REGULAR STRUCTURES IN MEMBRANES : I. Membranes in the Endocytic Complex of Ileal Epithelial Cells

An "apical endocytic complex" in the ileal lining cells of suckling rats is described. The complex consists of a continuous network of membrane-limited tubules which originate as invaginations of the apical plasma membrane at the base of the microvilli, some associated vesicles, and a giant vacuole. The lumenal surface of this tubular network of membranes and associated vesicles is covered with a regular repeating particulate structure. The repeating unit is an ~7.5-nm diameter particle which has a distinct subunit structure composed of possibly nine smaller particles each ~3 nm in diameter. The ~7.5-nm diameter particles are joined together with a center-to-center separation of ~15 nm to form long rows. These linear aggregates, when arranged laterally, give rise to several square and oblique two-dimensional lattice arrangements of the particles which cover the surface of the membrane. Whether a square or oblique lattice is generated depends on the center-to-center separation of the rows and on the relative displacement of the particles in adjacent rows. Four membrane faces are revealed by fracturing frozen membranes of the apical tubules and vesicles: two complementary inner membrane faces exposed by the fracturing process and the lumenal and cytoplasmic membrane surfaces revealed by etching. The outer membrane face reveals a distinct array of membrane particles. This array also sometimes can be seen on the outer (B) fracture face and is sometimes faintly visible on the inner (A) fracture face. Combined data from sectioned, negatively stained, and freeze-etched preparations indicate that this regular particulate structure is a specialization that is primarily localized in the outer half of the membrane mainly in the outer leaflet.     

New comprehension of the apicoplast of Sarcocystis by transmission electron tomography

BACKGROUND INFORMATION: Apicomplexan parasites (like Plasmodium, Toxoplasma, Eimeria and Sarcocystis) contain a distinctive organelle, the apicoplast, acquired by a secondary endosymbiotic process analogous to chloroplasts and mitochondria. The apicoplast is essential for long-term survival of the parasite. This prokaryotic origin implies that molecular and metabolic processes in the apicoplast differ from those of the eukaryotic host cells and therefore offer options for specific chemotherapeutic treatment. We studied the apicoplast in high-pressure frozen and freeze-substituted cysts of Sarcocystis sp. from roe deer (Capreolus capreolus) to get better insight in apicoplast morphology. RESULTS AND CONCLUSIONS: We observed that the apicoplast contains four continuous membranes. The two inner membranes have a circular shape with a constant distance from each other and large-sized protein complexes are located between them. The two outer membranes have irregular shapes. The periplastid membrane also contains large-sized protein complexes, while the outer membrane displays protuberances into the parasite cytoplasm. In addition, it is closely associated with the endoplasmic reticulum by 'contact sites'.     

Distribution of Intramembrane Particles and Its Changes during the Acrosome Reaction in Spermatozoa of the Japanese Abalone

The distribution of intramembrane particles in the plasma and acrosomal membranes of sperm of the Japanese abalone, Haliotis discus , and its changes during the acrosome reaction were studied by the freeze-fracture replica technique. The P face of the plasma membrane covering the acrosome has sparse membrane particles except in the apical region, which includes the trigger and 'truncated cone' regions. Large particles with an average diameter of 10 nm are located in this apical region. The E face of the plasma membrane has only a few particles. On the outer acrosomal membrane, many particles are randomly distributed throughout the P face, but only a small number of particles are found on the E face. Numerous particles on the P face of the inner acrosomal membrane show a regular arrangement as a dense lattice or with a concentric circular pattern. The initial change in the acrosome reaction is clearance of membrane particles from both the P and E faces of the plasma and outer acrosomal membranes around the apical region, where fusion of the two membranes occurs. As the acrosomal process elongates, the dense arrangement of particles on the inner acrosomal membrane changes via a loose lattice arrangement to a patchy distribution with particle-free areas. Then the arrangement is further disorganized becoming a sparse, random distribution.     

