L. Andrew Staehelin

Structure and Function of Intercellular Junctions

Publisher Summary Intercellular junctions are specialized regions of contact between the apposed plasma membranes of adjacent cells, and recent evidence suggests that they are essential for the development of multicellular organisms. They provide the structural means for groups of cells to interact in certain defined ways, and thereby enable them to create structures of higher order. This chapter reviews the morphological information on intercellular junctions derived from thin-sectioning, negative staining and freeze-cleave techniques, as well as from x-ray diffraction and biochemical investigations, and correlates the structural parameters with known or proposed physiological functions. The membrane structure of intercellular junctions is described. Membrane proteins can be divided into two groups: peripheral and integral. Peripheral membrane proteins are believed to be associated with the membrane surface, based on the observation that they are held to the membrane by rather weak noncovalent interactions, and are not strongly associated with membrane lipids. Only mild treatments, such as an increase in ionic strength of the medium or the addition of a chelating agent, are needed to dissociate them molecularly intact from the membrane. Furthermore, in the dissociated state they are relatively soluble in neutral aqueous buffers. In contrast, integral membrane proteins appear much more strongly bound to the lipid matrix, since they can be dissociated from the latter only by drastic treatments with chemicals such as detergents, protein denaturants, and organic solvents. The diversity in structure and function of intercellular junctions offers an exciting field for future research in which morphologists, physiologists, and biochemists should be able to make significant contributions to the knowledge of how individual cells interact to form structures of higher order.

Cytokinesis in Higher Plants

Completion of the fusion tube–generated membrane network signals the end of the first stage of cell plate formation. What follows is a series of steps that both mechanically stabilizes the initial delicate, interwoven membrane network and then transforms it into two new plasma membranes and a new cell wall. Mechanical stabilization of the fusion tube–generated membrane network appears to involve two processes: assembly of a very dense fibrous coat onto the membranes, and consolidation of the membranes into a tubulo-vesicular network (Figure 2bFigure 2b). In the presence of caffeine, both of these processes are inhibited, and the delicate network quickly breaks up into vesicles that are eventually resorbed by the cells, indicating a possible role for Ca2+ in these assembly processes (Samuels and Staehelin 1996xSamuels, A.L. and Staehelin, L.A. Protoplasma, in press. 1996; See all ReferencesSamuels and Staehelin 1996).Transformation of the tubulo-vesicular network first into a tubular network and then into a fenestrated membrane sheet (Figure 2b-dFigure 2b-d) involves the formation of clathrin coated buds, the deposition of callose (a β-1,3 glucose polymer produced by a Ca2+-activated synthase; Kakimoto and Shibaoka 1992xKakimoto, T. and Shibaoka, H. Plant Cell Physiol. 1992; 33: 353–361See all ReferencesKakimoto and Shibaoka 1992) in the network lumen, the loss of the dense membrane coat, and the disassembly of associated MTs. Because the appearance of clathrin-coated buds coincides with the appearance of nearby multivesicular bodies, their main function appears to be the removal of excess membrane and of selected membrane proteins targeted for destruction. A possible function for callose is suggested by its deposition in the form of a dense coat over the lumenal surface of the cell plate–forming membranes. Based on the visco-elastic properties of callose, the membrane-associated callose layer could provide the spreading force that converts the tubulo-vesicular network into a fenestrated sheet and ultimately into a cell wall (Samuels et al. 1995xSamuels, A.L., Giddings Jr, T.H., and Staehelin, L.A. J. Cell Biol. 1995; 130: 1345–1357Crossref | PubMed | Scopus (328)See all ReferencesSamuels et al. 1995).During the centrifugal expansion of the cell plate, which occurs at a rate of up to 1 μm per min, new vesicles continuously arrive at and fuse with the plate periphery, while the older and more centrally located cell plate domains simultaneously mature as discussed above (Figure 2dFigure 2d). When the cell plate reaches the side wall, fusion is brought about by hundreds of fusion tubes that arise from the cell plate margin and fuse with the actin-depleted plasma membrane domain originally demarcated by the preprophase band of MTs (Samuels et al. 1995xSamuels, A.L., Giddings Jr, T.H., and Staehelin, L.A. J. Cell Biol. 1995; 130: 1345–1357Crossref | PubMed | Scopus (328)See all ReferencesSamuels et al. 1995).Although virtually all of the Golgi-derived vesicles deliver cell wall matrix polysaccharides (hemicelluloses and esterified pectic polysaccharides) to the forming cell plate, callose remains the dominant polysaccharide until it is enzymatically removed following completion of the new cell wall. Significant amounts of cellulose fibrils, the tensile elements of plant cell walls, can only be detected beginning with the fenestrated sheet phase of cell plate formation (Samuels et al. 1995xSamuels, A.L., Giddings Jr, T.H., and Staehelin, L.A. J. Cell Biol. 1995; 130: 1345–1357Crossref | PubMed | Scopus (328)See all ReferencesSamuels et al. 1995). Plasmodesmata, the intercellular communication channels of plants, are also formed during this last stage of cell plate formation.The significant progress made in understanding the process of cell plate formation in descriptive terms has now set the stage for the characterization of these dynamic events at the molecular level.

