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In this study I analysed past and recent Daphnia populations from Lake Constance and Greifensee. Herefore, I first established a set of microsatellite markers applicable to European Hyalodaphnia species (chapter 1). Primers were also identified for species specific fragment lengths. 32 markers were then available to characterize the resting egg banks of Daphnia galeata and D. hyalina. Chapter 2 presents the reconstruction of the taxonomic composition in these two ecologically different lakes. This part of my work shows that the eutrophication that occurred in both lakes in the mid of the last century has strongly influenced the Daphnia populations. In both lakes Daphnia galeata established and hybridized with the indigenous D. hyalina. Interspecific hybridization resulted in introgression on the mitochondrial and nuclear level. In chapter 3 resting eggs from the sediments of the 1960s, 1970s, 1980s, 1990s and 2000s were characterized with microsatellite markers. The aim was to specify the extent of interspecific hybridization and nuclear introgression assuming that the genetic exchange between both species has an impact on their adaptation to their habitat. In life history experiments D. galeata and D. galeata x hyalina clones hatched from different time periods showed significant differential responses to food quality. Therefore, the question had to be answered how the Daphnia resting egg bank and the planktonic population are connected. In chapter 4 hatching experiments were conducted to bridge this gap of scientific knowledge in the life cycle of cyclic parthenogenetic waterfleas. Only D. galeata individuals were able to establish a clonal lineage after maturity. All observed recombinant individuals did not reproduce at all or firstly went through another sexual phase of reproduction i.e. produced resting eggs. In order to compare the findings of chapter 4 with the taxon composition of the recent planktonic population of Daphnia in Lake Constance, samples were taken over one season (between May 2005 and September 2006). During the season, the taxonomic composition of Daphnia changes severely with D. galeata being most abundant during the warm season and D. hyalina in the cold season. Moreover, some individuals were detected, that did not follow this pattern. With mitochondrial analysis those individuals were identified as mitochondrial introgressants and processed to life history experiments. Significant differences in the somatic growth rate under different temperatures (5°C, 12.5°C and 20°C) were related to the origin of the mitochondrial genome rather than the nuclear taxonomic assignment of the individual.
The findings of this study show that all organisms exposed to rapid ecological changes and their microevolutionary reaction to those.
The increasing resistance of almost all pathogenic bacteria to antibiotics (multidrug resistance) causes a severe threat to public health. The mechanisms underlying multidrug resistance include the induced over expression of multidrug transporters which extrude a variety of lipophilic and toxic substrates in an energy dependent fashion through the membrane out of the cell. These proteins are found in all transporter families. The work described in this thesis is dedicated to drug-proton antiporters from the small multidrug resistance (SMR) family. These efflux pumps with just four transmembrane helices per monomer are so far the smallest transporters discovered. Their oligomeric state, topology, three dimensional structure, catalytic cycle and transport mechanism are still rather controversial. Therefore, the aim of this thesis was to directly address these questions for the small multidrug resistance proteins Halobacterium salinarium Hsmr and Escherichia coli (E. coli) EmrE using a number of biophysical methods such as NMR, transport assays, mass spectrometry and analytical ultracentrifugation. Especially the work on Hsmr has been challenging due to the halophilic nature of this protein. In Chapter 1, key questions and the most important biophysical techniques are introduced followed by Material and Methods in Chapter 2. Depending on experimental requirements, cell free or ‘classical’ in vivo expression has been used for this thesis. Cell free expression as an option for the production of small multidrug transporters has been explored in Chapter 3. It has been possible to produce the SMR family members Hsmr, EmrE, TBsmr and YdgF in vitro. The expression of Hsmr was investigated in more detail under different experimental conditions. Hsmr was either refolded from precipitate or maintained in a soluble form during expression in the presence of detergents and liposomes. Furthermore, amino acids for which no auxotrophic strains were available could be labelled successfully. This expression system has been also used for preparing labelled samples of EmrE as described in Chapter 9. In vivo in E. coli expression of Hsmr, as described in Chapter 4, provided large amounts of proteins if fermenter production was used. Uniform labelling and selective unlabelling with stable isotopes (13C, 15N) for NMR spectroscopy was achieved in vivo in a more efficient and cost effective manner than using the cell free approach for this protein. Hsmr could be purified successfully from both in vitro and in vivo expression media. Hsmr is expressed in vivo and in vitro with N-terminal formylation. The Nterminal formylation is unstable and Hsmr in the presence of low salt concentrations was amenable to N-terminal degradation. It was found that Hsmr shows longest stability in Fos-ß-choline® 12 and sodium dodecyl sulphate, but best reconstitution conditions were found, when dodecyl maltoside is used and exchanged with Escherichia coli lipids. A molar protein lipid ratio of 1 to 100, amenable to solid state nuclear magnetic resonance, has been achieved. Sample homogeneity was shown by freeze fracture electron microscopy. The oligomeric state of Hsmr in detergent has been assessed by SDS PAGE, blue native PAGE, size exclusion chromatography, analytical ultracentrifugation and laser induced liquid bead ion desorption mass spectrometry (LILBID) as described in Chapter 5. A concentration and detergent dependent monomer-oligomer equilibrium has been found by all methods. The activity of Hsmr under the sample preparation conditions used here was shown using radioactive and fluorescence binding as well as fluorescence and electrochemical transport assays (Chapter 6). For transport studies, a stable pH gradient was generated by co-reconstitution of Hsmr with bacteriorhodopsin and subsequent sample illumination. Based on the observed long term stability of Hsmr in Fos-ß-choline® 12 and sodium dodecyl sulphate, liquid state NMR experiments were attempted in order to assess the correct folding of Hsmr in detergent micelles (Chapter 7). 1D proton and 2D HSQC spectra of U-15N Hsmr revealed a poor spectral dispersion, low resolution and only a small number of peaks. These are at least partly due to long rotational correlation times of the large protein detergent complex. This problem has been overcome by applying solid-state NMR to Hsmr reconstituted into E. coli lipids (Chapter 8). Uniform 13C labelled samples were prepared and two dimensional proton-driven spin diffusion and double quantum-single quantum correlation spectra were acquired successfully. Unfortunately, the spectral resolution was not yet sufficient for further structural studies. Reasons for the observed linebroadening could be structural heterogeneity or molecular motions which interfere with the NMR timescale. Therefore, the protein mobility has been probed using static 2H solid state NMR on Ala-d3-Hsmr. It could be shown, that parts of Hsmr are remarkably mobile in the membrane and that this mobility can be limited by the addition of the substrate ethidium bromide. Ethidium bromide as well as tetraphenylphosphonium (TPP+) is typical multidrug transporter substrates. The membrane interaction of TPP+ in DMPC membranes has been resolved by 1H MAS NMR. It was found that it penetrates into the interface region of the lipid bilayers and therefore behaves like many other transporter substrates adding to the hypothesis that the membrane could act as a pre-sorting filter. Finally, Chapter 9 is dedicated to the characterisation of the essential and highly conserved residue Glu-14 in EmrE by solid-state NMR. In order to avoid spectral overlap, the single Glu EmrE E25A mutant was chosen instead of the wildtype. The protein has been produced in vitro to take advantage of reduced isotope scrambling in the cell free expression system as verified by analytical NMR spectroscopy. Correct labelling of EmrE was tested by MALDI-TOF and solid-state NMR. The dimeric state of DDM solubilised EmrE has been probed by LILBID. The labelled protein was reconstituted into E. coli lipids to ensure a native membrane environment. Activity was determined by measuring ethidium bromide transport. Freeze fracture EM revealed very homogeneous protein incorporation even after many days of MAS NMR experiments. 2D 13C double quantum filtered experiments were used to obtain chemical shift and lineshape information of Glu-14 in EmrE. Two distinct populations were found with backbone chemical shift differences of 4 - 6 ppm which change upon substrate binding. These findings indicate a structural asymmetry at the assumed dimerisation interface and are discussed in the context of a model for shared substrate/proton binding. These studies represent the first successful use of cell free expression to prepare labelled membrane proteins for solid-state NMR and allow for the first time an NMR insight into the binding pocket of a multidrug efflux pump.
