The cell wall of the chlamydomonad flagellate,Gloeomonas kupfferi (Volvocales,Chlorophyta)

Summary The large unicellular flagellate,Gloeomonas kupfferi, has recently been used as an important tool in chlamydomonad cell biology research, especially in studies dealing with the structure and function of the endomembrane system. However, little is known about the main secretory product, the cell wall. This study presents structural, chemical and immunological information about this wall. This 850–900 nm thick matrix is highly elaborate and consists of three distinct layers: an inner stratum (325 nm thick) consisting of tightly interwoven fibers, a medial crystalline layer consisting of 22–23 nm subunits and an outer wall layer (500 nm thick) of outwardlyradiating fibrils. Rapid freeze-deep etch analysis reveals that the 35–40 nm fibers of the outer layer form a quasi-lattice of 160 nm subunits. The outer wall can be removed from whole pellets using the chelator, CDTA. The medial wall complex can be solubilized by perchlorate. SDS-gel electrophoresis reveals that the perchlorate soluble-material consists of five high molecular weight glycoproteins and five major low molecular weight glycoproteins. The electrophoretic profile is roughly similar to that ofChlamydomonas reinhardtii. Antibodies were successfully raised against the outer wall component and were shown to label the outer wall layer.     

Structure of the glycan chain from the surface layer glycoprotein of Clostridium thermohydrosulfuricum L77-66.

The thermophilic eubacterium Clostridium thermohydrosulfuricum L77-66 is covered by a crystalline surface layer composed of identical glycoprotein subunits which are arranged in a hexagonal lattice with centre-to-centre spacings of approx. 14.3 nm. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis of cell wall preparations showed the presence of several broadened, carbohydrate-containing bands in a molecular mass range of 90 to 200 kDa. A total carbohydrate content of approx. 14% was determined in the purified surface layer glycoprotein. Chemical deglycosylation of this material by trifluoromethanesulfonic acid resulted in the disappearance of the complex banding pattern. Only a single band with a molecular mass of 82 kDa remained visible upon Coomassie staining. After proteolytic digestion of the surface layer glycoprotein a single glycopeptide fraction with an apparent molecular mass of approx. 25 kDa was obtained by gel filtration. Composition analysis, methylation, periodate oxidation and a combination of homonuclear and 1H-detected heteronuclear shift-correlated nuclear magnetic resonance experiments established the following structure for the glycan chain of the surface layer glycoprotein.     

Self-assembly of a plant cell wall in vitro

A method has been developed by which the cell wall of Chlamydomonas reinhardi may be dissociated into its components, and then reassembled in vitro into a product that is chemically and structurally identical to the original cell wall. Chaotropic agents, such as lithium chloride and sodium perchlorate, separate the wall into two fractions, an insoluble amorphous inner wall layer, which retains its integrity (7.5% by weight of the complete wall) and a salt-soluble fraction containing the homogeneous glycoproteins responsible for the outer crystalline layers of the cell wall. Removal of the salt from dissociated walls by dialysis leads to the rapid recovery of complete reassembled cell walls. The conditions necessary for successful reconstitution of the cell wall in vitro include the presence of a suitable surface, across which a decreasing salt gradient exists, and the presence of both the salt-insoluble and the salt-soluble components. The salt-soluble glycoproteins alone can self-assemble under various conditions to form fragments that have the crystalline structure characteristic of the outer layers of the complete cell wall. Both the inner wall layer and the salt-soluble glyco-proteins have similar bulk amino acid and sugar (arabinose, galactose, mannose) compositions and both contain hydroxyproline. On the basis of the in vitro reconstitution of the cell wall we discuss certain aspects of in vivo cell wall morphogenesis. This communication describes the first case in which a plant cell wall has been reconstructed in vitro, and indicates that components of very large cellular structures are capable of being built by a simple self-assembly process.     

