Perpendicular Emission, Dichroism, and Energy Dependence in Angle-Resolved Photoemission: The Importance of The Final State.

Angle-resolved photoemission spectroscopy has been developed to a very high accuracy. However, effects that depend sensitively on the state of the emitted photoelectron were so far hard to compute for real molecules. We here show that the real-time propagation approach to time-dependent density functional theory allows us to obtain final-state effects consistently from first principles and with an accuracy that allows for the interpretation of experimental data. In a combined theoretical and experimental study we demonstrate that the approach captures three hallmark effects that are beyond the final-state plane-wave approximation: emission perpendicular to the light polarization, circular dichroism in the photoelectron angular distribution, and a pronounced energy dependence of the photoemission intensity.

Core hole-electron correlation in coherently coupled molecules.

We study the core hole-electron correlation in coherently coupled molecules by energy dispersive near edge x-ray absorption fine-structure spectroscopy. In a transient phase, which exists during the transition between two bulk arrangements, 1,4,5,8-naphthalene-tetracarboxylicacid-dianhydride multilayer films exhibit peculiar changes of the line shape and energy position of the x-ray absorption signal at the C K-edge with respect to the bulk and gas phase spectra. By a comparison to a theoretical model based on a coupling of transition dipoles, which is established for optical absorption, we demonstrate that the observed spectroscopic differences can be explained by an intermolecular delocalized core hole-electron pair. By applying this model we can furthermore quantify the coherence length of the delocalized core exciton.

Orbital density reconstruction for molecules.

The experimental imaging of electronic orbitals has allowed one to gain a fascinating picture of quantum effects. We here show that the energetically high-lying orbitals that are accessible to experimental visualization in general differ, depending on which approach is used to calculate the orbitals. Therefore, orbital imaging faces the fundamental question of which orbitals are the ones that are visualized. Combining angular-resolved photoemission experiments with first-principles calculations, we show that the orbitals from self-interaction-free Kohn-Sham density functional theory are the ones best suited for the orbital-based interpretation of photoemission.

Fine tuning of glutamate uptake and degradation in glial cells: common transcriptional regulation of GLAST1 and GS.

Glutamate is the major excitatory neurotransmitter in the mammalian brain and retina, and glutamate uptake is essential for the normal function of glutamatergic synapses in the retina. As summarized here, all neuronal and macroglial cells of the retina express high-affinity glutamate transporters. GLAST1 is expressed in glial cells, whereas GLT1 and EAAC1 are neuronal. Glutamate uptake studies in intact retina revealed that Müller glial cells dominate the total retinal glutamate transport and that this uptake is strongly influenced by the activity of glutamine synthetase. A prerequisite for an effective glutamate-glutamine cycle in glial cells would be the regulated coordination between glutamate uptake and glutamate degradation. Using cultured retinal Müller glial cells, we demonstrate that protein expression of both, GLAST1 and glutamine synthetase, are inducible by the glucocorticoid hormone cortisol. These results suggest a common transcriptional regulation of the key proteins in the glial portion of the glutamate-glutamine cycle and may impact on transmitter clearance, transmitter recycling and, as discussed, on the development of the cellular architecture in retina.

Complete determination of molecular orbitals by measurement of phase symmetry and electron density.

Several experimental methods allow measuring the spatial probability density of electrons in atoms, molecules and solids, that is, the absolute square of the respective single-particle wave function. But it is an intrinsic problem of the measurement process that the information about the phase is generally lost during the experiment. The symmetry of this phase, however, is a crucial parameter for the knowledge of the full orbital information in real space. Here, we report on a key experiment that demonstrates that the phase symmetry can be derived from a strictly experimental approach from the circular dichroism in the angular distribution of photoelectrons. In combination with the electron density derived from the same experiment, the full quantum mechanical wave function can thus be determined experimentally.

Substrate-mediated band-dispersion of adsorbate molecular states.

Charge carrier mobilities in molecular condensates are usually small, as the coherent transport, which is highly effective in conventional semiconductors, is impeded by disorder and the small intermolecular coupling. A significant band dispersion can usually only be observed in exceptional cases such as for π-stacking of aromatic molecules in organic single crystals. Here based on angular resolved photoemission, we demonstrate on the example of planar π-conjugated molecules that the hybridization with a metal substrate can substantially increase the delocalization of the molecular states in selective directions along the surface. Supported by ab initio calculations we show how this mechanism couples the individual molecules within the organic layer resulting in an enhancement of the in-plane charge carrier mobility.

Glutamate translocation of the neuronal glutamate transporter EAAC1 occurs within milliseconds.