Cytochrome c oxidase (CcO), also called Complex IV of the aerobic respiratory chain, is located in the plasma membrane of prokaryotes and in the inner mitochondrial membrane of eukaryotes. The redox energy of dioxygen reduction is used to translocate protons across the membrane resulting in an electrochemical proton gradient. The generated proton gradient is exploited by the adenosine-5’-triphosphate synthase. In this work, bacterial four-subunit aa3-Type CcO from Paracoccus denitrificans (ATCC 13543, 4 SU-wt ATCC CcO) was used for analyses. 1) The recombinant homologously produced 4 SU-wt CcO (4 SU-wt rec CcO) was functionally compared with the native 4 SU-wt ATCC CcO. The 4 SU-wt rec CcO showed functional deficiencies as determined by UV-vis spectroscopy and electron paramagnetic resonance (EPR) studies. Total X-ray Reflection Fluorescence measurements show in both wild type CcOs the same ratio of the redoxactive Fe and Cu (2 Fe : 3 Cu) indicating full complement of the functional metals. If CcO contains only subunit I and II, it loses its functional integrity during continuous turnover activity. The importance of subunit III for integrity of CcO was demonstrated using 2 SU-wt rec CcO. Crystallisation trials of suicide inactivated 2 SU-wt rec CcOs have been ineffective using standard crystallisation conditions. Crystals of active 2 SU-wt rec CcO (positive control) have been obtained under these conditions and this result indicates possible structural changes in suicide inactivated 2 SU-wt rec CcO. The structure of active 2 SU-wt rec CcO was determined to 2.25 Å resolution. 2) Terminal oxidases require four electrons for the cleavage of the dioxygen bond (O=O). In general, the catalytic cycle of CcO is described by the electron input and thus by the different redox states of the metal centres: the O, E, R, P and F state. The two-electron reduced R intermediate is able to donate four electrons for dioxygen reduction forming the P state. The P intermediate is an oxoferryl state implying the lack of an electron for the R -> P transition, because the metal centres can only provide three electrons (Fe+II forms Fe+IV and Cu+II forms Cu+I). The P state, where the dioxygen bond is already broken, shows an oxoferryl state (FeIV=O2-) and a nearby tyrosine is proposed to form a tyrosyl radical representing the donor of the missing electron. H2O2-induced artificial intermediates provide the opportunity to investigated different catalytic intermediates in detail. Mixing equimolar amounts of H2O2 to CcO in the O state induces the "two-electron" reduced PH state at high pH and the electronically equal "two-electron" reduced F• H state at low pH. The addition of an excess amount of H2O2 leads to the three-electron reduced FH state. Functional studies using the 4 SU-wt ATCC CcO have demonstrated a bound peroxide (O- - O-) intermediate during the catalytic cycle. Using EPR it was previously shown that Y167 hosts a radical species in PH/F• H state which suggests that Y167 could provide this "missing electron". While X-ray structural models of CcO and Fourier-transformed infrared (FTIR) measurements of oxygenated ("pulsed") 4 SU-wt ATCC CcO suggest a bound peroxide in the O state, UV-vis and EPR spectroscopic studies indicate that other intermediates may also contain such peroxide species. Equimolar and excess amounts of H2O2 induce the PH/F• H and FH states, respectively and catalase treatment of the FH state leads, contrary to the natural direction of the catalytic cycle, to the apparent transition of the FH -> PH/F• H states, which is accompanied by reappearance of an EPR signal from the Y167• radical. The novel PFH/F• FH states are presented here and we postulate that the FH state hosts a superoxide (or peroxide) adduct at CuB in the binuclear site. In addition, the novel P10 state is also introduced having a maximum at lambda = 612 nm in the difference absorption spectrum (minus the O state). The P10 state is induced by mixing CcO in the O state with a pH 10 buffer. This pH 10 induced state resembles standard P states such as PCO, PH and PR. However, the P10 state evolves out of the O state without addition of reduction equivalents. Using EPR spectroscopy it was shown that Y167 hosts a radical species in the P10 state such as in the PH state. In summary, all functional data presented here provide evidence for a peroxide bound during the O state. Finally, a new model for the natural catalytic cycle is proposed. If the O state contains a peroxide, it is also likely that the E and R state contain this species. Even the oxoferryl intermediates P and F states may complex a peroxide at CuB in the binuclear site. 3) The amino acid residue Y167, which hosts the radical in the PH/F•H states, is not directly part of the binuclear site of CcO. For identification of the primary electron donor, two tryptophan variants of CcO, W272F and W164F, which are located nearby the binuclear site, were produced. Evidence is provided that W272 is a kinetically fast electron donor for the O2 molecule. The electron is replenished by Y167, or probably by Y280 in the natural cycle. The Y167 radical is detectable by EPR spectroscopy after treatment with equimolar amounts of H2O2 in the active variant W164F, but is absent in the inactive variant W272F. 4) CcO contains two proton conducting pathways, the D- and the K-pathway. Proteoliposomes of the variants H28A and D30N, mutations located at the entrance of the D-pathway, both show the identical proton pumping activity as the 4 SU-wt rec CcO (pumped H+/e- = 1). The variant N113D shows abolished proton pumping (pumped H+/e- = 0), but a relative high cytochrome c oxidation activity (63 %). G196D displays no cytochrome c oxidation and proton pumping activity. Overall, the addition or removal of a negative charge within the D-pathway such as in D124N, N131D, N113D and G196D leads to a decoupled phenotype indicating the high degree of electrostatic coupling in CcO.