Volvocine cell walls and their constituent glycoproteins: An evolutionary perspective

Summary Similarities in the composition of the extracellular matrix suggest that only some species of the unicellularChlamydomonas are closely related to the colonial and multicellular flagellated members of the family Volvocaceae. The cell walls from all of the algae in this volvocine group contain a crystalline layer. This lattice structure can be used as a phylogenetic marker to divideChlamydomonas species into distinct classes, only one of which includes the volvocacean algae. Similarly, not all species ofChlamydomonas are sensitive to each other's cell wall lytic enzymes, implying divergence of the enzyme's inner wall substrate. Interspecific reconstitution of the crystalline layer is possible betweenC. reinhardtii and the multicellularVolvox carteri, but not betweenC. reinhardtii andC. eugametos. The hydroxyproline-rich glycoproteins (HRGPs) which make up the crystalline layer in genera which have a similar crystal structure exhibit many homologies. Interestingly, the evolutionarily distant cell walls ofC. reinhardtii andC. eugametos also contain some HRGPs displaying a few morphological and amino acid sequence homologies. The morphological similarities between the flagellar agglutinins (HRGPs responsible for sexual recognition and adhesion during the mating reaction) and the cell wall HRGPs leads to the proposal of a superfamily from which novel HRGPs (designed for self-assembly/recognition) can constantly evolve. Just as variations in the wall HRGPs can lead to unique wall structures, new agglutinins facilitate sexual isolation of new species. Thus, the HRGPs could emerge as valuable phylogenetic markers.Abbreviations GLE gametic lytic enzyme - GP glycoprotein - HRGP hydroxyproline-rich glycoprotein - SDS PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - VLE vegetative lytic enzyme - VSP vegetative serine/proline-rich - WP wall protein - ZSP zygotic serine/proline-rich     

Three-dimensional architecture of the cell sheath and septa of Methanospirillum hungatei.

The methanogenic bacterium Methanospirillum hungatei exists as filaments which have a very unusual cell wall architecture, comprising a long cylindrical sheath within which there may be many individual cells arranged in a line. The sheath has a two-dimensional crystalline structure, and the cells are separated within the tube by septa which also have a crystalline structure. We have used computer image processing of tilted-view electron micrographs to analyze the structure in negative stains of both of these components in three dimensions. The repeating unit of the sheath consists of four approximately spherical domains ca. 2.5 nm in diameter arranged in a row. Based on observations of the type of lattice imperfections that occur, we suggest that each of the domains represents a separate polypeptide subunit and that the subunits are incorporated into the wall one by one. The septa are circular plates of remarkably constant size. They are normally found as double layers. They are hexagonally symmetrical and consist of trimerically associated subunits which interact about dimer axes to form an open network containing large pores ca. 15 nm in diameter.     

The crystalline glycoprotein cell wall of the green alga Chlorogonium elongatum: a structural analysis.

Members of the Chlamydomonaceae, mostly single-celled green algae, have been shown to contain a crystalline glycoprotein cell wall component. Most of the species examined fall into a class of algae whose walls have an identical crystalline unit cell. Chlorogonium elongatum has been chosen as a representative of this class in order to investigate in more detail its cell wall structure. The alga has a spindleshaped cell wall which retains its asymmetric shape on isolation. Sections from walls fized in the presence of tannic acid clearly reveal a regular subunit monolayer, about 20 nm thick, within the wall. Sodium dodecylsulphate (SDS) polyacrylamide gel electrophoresis shows the presence of at least 2 major glycoprotein species in the wall. Negatively stained purified cell walls demonstrate the crystalline nature of the cell wall. Optical diffraction of bright-field images and direct electron diffraction both give clear diffraction patterns whose spacings extend out to 3 nm and fall on a reciprocal lattice whose vectors describe a 2-dimensional unit cell within the wall 21.5 nm X 7.0 nm and an included angle of 80 degrees. Lattice defects within the cell wall are revealed by both negative staining and surface replication. Through-focal series were used to choose images with the optimal degree of underfocus for image processing. Linear integration and optical filtering of such images gave essentially the same result. A similar image was also obtained by computing the autocorrelation function of the amplitudes in the electron-diffraction pattern and the optical-diffraction pattern of the in-focus image. On the basis of these data a 2-dimensional model of the crystalline cell wall layer is presented.     