Cryofracture electron microscopy of the ookinete pellicle of Plasmodium gallinaceum reveals the existence of novel pores in the alveolar membranes

The malaria parasite invades the midgut tissue of its mosquito host as a motile form called the ookinete. We have examined the pellicle of the ookinete of Plasmodium gallinaceum by freeze-fracture and quick-freeze, deep-etch electron microscopy. The general organization is analogous to that of invasive stages of other members of Apicomplexa. The pellicle is composed of three membranes: the plasma membrane, and the two linked intermediate and inner membranes, which in the ookinete form one flattened vacuole that is located beneath the plasma membrane. The edges of this vacuole form a longitudinal suture. Beneath the vacuole is found an array of microtubules that are connected to the inner membrane by intramembranous particles. During freeze-fracture, the membranes can split along their hydrophobic planes, thus yielding six fracture faces, each of which displays a characteristic pattern of intramembranous particles. Additionally, we find that the ookinete pellicle differs from all other apicomplexan motile stages by the presence of large pores. These pores are of unknown function, but clearly might constitute a novel pathway for the transport of molecules to and from the cortex, which is independent of the well-described route through the apical micronemal/rhoptry complex. The pores may be the route by which motor proteins or other non micronemal surface proteins are trafficked, such as P25/P28 and SOAP, some of which are implicated in transmission blocking immunity.     

William Trager: An Appreciation

SYNOPSIS. Additional information on host interactions with trypanosomatid membranes was obtained from studies of a monomorphic strain of Trypanosoma brucei harvested at peak parasitemia from intact and lethally irradiated rats. Pellets of trypanosomes were fixed briefly in glutaraldehyde and processed for thin section electron microscopy or freeze-cleave replicas. Observations of sectioned material facilitated orientation and comparison of details seen in replicas. Fracture faces of cell body and flagellar membranes as well as 3-dimensional views of the nuclear membrane were studied. Cell body membranes of 80% of the organisms from intact rats contained random arrays of intramembranous particles (IMP). Aggregated clusters of particles appeared on the fracture faces of 20% of the trypanosomes. Some of these membranes had nonrandomly distributed particles aligned in distinct rows on the outer fracture face of both cell body and flagellum. Many inner face fractures of the cell body membranes had a particle arrangement similar to the longitudinal alignment of cytoskeletal microtubules. No aggregated particle distribution was seen in membranes of trypanosomes harvested from lethally irradiated rats. Replicas of trypanosome pellets also had plasmanemes as a series of attached, empty, coated membrane vesicles. These structures were found in close association with, as well as widely separated from the parasites. The shedding of these vesicles and the variation of particles in cell body membranes are discussed in light of antibody-induced architectural and antigenic changes in surface properties of trypanosomatids. The convex face of the inner membrane of the nucleus also is covered with randomly arrayed particles. More IMP were observed on the inner than on the outer nuclear membranes. Images of nuclear pores were also seen. The importance of these structures in drug and developmental studies of trypanosomes is discussed. On fracture faces of the flagellar membrane there were miniature maculae adherentes, unique to the inner fracture face and occurring only at regions of membrane apposition between cell body and flagellum. Each cluster of particles exposed by the freeze-cleave method corresponds to an electron-dense plaque seen in thin section images. However, because of a unique fracture pattern, these plaques were not revealed on the apposing body membranes, as illustrated in thin sectioned organisms.     

The light-harvesting chlorpohyll-protein complex of photosystem II. Its location in the photosynthetic membrane

We have investigated the structure of the photosynthetic membrane in a mutant of barley known to lack a chlorophyll-binding protein. This protein is thought to channel excitation energy to photosystem II, and is known as the "light-harvesting chlorophyll-protein complex." Extensive stacking of thylakoids into grana occurs in both mutant and wild-type chloroplasts. Examination of membrane internal structure by freeze-fracturing indicates that only slight differences exist between the fracture faces of mutant and wild-type membranes. These differences are slight reductions in the size of particles visible on the EFs fracture face, and in the number of particles seen on the PFs fracture face. No differences can be detected between mutant and wild-type on the etched out surface of the membrane. In contrast, tetrameric particles visible on the etched inner surface of wild-type thylakoids are extremely difficult to recognize on similar surfaces of the mutant. These particles can be recognized on inner surfaces of the mutant membranes when they are organized into regular lattices, but these lattices show a much closer particle-to-particle spacing than similar lattices in wild-type membranes. Although several interpretations of these data are possible, these observations are consistent with the proposal that the light-harvesting chlorophyll-protein complex of photosystem II is bound to the tetramer (which is visible on the EFs face as a single particle) near the inner surface of the membrane. The large tetramer, which other studies have shown to span the thylakoid membrane, may represent an assembly of protein, lipid, and pigment comprising all the elements of the photosystem II reaction. A scheme is presented which illustrates one possibility for the light reaction across the photosynthetic membrane.     