ALICE (A Large Ion Collider Experiment), is the dedicated heavy-ion experiment at the Large Hadron Collider (LHC) at CERN. It is optimised to reconstruct and identify the particles created in a lead-lead collision with a centre of mass energy of 5.5TeV. The main tracking detector is a large-volume time-projection chamber (TPC). With an active volume of about 88m^3 and a total readout area of 32.5m^2 it is the most challenging TPC ever build. A central electrode divides the 5m long detector into two drift regions. Each readout side is subdivided into 18 inner and 18 outer multi-wire proportional read-out chambers. The readout area is subdivide into 557568 pads, where each pad is read out by and electronics chanin. A complex calibration is needed in order to reach the design position-resolution of the reconstructed particle tracks of about 200um. One part of the calibration lies in understanding the electronic-response. The work at hand presents results of the pedestal and noise behaviour of the front-end electronics (FEE), measurements of the pulse-shaping properties of the FEE using results obtained with a calibration pulser and measurements performed with the laser-calibration system. The data concerned were taken during two phases of the TPC commissioning. First measurements were performed in the clean room where the TPC was built. After the TPC was moved underground and built into the experiment, a second round of commissioning took place. Noise measurements in the clean room revealed a very large fraction of pads with noise values larger than the design specifications. The unexpected high noise values could be explained by the 'ground bounce' effect. Two modifications helped to reduce this effect: A desynchronisation in the the start of the readout of groups of channels and a modification in the grounding scheme of the FEE. Further noise measurements were carried out after the TPC has been moved to the experimental area underground. Here even a larger fraction of channels showed too large noise values. This could be traced back to a common mode current injected by the electronics power supplies. To study the shaping properties of the FEE a calibration pulser was used. To generate signals in the FEE a pulse is injected to the cathode wires of the read-out chambers. Due to manufacturing tolerances slight channel-by-channel variations of the shaping properties are expected. This effects the determination of the arrival time as well as the measured integral signal of the induced charge and has to be corrected. The measured arrival time variations follow a Gaussian distribution with a width (sigma) of 6.2ns. This corresponds to an error of the cluster position of about 170um. The charge variations are on the level of 2.8%. In order to reach the intrinsic resolution on the measurement of the specific energy loss of the particles (6%) those variations have to be taken into account. The photons of the laser-calibration system are energetic enough to emit photo electrons off metallic surfaces. Most interesting for the detector calibration are photo electrons from the central electrode. The laser light is intense enough to get a signal in all readout channels of the TPC. Since the central electrode is a smooth surface, differences in the arrival time between sectors reveal mechanical displacements of the readout sectors and can be used to correct for this effect. In addition the measurements can be used to determine the electron drift velocity in the TPC gas. The drift velocity measurements have shown a vertical as well as a radial gradient. The first can be explained by the temperature gradient, which naturally builds up in the 5m high detector. The second gradient is most probably caused by a relative conical deformation of the readout plane and the central electrode.
Plastids are complex plant organelles fulfilling essential physiological functions, such as photosynthesis and amino acid metabolism. The majority of proteins required for these functions are encoded in the nuclear genome and synthesized on cytosolic ribosomes as precursors, which are subsequently translocated across the outer and inner membrane of the organelle. Their targeting to the organelle is ensured by a so called transit peptide, which is specifically recognized by GTP-dependent receptors Toc159 and Toc34 at the cytosolic side of outer envelope. They cooperatively regulate the insertion of the precursor protein into the channel protein Toc75, thereby initiating the translocation process. Toc34 is regarded as the primary receptor, while Toc159 probably provides the driving force for the insertion. Precursor transfer is achieved by the physical interaction between both receptors in the GTP loaded state. One translocon unit, also called the Toc core complex, is formed by four molecules Toc34, four molecules Toc75 and one molecule Toc159. In the GDP-loaded state, Toc34 preferably forms homodimers, whose physiological function was investigated in the presented study. It could be shown that the dissociation of GDP and therefore the nucleotide exchange are inhibited by the homodimeric state of Toc34. Dissociation of the homodimer is induced by the recognition of a precursor protein, which renders the binding of GTP and subsequent interaction with Toc159 possible. Thus, the homodimeric conformation could reflect an inactive state of the translocon, preventing GTP consumption in the absence of a precursor protein. Both homodimerization as well as heterodimerization of the receptor are regulated by phosphorylation, which could be demonstrated by in vitro and in vivo approaches using atToc33 from Arabidopsis thaliana as a model system. Since the phosphorylated form of Toc34 cannot be assembled with the Toc core complex, it can be concluded that the interactions between GTPase domains not only regulate the transfer of precursor proteins, but also warrant the integrity of the translocon.
