Rotation and structure of FoF1-ATP synthase

F(o)F(1)-ATP synthase is one of the most ubiquitous enzymes; it is found widely in the biological world, including the plasma membrane of bacteria, inner membrane of mitochondria and thylakoid membrane of chloroplasts. However, this enzyme has a unique mechanism of action: it is composed of two mechanical rotary motors, each driven by ATP hydrolysis or proton flux down the membrane potential of protons. The two molecular motors interconvert the chemical energy of ATP hydrolysis and proton electrochemical potential via the mechanical rotation of the rotary shaft. This unique energy transmission mechanism is not found in other biological systems. Although there are other similar man-made systems like hydroelectric generators, F(o)F(1)-ATP synthase operates on the nanometre scale and works with extremely high efficiency. Therefore, this enzyme has attracted significant attention in a wide variety of fields from bioenergetics and biophysics to chemistry, physics and nanoscience. This review summarizes the latest findings about the two motors of F(o)F(1)-ATP synthase as well as a brief historical background.     

Fine structure of the chloroplast membranes ofEuglena gracilis as revealed by freeze-cleaving and deep-etching techniques

Summary The chloroplasts ofEuglena gracilis have been examined by freeze-cleaving and deep-etching techniques.The two chloroplast envelope membranes exhibit distinct fracture faces which do not resemble any of the thylakoid fracture faces.Freeze-cleaved thylakoid membranes reveal four split inner faces. Two of these faces correspond to stacked membrane regions, and two to unstacked regions. Analysis of particle sizes on the exposed faces has revealed certain differences from other chloroplast systems, which are discussed. Thylakoid membranes inEuglena are shown to reveal a constant number of particles per unit area (based on the total particle number for both complementary faces) whether they are stacked or unstacked.Deep-etchedEuglena thylakoid membranes show two additional faces, which correspond to true inner and outer thylakoid surfaces. Both of these surfaces carry very uniform populations of particles. Those on the external surface (the A surface) are round and possess a diameter of approximately 9.5 nm. Those on the inner surface (the D surface) appear rectangular (as paired subunits) and measure approximately 10 nm in width and 18 nm in length. Distribution counts of particles show that the number of particles per unit area revealed by freeze-cleaving within the thylakoid membrane approximates closely the number of particles exposed on the external thylakoid surface (the A surface) by deep-etching. The possible significance of this correlation is discussed. The distribution of rectangular particles on the inner surface of the thylakoid sac (D surface) seems to be the same in both stacked and unstacked membrane regions. We have found no correlation between the D surface particles and any clearly defined population of particles on internal, freeze-cleaved membrane faces. These and other observations suggest that stacked and unstacked membranes are similar, if not identical in internal structure.     

The chloroplast protein CPSAR1, dually localized in the stroma and the inner envelope membrane,is involved in thylakoid biogenesis

Thylakoid biogenesis is a crucial step for plant development involving the combined action of many cellular actors. CPSAR1 is shown here to be required for the normal organization of mature thylakoid stacks, and ultimately for embryo development. CPSAR1 is a chloroplast protein that has a dual localization in the stroma and the inner envelope membrane, according to microscopy studies and subfractionation analysis. CPSAR1 is close to the Obg nucleotide binding protein subfamily and displays GTPase activity, as demonstrated by in vitro assays. Disruption of the CPSAR1 gene via T‐DNA insertion results in the arrest of embryo development. In addition, transmission electron microscopy analysis indicates that mutant embryos are unable to develop thylakoid membranes, and remain white. Unstacked membrane structures resembling single lamellae accumulate in the stroma, and do not assemble into mature thylakoid stacks. CPSAR1 RNA interference induces partially developed thylakoids leading to pale‐green embryos. Altogether, the presented data demonstrate that CPSAR1 is a protein essential for the formation of normal thylakoid membranes, and suggest a possible involvement in the initiation of vesicles from the inner envelope membrane for the transfer of lipids to the thylakoids.     