The activity of glutamate transporters is essential for the temporal and spatial regulation of the neurotransmitter concentration in the synaptic cleft, and thus, is crucial for proper excitatory signaling. Initial steps in the process of glutamate transport take place within a time scale of microseconds to milliseconds. Here we compare the steady-state and pre-steady-state kinetics of the neuronal heterologously expressed glutamate transporter EAAC1, cloned from the mammalian retina. Rapid transporter dynamics, as measured by using whole-cell current recordings, were resolved by applying the laser-pulse photolysis technique of caged glutamate with a time resolution of 100 micros. EAAC1-mediated pre-steady-state currents are composed of two components: A transport current generated by substrate-coupled charge translocation across the membrane and an anion current that is not stoichiometrically coupled to glutamate transport. The two currents were temporally resolved and studied independently. Our results indicate a rapid glutamate-binding step occurring on a submillisecond time scale that precedes subsequent slower electrogenic glutamate translocation across the membrane within a few milliseconds. The voltage-dependent steady-state turnover time constant of the transporter is about 1/10 as fast, indicating that glutamate translocation is not rate limiting. A third process, the transition to an anion-conducting state, is delayed with respect to the onset of glutamate transport. These rapid transporter reaction steps are summarized in a sequential shuttle model that quantitatively accounts for the results obtained here and are discussed regarding their functional importance for glutamatergic neurotransmission in the central nervous system.

High-affinity glutamate transporters in the rat retina: a major role of the glial glutamate transporter GLAST-1 in transmitter clearance.

Glutamate is the major excitatory neurotransmitter of the mammalian retina and glutamate uptake is essential for normal transmission at glutamatergic synapses. The reverse transcriptase-polymerase chain reaction (RT-PCR) has revealed the presence of three different high-affinity glutamate transporters in the rat retina, viz. GLAST-1, GLT-1 and EAAC-1. No message has been found in the retina for EAAT-4, a transporter recently cloned from human brain. By using membrane vesicle preparations of total rat retina, we show that glutamate uptake in the retina is a high-affinity electrogenic sodium-dependent transport process driven by the transmembrane sodium ion gradient. Autoradiography of intact and dissociated rat retinae indicates that glutamate uptake by Müller glial cells dominates total retinal glutamate transport and that this uptake is strongly influenced by the activity of glutamine synthetase. RT-PCR, immunoblotting and immunohistochemistry have revealed that Müller cells express only GLAST-1. The Km for glutamate of GLAST-1 is 2.1+/-0.4 microM. This study suggests a major role for the Müller cell glutamate transporter GLAST-1 in retinal transmitter clearance. By regulating the extracellular glutamate concentration, the action of GLAST-1 in Müller cells may extend beyond the protection of neurons from excitotoxicity; we suggest a mechanism by which Müller cell glutamate transport might play an active role in shaping the time course of excitatory transmission in the retina.

Screening for vesicoureteral reflux in children using real-time sonography.

One hundred and ten children, ages 6 days to 14 years, were investigated for vesicoureteral reflux (VUR) using ultrasound before voiding cystourethrography (VCU). Sonographically a VUR was assumed if a retrovesical dilated ureter and/or an increase of the separation of the central renal echo complex (CRC) could be detected. By means of sonography VUR grades III and IV were seen in 100%, grade II in 84% of all cases. There was a false positive rate of 10%. Sonographic reflux study is a sensitive and specific screening and follow-up procedure for VUR.

[Platelet aggregation and prostaglandin turnover in man during defined linoleic acid supply with formula diets (author's transl)]. / Plättchenaggregation und Prostaglandinumsatz beim Menschen unter definierter Linolsäurezufuhr mit Formeldiäten.

A report is given on changes of platelet aggregation and prostaglandin turnover during a cross-over experiment with six female volunteers being given a linoleic acid supply with formula diets of 0 g or 50 g daily. Collagen- and ADP-induced platelet aggregation was determined with a Borne-type aggregometer. Prostaglandin turnover was measured by analyzing the excretion of a joint derivative of prostaglandin metabolites, tetranorprostanedioic acid, in urine. With a linoleic acid supply of 50 g daily we found an increase of tetranorprostanedioic acid in urine, while platelet aggregation decreased. When the experimental subjects came from a conventional diet (linoleic acid intake 20 g daily) these changes were seen later than after a linoleic acid free formula diet. A linoleic acid-deficient formula diet caused a fall in prostaglandin turnover within 24 hr. ADP-induced platelet aggregation was unchanged after 1 week, while collagen-induced platelet aggregation was increased after 1 and 3 weeks of linoleic acid-deficient diet. These results clearly demonstrate the influence of nutrition on platelet aggregation.