Structure of the Thylakoids and Envelope Membranes of the Cyanelles of Cyanophora paradoxa

The cyanelles of Cyanophora paradoxa Korsch. are photosynthetically active obligate endosymbionts in which phycobiliproteins serve as the major accessory pigments. Freeze-fracture electron micrographs of thylakoids in isolated cyanelles reveal long parallel rows of particles covering most of the E-face, while a more random particle arrangement is evident in some areas. The center-to-center spacing of particles within these rows is about 10 nanometers. Their mean diameter was measured at 9.4 nanometers. The particles on the P-face have a mean diameter of 7.2 nanometers. Thylakoids that retained nearly the full complement of phycobiliproteins (determined spectrophotometrically and by gel electrophoresis) were isolated from the cyanelles. In thin sections of these preparations, rows of disc-shaped phycobilisomes are evident on the surface of the thylakoids. The spacing of the rows of phycobilisomes corresponds to that of the rows of E-face particles (approximately 45 nanometers, center to center). The periodicity of the disc-shaped phycobilisomes within a row is 10 nanometers suggesting a one-to-one association between phycobilisomes and E-face particles.

In addition, visualization of the protoplasmic surface (PS) of isolated thylakoids by freeze-etch electron microscopy shows that rows of disc-shaped phycobilisomes are aligned directly above rows of particles exhibiting two subunits, presumably the P-surface projections of the 10-nanometer intramembrane particles. These observations, together with earlier studies indicating that the 10-nanometer E-face particles probably represent photosystem II (PSII) complexes, suggest that phycobilisomes are positioned on the thylakoid surface in direct contact with PSII centers within the thylakoid membrane.

The inner envelope membrane of the cyanelles, observed in freeze-fracture replicas, resembles cyanobacterial plasma membranes and is dissimilar to the chloroplast envelope membranes of red or green algae. The envelope of isolated cyanelles exhibits two additional layers: (a) a 5- to 7-nanometer-thick layer that lies adjacent to the inner membrane and which seems to correspond to the peptidoglycan layer of cyanobacteria; and (b) a layer external to the purported peptidoglycan layer that exhibits fracture faces similar to those of the lipopolysaccharide layer of gram negative bacteria. Our findings indicate that the supramolecular architecture of cyanelles differs only slightly from free-living cyanobacteria to which they are presumably related.

     

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.     

Spatial relationship of photosystem I, photosystem II, and the light- harvesting complex in chloroplast membranes

We have previously demonstrated (Armond, P. A., C. J. Arntzen, J.-M. Briantais, and C. Vernotte. 1976. Arch. Biochem. Biophys. 175:54-63; and Davis, D. J., P. A. Armond, E. L. Gross, and C. J. Arntzen. 1976. Arch. Biochem. Biophys. 175:64-70) that pea seedlings which were exposed to intermittent illumination contained incompletely developed chloroplasts. These plastids were photosynthetically competent, but did not contain grana. We now demonstrate that the incompletely developed plastids have a smaller photosynthetic unit size; this is primarily due to the absence of a major light-harvesting pigment-protein complex which is present in the mature membranes. Upon exposure of intermittent- light seedlings to continuous white light for periods up to 48 h, a ligh-harvesting chlorophyll-protein complex was inserted into the chloroplast membrane with a concomitant appearance of grana stacks and an increase in photosynthetic unit size. Plastid membranes from plants grown under intermediate light were examined by freeze-fracture electron microscopy. The membrane particles on both the outer (PF) and inner (EF) leaflets of the thylakoid membrane were found to be randomly distributed. The particle density of the PF fracture face was approx. four times that of the EF fracture face. While only small changes in particle density were observed during the greening process under continuous light, major changes in particle size were noted, particularly in the EF particles of stacked regions (EFs) of the chloroplast membrane. Both the changes in particle size and an observed aggregation of the EF particles into the newly stacked regions of the membrane were correlated with the insertion of light-harvesting pigment- protein into the membrane. Evidence is presented for identification of the EF particles as the morphological equivalent of a "complete" photosystem II complex, consisting of a phosochemically active "core" complex surrounded by discrete aggregates of the light-harvesting pigment protein. A model demonstrating the spatial relationships of photosystem I, photosystem II, and the light-harvesting complex in the chloroplast membrane is presented.     

