Variations in the first steps of photosynthesis for the diatom Cyclotella meneghiniana grown under different light conditions.

In this work we have applied picosecond and steady-state fluorescence measurements to study excitation energy transfer and trapping in intact Cyclotella meneghiniana diatom cells grown at different light intensities. Different excitation and detection wavelengths were used to discriminate between Photosystem I and II (PSI and PSII) kinetics and to study excitation energy transfer from the outer antenna to the core of PSI and PSII. It is found that the light-harvesting fucoxanthin chlorophyll proteins (FCPs) transfer their excitation energy predominantly to PSII. It is also observed that the PSII antenna is slightly richer in red-absorbing fucoxanthin than the FCPs associated with PSI. The average excitation trapping time in PSI is around 75 ps whereas this time is around 450 ps for PSII in cells grown in 20 µmol of photons per m(2) per s. The latter time decreases to 425 ps for 50 µmol of photons and 360 ps for 140 µmol of photons. It is concluded that cells grown under higher photon flux densities have a smaller antenna size than the ones grown in low light. At the same time, the increase of growth light intensity leads to a decrease of the relative amount of PSI. This effect is accompanied by a substantial increase in the amount of chlorophyll a that is not active in excitation energy transfer and most probably attached to inactivated/disassembled PSII units.

Monitoring photosynthesis in individual cells of Synechocystis sp. PCC 6803 on a picosecond timescale.

Picosecond fluorescence kinetics of wild-type (WT) and mutant cells of Synechocystis sp. PCC 6803, were studied at the ensemble level with a streak-camera and at the cell level using fluorescence-lifetime-imaging microscopy (FLIM). The FLIM measurements are in good agreement with the ensemble measurements, but they (can) unveil variations between and within cells. The BE mutant cells, devoid of photosystem II (PSII) and of the light-harvesting phycobilisomes, allowed the study of photosystem I (PSI) in vivo for the first time, and the observed 6-ps equilibration process and 25-ps trapping process are the same as found previously for isolated PSI. No major differences are detected between different cells. The PAL mutant cells, devoid of phycobilisomes, show four lifetimes: ∼20 ps (PSI and PSII), ∼80 ps, ∼440 ps, and 2.8 ns (all due to PSII), but not all cells are identical and variations in the kinetics are traced back to differences in the PSI/PSII ratio. Finally, FLIM measurements on WT cells reveal that in some cells or parts of cells, phycobilisomes are disconnected from PSI/PSII. It is argued that the FLIM setup used can become instrumental in unraveling photosynthetic regulation mechanisms in the future.

Photosynthesis. Many chlorophylls make light work.

The structure of a plant light-harvesting complex at atomic resolution, determined recently by electron crystallography, helps to explain the efficiency and speed of the light-gathering process.

Orientation of the bases of single-stranded DNA and polynucleotides in complexes formed with the gene 32 protein of bacteriophage T4. A linear dichroism study.

Linear dichroism measurements were performed in the wavelength region 250 to 350 nm on complexes between the single-stranded DNA binding protein of bacteriophage T4 (gp32) and single-stranded DNA and a variety of homopolynucleotides in compressed polyacrylamide gels. The complexes appeared to orient well, giving rise to linear dichroism spectra that showed contributions from both the protein aromatic residues and the bases of the polynucleotides. In most cases the protein contribution appeared to be very similar, and the linear dichroism of the bases could be explained by similar orientations of the bases for most of the complexes. Assuming a similar, regular structure for most of the polynucleotides in complex, only a limited set of combinations of tilt and twist angles can explain the linear dichroism spectra. These values of tilt and twist are close to (-40 degrees, 30 degrees), (-40 degrees, 150 degrees), (40 degrees, -30 degrees) or (40 degrees, -150 degrees), with an uncertainty in both angles of about 15 degrees. Although the linear dichroism results do not allow a choice between these possible orientations, the latter two combinations are not in agreement with earlier circular dichroism calculations. For the complexes formed with poly(rC) and poly(rA), the linear dichroism spectra could not be explained by the same base orientations. In these two cases also the protein contribution to the linear dichroism appeared to be different, indicating that for some aromatic residues the orientations are not the same as those in the other complexes. The different structures of these complexes are possibly related to the relatively low binding affinity of gp32 to poly(rC), and to a lesser extent to poly(rA).

Average orientation of aromatic residues in proteins determined from linear dichroism spectroscopy. A comparison of results on bovine gamma-crystallins with X-ray data.