Platelets are anucleate cells that play a major role in hemostasis and thrombosis in the vasculature. During primary hemostasis platelets adhere to sites of vascular damage and the initial platelet coat is reinforced by additional platelets forming a stable aggregate. At the same time platelets secrete their intracellular granules containing substances that further activate platelets in an autocrine and paracrine fashion and affect local coagulation and endothelial smooth muscle cell function. The small guanine nucleotide binding protein Rap1 regulates the activity of the platelet integrin alphaIIbbeta3 and thus platelet aggregation. Rap1 activity is controlled by guanine nucleotide exchange factors and GTPase activating proteins. In platelets, Rap1GAP2 is the only GTPase activating protein of Rap1. In order to identify Rap1GAP2-associated proteins, a genetic two-hybrid screening in yeast was performed and synaptotagmin-like protein 1 (Slp1, also called JFC1) was found as a new putative binding partner of Rap1GAP2. Slp1 is a tandem C2 domain containing protein and is known to bind to Rab27, a small GTPase involved in platelet dense granule secretion. The direct interaction between Rap1GAP2 and Slp1 was confirmed in yeast and in transfected cells. More importantly, Slp1 is expressed in platelets and binding of endogenous Rap1GAP2 and Slp1 was verified in these cells. The Rap1GAP2 and Slp1 interaction sites were mapped by mutational analysis. Rap1GAP2 binds through the -TKXT- motif within its C-terminus to the C2A domain of Slp1. Moreover, the Slp1 binding -TKXT- motif of Rap1GAP2 was confirmed by complementary approaches using short synthetic Rap1GAP2 peptides. The C2A domain of Slp1 is a phospholipid binding domain and thus mediates binding of Slp1 to the plasma membrane. Phospholipid overlay assays revealed that simultaneous binding of Slp1 via its C2A domain to Rap1GAP2 and to phospholipids can occur. In addition, the interaction between Rap1GAP2 and Slp1 is regulated by cAMP-dependent protein kinase (cAK or PKA), and kinase activation in platelets enhanced binding of endogenous Rap1GAP2 to Slp1. In-vitro phosphorylation assays revealed that Slp1 is a substrate of PKA, and serine 111 was identified as phosphorylation site. Since Slp1 is a Rab27 binding protein, a trimeric complex of Slp1, Rab27 and Rap1GAP2 is conceivable. The association of Slp1, Rab27 and Rap1GAP2 was investigated by immunofluorescence and co-immuno-precipitation experiments in both, transfected cells and platelets. By Slp1 affinity chromatography and subsequent mass spectrometric analysis additional Slp1 binding proteins were identified in platelets, and binding of Slp1 to Rab8 was confirmed in pull-down assays. To investigate the functional significance of the interaction between Rap1GAP2 and Slp1, an assay system was established to determine serotonin secretion of streptolysin-O permeabilized platelets. Addition of recombinant Slp1 protein to permeabilized platelets strongly inhibited platelet dense granule secretion, whereas addition of recombinant Rap1GAP2 protein or synthetic Rap1GAP2 peptide enhanced secretion. Deleting the Slp1 binding -TKXT- motif abolished the stimulatory effect of Rap1GAP2 on secretion. Addition of Rap1 to permeabilized platelets had no effect on secretion. These findings indicate that the Rap1GAP2 effect on platelet secretion does not depend on the GTPase activating function of Rap1GAP2, but is rather dependent on the -TKXT- mediated interaction of Rap1GAP2 with Slp1. In addition, in-vitro GAP assays revealed that Slp1 binding to Rap1GAP2 does not affect the Rap1GAP activity of Rap1GAP2, and adhesion assays excluded a role for the Rap1GAP2/Slp1 interaction in cell adhesion. Altogether, the results of the present study demonstrate that besides its function in platelet aggregation by controlling the activity of the small guanine nucleotide binding protein Rap1, Rap1GAP2 is involved in platelet dense granule secretion by the new -TKXT- mediated interaction with the Rab27 and membrane binding protein Slp1. In addition, the interaction between Rap1GAP2 and Slp1 is embedded into an elaborate network of protein-protein interactions in platelets which appear to be regulated by phosphorylation. Future studies will in particular aim to dissect the molecular details of Rap1GAP2 and Slp1 action in platelet secretion and investigate the potential biochemical and pharmacological value of the unique protein binding -TKXT- motif of Rap1GAP2.
The crude oil constituents benzene, toluene, ethylbenzene, and the three xylene isomers (BTEX) are the dominating groundwater contaminants originating from surface spill accidents by oil production facilities and with gasoline and jet fuel. Thereby BTEX posing a threat to the world´s scarce drinking water resources due to their water solubility and toxicity. An active remediation cleanup involving a BTEX event proves not only to be very expensive but almost impossible when it comes to the complete removal of contaminants from the subsurface. A favoured and common practice is combining an active remediation process focussing on the source of contamination coupled together with the monitoring of the residual contamination in the subsurface (monitored natural attenuation; MNA). MNA include all naturally occuring biological, chemical and physical processes in the subsurface. The general goal of this work was to improve the knowledge of biodegradation of aromatic hydrocarbons under anaerobic conditions in groundwater. For this groundwater and soil at the former military underground storage tank (UST) site Schäferhof – Süd near Nienburg/Weser (Niedersachsen, Germany) were sampled and analysed. The investigations were done in collaboration of the Umweltbundesamt, the universitys of Frankfurt and Bremen and the alphacon GmbH Ganderkesee. To investigate the extent of groundwater contamination, the terminal electron acceptor processes (TEAPs) and the metabolites of BTEX degradation in groundwater, six observation wells were sampled at regular intervals between January 2002 and September 2004. The wells were positioned in order to cover the upstream, the source area and the downstream of the presumed contamination source. Additionally, vertical sediment profiles were sampled and investigated with respect to spreading and concentration of BTEX in the subsurface. A large residual contamination involving BTEX is present in soil and groundwater at the studied locality. Maximum BTEX concentration values of 17 mg/kg were recorded in analysing sediment in the unsaturated zone. In the capillary fringe, values of 450 mg/kg were recorded (October 2004) and in the saturated zone maximum values of 6.7 mg/kg BTEX were detected. The groundwater samples indicate increasing BTEX concentrations in the groundwater flow direction (from 532 µg/l up to 3300 µg/l (mean values)). Biodegradation of aromatic hydrocarbons under anaerobic conditions in the sub surface at contaminated sites is characterised by generation of metabolites. From the monoaromatic hydrocarbons BTEX metabolites such as benzoic acid (BA) and the methylated homologs and C1-and C2-benzyl-succinic acids (BSA) are generated as intermediates. A solid-phase extraction method based on octadecyl-bonded silica sorbent has been developed to concentrate such metabolite compounds from water samples followed by derivatization and gas chromatography/mass spectrometry (GC/MS) of the extracts. The recovery rate range between 75 and 97%. The method detection limit was 0.8 µg/l. Organic acids were identified as metabolic by-products of biodegradation. Benzoic acid, C1-, C2- and C3-benzoic acid were determined in all contaminated wells with considerable concentrations. Furthermore, the depletion of the dominant terminal electron acceptors (TEAs) oxygen, nitrate, and sulphate and the production of dissolved ferrous iron and methane in groundwater indicate biological mediated processes in the plume evidently proving the occurrence of NA. A large overlap of different redox zones at the studied part of the plume has been observed. A important finding in this study is the strong influence of groundwater level fluctuations on the BTEX concentration in groundwater. A very dry summer in 2003 was recorded during the monitoring period, resulting on site in a drop of the groundwater level to 1.7 m and a concomitant increase of BTEX concentrations from 240 µg/l to 1300 µg/l. The groundwater level fluctuations, natural degradation and retention processes essentially influence BTEX concentrations in the groundwater. Groundwater level fluctuations have by far a stronger influence than the influence of biological degradation. Increasing BTEX concentrations are hence not a consequence of limited biological degradation. Another part of the study was to observe the isotopic fractionation of the electron acceptor Fe(III), due to biologically mediated reduction of Fe(III) to the watersoluble Fe(II) at the site and first field data are presented. Both groundwater and sediment samples were analysed with respect to their Fe isotopic compositions using high mass resolution Multi Collector-Inductively Coupled Plasma-Mass Spectrometry (MC-ICP-MS). The delta56Fe -values of groundwater samples taken from observation wells located downstream of the source area were isotopically lighter than delta56Fe -values obtained from groundwater in the uncontaminated well. The Fe isotopic composition of most parts of the sediment profile was similar to the Fe isotopic composition of uncontaminated groundwater. Thus, a significant iron isotope fractionation can be observed between sediment and groundwater downstream of the BTEX contamination.