Reevaluation of the Effects of Brefeldin A on Plant Cells Using Tobacco Bright Yellow 2 Cells Expressing Golgi-Targeted Green Fluorescent Protein and COPI Antisera

Brefeldin A (BFA) causes a block in the secretory system of eukaryotic cells by inhibiting vesicle formation at the Golgi apparatus. Although this toxin has been used in many studies, its effects on plant cells are still shrouded in controversy. We have reinvestigated the early responses of plant cells to BFA with novel tools, namely, tobacco Bright Yellow 2 (BY-2) suspension-cultured cells expressing an in vivo green fluorescent protein–Golgi marker, electron microscopy of high-pressure frozen/freeze-substituted cells, and antisera against Atγ-COP, a component of COPI coats, and AtArf1, the GTPase necessary for COPI coat assembly. The first effect of 10 μg/mL BFA on BY-2 cells was to induce in <5 min the complete loss of vesicle-forming Atγ-COP from Golgi cisternae. During the subsequent 15 to 20 min, this block in Golgi-based vesicle formation led to a series of sequential changes in Golgi architecture, the loss of distinct Golgi stacks, and the formation of an endoplasmic reticulum (ER)–Golgi hybrid compartment with stacked domains. These secondary effects appear to depend in part on stabilizing intercisternal filaments and include the continued maturation of cis- and medial cisternae into trans-Golgi cisternae, as predicted by the cisternal progression model, the shedding of trans-Golgi network cisternae, the fusion of individual Golgi cisternae with the ER, and the formation of large ER-Golgi hybrid stacks. Prolonged exposure of the BY-2 cells to BFA led to the transformation of the ER-Golgi hybrid compartment into a sponge-like structure that does not resemble normal ER. Thus, although the initial effects of BFA on plant cells are the same as those described for mammalian cells, the secondary and tertiary effects have drastically different morphological manifestations. These results indicate that, despite a number of similarities in the trafficking machinery with other eukaryotes, there are fundamental differences in the functional architecture and properties of the plant Golgi apparatus that are the cause for the unique responses of the plant secretory pathway to BFA.

Plastoglobules are lipoprotein subcompartments of the chloroplast that are permanently coupled to thylakoid membranes and contain biosynthetic enzymes.

Plastoglobules are lipoprotein particles inside chloroplasts. Their numbers have been shown to increase during the upregulation of plastid lipid metabolism in response to oxidative stress and during senescence. In this study, we used state-of-the-art high-pressure freezing/freeze-substitution methods combined with electron tomography as well as freeze-etch electron microscopy to characterize the structure and spatial relationship of plastoglobules to thylakoid membranes in developing, mature, and senescing chloroplasts. We demonstrate that plastoglobules are attached to thylakoids through a half-lipid bilayer that surrounds the globule contents and is continuous with the stroma-side leaflet of the thylakoid membrane. During oxidative stress and senescence, plastoglobules form linkage groups that are attached to each other and remain continuous with the thylakoid membrane by extensions of the half-lipid bilayer. Using three-dimensional tomography combined with immunolabeling techniques, we show that the plastoglobules contain the enzyme tocopherol cyclase (VTE1) and that this enzyme extends across the surface monolayer into the interior of the plastoglobules. These findings demonstrate that plastoglobules function as both lipid biosynthesis and storage subcompartments of thylakoid membranes. The permanent structural coupling between plastoglobules and thylakoid membranes suggests that the lipid molecules contained in the plastoglobule cores (carotenoids, plastoquinone, and tocopherol [vitamin E]) are in a dynamic equilibrium with those located in the thylakoid membranes.