Plasmodium berghei: Architectural analysis by freeze-fracturing of the intraoocyst sporozoite's pellicular system

The technique of freeze-fracturing has been used to study the architecture of the pellicular complex of the intraoocyst sporozoite of Plasmodium berghei. The sporozoite is surrounded by three plasma membranes and a layer of subpellicular microtubules. During freeze-fracturing, each of the three membranes can split along its hydrophobic interior to yield a total of six fracture faces. The most obvious feature of each fracture face is the presence of globular intramembranous particles on the surface. The six fracture faces differ from one another in arrangement, size, and density of these intramembranous particles. Two of the fracture faces exhibit a unique arrangement of particles in well-organized parallel rows along the long axis of the sporozoite. This arrangement has not been reported in either the erythrocytic or the exoerythrocytic forms of Plasmodium spp. Another unique feature in the sporozoite revealed through freeze-fracturing is a single suture line that traverses the long axis of the inner two membranes of the parasite.     

Fine structures of sponge cell membranes: comparative study with freeze-fracture and conventional thin section methods

Freeze-fracture replicas of sponge cell membranes revealed in general a low density of intramembranous particles, with the exceptions of the membrane (silicalemma) surrounding the siliceous spicules in Ephydatia and the membranes of spherulous cells in Chondrosia. In addition, several types of particle arrangements were observed. A classical necklace is present at the base of the choanocyte flagellum. Rosettes of particles are particularly obvious in the apical membranes of choanocytes, where they are associated with the fuzzy coat covering these cells. Parallel ridges of particles were observed along the microvilli of the choanocyte collar, at sites of insertion of connecting filaments. Rows of particles were observed in the plasma membrane of pinacocytes in Ephydatia where they are located on areas deformed by protruding fibrillar inclusions. Pinacocyte plasma membranes in this species also can contain accumulations of particles which are likely related to desmosomes. Single rows of aligned particles and double rows of staggered particles (sometimes organized in large plates) in addition to rhombic particle arrays were encountered on replicas of marine sponge cell membranes. No classical arrangements corresponding to gap junctions, tight junctions or septate desmosomes were observed. The significance of these data is analysed.     

Quantitation of particles in the freeze-fractured nuclear membrane after renal ischemia.

Changes in the number and sizes of membrane-associated particles have been quantitated in the protoplasmic (P) and exoplasmic (E) fracture faces of the outer membrane of nuclei isolated from the inner cortex following renal ischemia and reflow in the rat. No changes were observed in the inner nuclear membrane. After 20-min ischemia, the number of particles in both fracture faces decreased. With reflow, the total number of particles decreased after both 20- and 60-min ischemia. The partition coefficient (Kp = CPF/CEF) increased from 10 to 11 and 17 at 20- and 60-min ischemia then fell below control values to a Kp of 7 after 120 min. After reflow, Kp steadily decreased except after 20-min ischemia followed by 240-min reflow when Kp began to rise. The sizes of particles were predominantly 60 A in the P face of control outer membranes but became larger after ischemia. After 20- and 60-min ischemia with reflow, the size distribution became more normal. The shifts in particle numbers and sizes seem to indicate modifications within the membrane resulting from ischemia.     

