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Institute
- Julius-von-Sachs-Institut für Biowissenschaften (88) (remove)
Sonstige beteiligte Institutionen
A central objective of many ecophysiological investigations is the establishment of mechanistic explanations for plant distributions in time and space. The important, albeit mostly ignored, question arises as to the nature of the organisms that should be used as representative in pertinent experiments. I suggest that it is essential to use a “demographic approach” in physiological ecology, because physiological parameters such as photosynthetic capacity (PC, determined under non-limiting conditions with the oxygen electrode) may change considerably with plant size. Moreover, as shown for nine epiphyte species covering the most important taxonomic groups, the intraspecific variability in PC was almost always higher than the interspecific variability when comparing only large individuals. In situ studies with the epiphytic bromeliad V. sanguinolenta revealed that besides physiological parameters (such as PC) almost all morphological, anatomical and other physiological leaf parameters studied changed with plant size as well. Likewise, important processes proved to be size-dependent on whole-plant level. For example, long-term water availability was clearly improved in large specimens compared to smaller conspecifics due to the increased efficiency of the tanks to bridge rainless periods. As model calculations on whole-plant level for V. sanguinolenta under natural conditions have shown photosynthetic leaf carbon gain as well as respiratory losses of heterotrophic plant parts scaled with plant size. The resulting area related annual carbon balances were similar for plants of varying size, which corresponded to observations of size-independent (and low) relative growth rates in situ. Under favorable conditions in the greenhouse, however, small V. sanguinolenta exhibited surprisingly high relative growth rates, similar to annuals, which clearly contradicts the prevalent, but barely tested notion of epiphytes as inherently slow growing plants and simultaneously illustrates the profound resource limitations that epiphytes are subjected to in the canopy of a seasonal rain forest. From habitat conditions it seems that size-related differences in water availability are the driving force behind the observed size-dependent ecophysiological changes: the larger an epiphyte grows the more independent it is with regard to precipitation patterns. In conclusion, the results strongly emphasize the need to treat plant size as an important source of intraspecific variability and thus urge researchers to consider plant size in the design of ecophysiological experiments with vascular epiphytes.
Beans, roots and leaves
(2001)
The author presents the first detailed review of the pharmacological therapy of parkinsonism from ancient times until the near present (1980). It is not clear whether parkinsonism as it is now defined – a progressive neurodegenerative disorder of the basal ganglia characterized by sharply reduced striatal dopamine levels, particularly in the striatum – has always affected a significant minority of aged persons, but suggestive evidence to this effect in the older literature is reviewed. The major discussion commences, however, with the administration of various plant alkaloids to parkinsonian patients in the second half of the 19th century. Antiparkinsonian therapy since this time may be divided into a number of phases: 1. The employment of alkaloids derived from solanaceous plants: initially hyoscyamine, then hyoscine/scopolamine and atropine. The discovery and characterization of these alkaloids, and the gradual recognition that other pharmacologically useful solanaceous alkaloids (such as duboisine) were identical with one or other of these three compounds, is discussed. 2. With the outbreak of encephalitis lethargica following the First World War, parkinsonian patient numbers increased dramatically, leading to a multiplicity of new directions, including the use of another solanaceous plant, stramonium, of extremely high atropine doses, and of harmala alkaloids. 3. The so-called “Bulgarian treatment” was popularized in western Europe in the mid-1930s. It was also a belladonna alkaloid-based therapy, but associated with greater efficacy and fewer side effects. This approach, whether as actual plant extracts or as defined combinations of belladonna alkaloids, remained internationally dominant until the end of the 1940s. 4. Synthetic antiparkinsonian agents were examined following the Second World War, with the aim of overcoming the deficiencies of belladonna alkaloid therapy. These agents fell into two major classes: synthetic anticholinergic (= antimuscarinic) agents, such as benzhexol, and antihistaminergic drugs, including diphenhydramine. These agents were regarded as more effective than plant-based remedies, but certainly not as cures for the disease. 5. A complete change in direction was heralded by the discovery in 1960 of the striatal dopamine deficit in parkinsonism. This led to the introduction of L-DOPA therapy for parkinsonism, the first approach directed against an identified physiological abnormality in the disorder. 