Assembly of cell-wall glycoproteins of Chlamydomonas reinhardii: Oligosaccharides are added in medial and trans Golgi compartments

A series of monoclonal antibodies and a polyclonal antiserum have been used to investigate the localisation and pathway of biosynthesis of the cell-wall hydroxyproline-rich glycoprotein 2BII in the alga Chlamydomonas reinhardii. Glyco-protein precursors were detected within the endoplasmic reticulum using a polyclonal antiserum raised to the deglycosylated 2BII. Monoclonal antibodies which are known to recognise different carbohydrate epitopes of 2BII were found to label two distinct regions of the Golgi stack. The immunolabelling results demonstrate that there is compartmentation of protein synthesis and glycosylation steps for these O-glycosidically linked glycoproteins. Newly synthesised glycoproteins are transported from the Golgi apparatus to the cell surface via two distinct routes. They then undergo assembly into a cell wall, the inner wall layer being formed first and probably functionaing as a template within which the outer crystalline wall layers are assembled.Abbreviations DGP deglycosylated glycoprotein - ER endoplasmic reticulum - MAC monoclonal antibody centre - M _r relative molecular mass     

Cell surface display of chimeric glycoproteins via the S-layer of Paenibacillus alvei

The Gram-positive, mesophilic bacterium Paenibacillus alvei CCM 2051^T possesses a two-dimensional crystalline protein surface layer (S-layer) with oblique lattice symmetry composed of a single type of O-glycoprotein species. Herein, we describe a strategy for nanopatterned in vivo cell surface co-display of peptide and glycan epitopes based on this S-layer glycoprotein self-assembly system. The open reading frame of the corresponding structural gene spaA codes for a protein of 983 amino acids, including a signal peptide of 24 amino acids. The mature S-layer protein has a theoretical molecular mass of 105.95 kDa and a calculated pI of 5.83. It contains three S-layer homology domains at the N-terminus that are involved in anchoring of the glycoprotein via a non-classical, pyruvylated secondary cell wall polymer to the peptidoglycan layer of the cell wall. For this polymer, several putative biosynthesis enzymes were identified upstream of the spaA gene. For in vivo cell surface display, the hexahistidine tag and the enhanced green fluorescent protein, respectively, were translationally fused to the C-terminus of SpaA. Immunoblot analysis, immunofluorescence staining, and fluorescence microscopy revealed that the fused epitopes were efficiently expressed and successfully displayed via the S-layer glycoprotein matrix on the surface of P. alvei CCM 2051^T cells. In contrast, exclusively non-glycosylated chimeric SpaA proteins were displayed, when the S-layer of the glycosylation-deficient wsfP mutant was used as a display matrix.     

Three-dimensional reconstruction of innermost chorion layer from Drosophila melanogaster

A low-resolution three-dimensional structure of the crystalline innermost chorion layer (ICL) has been calculated from electron microscope images of tilted negatively stained crystals. The isolated ICL is a single layer, about 12 nm thick and appears to be made up of two types of subunits, each approximately 3 nm in diameter, arranged regularly as groups of four heterodimers in space group C222. Linking density between these groups of subunits, maintaining the integrity of the layer, appears to be confined mainly to the outer surfaces of the ICL.     

Bacterial and Archaeal S-Layers as a Subject of Nanobiotechnology

Many bacteria and archaea have a crystalline surface layer (S-layer), which overlies the cell envelope. S-layers each consist of one protein or glycoprotein species. Protein subunits of the S-layer noncovalently interact with each other and with the underlying cell-envelope component. On average, the S-layer lattice has pores of 2–6 nm and is 5–10 nm high. Isolated S-layer proteins recrystallize to form two-dimensional crystalline structures in solution, on a solid support, and on planar lipid membranes. Owing to this unique property, S-layers have a broad range of applications. This review focuses on the structural features and applications of S-layers and their proteins, with special emphasis on their use in nanobiotechnology.     

