The fluorescence yield of the trimeric fucoxanthin–chlorophyll–protein FCPa in the diatom Cyclotella meneghiniana is dependent on the amount of bound diatoxanthin

The fluorescence yield of isolated fucoxanthin chlorophyll proteins, serving as light harvesting proteins in diatoms, was compared to the amount of diatoxanthin bound. Diatoxanthin was earlier shown to be involved in the xanthophyll cycle in diatoms as a functional analogue of zeaxanthin in higher plants. By growing cells under different light conditions, the amount of diatoxanthin in both the trimeric FCPa as well as the oligomeric FCPb of the diatom Cyclotella meneghiniana was increased. In the trimeric FCPa, the fluorescence yield decreased with increasing diatoxanthin content, whereas in the oligomeric FCPb fluorescence was generally lower, albeit constant. No pH dependence of fluorescence yield could be demonstrated except for artificially aggregated FCPa. Thus, diatoxanthin is able to quench fluorescence in FCPa, but the yield is also influenced by pH when the protein becomes aggregated.     

Evidence for water-mediated triplet–triplet energy transfer in the photoprotective site of the peridinin–chlorophyll a–protein

Experimental and theoretical studies indicate that water molecules between redox partners can significantly affect their electron-transfer and possibly also the triplet–triplet energy transfer (TTET) properties when in the vicinity of chromophores. In the present work, the interaction of an intervening water molecule with the peridinin triplet state in the peridinin–chlorophyll a–protein (PCP) from Amphidinium carterae is studied by using orientation selective ²H electron spin echo envelope modulation (ESEEM) spectroscopy, in conjunction with quantum mechanical calculations. This water molecule is located at the interface between the chlorophyll and peridinin pigments involved in the photoprotection mechanism (Chl601(602)–Per614(624), for nomenclature see reference [1]), based on TTET. The characteristic deuterium modulation pattern is observed in the electron spin-echo envelopes for the PCP complex exchanged against ²H₂O. Simulations of the time- and frequency-domain two-pulse and three-pulse ESEEM require two types of coupled ²H. The more strongly coupled ²H has an isotropic coupling constant (a_iso) of − 0.4 MHz. This Fermi contact contribution for one of the two water protons and the precise geometry of the water molecule at the interface between the chlorophyll and peridinin pigments, resulting from the analysis, provide experimental evidence for direct involvement of this structured water molecule in the mechanism of TTET. The PCP antenna, characterised by a unity efficiency of the process, represents a model for future investigations on protein- and solvent-mediated TTET in the field of natural/artificial photosynthesis.     

Insights into substrate binding at FeMo-cofactor in nitrogenase from the structure of an α-70 MoFe protein variant

The X-ray crystal structure is presented for a nitrogenase MoFe protein where the alpha subunit residue at position 70 (α-70^Val) has been substituted by the amino acid isoleucine (α-70^Ile). Substitution of α-70^Val by α-70^Ile results in a MoFe protein that is hampered in its ability to reduce a range of substrates including acetylene and N₂, yet retains normal proton reduction activity. The 2.3 Å structure of the α-70^Ile MoFe protein is compared to the α-70^Val wild-type MoFe protein, revealing that the δ methyl group of α-70^Val is positioned over Fe6 within the active site FeMo-cofactor. This work provides strong crystallographic support for the previously proposed model that substrates bind and are reduced at a single 4Fe-4S face of the FeMo-cofactor and that when α-70^Val is substituted by α-70^Ile access of substrates to Fe6 of this face is effectively blocked. Furthermore the detailed examination of the structure provides the basis for understanding the ability to trap and characterize hydrides in the variant, contributing significantly to our understanding of substrate access and substrate reduction at the FeMo-cofactor active site of nitrogenase.     

