Hypersensitivity of an Arabidopsis sugar signaling mutant toward exogenous proline application

In transgenic Arabidopsis a patatin class I promoter from potato is regulated by sugars and proline (Pro), thus integrating signals derived from carbon and nitrogen metabolism. In both cases a signaling cascade involving protein phosphatases is involved in induction. Other endogenous genes are also regulated by both Pro and carbohydrates. Chalcone synthase (CHS) gene expression is induced by both, whereas the Pro biosynthetic Delta(1)-pyrroline-5-carboxylate synthetase (P5CS) is induced by high Suc concentrations but repressed by Pro, and Pro dehydrogenase (ProDH) is inversely regulated. The mutant rsr1-1, impaired in sugar dependent induction of the patatin promoter, is hypersensitive to low levels of external Pro and develops autofluorescence and necroses. Toxicity of Pro can be ameliorated by salt stress and exogenously supplied metabolizable carbohydrates. The rsr1-1 mutant shows a reduced response regarding sugar induction of CHS and P5CS expression. ProDH expression is de-repressed in the mutant but still down-regulated by sugar. Pro toxicity seems to be mediated by the degradation intermediate Delta(1)-pyrroline-5-carboxylate. Induction of the patatin promoter by carbohydrates and Pro, together with the Pro hypersensitivity of the mutant rsr1-1, demonstrate a new link between carbon/nitrogen and stress responses.     

Dissection of the interferon gamma-MHC class II signal transduction pathway reveals that type I and type II interferon systems share common signalling component(s).

We have used a herpes virus thymidine kinase (HSV-TK) based metabolic selection system to isolate mutants defective in the interferon gamma mediated induction of the MHC class II promoter. All the mutations act in trans and result in no detectable induction of MHC and invariant chain (Ii) gene expression. Scatchard analysis indicates that the mutants have a normal number of surface IFN gamma receptors with the same affinity constant. The mutants fall into two broad categories. One class of mutants is still able to induce MHC class I, IRF-1, 9-27, 1-8 and GBP genes by IFN gamma. A second class of mutants is defective for the IFN gamma induction of all the genes tested; surprisingly, the IFN alpha/beta induction of MHC class I, 9-27, ISG54 and ISG15 genes is also defective in these mutants, although different members of this class can be discriminated by the response of the GBP and IRF-1 genes to type I interferons. These data demonstrate that the signalling pathways of both type I and type II interferon systems share common signal transduction component(s). These mutants will be useful for the study of IFN gamma regulation of class II genes and Ii chain, and to elucidate molecular components of type I and type II interferon signal transduction.     

Organ-specificity and inducibility of patatin class I promoter from potato in transgenic arabidopsis plants

Patatin class I promoter (B33 promoter) is a tissue-specific potato (Solanum tuberosum L.) promoter expressing the patatin gene mainly in tubers. However, it can be induced in other organs by sucrose or light. We compared the activity of this promoter fused with the reporter gene during heterological expression in B33::GUS transgenic arabidopsis (Arabidopsis thaliana L.) plants and homological expression of the same DNA construct in potato. Promoter activity was estimated from quantification of β-glucuronidase (GUS) activity. It was shown that, during heterological expression in arabidopsis seedlings, B33 promoter manifested a tissue-specificity and inducibility, although in a different manner than during homological expression in potato. In noninduced arabidopsis seedlings, B33 promoter was most active in the roots, whereas, after induction with sucrose treatment, it became most active in cotyledons. 10 mM sucrose was sufficient for a manifold activation of B33 promoter in intact seedlings. The degree of B33 promoter induction by sucrose in arabidopsis seedlings was strictly organ-specific and increased in the following sequence: root < hypocotyl < cotyledons. 150–200 mM sucrose enhanced B33 promoter activity in cotyledons by 200 to 300 times, i.e., much stronger than in potato organs. Glucose and fructose were less efficient than sucrose. Phytohormones affecting tuber formation in potato (gibberellins, auxins, and cytokinins) did not affect significantly B33 promoter activity in arabidopsis. A lag period of approximately 6 h preceded sucrose-induced B33 promoter activation. This indicates that the patatin promoter is not the primary target for the sucrose signal. The quantitative examination of heterological expression of patatin class I promoter further clarifies its basic functional characteristics and permits a better prognosis of its behavior after transferring into other plant species.     

