Uwe Gerken

Single Molecule Spectroscopy on the Light-Harvesting Complex II of Higher Plants

Spectroscopic and polarization properties of single light-harvesting complexes of higher plants (LHC-II) were studied at both room temperature and T < 5 K. Monomeric complexes emit roughly linearly polarized fluorescence light thus indicating the existence of only one emitting state. Most probably this observation is explained by efficient triplet quenching restricted to one chlorophyll a (Chl a) molecule or by rather irreversible energy transfer within the pool of Chl a molecules. LHC-II complexes in the trimeric (native) arrangement bleach in a number of steps, suggesting localization of excitations within the monomeric subunits. Interpretation of the fluorescence polarization properties of trimers requires the assumption of transition dipole moments tilted out of the symmetry plane of the complex. Low-temperature fluorescence emission of trimers is characterized by several narrow spectral lines. Even at lowest excitation intensities, we observed considerable spectral diffusion most probably due to low temperature protein dynamics. These results also indicate weak interaction between Chls belonging to different monomeric subunits within the trimer thus leading to a localization of excitations within the monomer. The experimental results demonstrate the feasibility of polarization sensitive studies on single LHC-II complexes and suggest an application for determination of the Chl transition-dipole moment orientations, a key issue in understanding the structure-function relationships.

Dimerization and direct membrane interaction of Nup53 contribute to nuclear pore complex assembly

Nuclear pore complexes (NPCs) fuse the two membranes of the nuclear envelope (NE) to a pore, connecting cytoplasm and nucleoplasm and allowing exchange of macromolecules between these compartments. Most NPC proteins do not contain integral membrane domains and thus it is largely unclear how NPCs are embedded and anchored in the NE. Here, we show that the evolutionary conserved nuclear pore protein Nup53 binds independently of other proteins to membranes, a property that is crucial for NPC assembly and conserved between yeast and vertebrates. The vertebrate protein comprises two membrane binding sites, of which the C‐terminal domain has membrane deforming capabilities, and is specifically required for de novo NPC assembly and insertion into the intact NE during interphase. Dimerization of Nup53 contributes to its membrane interaction and is crucial for its function in NPC assembly.

A model of dirigent proteins derived from structural and functional similarities with allene oxide cyclase and lipocalins

Dirigent proteins impart stereoselectivity on the phenoxy radical‐coupling reaction, yielding optically active lignans from two molecules of coniferyl alcohol. By an unknown mechanism, they direct the coupling of two phenoxy radicals toward the formation of optically active (+)‐ or (−)‐pinoresinol. We show here that the dirigent protein AtDIR6 from Arabidopsis thaliana is a homodimeric all‐beta protein in the superfamily of calycins. Based on its homology with calycins, the structure of AtDIR6 was modeled using allene oxide cyclase as template. The structural model of AtDIR6 was supported experimentally by confirmation of a predicted disulfide bridge and by the characterization of two N‐linked glycans at the solvent‐exposed protein surface. The model shows AtDIR6 as an eight‐stranded antiparallel β‐barrel with a central hydrophobic cavity for substrate binding, suggesting that dirigent proteins evolved from hydrophobic ligand‐binding proteins. The data are fully consistent with the current view of the dirigent protein mode of action, according to which each subunit of the homodimer captures one of the substrate radicals and orients them in a way that precludes undesired reaction channels, thus favoring the formation of the optically pure coupling product.

Substrate-Induced Conformational Change of the Escherichia coli Membrane Insertase YidC †

The membrane insertase YidC from Escherichia coli reversibly binds its substrate Pf3 coat protein. The effect of this initial binding process was examined in vitro by fluorescence quenching of the tryptophan (Trp) residues of YidC which are highly sensitive fluorescent probes for changes of the proteins tertiary structure. Membrane-reconstituted (in DOPC or DOPE/DOPG vesicles) as well as detergent-solubilized (C(12)PC) YidC was titrated with a Trp-free Pf3 coat mutant. Quenching of the intrinsic Trp fluorescence after titration indicates a change in the tertiary structure of YidC upon binding to the Pf3 coat substrate. Analysis of the binding curves taken from the fluorescence data yielded values for the dissociation constant (K(D)) in the range of 0.5-1.8 microM. Titration experiments with two Trp mutants reveal that the change in the tertiary structure involves mainly the membrane-spanning domain. The influence of the different environments on the secondary structure of YidC as well as of the YidC large periplasmic domain (P1) was investigated by circular dichroism (CD). The CD data show that the YidC secondary structure changes upon reconstitution into a membrane environment when compared to the detergent-solubilized state. In particular, the P1 domain of YidC is considerably affected by the detergent C(12)PC. This underlines the importance to study conformational changes with membrane-inserted proteins.

Substrate-Dependent Conformational Dynamics of the Escherichia coli Membrane Insertase YidC

The binding of Pf3 coat protein to the membrane insertase YidC from Escherichia coli induces a conformational change in the tertiary structure of the insertase, resulting in a quenching of the intrinsic tryptophan (Trp) fluorescence. Tryptophan mutants of YidC were generated to examine such conformational movements in detail with time-resolved and steady-state fluorescence spectroscopy. Ten of the 11 Trp residues within YidC were substituted to phenylalanines generating single Trp mutants either at position 354, 454, or 508. In addition, a double mutant with Trp residues at 332 and 334 was studied. Purified YidC mutants were reconstituted into DOPC/DOPG vesicles and titrated with a Trp-free mutant of Pf3 coat, enabling a detailed conformational study of the periplasmic P1, P2, and P3 domains of YidC before and after binding of substrate. Time-resolved fluorescence anisotropy revealed that the mobility of the residues W332/W334 and W508 was considerably increased after binding of Pf3 coat to the insertase. Furthermore, analysis of the fluorescence emission spectra and the decay times showed that all Trp residues are embedded in an equivalent environment that is a membrane/water interface.