The structures of the two very closely related proteins, bovine gamma II- and gamma IVa-crystallin have been studied by means of near-ultra-violet linear dichroism spectroscopy on squeezed polyacrylamide gel systems. The crystallin spectra are discussed in terms of the spectra of the aromatic chromophores present in these proteins and provide detailed information on the average orientation of these residues in the proteins. A comparison of our results with information based on crystallographic X-ray experiments shows excellent agreement, reflecting even some of the minor differences between the two proteins studied. Since linear dichroism measurements as performed here take a few days only, and can be done on most aqueous protein solutions, linear dichroism spectroscopy may give a valuable contribution to structural studies on proteins.

Complex between single-stranded DNA and gene 5 protein of bacteriophage M13 studied with linear dichroism and ultraviolet absorption.

We have studied complexes between the gene 5 protein (gp5) of bacteriophage M13 and various polynucleotides, including single-stranded DNA, using ultraviolet absorption and linear dichroism. Upon complex formation the absorption spectra of both the protein and the polynucleotides change. The protein absorption changes indicate that for at least two of the five tyrosine residues per protein monomer the environment becomes less polar upon binding to the polynucleotides but also to the oligonucleotide p(dT)8. All gp5-polynucleotide complexes give rise to intense linear dichroism spectra. These spectra are dominated by negative contributions from the bases, but also a small positive dichroism of the protein can be discerned. The spectra can be explained by polynucleotide structures, which are the same in all complexes. The base orientations are characterized by a substantial inclination and propellor twist. The number of possible combinations of inclination and propeller twist values, which are in agreement with the linear dichroism results, is rather limited. The base orientations with respect to the complex axis are essentially different from those in the complex with the single-stranded DNA-binding protein gp32 of bacteriophage T4.

Characterization of multiple oligomeric vimentin intermediate filament units by transient electric birefringence measurements.

In this work we have studied the structure of soluble vimentin units from which intermediate filaments (IFs) are built. Several oligomeric forms have been presented in the literature as IF "building blocks", but there is still no agreement on this matter. By comparing our data with various models as proposed in the literature we can favour certain models and reject others. Transient electric birefringence (TEB) measurements were performed from which information is obtained concerning electric and hydrodynamic properties of the particles under investigation. TEB decay analysis at pH 6.8 after 70 microseconds pulses (at 20 degrees C in aqueous solution) yielded three decay times: 1.1(+/- 0.3) microseconds, 4.0(+/- 1.0) microseconds and 20.0(+/- 5.0) microseconds, with amplitudes of 45% to 60%, 30% to 45%, and less than 10%, respectively. At pH 8.5 after 70 microseconds pulses, more than 90% of the TEB signal with the second decay time is obtained, while the remainder had a decay time of 15.0(+/- 4.0) microseconds. Only when the pulse duration was decreased, the fast decay time around 1 microsecond was observed, suggesting that only a minor fraction of the particles at this pH value causes such a short decay time. At both pH values, the TEB measurements indicated that, at least in part, the molecules are oriented by a permanent dipole moment. It will be shown that the shortest decay time originates from bent or flexible dimers, and the second decay time from particles with a length of 54 to 65 nm containing, at least in part, a relatively large overall dipole moment. The longest decay time is probably due to larger aggregates. These results are consistent with a model in which single dimers, antiparallel staggered tetramers and hexamers coexist. Alternatively, but less likely on the basis of literature data, a model of parallel in-register tetramers with a considerable length contribution of the head groups would fit our research.

Linear dichroism of the complex between the gene 32 protein of bacteriophage T4 and poly(1,N6-ethenoadenylic acid).

We performed linear dichroism measurements in compressed polyacrylamide gels on the complex between the helix-destabilizing protein of bacteriophage T4, GP32 and poly(1,N6-ethenoadenylic acid), which is used as a model system for single-stranded DNA. A strong hyperchromism for poly(1,N6-ethenoadenylic acid) in the complex indicates a strongly altered conformation. The positive linear dichroism in the wavelength region where the bases absorb must be explained by a strong tilting of the bases in the complex. This finding is in accordance with results from earlier studies, using electric birefringence and circular dichroism measurements. Our measurements show that the angle between the bases and the local helix axis is 42(+/- 6)degrees. In addition, a pronounced contribution from the tryptophan residues of GP32 can be recognized, indicating that several of these residues have a specific orientation in the complex. The sign of the dichroism due to the tryptophan residues is the same as that due to the DNA bases. However, it is not sufficient to assume that all the observed dichroism is due to one or more intercalated tryptophan residues and there must be one or more additional tryptophan residues that make an angle of less than 40 degrees with the local helix axis. Some possible structures of the DNA-protein complex are discussed.

Structural alterations of double-stranded DNA in complex with the adenovirus DNA-binding protein. Implications for its function in DNA replication.