Development of axonal membrane specializations defines nodes of Ranvier and precedes Schwann cell myelin elaboration

The development of the node of Ranvier has been previously described using thin-section electron microscopy. Using freeze-fracture, we have examined the development of glial and axonal membrane specializations before and during myelination. The spinal roots of the newborn rat are composed of bundles of unmyelinated and partially myelinated axons. At this early stage of development, the axons are engulfed by Schwann cells, while certain axons are segregated into a one to one relationship with myelinating cells. Patches of uniformly shaped 150- to 300-Å particles are readily distinguished against a relatively nonparticulate axonal E face. Patches of less uniform particles are found in the axonal P face, however, they are difficult to distinguish from a particulate background. Thin processes are found closely applied to the axonal membrane on the sides of a particle patch. While engulfing the axon with one or two noncompacted windings, the Schwann cell is predominantly restricted to one side of such a particle patch. As the number of windings covering the axon increases, so does the size of the particle patch, until an annulus of particles, similar to that of an adult node, is observed. The paucity of isolated particle patches in axolemma suggests that recognition and segregation of axons by Schwann cells are followed by a rapid initiation of myelination. Throughout the early periods of myelination there is evidence of endocytotic and exocytotic events at the nodal membrane associated with the appearance of 230-Å dimeric particles in the axolemma. Despite the paucity of windings and complete absence of compaction, the fracture faces of the glial and axonal membranes show linear organizations of particles. Scalloped regions in the P face of the nodal axolemma display dimeric-particle rows oriented along the scallop. These rows adopt a more circumferential orientation when the overlying glial process is wound into a paranodal location. While the spacing of dimeric-particle rows is maintained at a constant 360 Å, the number of rows per scallop necessarily decreases with compaction of the paranodal loops until a state similar to that of the adult, in which there are approximately two rows per scallop, is reached. In regions of close apposition between axon and Schwann cell, a linear arrangement of 160- and 75-Å particles in the glial fracture faces occurs prior to the appearance of tight junctions between glial loops and prior to compaction. Though the paranodes on each side of most nodes observed developed symmetrically, some asymmetric half-nodes have been observed.     

Immobilization of the type XIV myosin complex in Toxoplasma gondii

The substrate-dependent movement of apicomplexan parasites such as Toxoplasma gondii and Plasmodium sp. is driven by the interaction of a type XIV myosin with F-actin. A complex containing the myosin-A heavy chain, a myosin light chain, and the accessory protein GAP45 is attached to the membranes of the inner membrane complex (IMC) through its tight interaction with the integral membrane glycoprotein GAP50. For the interaction of this complex with F-actin to result in net parasite movement, it is necessary that the myosin be immobilized with respect to the parasite and the actin with respect to the substrate the parasite is moving on. We report here that the myosin motor complex of Toxoplasma is firmly immobilized in the plane of the IMC. This does not seem to be accomplished by direct interactions with cytoskeletal elements. Immobilization of the motor complex, however, does seem to require cholesterol. Both the motor complex and the cholesterol are found in detergent-resistant membrane domains that encompass a large fraction of the inner membrane complex surface. The observation that the myosin XIV motor complex of Toxoplasma is immobilized within this cholesterol-rich membrane likely extends to closely related pathogens such as Plasmodium and possibly to other eukaryotes.     

Freeze-Fracture Study of the Endosymbiont of Blastocrithidia culicis1

The two unit membranes which envelope the endosymbiont of the trypanosomatid protozoon, Blastocrithidia culicis, were studied using the freeze-fracture technique. The distribution of the intramembranous particles on both fracture faces of the inner and outer membrane of the endosymbiont was analyzed in the replicas. The protoplasmic face of the inner membrane (PFi) had a higher density of membrane particles than that observed on the extracellular face (EFi), a pattern typical of plasma membranes. The extracellular face of the outer membrane (EFo) presented a density of membrane particles much higher than that observed on the P face of the outer membrane (PFo) a distribution significantly different from that found in the inner membrane of the endosymbiont and in the plasma membrane of the protozoon, but similar to that observed in Gram-negative bacteria. The data obtained support the idea that the endosymbiont of trypanosomatids represents a Gram-negative bacterium-like microorganism enveloped by two unit membranes and lacking a peptidoglycan layer and which lives in direct contact with the cytoplasm of the protozoon.     