Three-dimensional reconstruction of innermost chorion layer from Drosophila melanogaster

A low-resolution three-dimensional structure of the crystalline innermost chorion layer (ICL) has been calculated from electron microscope images of tilted negatively stained crystals. The isolated ICL is a single layer, about 12 nm thick and appears to be made up of two types of subunits, each approximately 3 nm in diameter, arranged regularly as groups of four heterodimers in space group C222. Linking density between these groups of subunits, maintaining the integrity of the layer, appears to be confined mainly to the outer surfaces of the ICL.     

THE CRYSTALLINE CELL WALL OF TETRASELMIS CONVOLUTAE (CHLOROPHYTA): A FREEZE FRACTURE ANALYSIS1

A freeze fracture analysis of the cell wall of Tetraselmis convolutae (Parke et Manton) revealed the existence of a crystalline median layer consisting of regular repeating subunits of 27 nm. These circular subunits lie in curved, interlocking, longitudinal rows with some irregular discontinuities appearing in the subunit pattern of the crystalline lattice. A comparison with the cell walls of other green algal flagellates is presented, revealing similarities and suggesting evolutionary patterns.     

Three-dimensional structure of the surface layer protein of Aquaspirillum serpens VHA determined by electron crystallography.

The three-dimensional structure of the protein which forms the S layer of Aquaspirillum serpens strain VHA has been determined by electron microscopy. Structures have been reconstructed to a resolution of about 1.6 nm for single-layered specimens and about 4 nm for two-layered specimens. The structure, which has hexagonal symmetry, consists of a core in the shape of a cup, with six projections arising from the rim of the cup to join adjacent subunits at the threefold symmetry axes. The model is consistent with edge views of the S layer which have been obtained in this and other work. It is now clear from this work and from three-dimensional reconstructions of other bacterial S layers that a wide diversity exists in the morphology of surface layers.     

Two-dimensional crystalline sheets of Bacillus stearothermophilus 50S ribosomal particles.

Two-dimensional crystalline sheets of the large ribosomal subunit from Bacillus stearothermophilus have been obtained using a slightly modified procedure to that for growing three-dimensional crystals of the same material. The crystalline subunits are packed within monolayers in a relatively small unit cell, the dimensions of which are closely related to those observed for two forms of the three-dimensional crystals. The packing symmetry is p121, and the optical diffraction patterns of micrographs of negatively stained crystals extend to approximately 3.0 nm.     

The Chlamydomonas cell wall and its constituent glycoproteins analyzed by the quick-freeze, deep-etch technique

Using the quick-freeze, deep-etch technique, we have analyzed the structure of the intact cell wall of Chlamydomonas reinhardi, and have visualized its component glycoproteins after mechanical shearing and after depolymerization induced by perchlorate or by the wall-disrupting agent, autolysin. The intact wall has previously been shown in a thin-section study (Roberts, K., M. Gurney-Smith, and G. J. Hills, 1972, J. Ultrastruct. Res. 40:599-613) to consist of a discrete central triplet bisecting a meshwork of fibrils. The deep-etch technique provides additional information about the architecture of each of these layers under several different experimental conditions, and demonstrates that each layer is constructed from a distinct set of components. The innermost layer of the central triplet proves to be a fibrous network which is stable to perchlorate but destabilized by autolysin, disassembling into fibrillar units we designate as "fishbones." The medial layer of the triplet is a loose assemblage of large granules. The outer layer is a thin, crystalline assembly that is relatively unaffected by autolysin. It depolymerizes into two glycoprotein species, one fibrous and one globular. The wall glycoproteins prove to be structurally similar to two fibrous proteins that associate with the flagellar membrane, namely, the sexual agglutinins and the protomers of a structure we designate a "hammock." They are also homologous to some of the fibrous components found in the extracellular matrices of multicellular plants and animals. The quick-freeze, deep-etch technique is demonstrated to be a highly informative way to dissect the structure of a fibrous matrix and visualize its component macromolecules.     