Whether minorities such as the Māori in Aotearoa New Zealand, the San across Southern Africa and the Métis in Canada, or native majority peoples such as the Aymara and Quechua in South America: indigenous peoples" lifeworlds have been transfigured by the difficulties originating from a history of conquest, settlement and suppression. The imperialist strife of European empires and the atrocities committed by their gang of "explorers" – including "this person Cook" in the South Pacific, Columbus in North America, Cortéz in Mexico, Gomes in West Africa, or van Riebeeck in South Africa – was aimed at enforcing European values and institutions, destroying, silencing or marginalizing indigenous cultures and societies as inferior "others." Unsurprisingly, the disruption of formal colonialism in the second half of the 20th century held no inherent improvement for the concerns of formerly colonized peoples. ...
CHAPTER A: THE INVESTMENT BEHAVIOR OF PRIVATE EQUITY FUND MANAGERS I The Bright and Dark Side of Staging: Investment Performance and the Varying Motivations of Private Equity Firms II The Liquidation Dilemma of Money Losing Investments – The Impact of Investment Experience and Window Dressing of Private Equity and Venture Capital Funds CHAPTER B: THE ASSESSMENT OF RISK AND RETURN OF PRIVATE EQUITY I Venture Capital Performance Projection: A Simulation Approach II Modeling Default Risk of Private Equity Funds – A Market-based Framework
A novel experimental approach for studying exotic transitions in few-electron high-Z ions was developed. In this approach, few-electron ions with selectively produced single K-shell holes are used for the investigation of the transition modes that follow the decay of the excited ions. The feasibility of the developed approach was confirmed by an experimental study of the production of low-lying excited states in He-like uranium, produced by K-shell ionization of initially Li-like species. It was found that K-shell ionization is a very selective process that leads to the production of only two excited states, namely the 1s2s 21S0 and 1s2s 23S1. This high level of selectivity stays undisturbed by the rearrangement processes. These experimental findings can be explained using perturbation theory and an independent-particle model, and are a result of the very different impact parameter dependencies of K-shell ionization and L- intrashell excitation. The L-shell electron can be assumed to stay passive in the collision, whereas the K-shell electron is ionized. It was stressed that the current result might directly be applied to accurate studies of the two-photon decay in He-like ions. Up to now, the experimental challenge in conventional 2E1 experiments has been the photon-photon coincidence technique, which is required to separate the true 2E1 events from the x-ray background associated with single photon transitions. In contrast, by exploiting K-shell ionization, the spectral distribution of the two-photon decay could be obtained simply by a measurement of the photon emission, using only a single x-ray detector in coincidence with projectile ionization. One further particular advantage arises from the fact that the 1s2p 3P0 state is not populated, and does not contribute to the continuum distribution of the two-photon emission. At high Z, this state also undergoes a two-photon E1M1 decay, which would be indistinguishable from the 2E1 decay of the 1s2s 1S0. The first measurement of the two-photon energy distribution from the decay of 1s2s 1S0 level in He-like tin was performed by adopting the technique developed in this thesis. In this technique, excited He-like heavy ions were formed by K-shell ionization of initially Li-like species in collisions with a low-Z gas target, and x-ray spectra following the decay of the He-like ions were measured in coincidence with the up-charged tin ions. The observed intense production of the 2E1 transitions, and a very high level of selectivity, make this process particularly suited for the study of the two-photon continuum, and thus for a detailed investigation of the structure of high-Z He-like systems. The method allowed for a background-free measurement of the distribution of the two-photon decay (21S0 -> 11S0) in He-like tin. The measured distribution could also be discriminated from that of other He-like ions, and confirmed, for the first time, the fully relativistic calculations. In addition, the feasibility of the method was confirmed by studying another exotic transition, namely the two-electron one-photon transition (TEOP) in Li-like high-Z ions. An experimental investigation of the radiative decay modes of the 1s2s2 state in Li-like heavy ions has been started. In the first dedicated beam time at the ESR, selective population of this state via K-shell ionization of initially Be-like species was achieved. The x-rays produced in this process were measured by a multitude of x-ray detectors, each placed under different observation angles with respect to the ion beam direction. The spectra associated with projectile electron loss consist (in all cases) of one single x-ray transition, which was attributed to the TEOP decay to the 1s2 2p1/2 level, possibly contaminated by the M1 decay to the 1s22s. Thus it was proven that, by adopting the developed approach, one can indeed produce the desired initial state. This makes this method perfectly suited for studies of TEOP transitions in high-Z systems. An extension of this study, by the inclusion of an electron spectrometer, would also allow for measurements of the autoionization channel, which would provide complete information on the various decay modes of the 1s2s2 state.
This dissertation analyzes tax policy, corporations, and capital market effects. First, the Savings Directive, which has left a loophole by providing grandfathering for some securities, is examined. It can be shown that investors are not willing to pay a premium for bonds that are exempt from the withholding rate, so it may be concluded that the supply of existing loopholes is large enough to allow tax evaders to continue evasion at no additional cost. Second, tax neutrality towards alternative financing instruments for corporate investment is a ubiquitous demand in the political debate. However, the magnitude of possible efficiency costs of a departure from tax neutrality is hardly discussed. Against this background, this dissertation discusses the theory of capital structure and provides back-ofthe-envelope calculations of the possible efficiency cost of a tax distortion of the debt-equity decision. Third, the ex-dividend-day effect in relation to the Gennan tax reform of 2000/2001 is discussed. The abolishment of the imputation system allows reinvestigating the size of the exdividend- day effect. I find no structural break in the size of the German ex-dividend-day effect and no evidence of an ex-dividend-day price drop that exceeds the dividend paid. Fourth, an account of the quantitative development of tax legislation in post-war Germany is presented. It can be shown that the legislative output did not increase over the decades and is not affected by a split majority in the upper and lower houses. Finally, it turns out that an increasing fraction of this legislation is passed in December.