The Adenovirus DNA-binding protein (DBP) binds to single-stranded (ss) DNA as well as to double-stranded (ds) DNA and forms multimeric protein-DNA complexes with both. Gel retardation assays indicate rapid complex formation for both DNAs. DBP rapidly dissociates from dsDNA, indicating a dynamic equilibrium, whereas the ssDNA-DBP complex is much more stable. We investigated the complex between DBP and dsDNA in more detail. Electron microscopical analysis shows thick filament-like and beaded structures in which the length of the DNA is not significantly altered. Cryo-electron micrographs suggest the presence of interwound protein fibres around the DNA. Ligase-mediated cyclization, but not linear multimerization, of DBP-saturated DNA fragments exceeding the persistence length was severely inhibited. This suggests that DNA may be organized by DBP into a rigid structure. Under those conditions, DBP induces distinct changes in the circular dichroism spectrum of the DNA, indicative of structural DNA changes. No bending or twisting of the complex was observed. Hydroxyl radical footprinting showed that the breakdown pattern of DNA at saturating DBP concentrations is much more regular than the protein-free DNA. This suggests the removal of tertiary structures, which may be related to the effects of DBP on enhanced NFI binding and chain elongation during Adenovirus DNA replication. Using purified proteins in an in vitro replication system, we correlate the structural changes with the effects of DBP on enhancement of NFI-binding as well as on DNA replication.

Hydrodynamic studies of a DNA-protein complex. Elongation of single stranded nucleic acids upon complexation with the gene 32 protein of phage T4 deduced from electric field-induced birefringence experiments.

Short DNA and RNA fragments complexed with the helix destabilizing protein of bacteriophage T4, GP32, have been studied in solution by electric birefringence and circular dichroism. The birefringence of the complexes is positive and the magnitude indicates that the DNA and RNA fragments become linear and rigid upon protein binding. The field free decay is biphasic. On the basis of a rigid rod approximation the slow relaxation time leads to a base-base distance along the helix axis in the complex from 4.3 to 5.6 A, an elongation of at least 50% compared to single-stranded DNA.

The assembly state of the intermediate filament proteins desmin and glial fibrillary acidic protein at low ionic strength.

The low ionic strength structures of the type III intermediate filament (IF) proteins desmin and glial fibrillary acidic protein (GFAP) have been studied by transient electric birefringence measurements. Flexible dimers with a length of around 45 nm, particles with a length of 68 +/- 6 nm (presumably tetramers and hexamers) and larger aggregates of 108 +/- 19 nm are found. GFAP has an increased tendency to aggregate upon lowering of the pH. The aggregation state of desmin does not change in the pH range studied. The results are compared with previous results on vimentin.

Circularly polarized chlorophyll luminescence reflects the macro-organization of grana in pea chloroplasts.

Circular polarization of luminescence (CPL; Steinberg IZ (1978) Annu Rev Biophys Bioeng 7: 113-137) was applied to study pea chloroplasts in different structural states. The structural changes of chloroplasts were induced by variation of osmotic pressure, concentration of magnesium-ions or photoinhibition. Both large CPL and psi-type circular dichroism (psi, polymerization and salt induced) signals appeared in the presence of granal macrostructure and were sensitive to structural changes of the grana. The relation was studied between the amount of CPL expressed as an emission anisotropy factor g(em) and amplitudes of the red psi-type CD bands. The positive psi-type CD band was not directly correlated with g (em) possibly due to a large contribution of circular intensity differential scattering to the measured CD spectra. However, a linear correlation between the amplitude of the negative psi-type CD band and g (em) was found. The CPL signal of pea chloroplasts was attributed to a psi-type origin, which is observed in macroaggregates with densely packed chromophores with a long-range chiral order, and directly depends on the level of macroorganization. With the use of CPL-based microscopy, the long-range packing of LHC II particles can be studied in individual chloroplasts in future. In addition, the CPL method in general allows the study of the macro-organization of grana in green leaves, where conventional light-transmission methods fail.

A model for the complex between the helix destabilizing protein GP32 of bacteriophage T4 and single-stranded DNA.

A model for the structure of the complex between the helix-destabilizing protein of bacteriophage T4, GP32, and single-stranded DNA is proposed. In this model the bases are arranged in a helix, that is characterized by a relatively large distance between successive bases, a substantial base tilt, in combination with a small rotation per base. This helix is further organized into a tertiary structure, possibly a superhelix, of which the corresponding protein shell corresponds to the relatively rigid and rod-like structure that is observed in hydrodynamic experiments. It is proposed that similar structural features apply to other single-stranded DNA binding proteins in complex with polynucleotides.

Disentangling picosecond events that complicate the quantitative use of the calcium sensor YC3.60.