The Sec2 translocase of the chloroplast inner envelope contains a unique and dedicated SECE2 component

Biogenesis of chloroplasts involves a series of protein trafficking events. Nuclear‐encoded proteins are imported into the organelle, and then trafficked to various chloroplast locations by systems that are directly homologous to bacterial systems. Although the thylakoid‐based systems have been studied extensively, much less is known about the systems that reside and function in the inner envelope membrane. One such system, the Sec2 system, is homologous to both the thylakoid‐based Sec1 system and bacterial Sec systems, and may mediate both integration and translocation across the inner envelope. At a minimum, this system is expected to include three components, but only two, SCY2 and SECA2, have been identified in Arabidopsis. Bioinformatics and protein modeling were used to identify the protein encoded by At4g38490 as a candidate for the missing component (SECE2). Cellular localization, biochemistry, protein interaction assays in yeast, and co‐immunoprecipitation experiments were used to establish that this protein is an integral membrane protein of the inner envelope, and specifically interacts with the SCY2 component in vivo. Sequence analyses indicated that SECE2 proteins are found in a variety of plants, and differ from the thylakoid SECE1 proteins in a stroma‐exposed helical domain, which may contribute to their specificity. Finally, a genetic analysis indicated that SECE2 plays an essential role in plant growth and development.     

Two paths diverged in the stroma: targeting to dual SEC translocase systems in chloroplasts

Chloroplasts inherited systems and strategies for protein targeting, translocation, and integration from their cyanobacterial ancestor. Unlike cyanobacteria however, chloroplasts in green algae and plants contain two distinct SEC translocase/integrase systems: the SEC1 system in the thylakoid membrane and the SEC2 system in the inner envelope membrane. This review summarizes the mode of action of SEC translocases, identification of components of the SEC2 system, evolutionary history of SCY and SECA genes, and previous work on the co- and post-translational targeting of lumenal and thylakoid membrane proteins to the SEC1 system. Recent work identifying substrates for the SEC2 system and potential features that may contribute to inner envelope targeting are also discussed.     

Groups of bonds determining the configuration of the thylakoid system

Four groups of bonds determining the configuration of the thylakoid system have been established. The hypothesis presented here postulates the following. 1. There exist continuous lateral protein-protein interactions (bonds) all over the thylakoid membrane. 2. Lateral protein bonds are subdivided into two independent groups - lateral bonds of outer and inner membrane leaflets. 3. The configuration of a single thylakoid is determined by the mutual action of lateral and interlumenal bonds of the inner membrane leaflet, and the configuration of the thylakoid system of a chloroplast is determined by the mutual action of lateral and intermembrane (stacking) bonds of the outer membrane leaflet.     

Physcomitrella patens as a model for the study of chloroplast protein transport: conserved machineries between vascular and non-vascular plants

A single general import pathway in vascular plants mediates the transport of precursor proteins across the two membranes of the chloroplast envelope, and at least four pathways are responsible for thylakoid protein targeting. While the transport systems in the thylakoid are related to bacterial secretion systems, the envelope machinery is thought to have arisen with the endosymbiotic event and to be derived, at least in part, from proteins present in the original endosymbiont. Recently the moss Physcomitrella patens has gained worldwide attention for its ability to undergo homologous recombination in the nuclear genome at rates unseen in any other land plants. Because of this, we were interested to know whether it would be a useful model system for studying chloroplast protein transport. We searched the large database of P. patens expressed sequence tags for chloroplast transport components and found many putative homologues. We obtained full-length sequences for homologues of three Toc components from moss. To our knowledge, this is the first sequence information for these proteins from non-vascular plants. In addition to identifying components of the transport machinery from moss, we isolated plastids and tested their activity in protein import assays. Our data indicate that moss and pea (Pisum sativum) plastid transport systems are functionally similar. These findings identify P. patens as a potentially useful tool for combining genetic and biochemical approaches for the study of chloroplast protein targeting. Abbreviations: EST, expressed sequence tag; LHCP, light-harvesting chlorophyll-binding protein; NIBB, National Institute for Basic Biology; OE17, 17 kDa subunit of the oxygen-evolving complex; PC, plastocyanin; PEP, Physcomitrella EST Programme; SPP, stromal processing peptidase; SRP, signal recognition particle; Tat, twin-arginine translocation; Tic, translocon at the inner membrane of the chloroplast envelope; Toc, translocon at the outer membrane of the chloroplast envelope; TPP, thylakoid processing peptidase; TPR, tetratricopeptide repeatSupplementary material to this paper is available in electronic form at .This revised version was opublished online in July 2005 with corrected page numbers.     