Structural analysis of the enzyme N-formylmethanofuran:tetrahydromethanopterin formyltransferase
(2008)
Archaea represent a third domain of life and some archaea exhibit a high degree of tolerance to extreme environmental conditions. Several members are methanogens and present in many anaerobic environments. Most methanogens are able to maintain growth simply on H2 and CO2 via the enzymatically catalyzed reaction 4H2 + CO2 > CH4 + 2 H2O. The archaeon Methanopyrus kandleri grows optimally at temperatures of 84°C to 110°C, pH values of 5.5 to 7.0 and NaCl concentrations 0.2% to 4%. The enzyme N-formylmethanofuran tetrahydromethanopterin formyltransferase (MkFTR) catalyzes the transfer of a formyl group from the cofactor N-formylmethanofuran (FMF) to the cofactor tetrahydromethanopterin (H4MPT), the second step of the above reaction. X-ray crystallographic analysis yielded insights into the structure and function of MkFTR, (1) the MkFTR monomer exhibits a pseudo-two fold structure suggestive of an evolutionary gene duplication. (2) The structure is a D2 homo-tetramer with prominent cleft-like surface features. Analysis of the interface contacts showed that the tetramer is best described as a dimer of dimers. The clefts were associated with the monomer:monomer interface and were weakly occupied by extra electron density which might be attributed to the H4MPT analog folate. (3) This suggested that the clefts are active sites and their association with oligomer interfaces suggested a basis for the dependence of activity on oligomerization. (4) The thermal stability of MkFTR most likely arises from the greater number of H- and ionic-bonds within the monomer and between monomers with respect to mesophilic protein structures. (5) The structure showed a large number of surface exposed negatively charged, glutamate and aspartate residues. These residues explain the salt dependent oligomerization, as only at high enough salt concentration is the electrostatic charge compensated by cation binding and neutralized allowing oligomerization. (6) These residues also improve the solubility of MkFTR at high salt concentration by increased charge repulsion. (7) Comparison of MkFTR structures from low and hight salt conditions showed that surface glutamate residues bind slightly more water molecules at high salt conditions further contributing to MkFTR solubility at high salt concentration.
In 1911 Eugen Bleuler (Bleuler, 1911) postulated that schizophrenia was a disorder resulting from inability to properly integrate mental processes. Around the same time, Carl Wernicke (Wernicke, 1894) proposed that psychosis might result from disruption of white matter tracts. Both of these statements can be considered early cornerstones of modern connectivity hypotheses developed towards the end of the twentieth century by such researchers as Karl Friston (1998) and Nancy Andreansen (1998). In the current work, the hypothesis that schizophrenia, rather than being a disorder or either anatomical or functional connectivity, is a disorder where both of these processes interact and influence the clinical presentation of patients, is examined. This is achieved through a detailed examination of a sample of chronic schizophrenia patients using a combination of functional and anatomical Magnetic Resonance Imaging techniques. The relationship of these measures to clinical symptoms is also explored. In the first study, anatomical connectivity at the whole-brain level is examined using Diffusion Tensor Imaging. The results of the study contribute to the previous literature on auditory hallucinations in schizophrenia and provide the first direct correlation between increased anatomical connectivity and increased severity of psychotic symptoms. The second study provides a thorough examination of the interhemispheric connectivity. This is achieved through a detailed examination of the corpus callosum using a combination of diffusivity and volumetric values. This is the first study to date where several anatomical methods are used in one sample. The results illustrate the importance of using different techniques to accurately characterize anatomical abnormalities observed in schizophrenia. In addition, contrary to previous research reports, the results of the current study imply that only specific sub-sections of the corpus callosum are affected by anatomical abnormalities. The pattern of these changes may influence clinical presentation of patients. Finally, functional connectivity at the whole-brain level is examined during resting-state using Independent Component Analysis. Similarly to the results of the anatomical examinations, it provides further supporting evidence that the pattern of disturbances observed in the current sample of schizophrenia patients examined herein reflects a combination of hypo- and hyperconnectivity. Moreover, the study further validates resting-state functional Magnetic Resonance Imaging as a reliable tool for examining functional abnormalities in schizophrenia.
The Na+,K+-ATPase was discovered more than 50 years ago, but even today the pumpcycle and its partial reactions are still not completely understood. In this thesis, Voltage Clamp Fluorometry was used to monitor the conformational changes that are associated with several electrogenic partial reactions of the Na+,K+-ATPase. The conformational dynamics of the ion pump were analyzed at different concentrations of internal Na+ or of external K+ and the influences on the conformational equilibrium were determined. To probe the effect of the internal Na+ concentration on the Na+ branch of the ion pump, oocytes were first depleted of internal Na+ and then loaded with Na+ using the epithelial sodium channel which can be blocked by amiloride. The conformational dynamics of the K+ branch were studied using different external K+ concentrations in the presence and in the absence of external Na+ to yield additional information on the apparent affinity of K+. The results of our Voltage Clamp Fluorometry experiments demonstrate that lowering the intracellular concentration of Na+ has a comparable effect on the conformational equilibrium as increasing the amount of K+ in the external solution. Both of these changes shift the equilibrium towards the E1/E1(P) conformation. Furthermore, it can be shown that the ratio between external Na+ and K+ ions is also a determinant for the position of the conformational equilibrium: in the absence of external Na+, the K+ dependent shift of the equilibrium towards E1 was observed at a much lower K+ concentration than in the presence of Na+. In addition, indications were found that both external K+ and internal Na+ bind within an ion well. Finally, the crucial role of negatively charged glutamate residues in the 2nd extracellular loop for the control of ion-access to the binding sites could be verified.
Deformation quantization on symplectic stacks and applications to the moduli of flat connections
(2008)
It is a common problem in mathematical physics to describe and quantize the Poisson algebra on a symplectic quotient [...] given in terms of some moment map [...] on a symplectic manifold [...] with a hamiltonian action by a Lie group G. Among others, problems may arise in two parts of the process: c might be a singular value of the moment map and the quotient might not be well-behaving; in the interesting cases the quotient often is singular. By the famous result of Sjamaar and Lerman ([102]) X is a symplectic stratified space. We are interested in cases for which we can give a deformation quantization of the possibly singular Poisson algebra of X. To that purpose we introduce a Poisson algebra on the associated stack [...] for special cases and consider its deformations and their classification. We dedicate ourselves to use the rather geometric methods introduced by Fedosov for symplectic manifolds in [37]. That leads to the question how to perform differential geometry on a smooth stack. The Lie groupoid atlas of a smooth stack is a nice model for the same space (Tu, Xu and Laurent-Gengoux in [107] and Behrend and Xu in [16]), but both have different topoi. We give a morphism (P,R) that compares the topologies of a smooth stack and its atlas. This yields a method to transport sheaves and their sections between a smooth stack and its Lie groupoid atlas. A symplectic stack is a smooth separated Deligne-Mumford stack with a 2-form which is closed and non-degenerate in an atlas. Via (P,R) a deformation quantization on a symplectic stack can be performed in terms of an atlas. We also give a classification functor for the quantizations in the spirit of Deligne ([35]) based on the geometric interpretation given by Gutt and Rawnsely in [49]. As an application we give a deformation quantization for the moduli stack of flat connections in particular configurations. We use Darboux charts provided by Huebschmann (e.g. in [54]) to construct the corresponding Lie groupoid. This captures the symplectic form arising in the reduction process and differs from other approaches using gerbes of bundles (e.g. Teleman [105]).