6. Subsequent developments have thus far concentrated on refinement or supplementation of the L-DOPA effect. Recent attempts to develop neuroprotective or -restorative approaches are also briefly discussed. The thesis also discusses the mechanisms by which the various types of antiparkinsonian agent achieved their effects, and also the problems confronting workers at various periods in the design and assessment of novel agents. The impact of attitudes regarding the etiology and nature of parkinsonism, particularly with regard to symptomatology, is also considered. Finally, the history of antiparkinsonian therapy is discussed in context of the general development of both clinical neurology and fundamental anatomical, physiological and biochemical research. In particular, the deepening understanding of the neurochemical basis of central nervous system function is emphasized, for which reason the history of dopamine research is discussed in some detail. This history of antiparkinsonian therapy also illustrates the fact that the nature of experimental clinical pharmacology has markedly changed throughout this period: No longer the preserve of individual physicians, it is now based firmly on fundamental laboratory research, the clinical relevance of which is not always immediately apparent, and which is only later examined in (large scale) clinical trials. It is concluded that antiparkinsonian therapy was never irrational or without basis, but has always been necessarily rooted in current knowledge regarding neural and muscular function. The achievements of L-DOPA therapy, the first successful pharmacological treatment for a neurodegenerative disorder, derived from the fruitful union of the skills and contributions of different types by laboratory scientists, pharmacologists and clinicians.
The understanding of the mechanisms underlying the establishment and maintenance of the extraordinary biodiversity in tropical forests is a major challenge for modern biology. In this context, epiphytes are presumed to play an important role. To investigate the biological reality of this persistent yet insufficiently investigated notion, I conducted the present study. The main questions I intended to clarify were: (1) do epiphytes affect arthropod abundance and diversity in tropical tree crowns? and (2) what might be the driving forces behind this potential influence? I studied the arthropod fauna of 25 tree crowns bearing different epiphyte assemblages, and the resident fauna of 90 individual epiphytes. I also quantified the mitigating influence of epiphytes on the microclimate in tree crowns. In total, more than 277,000 arthropods were collected and about 700 morphospecies determined. Epiphytes had a significant moderating influence on canopy microclimate (Chapter 3), both at various microsites within a tree crown and among tree crowns with different epiphyte growth. On hot dry season days, they provided microsites with lower temperatures and reduced evaporative water loss compared to epiphyte-free spaces within the same tree crown. Quantitative sampling of the arthropods inhabiting three different epiphyte species provided compelling evidence for the specificity of epiphyte-associated faunas (Chapter 4). Epiphytes proved to be microhabitats for a diverse and numerous arthropod fauna, and different epiphyte species fostered both taxonomically and ecologically very distinct arthropod assemblages: among epiphyte hosts, the inhabitant faunas showed remarkably little species overlap, and guild composition differed strongly. In the subsequent chapters I investigated if this pronounced effect scaled up to the level of entire tree crowns. Arthropods were captured with three different trap types to obtain an ample spectrum of the canopy fauna (Chapter 2). Four tree categories were classified, three of which were dominated by a different species of epiphyte, and an epiphyte-free control group. On a higher taxonomic level, there were no detectable effects of epiphytes on the fauna: the ordinal composition was similar among tree categories and indifferent of the amount of epiphytes in a tree crown (Chapter 5). I examined three focal groups (ants, beetles and spiders) on species level. The diversity and abundance of ants was not influenced by the epiphyte load of the study trees (Chapter 6). Although many species readily used the epiphytes as nesting site and shelter, they seemed to be highly opportunistic with respect to their host plants. Likewise, the species richness and abundance of beetles, as well as their guild composition were entirely unaffected by the presence of epiphytes in the study trees (Chapter 7). Focusing on herbivorous beetles did not alter these results. Spiders, however, were strongly influenced by the epiphyte assemblages of the host trees (Chapter 8). Overall spider abundance and species richness did not differ among trees, but particular families and guilds exhibited marked differences in abundance between the tree categories. Most remarkable were the substantial differences in spider species composition across trees with different epiphyte assemblages. Conclusion Thus, the prevalent notion that epiphytes positively influence arthropod diversity in tropical canopies seems justified, but not without reservation. Whether an influence of epiphytes on the fauna was discernible depended greatly on (1) the scale of the investigated system: clear faunal distinctions at the microhabitat level were absent or much more subtle at the level of tree crowns. (2) the focal taxa: different arthropod orders allowed for completely different statements concerning the importance of epiphytes for canopy fauna. I therefore recommend a multitaxon approach for the investigation of large-scale ecological questions. In conclusion, I resume that epiphytes are associated with a species-specific inhabiting fauna,and that epiphytes impose an influence on certain, but not all, taxa even at the level of entire tree crowns. Although I could only hypothesize about the potential causes for this influence, this study provided the first comprehensive investigation of the role of epiphytes in determining arthropod abundance and diversity in tropical tree crowns.