Real time observation of single membrane protein insertion events by the Escherichia coli insertase YidC.

Membrane protein translocation and insertion is a central issue in biology. Here we focus on a minimal system, the membrane insertase YidC of Escherichia coli that inserts small proteins into the cytoplasmic membrane. In a reconstituted system individual insertion processes were followed by single-pair fluorescence resonance energy transfer (FRET), with a pair of fluorophores on YidC and the substrate Pf3 coat protein. After addition of N-terminally labeled Pf3 coat protein a close contact to YidC at its cytoplasmic label was observed. This allowed to monitor the translocation of the N-terminal domain of Pf3 coat protein across the membrane in real time. Translocation occurred within milliseconds as the label on the N-terminal domain rapidly approached the fluorophore on the periplasmic domain of YidC at the trans side of the membrane. After the close contact, the two fluorophores separated, reflecting the release of the translocated Pf3 coat protein from YidC into the membrane bilayer. When the Pf3 coat protein was labeled C-terminally, no translocation of the label was observed although efficient binding to the cytoplasmic positions of YidC occurred.

Initial Binding Process of the Membrane Insertase YidC with Its Substrate Pf3 Coat Protein Is Reversible

The binding of the inner membrane insertase YidC from Escherichia coli to its substrate, the Pf3 coat protein, was examined in vitro by fluorescence spectroscopy. Purified YidC protein was solubilized with the lipid-like detergent n-dodecylphosphocholine and noncovalently labeled with 1-anilino-naphthalene-8-sulfonate (ANS), whereas the Pf3 coat protein was kept in solution by the addition of 10% (v/v) isopropanol to the buffer. The binding of Pf3 coat protein was analyzed by fluorescence quenching of ANS bound to YidC. All binding curves showed a strict hyperbolic form at pH values between 9.0 and 5.0, indicating a reversible and noncooperative binding between YidC and its substrate. Analysis of the data revealed a dissociation constant K D for the binding process in the range of 1 microM. The pH profile of the K D values suggests that the binding of the Pf3 coat protein is dominated by hydrophobic interactions. The titration experiments provide strong evidence for a conformational change of the insertase upon binding a Pf3 coat protein molecule.

Polarization Measurements on Single Pigment‐Protein Complexes

Individual antenna complexes from different photosynthetic units have been investigated by single molecule spectroscopy. In such energy transfer systems the polarization of the fluorescence emission gives valuable information about the nature of the emitting state, which is not readily available with other methods like fluorescence excitation or emission spectroscopy. The peripheral antenna light harvesting complex from purple bacterium Rhodopseudomonas Acidophila shows predominantly linear polarized fluorescence emission at low temperature, whereas at room temperature the fluorescence is randomly polarized. This is attributed to the fact, that at low temperature in the fluorescence emitting state the excitation energy is localized mainly on 4-5 chromophores. Analysis of the fluorescence emission of single peripheral antenna complexes of green plants indicate that for trimers of this species more than one Chlorophyll is responsible for the final fluorescence emission, which points towards a weak intermonomer coupling in the complex.

Single Molecule Spectroscopy of Oriented Recombinant Trimeric Light Harvesting Complexes of Higher Plants

The bleaching dynamics of reconstituted single light-harvesting chlorophyll a/b investigated. The complexes containing one histidine6 tag per monomeric subunit were immobilised predominantly in a defined orientation with their symmetry axis perpendicular to a Ni-ion-containing surface allowing for the first time the examination of single LHCIIb in an aqueous environment. Most complexes exhibit photobleaching in one step, indicating coupling between the monomeric subunits leading to an energy transfer between adjacent subunits. Differences in bleaching behaviour between these and previous observations with single LHCIIb are discussed.

Single molecule spectroscopy on photosynthetic pigment-protein complexes

Single molecule spectroscopy was applied to unravel the energy transfer pathway in photosynthetic pigment-protein complexes. Detailed analysis of excitation and fluorescence emission spectra has been made for peripheral plant antenna LHC II and Photosystem I from cyanobacterium Synechococcus elongatus. Optical transitions of individual pigments were resolved under nonselective excitation of antenna chlorophylls. High-resolution fluorescence spectroscopy of individual plant antenna LHC II indicates that at low temperatures, the excitation energy is localized on the red-most Chl a pool absorbing at 680 nm. More than one pigment molecule is responsible for the fluorescence emission of the LHC II trimer. The spectral lines of single Chl a molecules absorbing at 675 nm are broadened because of the Foerster energy transfer towards the red-most pigments. Low-temperature spectroscopy on single PS I trimers indicates that two subgroups of pigments, which are present in the red antenna pool, differ by the strength of the coupling with the protein environment and by the efficiency of the triplet state quenching. Based on single molecule and hole burning data, we envisage the dimeric nature of the strongly phonon coupled red-most Chl state.