A class II patatin promoter is under developmental control in both transgenic potato and tobacco plants

Summary A new member of the patatin gene family belonging to the class II subfamily was isolated and characterized by DNA sequencing. In order to study the expression profile of this gene, the promoter was fused to the -glucuronidase gene and transferred to potato and tobacco. Histochemical analysis revealed high expression in a few defined cells in potato tubers and in a specific layer of both potato and tobacco root tips. In contrast to the developmentally and metabolically regulated class I patatin gene B33 this gene was not inducible by elevated levels of sucrose. Expression of this chimaeric gene was also found in callus and suspension cultures of potato.     

Storekeeper defines a new class of plant-specific DNA-binding proteins and is a putative regulator of patatin expression

The expression of class I patatin genes is restricted to potato tubers but can be induced in other tissues by exogenous sucrose. Here we show that tuber-specific and sucrose-inducible gene expression is reduced in transgenic potato plants by mutations in a conserved 10 base pair motif within the B-box of the patatin promoter. In a southwestern screen, we have isolated a novel DNA-binding protein designated Storekeeper (STK) that specifically recognises the B-box motif in vitro. Gel shift experiments with an STK-specific antibody suggest that STK is the B-box binding protein found in tuber nuclei. We propose that STK, the defining member of a new class of DNA binding proteins, regulates patatin expression in potato tubers via the B-box motif.     

Characterization of mutants in Arabidopsis showing increased sugar-specific gene expression, growth, and developmental responses

Sugars such as sucrose serve dual functions as transported carbohydrates in vascular plants and as signal molecules that regulate gene expression and plant development. Sugar-mediated signals indicate carbohydrate availability and regulate metabolism by co-coordinating sugar production and mobilization with sugar usage and storage. Analysis of mutants with altered responses to sucrose and glucose has shown that signaling pathways mediated by sugars and abscisic acid interact to regulate seedling development and gene expression. Using a novel screen for sugar-response mutants based on the activity of a luciferase reporter gene under the control of the sugar-inducible promoter of the ApL3 gene, we have isolated high sugar-response (hsr) mutants that exhibit elevated luciferase activity and ApL3 expression in response to low sugar concentrations. Our characterization of these hsr mutants suggests that they affect the regulation of sugar-induced and sugar-repressed processes controlling gene expression, growth, and development in Arabidopsis. In contrast to some other sugar-response mutants, they do not exhibit altered responses to ethylene or abscisic acid, suggesting that the hsr mutants may have a specifically increased sensitivity to sugars. Further characterization of the hsr mutants will lead to greater understanding of regulatory pathways involved in metabolite signaling.     

A detailed study of the regulation and evolution of the two classes of patatin genes in Solanum tuberosum L.

The class-specific expression of patatin genes was investigated by analysing four new patatin genes. A class I patatin gene from cv. Berolina as well as a class I and two class II patatin genes from the monohaploid cultivar AM 80/5793 were isolated and partially sequenced. Sequence comparison indicates rearrangements as the major source for the generation of diversity between the different members of the classes. The expression of single genes was studied in potato plants transformed with chimaeric genes where the putative patatin promoters were fused to the GUS reporter gene. A detailed histochemical analysis reveals that both class I genes are expressed as the previously described class I patatin gene B33 from cv. Berolina [1], i.e. in the starch-containing cells of potato tubers and in sucrose-induced leaves. The class II gene pgT12 shows the same pattern as the previously described class II gene pgT2 [2], i.e. expression in root tips and in the vascular tissue of tubers, whereas no activity was detectable for pgT4. Thus the expression pattern of both classes of genes seems to be stable at least within or even between different cultivars.     