The presented work shows the analysis of the correlation between the spatial and temporal expression pattern of NtAQP1 and its function in water relation in planta. In situ immunological studies indicated NtAQP1-protein accumulation in the root exodermis and endodermis, in the cortex, close to vascular bundles, in the xylem parenchyma and in cells of the stomatal cavities. The aquaporin was also found to be abundant in longitudinal cell-rows in the petioles. Expression studies with generated transgenic plants (Ntaqp1-promoter::gus or luc) confirmed the Ntaqp1 accumulation in the root, stem and petioles but also revealed further localization in pollen grains, adventitious roots and leaf glandular hairs. Ntaqp1-expression was induced during growth processes, like stem bending after gravistimulation or photostimulation, seed germination and hypocotyl elongation as well as during the comparatively fast circadian leaf movement. The expression was further stimulated by phytohormones, especially gibberellic acid (GA) and osmotic stress. Further analysis displayed a diurnal and even circadian expression of Ntaqp1 in roots and petioles. The functional analysis of the aquaporin was accomplished by reverse genetics and biophysical studies. The antisense technique was used to reduce NtAQP1-expression in tobacco plants. The antisense (AS) plants exhibited a severe reduction of Ntaqp1-mRNA, less reduction of the highly homologous NtPIP1a RNA and no effect on expression of other aquaporin family genes (PIP2, TIP). The function of NtAQP1 at the cellular level was investigated by a newly developed experimental setup to record the osmotically induced increase in protoplast volume. The reduction of NtAQP1 by the antisense expression decreased the overall cellular waterpermeability Pos for more than 50 %. Function of NtAQP1 at the whole plant level was e.g. measured by the “high-pressure flow meter method”. Those measurements revealed that the root hydraulic conductivity per unit root surface area (KRA) of roots from the AS-lines was reduced by more than 50 %. KRA displayed a strong diurnal and circadian variation with a maximum in the middle of the light period, similar to the expression pattern of Ntaqp1 in roots. Gas exchange-, stem (Ystem) and leaf (Yleaf) water potential measurement gave dissimilar values in AS and control plants under well-watered conditions. Under a water-limiting environment the Y of AS-plants remained at more negative water values, even though a further decrease in transpiration of AS-plants was detected. Quantitative analysis displayed a much stronger wilting reaction in the AS than in the control plants. Quantitative studies of the leaf movement in AS compared to control plants exhibited a dramatic reduction in velocity and also in the extent of the process. The following conclusions can be drawn. NtAQP1 was expressed at sites of anticipated high water fluxes from and to the apoplast or symplast. Additionally, the specific distribution pattern and temporal expression of NtAQP1 in petioles and the bending stem strongly indicate a role in transcellular movement of water. The reduction of NtAQP1 by the antisense expression decreased the overall cellular Pos. Conclusively, NtAQP1-function increases membrane water permeability of tobacco root protoplasts. The decrease of the specific root hydraulic conductivity (KRA) was in the same order of magnitude as the mean cellular water permeability reduction, indicating that aquaporin expression is essential in maintaining a natural root hydraulic conductance. Reduction of KRA in AS plants might be the first definitive proof that the pathway of water uptake from the root surface to the xylem involves passage across membranes. The absence of NtAQP1 resulted in a water stress signal, causing a certain stomatal closure. NtAQP1 seems to contribute to water stress avoidance in tobacco. NtAQP1 plays an essential role in fast plant movements and transcellular water shift.
