ferredoxin A gene under the influence of light. These results suggest the involvement of post-transcriptional processes in light-regulated gene expression. A ferredoxin promoter deletion series ranging from -1205 to -143 was studied. All but the smallest deletion construct (at position -143 relative to the translation start site) showed comparable expression levels in mature leaves, suggesting the presence of a positive regulating element between -269 and -143. The same pattern of tissue specificity was found in all promoter deletions studied. Expression of the fusion genes is high in all chloroplast-containing cells: mesophyll, chlorenchyma, paravascular tissue, epidermal and stomatal guard cells and trichomes. Transgenic seedlings treated with norflurazon, which blocks the development of green chloroplasts, showed a two- to fourfold reduction in GUS expression for all constructs. In Arabidopsis seedlings the effect of norflurazon on the expression of the ferredoxin A was eightfold. This again can be explained by the need for post-transcriptional processes of the regulated gene expression of Arabidopsis ferredoxin A.

Response of a nitrite-reductase 3.1-kilobase upstream regulatory sequence from spinach to nitrate and light in transgenic tobacco

In the present study the question was addressed of whether the nitrite-reductase (NIR-)promoter from spinach (Spinacia oleracea L.), fused to a reporter gene (bacterial β-glucuronidase, GUS) and introduced into tobacco (Nicotiana tabacum L.) responds to nitrate and light in accordance with spinach (donor) or in accordance with tobacco (host). The data obtained at the GUS enzyme level as well as at the transcript level allow an unambiguous answer to this question: GUS gene expression under the control of the NIR-promoter from spinach responds to nitrate and light in accordance with the host (tobacco). Expression of the promoter-less GUS gene was not induced by any treatment.

Iron-dependent stability of the ferredoxin I transcripts from the cyanobacterial strains Synechococcus species PCC 7942 and Anabaena species PCC 7937

The effect of iron on ferredoxin I specific mRNA levels was studied in the cyanobacterial strains Synechococcus sp. PCC 7942 (Anacystis nidulans R2) and Anabaena sp. PCC 7937 (Anabaena variabilis ATCC 29413). In both strains addition of iron to iron-limited cells resulted in a rapid increase in ferredoxin mRNA levels. To investigate the possible role of the ferredoxin promoter in iron regulation, a vector for promoter analysis in Synechococcus PCC 7942 strain R2-PIM9 was constructed, which contains the ferredoxin promoter fused to the gene encoding beta-glucuronidase (GUS) as reporter. Neither the Synechococcus nor the Anabaena ferredoxin promoter was able to direct iron-regulated GUS activity in Synechococcus R2-PIM9, indicating that transcription initiation is not responsible for the iron-dependent ferredoxin mRNA levels. Determination of the half-life of the ferredoxin transcript in iron-supplemented and iron-limited cells revealed that, in both strains, the ferredoxin transcript is much more stable in iron-supplemented cells than in iron-limited cells. These results lead to the conclusion that in these strains, iron-regulated expression of the ferredoxin I gene is mediated via differential mRNA stability.

Expression of the chlorophyll-a/b-protein multigene family in pea (Pisum sativum L.) : Evidence for distinct developmental responses

To measure transcript levels for individual members of the Cab (chlorophyll a/b protein) multigene family in pea under a range of developmental situations, we developed a system using cDNA synthesis, the polymerase chain reaction (PCR), and chemiluminescence detection. In order to design gene-specific PCR primers for all genes, a partial genomic clone for a fifth, Type I LHCII (light-harvesting complex of photosystem II) gene, Cab-9 The Cab-9 sequence appears in the Genbank/EMBL databases under the accession number M86906 , was isolated and sequenced. All seven known Cab genes in pea are expressed in light-grown buds and leaves, including several genes previously known only from genomic clones. There appear to be at least two groups of Cab genes in pea which differ in their response to light and development. The first group (consisting of Cab-8, AB96, Cab-215 and Cab-315) includes Type I, Type II and Type III genes, shows a relatively strong response to red light, and has bud transcript levels similar to or slightly higher than leaves. The second group, consisting of the Type I genes Cab-9, AB80 and AB66, shows little or no transcript accumulation 24 h after a red light pulse, and has higher transcript levels in leaves than in buds. Transcript levels for genes in this second group appear to be lower than those of the first group in all developmental situations examined. These data indicate that there has been an evolutionary divergence of the responses to light and development among the Type I LHCII genes.

Both internal and external regulatory elements control expression of the pea Fed-1 gene in transgenic tobacco seedlings

In previous studies using leaves of light-grown transgenic tobacco plants, we have shown that sequences located within the transcribed region of the pea Fed-1 gene (encoding ferredoxin I) are major cis-acting determinants of light-regulated mRNA accumulation. However, we show here that these internal sequences are less important for the Fed-1 light response in etiolated tobacco seedlings than they are in green leaves and that upstream elements confer organ specificity and contribute significantly to Fed-1 light responses in etiolated material. Light effects mediated by upstream response elements are thus most pronounced during the initial induction of gene activity, whereas internal elements play a more prominent role in modulating Fed-1 expression once the gene is already active.