Channel-tunnels: outer membrane components of type I secretion systems and multidrug efflux pumps of Gram-negative bacteria

For translocation across the cell envelope of Gram-negative bacteria, substances have to overcome two permeability barriers, the inner and outer membrane. Channel-tunnels are outer membrane proteins, which are central to two distinct export systems: the type I secretion system exporting proteins such as toxins or proteases, and efflux pumps discharging antibiotics, dyes, or heavy metals and thus mediating drug resistance. Protein secretion is driven by an inner membrane ATP-binding cassette (ABC) transporter while drug efflux occurs via an inner membrane proton antiporter. Both inner membrane transporters are associated with a periplasmic accessory protein that recruits an outer membrane channel-tunnel to form a functional export complex. Prototypes of these export systems are the hemolysin secretion system and the AcrAB/TolC drug efflux pump of Escherichia coli, which both employ TolC as an outer membrane component. Its remarkable conduit-like structure, protruding 100 ? into the periplasmic space, reveals how both systems are capable of transporting substrates across both membranes directly from the cytosol into the external environment. Proteins of the channel-tunnel family are widespread within Gram-negative bacteria. Their involvement in drug resistance and in secretion of pathogenic factors makes them an interesting system for further studies. Understanding the mechanism of the different export apparatus could help to develop new drugs, which block the efflux pumps or the secretion system. Electronic Publication     

Fluorescence staining of live cyanobacterial cells suggest non-stringent chromosome segregation and absence of a connection between cytoplasmic and thylakoid membranes

Background  

In spite of their abundance and importance, little is known about cyanobacterial cell biology and their cell cycle. During each cell cycle, chromosomes must be separated into future daughter cells, i.e. into both cell halves, which in many bacteria is achieved by an active machinery that operates during DNA replication. Many cyanobacteria contain multiple identical copies of the chromosome, but it is unknown how chromosomes are segregated into future daughter cells, and if an active or passive mechanism is operative. In addition to an outer and an inner cell membrane, cyanobacteria contain internal thylakoid membranes that carry the active photosynthetic machinery. It is unclear whether thylakoid membranes are invaginations of the inner cell membrane, or an independent membrane system.     

Antistaphylococcal and biofilm inhibitory activities of gallic,caffeic, and chlorogenic acids

Staphylococcus aureus is a Gram-positive pathogen which is able to form biofilms, exhibiting a more pronounced resistance to antibiotics and disinfectants. The?hurdles posed in eradicating biofilms?have driven the search for new compounds able to fight these structures. Phenolic compounds constitute one of the most numerous and ubiquitous group of plant secondary metabolites with many biological activities. The aim of the present work was to study the potential antimicrobial and antibiofilm properties of gallic, caffeic, and chlorogenic acids against S. aureus as well to elucidate its mechanism of action. It was concluded that the phenolic acids studied in this work?have antistaphylococcal properties. For instance, gallic acid is able to influence the adhesion properties of S. aureus. The phenolic acids tested were also able to inhibit the production of α-hemolysin by this microorganism, with the exception of chlorogenic acid. Regarding its mechanism of action, caffeic acid interferes with the stability of the cell membrane and with the metabolic activity of the cells of S. aureus.     

Mechanics and Dynamics of Bacterial Cell Lysis

Membrane lysis, or rupture, is a cell death pathway in bacteria frequently caused by cell wall-targeting antibiotics. Although previous studies have clarified the biochemical mechanisms of antibiotic action, a physical understanding of the processes leading to lysis remains lacking. Here, we analyze the dynamics of membrane bulging and lysis in Escherichia coli, in which the formation of an initial, partially subtended spherical bulge (“bulging”) after cell wall digestion occurs on a characteristic timescale of 1 s and the growth of the bulge (“swelling”) occurs on a slower characteristic timescale of 100 s. We show that bulging can be energetically favorable due to the relaxation of the entropic and stretching energies of the inner membrane, cell wall, and outer membrane and that the experimentally observed timescales are consistent with model predictions. We then show that swelling is mediated by the enlargement of wall defects, after which cell lysis is consistent with both the inner and outer membranes exceeding characteristic estimates of the yield areal strains of biological membranes. These results contrast biological membrane physics and the physics of thin, rigid shells. They also have implications for cellular morphogenesis and antibiotic discovery across different species of bacteria.     