Normoxic and anoxic metabolism of Nicotiana tabacum transformants lacking root nitrate reductase
(2002)
The aim of this work was to find out whether and how nitrate reduction in roots would facilitate survival of hypoxic and anoxic (flooding)-phases. For that purpose, we compared the response of roots of hydroponically grown tobacco wildtype (Nicotiana tabacum cv. Gatersleben) and of a transformant (LNR-H) with no nitrate reductase (NR) in the roots but almost normal NR in leaves (based on a nia2-double mutant). As an additional control we used occasionally a 35S-transformant of the same nia2-double mutant, which on the same genetic background constitutively expressed NR in all organs. In some cases, we also compared the response of roots from WT plants, which had been grown on tungstate for some time in order to completely suppress NR activity. The following root parameters were examined: 1) Growth and morphology 2) Root respiration rates and leaf transpiration 3) Metabolite contents in roots (ATP, hexosemonophosphates, free sugars, starch, amino acids, total protein) 4) Inorganic cation and anion contents 5) Lactate and ethanol production 6) Extractable LDH-and ADH-activities 7) Cytosolic pH values (by 31P-NMR) 8) NO Cation and anion contents of roots from WT and LNR-H were only slightly different, confirming that these plants would be better suited for our purposes than the widely used comparison of nitrate-versus ammonium-grown plants, which usually show up with dramatic differences in their ion contents. Normoxia: LNR-H-plants had shorter and thicker roots than WT with a lower roots surface area per leaf FW. This was probably the major cause for the significantly lower specific leaf transpiration of LNR-H. WT-roots had lower respiration rates, lower ATP-and HMP-contents, slightly lower sugar- and starch contents and somewhat lower amino acid contents than LNR-H roots. However, total protein/FW was almost identical. Obviously the LNR-H transformants did not suffer from N-defciency, and their energy status appeared even better than that of WT-roots. Data from the 35S-transformant were similar to those of WT. This indicates that the observed differences between WT and LNR-H were not due to unknown factors of the genetic nia2-background, but that they could be really traced back to the presence resp. absence of nitrate reduction. Anoxia: Under short-term anoxia (2h) LNR-H plants, but not WT-plants exhibited clear symptoms of wilting, although leaf transpiration was lower with LNR-H. Reasons are not known yet. LNR-H roots produced much more ethanol (which was excreted) and lactate compared to WT, but extractable ADH and LDH activities, were not induced by anoxia. However, the LDH activity background was twice as high as that of the WT troughout the time period studied. Tungstate-treated WT-roots also gave higher fermentation rates than normal WT roots. Sugar- and HMP-contents remained higher in LNR-H roots than in WT. NR in WT roots was activated under anoxia and roots accumulated nitrite, which was also released to the medium. 31P-NMR spectroscopy showed that LNR-H- roots, in spite of their better energy status, acidified their cytosol more than WT roots. Conclusions: Obviously nitrate reduction affects - by as yet unknown mechanisms - root growth and morphology. The much lower anoxic fermentation rates of WT-roots compared to LNR-H roots could not be traced back to an alternative NADH consumption by nitrate reduction, since NR activity was too low for that. An overall estimation of H+-production by glycolysis, fermentation and nitrate reduction (without nitrite reduction, which was absent under anoxia) indicated that the stronger cytosolic acidification of anoxic LNR-H roots was based on their higher fermentation rates. Thus, nitrate reduction under anoxia appears advantageous because of lower fermentation rates and concomitantly lower cytosolic acidification. However, it remained unclear why fermentation rates were so different. Perspective: Preliminary experiments had indicated that WT-roots produced more nitric oxide (NO) under anoxia than LNR-H-roots. Accordingly, we suggest that nitrate reduction, beyond a merely increased NADH-consumption, would lead to advantageous changes in metabolism, eventually via NO-production, which is increasingly recognized as an important signaling compound regulating many plant functions.