Fine structure of Blastocrithidia culicis as seen in thin sections and freeze-fracture replicas

The fine structure of epimastigotes of Blastocrithidia culicis was studied by transmission electron microscopy of thin sections and freeze-fracture replicas. This parasite presents a well developed endoplasmic reticulum and Golgi complex systems. Differences in the density and organization of the intramembranous particles were observed between the membranes which enclose the cell body and the flagellum. Ridge-like elevations, visualized in freeze-fracture replicas, were observed in sites where the mitochondrial branches touched the plasma membrane. A special array of membrane particles was observed on both faces of the flagellar and the cell body membranes at the region where the flagellum adheres to the cell body. It appeared as strands made of two rows of membrane particles. Filipin-treated cells were used for the localization of membrane sterols in freeze-fracture replicas. The number of filipin-sterol complexes varied from cell to cell. In some cells, rows of filipin-sterol complexes were seen. No complexes were observed in the region of the attachment of the flagellum to the cell body.     

Fine Structure of the Schizont and Merozoite of Isospora sp. (Sporozoa: Eimeriidae) Parasitic in Gehyra variegata (Dumeril and Bibron, 1836) (Reptilia: Gekkonidae)

SYNOPSIS. A study was made of the fine structure of some stages in the life cycle of an undesignated species of Isospora parasitic in a gecko. The merozoites which lay within a membrane-bound periparasitic vacuole in the host epithelial cell, had a striking similarity to Plasmodium, Lankesterella, Toxoplasma, Besnoitia, Sarcocystis, Eimeria and the M-organism. Each merozoite was invested with a triple-layered pellicle, the outer membrane of which was loosely applied. At the anterior end of the merozoite were conoid and apical rings; microtubules terminated in the posterior apical ring. Other organelles included nucleus, endoplasmic reticulum, mitochondria, micropyle, paired organelle, toxonemes and a variety of vacuoles. Although the sequence of development of the merozoite was not completely followed, some events in this process were recorded. The evidence suggests that anterior ends are formed early and that merozoites develop subsequently by a process of budding. The merozoite pellicle appears to be continuous with, altho structurally different from, the investing membrane of the parent cell.     

The Ultrastructure of Lankesterella hylae

SYNOPSIS. The ultrastructure of Lankesterella hylae was studied and numerous points of similarity to Plasmodium, Toxoplasma, Sarcocystis and Lankesterella garnhami were found. The protozoa were intracellular and lay within vacuoles containing vesicles, unusual membrane formations and dense granular material. The parasite was invested by a double membrane and had a micropyle, as well as membranous processes extending from the surface. At the anterior end were conoid and apical rings. The cell contained a nucleus, nucleolus, bipolar paranuclear vacuoles or bodies, a series of microtubules beneath the pellicle, endoplasmic reticulum, mitochondria, toxonemes and a variety of vacuoles. In addition, dense particles, similar to those related to the endoplasmic reticulum, were scattered throughout the cytoplasm.
The unusual membrane formations and vesicles in the periparasitic vacuoles were striking observations possibly related to the nutrition of the parasite.     

The morphology and configurational states of isolated heavy beef heart mitochondria by the freeze fracture technique

Configurational changes of glutaraldehyde fixed heavy beef heart mitochondria are confirmed using the freeze fracture technique. Large amplitude swelling occurred after unfixed mitochondria were suspended in 30% glycerol. Fine structure of the outer and inner mitochondrial membranes is described using unfixed heavy beef heart mitochondria by the freeze fracture technique. The matrix side of the inner membrane appears to be covered with 90 Å particles while the opposite side (cytochromec side) is also particulate covered by a high density of lower profile particles with a smooth underlying mosaic layer beneath. The outer surface of the outer membrane is smooth with particles embedded within the membrane. Possible structure of the membrane is discussed.