Electron Tomographic Analysis of Somatic Cell Plate Formation in Meristematic Cells of Arabidopsis Preserved by High-Pressure Freezing

We have investigated the process of somatic-type cytokinesis in Arabidopsis (Arabidopsis thaliana) meristem cells with a three-dimensional resolution of ∼7 nm by electron tomography of high-pressure frozen/freeze-substituted samples. Our data demonstrate that this process can be divided into four phases: phragmoplast initials, solid phragmoplast, transitional phragmoplast, and ring-shaped phragmoplast. Phragmoplast initials arise from clusters of polar microtubules (MTs) during late anaphase. At their equatorial planes, cell plate assembly sites are formed, consisting of a filamentous ribosome-excluding cell plate assembly matrix (CPAM) and Golgi-derived vesicles. The CPAM, which is found only around growing cell plate regions, is suggested to be responsible for regulating cell plate growth. Virtually all phragmoplast MTs terminate inside the CPAM. This association directs vesicles to the CPAM and thereby to the growing cell plate. Cell plate formation within the CPAM appears to be initiated by the tethering of vesicles by exocyst-like complexes. After vesicle fusion, hourglass-shaped vesicle intermediates are stretched to dumbbells by a mechanism that appears to involve the expansion of dynamin-like springs. This stretching process reduces vesicle volume by ∼50%. At the same time, the lateral expansion of the phragmoplast initials and their CPAMs gives rise to the solid phragmoplast. Later arriving vesicles begin to fuse to the bulbous ends of the dumbbells, giving rise to the tubulo-vesicular membrane network (TVN). During the transitional phragmoplast stage, the CPAM and MTs disassemble and then reform in a peripheral ring phragmoplast configuration. This creates the centrifugally expanding peripheral cell plate growth zone, which leads to cell plate fusion with the cell wall. Simultaneously, the central TVN begins to mature into a tubular network, and ultimately into a planar fenestrated sheet (PFS), through the removal of membrane via clathrin-coated vesicles and by callose synthesis. Small secondary CPAMs with attached MTs arise de novo over remaining large fenestrae to focus local growth to these regions. When all of the fenestrae are closed, the new cell wall is complete. Few endoplasmic reticulum (ER) membranes are seen associated with the phragmoplast initials and with the TVN cell plate that is formed within the solid phragmoplast. ER progressively accumulates thereafter, reaching a maximum during the late PFS stage, when most cell plate growth is completed.

Supramolecular organization of chlorosomes (chlorobium vesicles) and of their membrane attachment sites in Chlorobium Limicola

The photosynthetic green bacterium Chlorobium limicola 6230 has been examined by freeze-fracture electron microscopy to investigate the size, form, distribution and supramolecular architecture of its chlorosomes (chlorobium vesicles) as well as the chlorosome attachment sites on the cytoplasmic membrane. The oblong chlorosomes that underlie the cytoplasmic membrane show a considerable variation in size from about 40 X 70 nm to 100 X 260 nm and exhibit no particular orientation. The chlorosome core, which appears to be hydrophobic in nature, contains between 10 and 30 rod-shaped elements (approx. 10 nm in diameter) surrounded by an unetchable matrix. The rod elements are closely packed and extend the full length of the chlorosome. Separating the chlorosome core from the cytoplasm is a approx. 3 nm thick lipid-like envelope layer, which exhibits no substructure. A 5-6 nm thick, crystalline baseplate connects the chlorosome to the cytoplasmic membrane. The ridges of the baseplate lattice make an angle of between 40 degrees and 60 degrees with the longitudinal axis of the chlorosome and have a repeating distance of approx. 6 nm. In addition, each ridge exhibits a granular substructure with a periodicity of approx. 3.3 nm. The cytoplasmic membrane regions adjacent to the baseplates are enriched in large (greater than 9 nm) intramembrane particles, most of which belong to approx. 10 nm and approx. 12.5 nm particle size categories. Each chlorosome attachment site contains between 20 and 30 very large (greater than 12.0 nm diameter) intramembrane particles. The following interpretive model of a chlorosome is discussed in terms of biophysical, biochemical and structural information reported by others: it is proposed that the bacteriochlorophyll c (BChl c; chlorobium chlorophyll) is located in the rod elements of the core and that it is complexed with specific proteins. The cytoplasm-associated envelope layer is depicted as consisting of a monolayer of galactosyl diacylglycerol molecules. BChl alpha-protein complexes in a planar lattice configuration most likely make up the crystalline baseplate. The greater than 12-nm particles in the chlorosome attachment sites of the cytoplasmic membrane, finally, may correspond to complexes containing a reaction center and non-crystalline light-harvesting BChl alpha. The crystalline nature of the baseplate is consistent with the notion that it serves two functions: besides transferring excitation energy to the reaction centers it could also function as a distributor of this energy amongst the reaction centers.