RNA interference (RNAi) is triggered by recognition of double-stranded RNA (dsRNA), and elicits the silencing of gene(s) complementary to the dsRNA sequence. RNAi is thought to have emerged as a way of safeguarding the genome against mobile genetic elements and viral infection, thus maintaining genomic integrity. dsRNA is first processed into small interfering RNAs (siRNA) by the enzyme Dicer. siRNAs are ~21 to 25 -nt long, and contain a signature 5’ phosphate group and a two nucleotide long 3’ overhang (Bernstein et al., 2001). The siRNA is then loaded into the RNA-induced si-lencing complex (RISC), of which Argonaute is the primary catalytic component (Liu et al., 2004). Energetic asymmetry of the siRNA ends allows for its directional loading into RISC (Khvorova et al., 2003; Schwarz et al., 2003). Argonaute cleaves the passen-ger strand of the siRNA, leaving the guide strand of the siRNA bound to RISC (Gregory et al., 2005; Matranga et al., 2005; Rand et al., 2005). This single-stranded guide strand siRNA bound to Argonaute is able to recognize target mRNA in a sequence-specific manner, and cleaves the mRNA. Argonaute 2 in complex with single-stranded siRNA is sufficient for mRNA recognition and cleavage, thus forming a minimal RISC (Rivas et al., 2005). miRNAs, endogenously expressed small RNA genes which typically contain mismatches and non-Watson-Crick base pairing, are processed by this general pathway, although typically modulate gene expression by translational repression as opposed to cleavage of their target mRNA. The number of Argonaute genes is highly variable between species, ranging from one in S. pombe to twenty-seven in C. elegans. Earlier crystal structures of Argonaute apoen-zymes show the architecture of Argonaute to be a multidomain protein composed of N terminal, PAZ, MID, and PIWI domains (Song et al., 2004; Yuan et al., 2005). These multi-domain proteins are present in both prokaryotic and eukaryotic organisms. The role of Argonaute proteins in prokaryotes is still unknown, but based similarity to eu-karyotic Argonautes, they may also be involved in nucleic acid-directed regulatory pathways. These proteins have served as excellent models for learning about the struc-ture and function of this family of proteins. RNAi has found a widespread application for the simple yet effective knockdown of genes of interest. The catalytic cycle of RISC requires the binding of a number of different nucleotide structures to Argonaute, and we expect Argonaute to undergo a number of conforma-tional changes during the cycle of mRNA recognition by RISC (Filipowicz, 2005; Tom-ari and Zamore, 2005). Nevertheless, it remains unclear how the multi-domain ar-rangement of Argonaute recognizes and distinguishes between single-stranded and dou-ble-stranded oligonucleotides, which correspond to the Dicer-processed siRNA product, guide strand siRNA, and the guide strand / mRNA duplex. The Argonaute protein from Aquifex aeolicus was cloned, expressed, crystallized and solved by molecular replacement. Relative to earlier Argonaute structures, a 24° reorientation of the PAZ domain in this structure opens a basic cleft between the N-terminal and PAZ domains, exposing the guide strand binding pocket of PAZ. A 5.5-ns molecular dynamics simulation of Argonaute showed a strong tendency of the PAZ and N-terminal domains to be mobile. Binding of single-stranded DNA to Argonaute was monitored by total internal reflection fluorescence spectroscopy (TIRFS). The experi-ments showed biphasic kinetics indicative of large conformational changes, and re-vealed a hotspot of binding energy corresponding to the first 9 nucleotides, the so-called “seed region” most crucial for sequence-specific target recognition. As RNAi may have evolved as a way of safeguarding the genome viral infection, it is not surprising that viruses have evolved different strategies to suppress the host RNAi response in the form of viral suppressor protein. (Hock and Meister, 2008; Lecellier and Voinnet, 2004; Rashid et al., 2007; Song et al., 2004; Vastenhouw and Plasterk, 2004). These viral suppressors are widespread, having been identified in a number of different viral families. Not surprisingly, they generally share little sequence homology with one another, although they appear to exist as oligomers built upon a ~ 100-200 amino acid protomer. Tomato aspermy virus, a member of the Cucumoviruses, encodes for protein 2B (TAV 2B, 95 a.a., ~11.3 kDa) that acts as an RNAi suppressor. Intriguingly, a similar genomic arrangement is seen in RNAi suppressors in the Nodaviruses, a family of viruses that can infect both plants and animals, such as Flock house virus b2 (FHV b2). The 2B and b2 proteins are both derived from a frameshifted ORF within the RNA polymerase gene (Chao et al., 2005). In spite of this genomic similarity, the 2B and b2 proteins share little sequence identity, and it is not well understood how the Cucumovirus 2B proteins suppress RNAi. To address how TAV 2B suppresses RNAi, the oligonucleotide-binding properties of TAV 2B were studied. TAV 2B shows a preference for double-stranded RNA oligonucleotides corresponding to siRNAs and miRNAs, and also binds to single-stranded RNA oligonucleotides. A stretch of positively charged residues between amino acids 20-30 are critical for RNA binding. Binding to RNA oligomerizes and induces a conformational change in TAV 2B into a primarily helical structure. These studies sug-gest that suppression of RNAi by TAV 2B may occur by targeting different stages of the RNAi pathway. TAV 2B falls under the category of more general RNAi suppres-sors, with potentially multiple targets for suppression.
Flexibility and constraints in migration and breeding of the barnacle goose Maximising fitness means, to a large extent, optimising management of time and energy. This thesis investigates aspects of timing and resource acquisition and utilisation in the barnacle goose Branta leucopsis during spring migration and reproduction. The barnacle goose population wintering along the Wadden Sea coast, and traditionally migrating via a stopover in the Baltic to its breeding sites in northern Russia, has shown some remarkable developments, among them, a geometric growth rate since the 1950s and a notable change in the timing of departure from the wintering grounds. Furthermore, long being regarded as an obligate Arctic breeder, within the past three decades this species has successfully colonised a wide variety of habitats at temperate latitudes, thereby shortening the migratory distances considerably or refraining from migration altogether. These remarkable changes raise questions about the flexibility of migratory and reproductive schedules. What are the costs and benefits of different migration strategies? And, given the context of global change, to what extent are animals capable of adapting to rapidly changing environments? In order to answer these questions we tracked migratory geese by satellite and with the help of data loggers and, furthermore, explored possible relationships of migratory behaviour and breeding performance. Another central thesis topic represents a within-species comparison of major life-history traits in populations breeding along a large ecological gradient from arctic to temperate environments. Fieldwork was conducted in arctic Russia, Sweden and The Netherlands.