Low-molecular mass natural products from bacteria, fungi, plants and marine organisms exhibit unique structural diversity which are of interest for the identification of new lead structures for medicinals and agrochemicals. In the search for bioactive compounds from marine sponges and sponge-associated fungi, this research work resulted to the isolation of twenty-six compounds, eight of which are new metabolites. The sponges were collected from the Indo-pacific regions, particularly those from Indonesian and Philippine waters, as well as those from the Mediterranean Sea near the island of Elba in Italy. A combination of the chemically- and biologically-driven approach for drug discovery was employed, wherein extracts were screened for antibacterial, antifungal and cytotoxic activities. In addition to the bioassay-guided approach to purify the compounds responsible for the activity of the extract, TLC, UV and MS were also used to isolate the chemically most interesting substances. Hence, purified compounds which are not responsible for the initial bioscreening activity may have a chance to be evaluated for other bioactivities. Enumerated below are the compounds which have been isolated and structurally elucidated and whose bioactivities have been further characterized. 1. The extract of the fungus Cladosporium herbarum associated with the sponge Callyspongia aerizusa afforded seven structurally related polyketides, including two new twelve-membered macrolides: pandangolide 3 and 4, and a new acetyl congener of the previously isolated 5-hydroxymethyl-2-furoic acid. The two furoic acid analogues isolated were found to be responsible for the antimicrobial activity of the extract. The isolation of the known phytotoxin Cladospolide B from Cladosporium herbarum, which was originally known from Cladosporium cladosporioides and C. tenuissimum, indicates the possibility that Cladospolide B may be a chemotaxonomic marker of particular Cladosporium species. 2. The extract of the fungus Curvularia lunata associated with the Indonesian sponge Niphates olemda yielded three compounds, namely the new antimicrobially-active anthraquinone lunatin, the known bisanthraquinone cytoskyrin A, and the known plant hormone abscisic acid. The co-occurrence of the two structurally-related anthraquinones suggests that the monomeric lunatin may be a precursor in the biosynthesis of the bisanthraquinone cytoskyrin A. 3. The fungus Penicillium spp. associated with the Mediterranean sponge Axinella verrucosa yielded six compounds, namely the known antifungal griseofulvin and its less active dechloro analogue; the known toxin oxaline; and the known cytotoxic metabolite communesin B and its two new congeners communesin C and D. The new communesins were less active than communesin B in the brine-shrimp lethality test. 4. An unidentified fungus which was also isolated from the same Mediterranean sponge Axinella verrucosa as Penicillium spp. yielded the known compound monocerin which has been reported to possess phytotoxic and insecticidal activities. 5. The fungus Aspergillus flavus associated with the Philippine sponge Hyrtios aff. reticulatus yielded the known toxin a-cyclopiazonic acid. 6. The Indonesian sponge Agelas nakamurai yielded four bromopyrrole alkaloids namely the new compound 4-bromo-pyrrole-2-carboxylic acid, and the known compounds: 4-bromo-pyrrole-2-carboxamide, mukanadin B and mukanadin C. All of the four compounds except mukanadin B were found to be antimicrobially-active. Bromopyrrole alkaloids are well-known metabolites of the genus Agelas and are proven to play an important role in the chemical defense of the sponge against predation from fishes. 7. The Indonesian sponge Jaspis splendens yielded three known substances which are known for their antiproliferative activities, namely the depsipeptides jaspamide (jasplakinolide), and its derivatives jaspamide B and jaspamide C.
Plants have evolved an elaborate system to cope with a variety of biotic and abiotic stresses. Typically, under stress conditions an appropriate defense response is invoked which is accompanied by changes in the metabolic status of the plant. Photosynthesis is downregulated and sucrose is imported into the tissue, which provides a faster and more constant flux of energy and carbon skeletons to perform the defense response. Interestingly, these processes are co-ordinately regulated and the signal transduction chains underlying these cellular programs appear to share at least some common elements. Both the induction of sink metabolism and defense response is dependent on signal transduction pathways involving protein phosphorylation. Furthermore, regulation of extracellular invertase (INV) and phenylalanine ammonia lyase (PAL) which are markers for sink metabolism and defense response is preceded by the transient activation of MAP kinases. In depth analysis of MAP kinase activation by partial purification led to the discovery that, depending on the stimulus, different subsets of MAP kinases are activated. This differential MAPK activation is likely to possess a signal encoding function. In addition, the partial purification of MAP kinases was found to be suitable to address specific cellular functions to individual MAP kinase isoenzymes. By this way, LpWIPK was identified as the major MAP kinase activity induced after stimulation of tomato cells with different elicitors. LpWIPK is thus considered as a key regulator of defense response together with sink induction in tomato. A study using nonmetabolisable sucrose analogs revealed that the regulation of photosynthesis is not directly coupled to this signal transduction pathway since it is independent of MAP kinase activation. Nonetheless, downregulation is induced by the same stimuli that induce the defense response and sink metabolism and it will therefore be interesting to uncover the branch points of this signalling network in the future. MAP kinases are not only central components regulating the