Structure of the cell envelope of Halobacterium halobium

The structure of the isolated cell envelope of Halobacterium halobium is studied by X-ray diffraction, electron microscopy, and biochemical analysis. The envelope consists of the cell membrane and two layers of protein outside. The outer layer of protein shows a regular arrangement of the protein or glycoprotein particles and is therefore identified as the cell wall. Just outside the cell membrane is a 20 A-thick layer of protein. It is a third structure in the envelope, the function of which may be distinct from that of the cell membrane and the cell wall. This inner layer of protein is separated from the outer protein layer by a 65 A-wide space which has an electron density very close to that of the suspending medium, and which can be etched after freeze-fracture. The space is tentatively identified as the periplasmic space. At NaCl concentrations below 2.0 M, both protein layers of the envelope disintegrate. Gel filtration and analytical ultracentrifugation of the soluble components from the two protein layers reveal two major bands of protein with apparent mol wt of approximately 16,000 and 21,000. At the same time, the cell membrane stays essentially intact as long as the Mg++ concentration is kept at treater than or equal to 20 mM. The cell membrane breaks into small fragments when treated with 0.1 M NaCl and EDTA, or with distilled water, and some soluble proteins, including flavins and cytochromes, are released. The cell membrane apparently has an asymmetric core of the lipid bilayer.     

Fine structure of the compound eyes of the midwater amphipod Phronima in relation to behavior and habitat

Pelagic amphipods belonging to the genus Phronima have four compound eyes; two lateral eyes and two large transparent medial eyes which comprise the entire top of the head. The eyes are structurally similar but the crystalline cones of the medial eyes are more than twenty times as long as those of the lateral eyes, reaching 5 mm in a large animal. The dioptric system of each ommatidium consists of an unfaceted cornea, a layer of hypodermal cells, two rudimentary cone cells, two cells which surround and form the crystalline cone, and the cone itself. The cone and its surrounding cells penetrate the layer of accessory pigment cells which surrounds the retina. The fused rhabdom is formed by the five retinula cells but is separated from them by an extracellular palisade which is crossed by bridges. The retinula cell nuclei lie proximal to the basement membrane. Further proximally the bundle of retinula cell axons is crossed by a second basement membrane, which surrounds each axon with a collar. Medial and lateral eyes on each side of the head share a common lamina. The medial eyes of Phronima appear to be a solution to the problem of remaining inconspicuous to predators while still maintaining sensitivity and resolution.     

Evidence for an S-layer protein pool in the peptidoglycan of Bacillus stearothermophilus.

Intact cells of Bacillus stearothermophilus PV72 revealed, after conventional thin-sectioning procedures, the typical cell wall profile of S-layer-carrying gram-positive eubacteria consisting of a ca. 10-nm-thick peptidoglycan-containing layer and a ca. 10-nm-thick S layer. Cell wall preparations obtained by breaking the cells and removing the cytoplasmic membrane by treatment with Triton X-100 revealed a triple-layer structure, with an additional S layer on the inner surface of the peptidoglycan. This profile is characteristic for cell wall preparations of many S-layer-carrying gram-positive eubacteria. Among several variants of strain PV72 obtained upon single colony isolation, we investigated the variant PV72 86-I, which does not exhibit an inner S layer on isolated cell walls but instead possesses a profile identical to that observed for intact cells. In the course of a controlled mild autolysis of isolated cell walls, S-layer subunits were released from the peptidoglycan of the variant and assembled into an additional S layer on the inner surface of the walls, leading to a three-layer cell wall profile as observed for cell wall preparations of the parent strain. In comparison to conventionally processed bacteria, freeze-substituted cells of strain PV72 and the variant strain revealed in thin sections a ca. 18-nm-wide electron-dense peptidoglycan-containing layer closely associated with the S layer. The demonstration of a pool of S-layer subunits in such a thin peptidoglycan layer in an amount at least sufficient for generating one coherent lattice on the cell surface indicated that the subunits must have occupied much of the free space in the wall fabric of both the parent strain and the variant. It can even be speculated that the rate of synthesis and translation of the S-layer protein is influenced by the packing density of the S-layer subunits in the periplasm of the cell wall delineated by the outer S layer and the cytoplasmic membrane. Our data indicate that the matrix of the rigid wall layer inhibits the assembly of the S-layer subunits which are in transit to the outside.