The consequence of sequence alteration of an amphipathic alpha-helical antimicrobial peptide and its diastereomers

The search for antibiotics with a new mode of action led to numerous studies on antibacterial peptides. Most of the studies were carried out with l-amino acid peptides possessing amphipathic alpha-helix or beta-sheet structures, which are known to be important for biological activities. Here we compared the effect of significantly altering the sequence of an amphipathic alpha-helical peptide (15 amino acids long) and its diastereomer (composed of both l- and d-amino acids) regarding their structure, function, and interaction with model membranes and intact bacteria. Interestingly, the effect of sequence alteration on biological function was similar for the l-amino acid peptides and the diastereomers, despite some differences in their structure in the membrane as revealed by attenuated total reflectance Fourier-transform infrared spectroscopy. However, whereas the all l-amino acid peptides were highly hemolytic, had low solubility, lost their activity in serum, and were fully cleaved by trypsin and proteinase K, the diastereomers were nonhemolytic and maintained full activity in serum. Furthermore, sequence alteration allowed making the diastereomers either fully, partially, or totally protected from degradation by the enzymes. Transmembrane potential depolarization experiments in model membranes and intact bacteria indicate that although the killing mechanism of the diastereomers is via membrane perturbation, it is also dependent on their ability to diffuse into the inner bacterial membrane. These data demonstrate the advantage of the diastereomers over their all l-amino acid counterparts as candidates for developing a repertoire of new target antibiotics with a potential for systemic use.     

Ultrastructure of the Thylakoid Membrane in Tomato Leaf Chloroplast Revealed by Liquid Helium Rapid-Freezing and Substitution-Fixation Method

The ultrastructure of the chloroplast in tomato leaves was studiedby a liquid helium rapid-freezing and substitution-fixationmethod. Distinct morphological differences were observed betweenthe ultrastructure of the thylakoid membrane fixed by this methodand the one fixed by the conventional chemical fixation method.The membrane was asymmetrical and consisted of triple-layeredleaflets. While the leaflet facing the stroma (outer leaflet)was very electron-dense, the one facing the thylakoid lumen(inner leaflet) was less electron-dense. The triple-layeredleaflets showed a structural difference between the grana thylakoidand the stroma thylakoid. In the grana region, where thylakoidmembranes are appressed, the part of outer leaflets were lookedlike fused or adhered to each other making one highly electron-denselayer composed of linings of particles (about 4 nm in diameter).The inner leaflet of the grana thylakoid membrane showed discontinuousstructure. This discontinuous structure was composed of a clusterof irregular particles (about 2–3 nm in diameter). Thesize of cluster varied from about 10nm to 16nm. The discontinuityof the inner leaflet, i.e. linings of the clusters at ratherconstant intervals, was not observed clearly in the stroma thylakoid.The liquid helium rapid-freezing and substitution-fixation methodcan be used to observe the details of protein complexes in thethylakoid membrane organization. (Received March 23, 1988; Accepted August 17, 1988)     

Cubic Membrane Structure in Amoeba (Chaos carolinensis) Mitochondria Determined by Electron Microscopic Tomography

Cubic membranes occur in a variety of membrane-bound organelles in many cell types. By transmission electron microscopy (TEM) these membrane systems appear to consist of highly curved periodic surfaces that fit mathematical models analogous to those used to describe lipidic cubic phases. For the first time, a naturally occurring cubic membrane system has been reconstructed in three dimensions by electron microscopic tomography, and its periodicity directly characterized. Double-tilt tomographic reconstruction of mitochondria in the amoeba, Chaos carolinensis, confirms that their cristae (inner membrane infoldings) have the cubic structure suggested by modeling studies based on thin-section TEM images. Analysis of the membrane surfaces in the reconstruction reveals the connectivity of the internal compartments within the mitochondria. In the cubic regions, the matrix is highly condensed and confined to a continuous, small space between adjacent cristal membranes. The cristae form large, undulating cisternae that communicate with the peripheral (inner membrane) compartment through narrow tubular segments as seen in other types of mitochondria. The cubic periodicity of these mitochondrial membranes provides an ideal specimen for measuring geometrical distortions in biological electron tomography. It may also prove to be a useful model system for studies of the correlation of cristae–matrix organization with mitochondrial activity.     