Constrained geometric dynamics of the Fenna–Matthews–Olson complex: the role of correlated motion in reducing uncertainty in excitation energy transfer

The trimeric Fenna–Mathews–Olson (FMO) complex of green sulphur bacteria is a well-studied example of a photosynthetic pigment–protein complex, in which the electronic properties of the pigments are modified by the protein environment to promote efficient excitonic energy transfer from antenna complexes to the reaction centres. By a range of simulation methods, many of the electronic properties of the FMO complex can be extracted from knowledge of the static crystal structure. However, the recent observation and analysis of long-lasting quantum dynamics in the FMO complex point to protein dynamics as a key factor in protecting and generating quantum coherence under laboratory conditions. While fast inter- and intra-molecular vibrations have been investigated extensively, the slow, conformational dynamics which effectively determine the optical inhomogeneous broadening of experimental ensembles has received less attention. The following study employs constrained geometric dynamics to study the flexibility in the protein network by efficiently generating the accessible conformational states from the published crystal structure. Statistical and principle component analyses reveal highly correlated low frequency motions between functionally relevant elements, including strong correlations between pigments that are excitonically coupled. Our analysis reveals a hierarchy of structural interactions which enforce these correlated motions, from the level of monomer-monomer interfaces right down to the α-helices, β-sheets and pigments. In addition to inducing strong spatial correlations across the conformational ensemble, we find that the overall rigidity of the FMO complex is exceptionally high. We suggest that these observations support the idea of highly correlated inhomogeneous disorder of the electronic excited states, which is further supported by the remarkably low variance (typically <5 %) of the excitonic couplings of the conformational ensemble.     

Insights into base selectivity from the 1.8 Å resolution structure of an RB69 DNA polymerase ternary complex

Bacteriophage RB69 DNA polymerase (RB69 pol) has served as a model for investigating how B family polymerases achieve a high level of fidelity during DNA replication. We report here the structure of an RB69 pol ternary complex at 1.8 ? resolution, extending the resolution from our previously reported structure at 2.6 ? [Franklin, M. C., et al. (2001) Cell 105, 657-667]. In the structure presented here, a network of five highly ordered, buried water molecules can be seen to interact with the N3 and O2 atoms in the minor groove of the DNA duplex. This structure reveals how the formation of the closed ternary complex eliminates two ordered water molecules, which are responsible for a kink in helix P in the apo structure. In addition, three pairs of polar-nonpolar interactions have been observed between (i) the Cα hydrogen of G568 and the N3 atom of the dG templating base, (ii) the O5' and C5 atoms of the incoming dCTP, and (iii) the OH group of S565 and the aromatic face of the dG templating base. These interactions are optimized in the dehydrated environment that envelops Watson-Crick nascent base pairs and serve to enhance base selectivity in wild-type RB69 pol.     

Function of the IsiA pigment–protein complex in vivo

Photosynthesis Research - The acclimation of cyanobacterial photosynthetic apparatus to iron deficiency is crucial for their performance under limiting conditions. In many cyanobacterial species,...     

Insights into the structure–function relationship of brown plant hopper resistance protein,Bph14 of rice plant: a computational structural biology approach

Brown plant hopper (BPH) is one of the major destructive insect pests of rice, causing severe yield loss. Thirty-two BPH resistance genes have been identified in cultivated and wild species of rice Although, molecular mechanism of rice plant resistance against BPH studied through map-based cloning, due to non-existence of NMR/crystal structures of Bph14 protein, recognition of leucine-rich repeat (LRR) domain and its interaction with different ligands are poorly understood. Thus, in the present study, in silico approach was adopted to predict three-dimensional structure of LRR domain of Bph14 using comparative modelling approach followed by interaction study with jasmonic and salicylic acids. LRR domain along with LRR-jasmonic and salicylic acid complexes were subjected to dynamic simulation using GROMACS, individually, for energy minimisation and refinement of the structure. Final binding energy of jasmonic and salicylic acid with LRR domain was calculated using MM/PBSA. Free-energy landscape analysis revealed that overall stability of LRR domain of Bph14 is not much affected after forming complex with jasmonic and salicylic acid. MM/PBSA analysis revealed that binding affinities of LRR domain towards salicylic acid is higher as compared to jasmonic acid. Interaction study of LRR domain with salicylic acid and jasmonic acid reveals that THR987 of LRR form hydrogen bond with both complexes. Thus, THR987 plays active role in the Bph14 and phytochemical interaction for inducing resistance in rice plant against BPH. In future, Bph14 gene and phytochemicals could be used in BPH management and development of novel resistant varieties for increasing rice yield.     