Structural, biochemical and biophysical characterization of four oxygen-evolving Photosystem II preparations from spinach

Abstract Four procedures utilizing different detergent and salt conditions were used to isolate oxygen-evolving Photosystem II (PS II) preparations from spinach thylakoid membranes. These PS II preparations have been characterized by freeze-fracture electron microscopy, SDS-polyacrylamide gel electrophoresis, steady-state and pulsed oxygen evolution, 77 K fluorescence, and room-temperature electron paramagnetic resonance. All of the O 2 -evolving PS II samples were found to be highly purified grana membrane fractions composed of paired, appressed membrane fragments. The lumenal surfaces of the membranes and thus the O 2 -evolving enzyme complex, are directly exposed to the external environment. Biochemical and biophysical analyses indicated that all four preparations are enriched in the chlorophyll a b- light-harvesting complex and Photosystem II, and depleted to varying degrees in the stroma-associated components, Photosystem I and the CF 1 -ATPase. The four PS II samples also varied in their cytochrome f content. All preparations showed enhanced stability of oxygen production and oxygen-rate electrode activity compared to control thylakoids, apparently promoted by low concentrations of residual detergent in the PS II preparations. A model is presented which summarizes the effects of the salt and detergent treatments on thylakoid structure and, consequently, on the configuration and composition of the oxygen-evolving PS II samples.

A nomenclature for the genes encoding the chlorophylla/b-binding proteins of higher plants

We propose a nomenclature for the genes encoding the chlorophylla/b-binding proteins of the light-harvesting complexes of photosystem I and II. The genes encoding LHC I and LHC II polypeptides are namedLhca1 throughLhca4 andLhcb1 throughLhcb6, respectively. The proposal follows the general format recommended by the Commision on Plant Gene Nomenclature. We also present a table for the conversion of old gene names to the new nomenclature.

The Proteolytic Processing of Seed Storage Proteins in Arabidopsis Embryo Cells Starts in the Multivesicular Bodies

We have investigated the transport of storage proteins, their processing proteases, and the Vacuolar Sorting Receptor-1/Epidermal Growth Factor Receptor–Like Protein1 (VSR-1/ATELP1) receptor during the formation of protein storage vacuoles in Arabidopsis thaliana embryos by means of high-pressure freezing/freeze substitution, electron tomography, immunolabeling techniques, and subcellular fractionation. The storage proteins and their processing proteases are segregated from each other within the Golgi cisternae and packaged into separate vesicles. The storage protein–containing vesicles but not the processing enzyme–containing vesicles carry the VSR-1/ATELP1 receptor. Both types of secretory vesicles appear to fuse into a type of prevacuolar multivesicular body (MVB). We have also determined that the proteolytic processing of the 2S albumins starts in the MVBs. We hypothesize that the compartmentalized processing of storage proteins in the MVBs may allow for the sequential activation of processing proteases as the MVB lumen gradually acidifies.

Freeze-etch appearance of the tight junctions in the epithelium of small and large intestine of mice

SummaryThe ultrastructure of the central layer and the contributing plasma membranes of tight junctions has been studied in epithelia of the jejunum and colon of mice.Examination of freeze-etched plasma membranes of epithelial cells has revealed that they consist of a central layer, with fracturing characteristics similar to bimolecular lipid leaflets, which is covered on both sides with a layer of particles.The “fusion” of the outer membrane surfaces of adjacent cells in the region of the tight junction leads to the formation of a new common structure consisting of a meshwork of fibrils embedded in a matrix substance. The fibrils probably contain protein. They have a diameter of 65 ± 10 Å and are linked together so that they form around the distal end of each cell a continuous belt-like meshwork which is extended proximally at the joints where three cells meet. As the fibrillar mesh appears to be strongly attached to the central lipid layer of the two adjoining membranes, in contrast to the weakly bound surrounding matrix, it is believed that the fibrils forming the continuous meshwork could be the mechanical coupling and the sealing elements of the tight junction. Their arrangement in the form of a concertinalike mesh would make the whole structure very flexible. In the region of the junction the membranes are constricted along the lines of attachment to the fibrils and bulge outwards,i.e. towards the cytoplasm, in the areas of the matrix material. In the resulting grooves on the cytoplasmic side of the plasma membranes regularly spaced particles with a diameter of 90 ± 10 Å can be detected. Various observations suggest that these particles could be connected through the central layer of the membranes to the fibrils on the other side. This would offer a possible explanation for the known abhesion properties of tight junctions. The described structures are also evaluated in terms of current theories of cell communication.