response to biotic stresses. In addition to e.g. pathogens, MAP kinases are as well involved in signal transduction events invoked by abiotic stresses like cold and drought. In a recent study, we could show that a MAP kinase is activated by heat stress, under conditions a plant will encounter in nature. This previously unknown MAP kinase is able to specifically recognise the heat stress transcription factor HsfA3 as a substrate, which supports a role of this MAP kinase in the regulation of the heat stress response. Moreover, the observation that HsfA3 is phosphorylated by the heat activated MAP kinase in vitro provides a promising basis to identify HsfA3 as the first physiological substrate of a plant MAP kinase. Intracellular protons have been implicated in the signal transduction of defense related signals. In a study using Chenopodium rubrum cells, we could show that cytosolic changes in pH values do not precede the regulation of the marker genes INV and PAL. Depending on the stimulus applied, cytosolic acidification or alkalinisation can be observed, which excludes a role for protons as signals in this pathway. Together with the concomitant changes of the pH value of the extracellular space, these variations can thus be considered as terminal part of the defense response itself rather than as a second messenger. WRKY transcription factors have only recently been identified as indirect targets of a central plant MAP kinase cascade. In addition, the identification of cognate binding sites in the promoters of INV and PAL supports a role for these proteins in the co-ordinate regulation of defense response and sink induction. A novel elicitor responsive WRKY transcription factor, LpWRKY1, was cloned from tomato and characterised with respect to its posttranslational modification. This immediate early transcription factor is transiently induced upon pathogen attack and the induction is dependent on phosphorylation. Furthermore, it was shown for the first time with respect to WRKY transcription factors, that LpWRKY1 is phosphorylated in vivo. Analysis of the role of this phosphorylation by in gel assays using recombinant WRKY protein as the substrate revealed two protein kinases that are transiently activated during the defense response to phosphorylate LpWRKY1. This data demonstrates that WRKY proteins require phosphorylation to modulate their DNA binding or transactivating activity.
Summary Background: In a previous study, nitrate reductase (NR, EC 1.6.6.1) from leaves of Ricinus communis L. showed different regulatory properties from most other higher plants NR's by an unusually strong Mg2+-sensitivity, a different pH-activity profile and only little ATP-dependent inactivation. The aim of this work was to elucidate the deviating properties of Ricinus NR in more details, from both molecular and physiological aspects. For that purpose, the NR gene from R. communis was cloned, expressed heterologously and characterized. Results: The deduced protein sequence showed that Ricinus NR shared high similarity with other NRs, apart from the N-terminal region. In the N-terminal region, the Ricinus NR possesses an acidic stretch which is conserved only in higher plants. Within the Moco-binding domain the Ricinus NR contained few amino acid residues which were unique in comparison with 17 plant NRs, including His103, Gln123, Val266 and Ala284 where other NRs possess asparagine, arginine, aspartate and praline. In the Dimer interface and Hinge 1 regions, the Ricinus NR also had some unique residues like Asn460 and Ala498 where other NRs have isoleucine and glycine instead. The Ricinus NR possesses an Arg482 which provides an additional predicted Trypsin cleavage site within 481KRHK484 (while most of plant-NRs possess KPHK). Additionally, the Ricinus NR contains a serine phosphorylation site (Ser-526) within the potential 14-3-3 binding motif 523KSVS*TP528, which is a common characteristic of nitrate reductases. In the C-Terminus of Ricinus NR a sequence 886CGPPP890 confirmed that Ricinus NR is a NADH-specific enzyme. Functional Ricinus NR protein was expressed in Pichia pastoris and compared with the features of Arabidopsis NR2 synthesized by the same expression system (AtNR2). The recombinant Ricinus NR (RcNR) itself was unresponsive to the incubation with MgATP, and so was AtNR2. As yeast extracts might lack factors required for NR regulation, desalted leaf extracts containing NR kinases and 14-3-3s were prepared from 4-day darkened (and therefore NR-free) leaves of Arabidopsis (ADL), spinach (SDL) and Ricinus (RDL), and added to the assay of RcNR and AtNR2 to check for ATP-dependent inactivation and Mg2+-sensitivity. When RcNR was combined with the NR-free extracts described above, it's unusually high Mg2+-sensitivity was restored only by incubation with RDL, but it remained unresponsive to ATP. In contrast, AtNR2 became inactive when incubated with the protein mixtures and ATP. It is obvious that one or some factors existing in RDL could interact with RcNR and therefore provide its high Mg2+-sensitivity. Interestingly, incubation of AtNR2 with different NR-free leaf extracts gave a significant activation of the enzyme activities, both in Mg2+ and EDTA, which were not observed in the case of RcNR. Moreover, using ammonium sulfate to fractionation the RDL revealed that about 0.2 mg of the protein factor(s) from 0-35% of ammonium sulfate precipitation was sufficient to provide the maximum inhibition of the RcNR. Conclusions: The insensitivity to ATP appears an inherent property of Ricinus NR, whereas the high Mg2+-sensitivity depends on one or several factors in Ricinus leaves. This as yet unknown factor(s) was boiling-sensitive and could be precipitated by ammonium sulfate. It appeared to interact specifically with recombinant Ricinus-NR to provide the Mg2+-sensitivity of the authentic leaf enzyme. Presumably, there is also a positive regulatory factor(s) for nitrate reductase existing in the leaves of higher plants.