Yellow Cameleon 3.60 (YC3.60) is a calcium sensor based on Förster resonance energy transfer (FRET). This sensor is composed of a calmodulin domain and a M13 peptide, which are located in between enhanced cyan-fluorescent protein (ECFP) and the Venus variant of enhanced yellow-fluorescent protein (EYFP). Depending on the calcium concentration, the efficiency of FRET from donor ECFP to acceptor EYFP is changing. In this study, we have recorded time-resolved fluorescence spectra of ECFP, EYFP, and YC3.60 in aqueous solution with picosecond time resolution, using different excitation wavelengths. Detailed insight in the FRET kinetics was obtained by using global and target analyses of time- and wavelength-resolved fluorescence of purified YC3.60 in calcium-free and calcium-bound conformations. The results clearly demonstrate that for both conformations, there are two distinct donor populations: a major one giving rise to FRET and a minor one not able to perform FRET. The transfer time for the calcium-bound conformation is 21 ps, whereas it is in the order of 1 ns for the calcium-free conformation. Ratio imaging of acceptor and donor fluorescence intensities of YC3.60 is usually applied to measure Ca(2+) concentrations in living cells. From the obtained results, it is clear that the intensity ratio is strongly influenced by the presence of donor molecules that do not take part in FRET, thereby significantly affecting the quantitative interpretation of the results.

5-fluorotryptophan as dual probe for ground-state heterogeneity and excited-state dynamics in apoflavodoxin.

The apoflavodoxin protein from Azotobacter vinelandii harboring three tryptophan (Trp) residues, was biosynthetically labeled with 5-fluorotryptophan (5-FTrp). 5-FTrp has the advantage that chemical differences in its microenvironment can be sensitively visualized via (19)F NMR. Moreover, it shows simpler fluorescence decay kinetics. The occurrence of FRET was earlier observed via the fluorescence anisotropy decay of WT apoflavodoxin and the anisotropy decay parameters are in excellent agreement with distances between and relative orientations of all Trp residues. The anisotropy decay in 5-FTrp apoflavodoxin demonstrates that the distances and orientations are identical for this protein. This work demonstrates the added value of replacing Trp by 5-FTrp to study structural features of proteins via (19)F NMR and fluorescence spectroscopy.

Linear dichroism of chlorosomes from chloroflexus aurantiacus in compressed gels and electric fields.

The linear dichroism of chlorosomes from Chloroflexus aurantiacus was measured between 250 and 800 nm. To orient the chlorosomes we used a new way of compressing polyacrylamide gels, where the dimension of the gel along the measuring light-beam is kept constant. The press required for such a way of compressing is relatively easy to construct. A theoretical description is given to interpret the measured linear dichroism in terms of the orientation of the transition moments. The results obtained with the polyacrylamide gels are compared with the linear dichroism measurements for chlorosomes oriented in electric fields. Both the spectral features as well as the absolute size of the linear dichroism signals are in reasonable agreement. We find that the transition moment corresponding to the 741 nm bacteriochlorophyll c (Bchl c) absorption band makes an angle of 20 degrees with the long axis of the chlorosome. For the 461 nm Bchl c band an angle of 30 degrees is found. Both angles are significantly lower than the values reported so far in literature and they imply that Bchl c is highly organized in the chlorosomes.

Spectral broadening of interacting pigments: polarized absorption by photosynthetic proteins.

Excitonic interaction between pigment molecules is largely responsible for the static and dynamic spectroscopic properties of photosynthetic pigment-proteins. This paper provides a new description of its effect on polarized absorption spectroscopy, in particular on circular dichroism (CD). We investigate excitonic spectra of finite width and use "spectral moments" to compare 1) inhomogeneously broadened excitonic spectra, 2) spectra that are (homogeneously broadened by vibrations or electron-phonon interaction, and 3) spectra that are simulated by applying convolution after the interaction has been evaluated. Two cases are distinguished. If the excitonic splitting is smaller than the width of the interacting absorption bands, the broadening of the excitonic spectrum can be approximated by a convolution approach, although a correction is necessary for CD spectra. If the excitonic splitting exceeds the bandwidth, the well-known exchange narrowing occurs. We demonstrate that this is accompanied by redistribution of dipole strength and spectral shifts. The magnitude of a CD spectrum is conveniently expressed by its first spectral moment. As will be shown, this is independent of spectral broadening as well as dispersive shifts induced by pigment-protein interactions. Consequently, it provides a simple tool to relate the experimental CD spectrum of a pigment complex to the excitonic interactions from which it originates. To illustrate the potential of the presented framework, the spectroscopy of the LH2 pigment-protein complex from purple bacteria is analyzed and compared for dimer-like and ring-like structures. Furthermore, it is demonstrated that the variability of the CD of chlorosomes from green bacteria can be explained by small changes in the structure of their cylindrical bacteriochlorophyll c subunits.