MFP1 is a thylakoid-associated,nucleoid-binding protein with a coiled-coil structure

Plastid DNA, like bacterial and mitochondrial DNA, is organized into protein–DNA complexes called nucleoids. Plastid nucleoids are believed to be associated with the inner envelope in developing plastids and the thylakoid membranes in mature chloroplasts, but the mechanism for this re-localization is unknown. Here, we present the further characterization of the coiled-coil DNA-binding protein MFP1 as a protein associated with nucleoids and with the thylakoid membranes in mature chloroplasts. MFP1 is located in plastids in both suspension culture cells and leaves and is attached to the thylakoid membranes with its C-terminal DNA-binding domain oriented towards the stroma. It has a major DNA-binding activity in mature Arabidopsis chloroplasts and binds to all tested chloroplast DNA fragments without detectable sequence specificity. Its expression is tightly correlated with the accumulation of thylakoid membranes. Importantly, it is associated in vivo with nucleoids, suggesting a function for MFP1 at the interface between chloroplast nucleoids and the developing thylakoid membrane system.     

Insights into the complex 3-D architecture of thylakoid membranes in the unicellular cyanobacterium Cyanothece sp. ATCC 51142

In cyanobacteria and chloroplasts, thylakoids are the complex internal membrane system where the light reactions of oxygenic photosynthesis occur. In plant chloroplasts, thylakoids are differentiated into a highly interconnected system of stacked grana and unstacked stroma membranes. In contrast, in cyanobacteria, the evolutionary progenitors of chloroplasts, thylakoids do not routinely form stacked and unstacked regions, and the architecture of the thylakoid membrane systems is only now being described in detail in these organisms. We used electron tomography to examine the thylakoid membrane systems in one cyanobacterium, Cyanothece sp. ATCC 51142. Our data showed that thylakoids form a complicated branched network with a rudimentary quasi-helical architecture in this organism. A well accepted helical model of grana-stroma architecture of plant thylakoids describes an organization in which stroma thylakoids wind around stacked granum in right-handed spirals. Here we present data showing that the simplified helical architecture in Cyanothece 51142 is lefthanded in nature. We propose a model comparing the thylakoid membranes in plants and this cyanobacterium in which the system in Cyanothece 51142 is composed of non-stacked membranes linked by fret-like connections to other membrane components of the system in a limited left-handed arrangement.Key words: cyanobacteria, Cyanothece 51142, thylakoid membrane, electron tomography, chloroplast     

Structural mechanism of phospholipids translocation by MlaFEDB complex

In Gram-negative bacteria, phospholipids are major components of the inner membrane and the inner leaflet of the outer membrane, playing an essential role in forming the unique dual-membrane barrier to exclude the entry of most antibiotics. Understanding the mechanisms of phospholipid translocation between the inner and outer membrane represents one of the major challenges surrounding bacterial phospholipid homeostasis. The conserved MlaFEDB complex in the inner membrane functions as an ABC transporter to drive the translocation of phospholipids between the inner membrane and the periplasmic protein MlaC. However, the mechanism of phospholipid translocation remains elusive. Here we determined three cryo-EM structures of MlaFEDB from Escherichia coli in its nucleotide-free and ATP-bound conformations, and performed extensive functional studies to verify and extend our findings from structural analyses. Our work reveals unique structural features of the entire MlaFEDB complex, six well-resolved phospholipids in three distinct cavities, and large-scale conformational changes upon ATP binding. Together, these findings define the cycle of structural rearrangement of MlaFEDB in action, and suggest that MlaFEDB uses an extrusion mechanism to extract and release phospholipids through the central translocation cavity.Subject terms: Electron microscopy, Membrane trafficking     

Isolation and Characterization of the Thylakoid Membranes from the NaCl-Resistant (NaClr) Mutant Strain of the Cyanobacterium Anabaena variabilis