Two isoforms of human CD23 (CD23a and CD23b) have been described. They differ by only 6-7 residues in the N-terminal cytoplasmic tail. CD23a is restrictively expressed on B-cells while CD23b is inducible on B-cells, as well as monocytes, eosinophils, macrophages and a variety of other cell types, after IL-4 stimulation. The two isoforms seems to have different functions. CD23a appears to be the isoform associated with endocytosis of IgE immune complexes and mediating antigen presentation on B-cells. CD23b has a phagocytosis motif and seems to be involved in the phagocytosis of IgE-coated particles, cytokine release and the generation of superoxides. Previous studies indicate that the two isoforms connect to different signal transduction pathways. Comparing the cells that express only one or both CD23 isoforms suggests that CD23b is involved in upregulating cAMP and iNOS, whereas CD23a mediates an increase in intracellular calcium. In the main part of the study we investigated how the CD23a B-cell specific expression is regulated. Pax-5 is a B-cell restricted transcription factor with an essential role in early and late B-cell development. Putative Pax-5 binding sites have been predicted in the CD23a proximal promoter. Analyses of the CD23a promoter revealed three putative Pax-5 binding sites with more than 50% homology to the consensus sequence. One of these sites, named CD23-1 can compete a high affinity Pax-5 binding site or can directly bind Pax-5 protein in electrophoretic mobility shift assays. Introducing mutations into this site abrogates the binding. A different approach, in which overlapping peptides covering the length of the CD23a promoter were tested in competition assays against a high affinity binding site, also revealed CD23-1 as the only site that directly binds Pax-5 protein. Expression of Pax-5 in 293 cells resulted in a 7-fold activation of a CD23a core promoter construct. Co-transfection together with STAT6 showed that Pax-5 cooperates with this transcription factor in enhancing the level of transcription of a CD23a extended promoter construct. Most importantly, ectopic expression of Pax-5 in the monocytic cell line U-937 that regularly expresses only the CD23b isoform enabled a significant CD23a expression after stimulation with IL-4 and PMA. Our results suggest that Pax-5 is a key regulator of the B-cell restricted expression of the CD23a isoform. In the second part of the project, we used a yeast two-hybrid system (CytoTrapTM from Stratagene) in order to look for cytoplasmic interaction partners for the CD23 receptor. The system was established in order to reach a high efficiency of transformation and different bait vector constructs were made. The screening was performed using a human spleen library cloned in the target vector of the system. The first bait constructs used (pSosCD23a and pSosCD23b) expressed the very short (22 amino acids) cytoplasmic tails of the isoforms at the C-terminal end of the fusion protein (human SOS). Improved bait constructs, (pSosCD23a+Linker and pSos CD23b+Linker) expressed the cytoplasmic tail of CD23a/b at the N-terminal side of the human SOS and had in consequence the N-terminal part free as a bait, as it occurs in vivo. A flexible linker region separated the fusion proteins in order to make the small amino acid bait chain more obvious. Approximately three million library clones were screened with these various constructs. No “true positive” interaction was detected. A relatively high number of “false positive” clones were obtained and checked in another two-hybrid system. A new bait construct, in which the tyrosine residue in the cytoplasmic tail of CD23a was replaced by a glutamic acid residue will be used for future screening. The system was also used in order to test the interaction between CD23 and p59fyn, a member of the Src family of protein kinases that was mentioned to associate with CD23a. No interaction was detected by using the CytoTrap two-hybrid system. In conclusion, the key result of the study demonstrates that Pax-5 is a main regulator of the B-cell specific expression of the CD23a isoform. In addition, a two-hybrid system was established and employed in order to look for cytoplasmic interaction partners for CD23.