Structurally flexible macro-organization of the pigment–protein complexes of the diatom Phaeodactylum tricornutum

By means of circular dichroism (CD) spectroscopy, we have characterized the organization of the photosynthetic complexes of the diatom Phaeodactylum tricornutum at different levels of structural complexity: in intact cells, isolated thylakoid membranes and purified fucoxanthin chlorophyll protein (FCP) complexes. We found that the CD spectrum of whole cells was dominated by a large band at (+)698 nm, accompanied by a long tail from differential scattering, features typical for psi-type (polymerization or salt-induced) CD. The CD spectrum additionally contained intense (−)679 nm, (+)445 nm and (−)470 nm bands, which were also present in isolated thylakoid membranes and FCPs. While the latter two bands were evidently produced by excitonic interactions, the nature of the (−)679 nm band remained unclear. Electrochromic absorbance changes also revealed the existence of a CD-silent long-wavelength (∼545 nm) absorbing fucoxanthin molecule with very high sensitivity to the transmembrane electrical field. In intact cells the main CD band at (+)698 nm appeared to be associated with the multilamellar organization of the thylakoid membranes. It was sensitive to the osmotic pressure and was selectively diminished at elevated temperatures and was capable of undergoing light-induced reversible changes. In isolated thylakoid membranes, the psi-type CD band, which was lost during the isolation procedure, could be partially restored by addition of Mg-ions, along with the maximum quantum yield and the non-photochemical quenching of singlet excited chlorophyll a, measured by fluorescence transients.     

Domain conformational switch of the iron–sulfur protein in cytochrome bc1 complex is induced by the electron transfer from cytochrome bL to bH

Intensive biochemical, biophysical and structural studies of the cytochrome (cyt) bc₁ complex in the past have led to the formulation of the “protonmotive Q-cycle” mechanism for electron and proton transfer in this vitally important complex. The key step of this mechanism is the separation of electrons during the oxidation of a substrate quinol at the Q_P site with both electrons transferred simultaneously to ISP and cyt b_L when the extrinsic domain of ISP (ISP-ED) is located at the b-position. Pre-steady state fast kinetic analysis of bc₁ demonstrates that the reduced ISP-ED moves to the c₁-position to reduce cyt c₁ only after the reduced cyt b_L is oxidized by cyt b_H. However, the question of how the conformational switch of ISP-ED is initiated remains unanswered. The results obtained from analysis of inhibitory efficacy and binding affinity of two types of Q_P site inhibitors, Pm and Pf, under various redox states of the bc₁ complex, suggest that the electron transfer from heme b_L to b_H is the driving force for the releasing of the reduced ISP-ED from the b-position to c₁-position to reduce cyt c₁.     

A computational tool to predict the evolutionarily conserved protein–protein interaction hot-spot residues from the structure of the unbound protein

Identifying hot-spot residues – residues that are critical to protein–protein binding – can help to elucidate a protein’s function and assist in designing therapeutic molecules to target those residues. We present a novel computational tool, termed spatial-interaction-map (SIM), to predict the hot-spot residues of an evolutionarily conserved protein–protein interaction from the structure of an unbound protein alone. SIM can predict the protein hot-spot residues with an accuracy of 36–57%. Thus, the SIM tool can be used to predict the yet unknown hot-spot residues for many proteins for which the structure of the protein–protein complexes are not available, thereby providing a clue to their functions and an opportunity to design therapeutic molecules to target these proteins.     

Phylogenetic structure of the Thomomys bottae–umbrinus complex in North America

The phylogeography of the Thomomys bottae–umbrinus complex in the United States and Mexico was assessed with sequences of the mitochondrial cytochrome b gene. These sequences were obtained from 225 individuals representing 108 locations over the range, including 56 sequences from GenBank. 110 (500 bp) sequences were used for Bayesian inference and neighbor-joining analyses, and 34 (1140 bp) specimens from the main clades obtained from the Bayesian inference were used in maximum-parsimony and maximum-likelihood analyses. The different analyses indicate significant variation within the species complex that averages 13% among major groups of genetic differences among Thomomys bottae–umbrinus. The overall pattern of geographic variation is not concordant with the current taxonomy. To the contrary, eight monophyletic groups are supported by all analyses and can be considered phylogenetic species. Overall divergence among these groups appears influenced by historical biogeographic events active during the Pliocene and Pleistocene.     