The relation between reality and language, the instability of language as a signification system, the representation crisis, and the borders of interpretation are the controversial issues that have engaged not only philosophers, but also many authors, translators, and literary critics. Some philosophers like Derrida accuse Western thinking of being obsessed with binary oppositions. In Derrida's view, Western tradition resorts to external references as God, truth, origin, center and reason to stabilize the signification system. Since these concepts lack an internal sense and there is no transcendental signified that can fix these signifiers, language turns to an instable system by means of which no fixed meaning can be created. Many authors like Beckett, Stoppard, and Caryl Churchill also noticed this impossibility of language. While Derrida's deconstructive approach to this crisis has an epistemological nature, these playwrights present an aesthetic solution by turning the deconstructive potential of language against itself in text and performance. This dissertation aims at exploring their performing methods and dramatic texts to demonstrate how their delogocentric strategies work. By analyzing their plays, I will examine if their use of signifiers that have no references in reality, intentional misconceptions, disintegrated subjectivities, decentered narratives, and experimental performances can help them undermine the prevailing logocentrism of Western thought. The examination of the change in aesthetic strategies from Beckett, who belongs to earlier stages of post modernism, to Caryl Churchill, who should perform in a globalized world with increasing dominance of speed and information, is another aim of this research. In my view,Beckett's obsession with unspeakable, absurdity, and disintegration of subjectivity develops to Stoppard's language games, metadrama, and anti-representation and culminates in Churchill's anti-narrative texts and pluralistic performances. The monophony of Beckett's dramatic texts is replaced by the polyphony of Churchill's performances, which are a mixture of theater, dance and music. However, all explored dramatic texts in this dissertation have something in common: they are language games, which have no claim on a faithful representation of reality or transcendental truth.
The reggie protein family consists of two homologous members, reggie-1 and reggie-2, also termed flotillin-2 and flotillin-1, respectively, that are ubiquitously expressed and evolutionarily well conserved, suggesting an important but so far ill-defined function. In various cell types, both reggies have been found to be constitutively associated with lipid rafts by means of acylation modifications and oligomerization. Lipid rafts are glycosphingolipid- and cholesterol-rich membrane microdomains which have been implicated in several cellular processes including membrane transport and signal transduction through growth factor receptors. However, the molecular details of these processes are still poorly understood. With the observation that reggies colocalize with activated glycosylphosphatidylinositolanchored proteins (GPI-APs) and Fyn kinase in rafts, a role for these proteins in signaling events has been suggested. In agreement with that, we have previously shown that reggie-1 becomes multiply tyrosine phosphorylated by Src kinases in response to epidermal growth factor (EGF) stimulation, pointing to a function for reggie-1 in growth factor signaling. Furthermore, overexpression of reggie-1 enhances spreading on fibronectin substrate in a tyrosine-dependent manner, thus revealing a role for reggie-1 in regulation of actin cytoskeleton through growth factor receptors. Due to the similarity shared by reggie proteins at amino acid level and to their ability to form hetero-oligomeric complexes, the first aim of this study was to analyze the putative tyrosine phosphorylation of reggie-2 in growth factor stimulated cells. Similarly to reggie-1, reggie-2 was found to be multiply tyrosine phosphorylated by Src kinase and to exist in a molecular complex with Src, with the degree of co-immunoprecipitation dependent on the activity of Src. Recent studies from us have also shown that administration of EGF results in the endocytosis of reggie-1 from the plasma membrane into endosomes, which is in line with a proposed role for reggies in membrane trafficking processes. In order to characterize in detail the endocytic mechanism that mediates the uptake of reggie-1, the dependency of reggie-1 endocytosis on clathrin and dynamin was investigated by means of overexpressing a variant form of Eps15 or a dominant negative form of dynamin-2. In either case the translocation of reggie-1 into endosomes in response to EGF was not affected, and this, together with the results that reggie-1 colocalized with cholera toxin (CTX) but not with transferrin receptor (TfnR) during EGF signaling, indicates that reggie-1 is taken up by means of a dynaminindependent, raft-mediated pathway. These findings are very well in line with recent data showing the pathway of entry into cells of reggie-2 as a raft-mediated endocytic pathway. The endocytosis of reggie-2 in response to EGF was also analyzed in this study. Similarly to reggie-1, in growth factor stimulated cells reggie-2 underwent a translocation from the plasma membrane to endosomes where the two reggies were found to colocalize with each other, suggesting that epidermal growth factor signaling might trigger the endocytosis of reggie oligomers. In addition, colocalization with both the late endosomal marker LAMP3/CD63 and epidermal growth factor receptor (EGFR) was detected, again indicating a function for reggies in signal transduction through growth factor receptors. EGFR has been reported to localize in rafts but, although this association is thought to be functional during EGF stimulation, how segregation of EGFR into rafts modulates its endocytosis and signaling is still under debate. Since reggie oligomers have recently been suggested to define a raft subtype, a further aim of this study was to investigate whether the depletion of reggies by means of small interfering RNA could interfere with the signaling and the trafficking through EGFR. Knockdown of reggie-2 resulted in an altered tyrosine phosphorylation of EGFR in response to EGF, while the degree of ubiquitination was not affected. Less efficient phosphorylation of tyrosine residues, especially of those which are docking sites for Grb2 and Shc, led in turn to an impaired activation of p38 and ERK1/2 MAPKs. Depletion of reggie-2 did not affect the early trafficking of activated EGFRs, with receptors being endocytosed and delivered to late endosomes as efficiently as in control cells. This would be in line with the normal degree of ubiquitination observed for EGFR, as ubiquitin moieties have been proposed to represent sorting tags that ensure receptor endocytosis into early endosomes and its proper intracellular trafficking. On the contrary, after prolonged EGF stimulation, depletion of reggie-2 resulted in a decreased downregulation of both receptor-bound ligand and EGFR, and in their accumulation in intracellular vesicles, thus pointing to a role for reggie-2 in the degradative pathway. Taken all together, these data ndicate that the association of EGFR with reggie-microdomains is likely to be important for proper receptor trafficking and signaling.