Both developmental and metabolic signals activate the promoter of a class I patatin gene

Patatin is one of the major soluble proteins in potato tubers and is encoded by a multigene family. Based on structural considerations two classes of patatin genes are distinguished. The 5′-upstream regulatory region of a class I gene contained within a 1.5 kb sequence is essential and sufficient to direct a high level of tuber-specific gene activity which was on average 100- to 1000-fold higher in tubers as compared to leaf, stem and roots in greenhouse grown transgenic potato plants when fused to the β-glucuronidase reporter gene. Histochemical analysis revealed this activity to be present in parenchymatic tissue but not in the peripheral phellem cells of transgenic tubers. Furthermore the promoter fragment can be activated in leaves under conditions that simulate the need for the accumulation of starch in storage organs, i.e. high levels of sucrose. The expression is restricted to both mesophyll and epidermal cells in contrast to vascular tissue or hair cells.     

Differential expression of the CO2 fixation operons of Rhodobacter sphaeroides by the Prr/Reg two-component system during chemoautotrophic growth

In Rhodobacter sphaeroides, the two cbb operons encoding duplicated Calvin-Benson Bassham (CBB) CO2 fixation reductive pentose phosphate cycle structural genes are differentially controlled. In attempts to define the molecular basis for the differential regulation, the effects of mutations in genes encoding a subunit of Cbb3 cytochrome oxidase, ccoP, and a global response regulator, prrA (regA), were characterized with respect to CO2 fixation (cbb) gene expression by using translational lac fusions to the R. sphaeroides cbb(I) and cbb(II) promoters. Inactivation of the ccoP gene resulted in derepression of both promoters during chemoheterotophic growth, where cbb expression is normally repressed; expression was also enhanced over normal levels during phototrophic growth. The prrA mutation effected reduced expression of cbb(I) and cbb(II) promoters during chemoheterotrophic growth, whereas intermediate levels of expression were observed in a double ccoP prrA mutant. PrrA and ccoP1 prrA strains cannot grow phototrophically, so it is impossible to examine cbb expression in these backgrounds under this growth mode. In this study, however, we found that PrrA mutants of R. sphaeroides were capable of chemoautotrophic growth, allowing, for the first time, an opportunity to directly examine the requirement of PrrA for cbb gene expression in vivo under growth conditions where the CBB cycle and CO2 fixation are required. Expression from the cbb(II) promoter was severely reduced in the PrrA mutants during chemoautotrophic growth, whereas cbb(I) expression was either unaffected or enhanced. Mutations in ccoQ had no effect on expression from either promoter. These observations suggest that the Prr signal transduction pathway is not always directly linked to Cbb3 cytochrome oxidase activity, at least with respect to cbb gene expression. In addition, lac fusions containing various lengths of the cbb(I) promoter demonstrated distinct sequences involved in positive regulation during photoautotrophic versus chemoautotrophic growth, suggesting that different regulatory proteins may be involved. In Rhodobacter capsulatus, ribulose 1,5-bisphosphate carboxylase-oxygenase (RubisCO) expression was not affected by cco mutations during photoheterotrophic growth, suggesting that differences exist in signal transduction pathways regulating cbb genes in the related organisms.     

Mitogen-activated protein kinase activation induces corticotrophin-releasing hormone gene expression in human placenta

Corticotropin-releasing hormone (CRH) gene expression in human placental cells is induced by activation of the cyclic AMP and protein kinase C signal transduction pathways, but the role of the mitogen-activated kinase (MAPK) pathway is unknown. In this study, we showed that the MAPK inhibitor, PD098059, causes a dose-dependent inhibition of placental CRH gene expression. In contrast, overexpression of RAF in human choriocarcinoma JEG cells stimulates CRH promoter activity by 15-fold, and the stimulation is inhibited by 65% by co-transfection of the cells with a plasmid expressing a RAF dominant/negative protein. The stimulation by RAF was completely abolished by mutation of the cyclic AMP response element (CRE) in the proximal region of the CRH promoter. Taken together, these results strongly suggest that the MAPK signal transduction pathway plays a pivotal role in the regulation of CRH gene expression in human placenta, and that the CRE binding site in the proximal CRH promoter acts as a point of convergence for different signal transduction pathways in the regulation of CRH gene expression in placenta cells.