Because of growth and development, plant tissues are characterised by a permanent change in source-sink relations. Tissues with a net carbohydrate export (source) or import (sink) have to adopt their actual demand for assimilates according to the developmental status. Furthermore, plants, as sessile life forms, have developed regulatory mechanisms that enable a flexible response of assimilate partitioning to specific requirements of the habitat, like biotic and abiotic stress factors and changing light conditions. The distribution of assimilates involves specific enzyme functions including sugar transporters and sucrose cleaving enzymes and is regulated by a variety of stimuli. Extracellular invertases cover an essential function in apoplastic phloem unloading and play an important role in regulating source-sink relations. This property is reflected by the occurrence of different invertase isoenzymes with specific expression and regulation patterns that enable a co-ordination of the carbohydrate metabolism in diverse tissues, at different developmental stages, and under varying environmental conditions. Improved knowledge of extracellular invertase function might allow altering growth, development or pathogen resistance of crop plants in a specific way. The present study is aimed at elucidating the regulation patterns and functions of three members of the extracellular invertase gene family of tomato, Lin5, Lin6, and Lin7. Detailed promoter analysis revealed a tissue- and developmental-specific expression of isoenzymes and corresponding regulation patterns. Lin5 shows a developmental regulated expression in fruits. Lin6 is expressed in early developmental stages starting in germinating seeds; in grown up plants Lin6 is solely expressed in pollen and upon wound-stimulation. Lin7 is exclusively expressed in tapetum and pollen tissue. The hormonal regulation of all three isogenes was analysed in detail, whereby known GA- and JA-mediated flower phenotypes could be correlated with invertase functions. In addition, an important role of Lin7 invertase in pollen germination was demonstrated in a functional approach. This is the most profound analysis of extracellular invertases in the delicate process of floral organ development that includes three tomato isoenzymes. In particular, dissection of the individual roles of Lin5, Lin6, and Lin7 reveals novel insights in carbohydrate supply during flower and fruit development. The analysed tissue-specific promoters are profitable tools in plant biotechnology, which in particular applies to the pollen-specific Lin7 promoter. It has been demonstrated that the Lin6 promoter serves as target for hormonal-, sugar-, and wound-mediated signalling pathways. Moreover, a functional interaction of circadian oscillator elements of A. thaliana with the Lin6 promoter and a diurnal rhythm of Lin6 expression have been substantiated. This complex regulation pattern is reflected by the identification of many well-defined cis-acting elements within the Lin6 promoter. This feature supports an integration of various stimuli mediated via extracellular invertase expression resulting in a co-ordinated cellular response to changing internal and external conditions. As sugars on their part induce Lin6 expression, this could result in signal amplification via a positive feedback loop. Furthermore, the extensive appearance and constellation of cisacting elements within the Lin6 promoter provides the basis to answer questions in signal cross-talk and signal integration in plant gene expression. In addition, the Lin6 promoter was successfully used as an inducible expression system. In transgenic tobacco lines an invertase inhibitor was expressed under control of the cytokinin-inducible Lin6 promoter. Thereby, a causal relationship between cytokinin and extracellular invertase for the delay of senescence was demonstrated. This study emphasises the importance of inducible expression systems to address specific questions on a molecular basis. The above-mentioned promoter sequences were obtained via sequential genome walks. Hereby two interesting structural features appeared. First, Lin5 and Lin7 genes are arranged in a direct tandem repeat on the genome. Second, a CACTA-like transposon insertion in intron I of the Lin5 gene was revealed. A primer pair deduced from the transposase region of this transposon allowed the amplification of similar sequences of various Solanaceae species.