NaCl-induced changes in the thylakoid membrane of wild-type Anabaena variabilis and its NaCl^r mutant strain have been studied. Biochemical characterization of the thylakoid membrane was done by taking its absorption and fluorescence spectra at different wavelength. The thylakoid membranes of both strains were isolated by mechanical disruption of the freeze-dried and lysozyme-treated cells, followed by differential and density gradient centrifugation. The light absorption spectra of the thylakoid membrane showed three and two peaks in NaCl^r mutant strain and its wild-type counterpart respectively at wavelengths of 400–850 nm. These peaks revealed that the thylakoid membrane contains a large amount of carotenoid and chlorophyll a. Fluorescence emission spectra of thylakoid membrane of NaCl^r mutant and its wild-type strain at excitation wavelength of 335 nm showed two different peaks, one at 340 nm and the other at 663 nm respectively. The light absorption and fluorescence spectra of the thylakoid membrane also revealed that the membrane contained carotenoid pigment, chlorophyll (Chl) a, and a pigment with an emission peak at 335 nm. The HPLC analysis of the pigments of the thylakoid membrane indicates that the NaCl^r mutant strain under NaCl stress contained an additional peak for the carotenoid pigment, which was lacking in its wild-type counterpart. The major peak in thylakoid membrane was that of echinenone and β-carotene. Whereas the polypeptide composition of thylakoid membrane differed in the wild-type and its NaCl^r mutant strain, no difference in the cell wall protein pattern was observed in both strains. The thylakoid membrane of NaCl^r mutant strain contained two additional protein bands that were absent in its wild-type counterpart. The thylakoid membrane of the wild-type and its NaCl^r mutant strain also showed morphological variations under NaCl stress. Received: 14 April 2000 / Accepted: 23 May 2000     

A copper-transporting P-type ATPase found in the thylakoid membrane of the cyanobacterium Synechococcus species PCC7942

P-type ATPases constitute a large family of cation pumps that play crucial physiological roles in many organisms, including bacteria, plants and mammals. They are postulated to play important roles in a variety of environmental adaptation systems. Recently, we cloned two distinct putative P-type ATPase genes (pacS and pacL) from a photosynthetic cyanobacterium, Synechococcus species PCC7942. in this study, one of the gene products (named PacS) was found to possess a putative metal-binding motif (Gly-Met-X-Cys-X-X-Cys) in its N-terminal portion. Thus we supposed that this ATPase may function as a metal pump. Indeed, the results of Northern blotting analysis showed that pacS-mRNA specifically increases upon addition of copper or silver to the growth medium. The results of Western blotting analysis confirmed the view that PacS accumulates in copper-treated Synechococcus cells. Thus we concluded that the expression of PacS ATPase is regulated in response to the change in concentration of external metals, namely copper and silver. Consistent with this, an insertional inactivation mutant of pacS exhibited hypersensitivity in terms of growth to these potentially toxic metals, it was also revealed that PacS was mainly located in the thylakoid membrane, in which the photosynthetic reactions take place. This P-type ATPase in the thylakoid membrane is implicated as a copper-transporting system that may be involved in copper-homeostasis crucial to the photosynthetic thylakoid function.     

Gene sequence for the 9 kDa component of Photosystem II from the cyanobacterium Phormidium laminosum indicates similarities between cyanobacterial and other leader sequences

Summary A 9 kDa polypeptide which is loosely attached to the inner surface of the thylakoid membrane and is important for the oxygen-evolving activity of Photosystem II in the thermophilic cyanobacterium Phormidium laminosum has been purified, a partial amino acid sequence obtained and its gene cloned and sequenced. The derived amino acid sequence indicates that the 9 kDa polypeptide is initially synthesised with an N-terminal leader sequence of 44 amino acids to direct it across the thylakoid membrane. The leader sequence consists of a positively charged N-terminal region, a long hydrophobic region and a typical cleavage site. These features have analogous counterparts in the thylakoid-transfer domain of lumenal polypeptides from chloroplasts of higher plants. These findings support the view of the proposed function of this domain in the two-stage processing model for import of lumenal, nuclear-encoded polypeptides. In addition, there is striking primary sequence homology between the leader sequences of the 9 kDa polypeptide and those of alkaline phosphatase (from the periplasmic space of Escherichia coli) and, particularly in the region of the cleavage site, the 16 kDa polypeptide of the oxygen-evolving apparatus in the thylakoid lumen of spinach chloroplasts.