Regulation of actin dynamics and protein trafficking during spermatogenesis – Insights into a complex process

Abstract

In the mammalian testis, extensive restructuring takes place across the seminiferous epithelium at the Sertoli–Sertoli and Sertoli–germ cell interface during the epithelial cycle of spermatogenesis, which is important to facilitate changes in the cell shape and morphology of developing germ cells. However, precise communications also take place at the cell junctions to coordinate the discrete events pertinent to spermatogenesis, namely spermatogonial renewal via mitosis, cell cycle progression and meiosis, spermiogenesis and spermiation. It is obvious that these cellular events are intimately related to the underlying actin-based cytoskeleton which is being used by different cell junctions for their attachment. However, little is known on the biology and regulation of this cytoskeleton, in particular its possible involvement in endocytic vesicle-mediated trafficking during spermatogenesis, which in turn affects cell adhesive function and communication at the cell–cell interface. Studies in other epithelia in recent years have shed insightful information on the intimate involvement of actin dynamics and protein trafficking in regulating cell adhesion and communications. The goal of this critical review is to provide an updated assessment of the latest findings in the field on how these complex processes are being regulated during spermatogenesis. We also provide a working model based on the latest findings in the field including our laboratory to provide our thoughts on an apparent complicated subject, which also serves as the framework for investigators in the field. It is obvious that this model will be rapidly updated when more data are available in future years.     

Modeling of the structure of protein–DNA complexes using the data from FRET and footprinting experiments

We discuss the question of constructing three-dimensional models of DNA in complex with proteins using computer modeling and indirect methods of studying the conformation of macromolecules. We consider the methods of interpreting the experimental data obtained by indirect methods of studying the three-dimensional structure of biomolecules. We discuss some aspects of integrating such data into the process of constructing the molecular models of DNA–protein complexes based on the geometric characteristics of DNA. We propose an algorithm for estimating conformations of such complexes based on the information about the local flexibility of DNA and on the experimental data obtained by Forster resonance energy transfer (FRET) and hydroxyl footprinting. Finally, we use this algorithm to predict the hypothetical configuration of DNA in a nucleosome bound with histone H1.     

Excitation energy transfer in the LHC-II trimer: a model based on the new 2.72 Å structure

Energy transfer of the light harvesting complex LHC-II trimer, extracted from spinach, was studied in the Q(y) region at room temperature by femtosecond transient absorption spectroscopy. Configuration interaction exciton method [Linnanto et al. (1999) J Phys Chem B 103: 8739-8750] and 2.72 A structural information reported by Liu et al. was used to calculate spectroscopic properties and excitation energy transfer rates of the complex. Site energies of the pigments and coupling constants of pigment pairs in close contact were calculated by using a quantum chemical configuration interaction method. Gaussian random variation of the diagonal and off-diagonal exciton matrix elements was used to account for inhomogeneous broadening. Rate calculations included only the excitonic states initially excited and probed in the experiments. A kinetic model was used to simulate time and wavelength dependent absorption changes after excitation on the blue side of the Q(y) transition and compared to experimentally recorded rates. Analysis of excitonic wavefunctions allowed identification of pigments initially excited and probed into later. It was shown that excitation of the blue side of the Q(y) band of a single LHC-II complex results in energy transfer from chlorophyll b's of the lumenal side to chlorophyll a's located primarly on one of the monomers of the stromal side.     

The transformation of the cytoplasmic oestradiol–receptor complex into the nuclear complex in a uterine cell-free system

Experiments performed with a cell-free system in tris-EDTA buffer, pH 7.4, indicate that the high-speed supernatant fraction of the rat uterus contains all the factors necessary to transform the 8S cytoplasmic oestradiol-receptor complex to the nuclear complex. The transformation is temperature-dependent. This nuclear complex was extracted in the form of a 5S particle with 0.4m-KCl from sediments of either uterine or heart nuclei that had been incubated together with the cytoplasmic soluble fraction of the uterus at 2 degrees C for 30min. This complex can also be obtained similarly from the soluble fraction of the uterus, incubated in the absence of nuclei. Previous warming of the soluble fraction to 37 degrees C for 7min was necessary for the successful extraction of the nuclear particle under these conditions of incubation. After an incubation of the transformed complex with the nuclear sediment at 37 degrees C for 7min, the 5S complex was extractable from the uterine nuclear sediment but not from the heart nuclear sediment, which may indicate the tissue specificity of the nuclear acceptor sites for the transformed complex. The extracted uterine nuclear complex sediments in the 5S region, but whether it is the native complex or a subunit or other part of the native complex resulting from the extraction with salt is unknown.