Synaptic fine structure and nuclear, cytoplasmic and extracellular networks: The stereoframework concept

Characterization of Vibrio cholerae's Extracellular Nuclease Xds

The Gram-negative bacterium Vibrio cholerae encodes two nucleases, Dns and Xds, which play a major role during the human pathogen's lifecycle. Dns and Xds control three-dimensional biofilm formation and bacterial detachment from biofilms via degradation of extracellular DNA and thus contribute to the environmental, inter-epidemic persistence of the pathogen. During intestinal colonization the enzymes help evade the innate immune response, and therefore promote survival by mediating escape from neutrophil extracellular traps. Xds has the additional function of degrading extracellular DNA down to nucleotides, which are an important nutrient source for V. cholerae. Thus, Xds is a key enzyme for survival fitness during distinct stages of the V. cholerae lifecycle and could be a potential therapeutic target. This study provides detailed information about the enzymatic properties of Xds using purified protein in combination with a real time nuclease activity assay. The data define an optimal buffer composition for Xds activity as 50 mM Tris/HCl pH 7, 100 mM NaCl, 10 mM MgCl2, and 20 mM CaCl2. Moreover, maximal activity was observed using substrate DNA with low GC content and ambient temperatures of 20-25°C. In silico analysis and homology modeling predicted an exonuclease domain in the C-terminal part of the protein. Biochemical analyses with truncated variants and point mutants of Xds confirm that the C-terminal region is sufficient for nuclease activity. We also find that residues D787 and H837 within the predicted exonuclease domain are key to formation of the catalytic center.

RIM and RIM-BP Form Presynaptic Active-Zone-like Condensates via Phase Separation

Both the timing and kinetics of neurotransmitter release depend on the positioning of clustered Ca²⁺ channels in active zones to docked synaptic vesicles on presynaptic plasma membranes. However, how active zones form is not known. Here, we show that RIM and RIM-BP, via specific multivalent bindings, form dynamic and condensed assemblies through liquid-liquid phase separation. Voltage-gated Ca²⁺ channels (VGCCs), via C-terminal-tail-mediated direct binding to both RIM and RIM-BP, can be enriched to the RIM and RIM-BP condensates. We further show that RIM and RIM-BP, together with VGCCs, form dense clusters on the supported lipid membrane bilayers via phase separation. Therefore, RIMs and RIM-BPs are plausible organizers of active zones, and the formation of RIM and RIM-BP condensates may cluster VGCCs into nano- or microdomains and position the clustered Ca²⁺ channels with Ca²⁺ sensors on docked vesicles for efficient and precise synaptic transmissions.

Transcellular Nanoalignment of Synaptic Function

At each of the brain's vast number of synapses, the presynaptic nerve terminal, synaptic cleft, and postsynaptic specialization form a transcellular unit to enable efficient transmission of information between neurons. While we know much about the molecular machinery within each compartment, we are only beginning to understand how these compartments are structurally registered and functionally integrated with one another. This review will describe the organization of each compartment and then discuss their alignment across pre- and postsynaptic cells at a nanometer scale. We propose that this architecture may allow for precise synaptic information exchange and may be modulated to contribute to the remarkable plasticity of brain function.

Transcellular Nanoalignment of Synaptic Function

At each of the brain's vast number of synapses, the presynaptic nerve terminal, synaptic cleft, and postsynaptic specialization form a transcellular unit to enable efficient transmission of information between neurons. While we know much about the molecular machinery within each compartment, we are only beginning to understand how these compartments are structurally registered and functionally integrated with one another. This review will describe the organization of each compartment and then discuss their alignment across pre- and postsynaptic cells at a nanometer scale. We propose that this architecture may allow for precise synaptic information exchange and may be modulated to contribute to the remarkable plasticity of brain function.

Identification of endophilins 1 and 3 as selective binding partners for VGLUT1 and their co-localization in neocortical glutamatergic synapses: implications for vesicular glutamate transporter trafficking and excitatory vesicle formation

1. Selective protein-protein interactions between neurotransmitter transporters and their synaptic targets play important roles in regulating chemical neurotransmission. We screened a yeast two-hybrid library with bait containing the C-terminal amino acids of VGLUT1 and obtained clones that encode endophilin 1 and endophilin 3, proteins considered to play an integral role in glutamatergic vesicle formation. 2. Using a modified yeast plasmid vector to enable more cost-effective screens, we analyzed the selectivity and specificity of this interaction. Endophilins 1 and 3 selectively recognize only VGLUT1 as the C-terminus of VGLUT2 and VGLUT3 do not interact with either endophilin isoform. We mutagenized four conserved stretches of primary sequence in VGLUT1 that includes two polyproline motifs (Pro1, PPAPPP, and Pro2, PPRPPPP), found only in VGLUT1, and two conserved stretches (SEEK, SYGAT), found also in VGLUT2 and VGLUT3. The absence of the VGLUT conserved regions does not affect VGLUT1-endophilin association. Of the two polyproline stretches, only one (Pro2) is required for binding specificity to both endophilin 1 and endophilin 3. 3. We also show that endophilin 1 and endophilin 3 co-localize with VGLUT1 in synaptic terminals of differentiated rat neocortical neurons in primary culture. These results indicate that VGLUT1 and both endophilins are enriched in a class of excitatory synaptic terminals in cortical neurons and there, may interact to play an important role affecting the vesicular sequestration and synaptic release of glutamate.

Morphological characterization of molecular complexes present in the synaptic cleft

We obtained tomograms of isolated mammalian excitatory synapses by cryo-electron tomography. This method allows the investigation of biological material in the frozen-hydrated state, without staining, and can therefore provide reliable structural information at the molecular level. We developed an automated procedure for the segmentation of molecular complexes present in the synaptic cleft based on thresholding and connectivity, and calculated several morphological characteristics of these complexes. Extensive lateral connections along the synaptic cleft are shown to form a highly connected structure with a complex topology. Our results are essentially parameter-free, i.e., they do not depend on the choice of certain parameter values (such as threshold). In addition, the results are not sensitive to noise; the same conclusions can be drawn from the analysis of both nondenoised and denoised tomograms.

The cytoskeleton and neurotransmitter receptors

The neuronal cytoskeleton consists of microtubules and microfilaments that can interact with membrane proteins including neurotransmitter receptors and ion channels. Ligand-gated ion channels, such as nicotinic acetylcholine receptors, glycine receptors, glutamate receptors and gamma-aminobutryic acidA (GABAA) receptors, are known to cluster in plasma membranes. Studies suggest that postsynaptic ligand-gated channels form clusters that are anchored in the plasma membrane by interacting with cytoskeletal components and these clusters may serve to optimize delivery of neurotransmitters to the channels. Other findings indicate that the interaction of clustered ligand-gated ion channels with cytoskeletal components may also play a role in channel function. For example, studies suggest that the interaction of microtubules with GABAA receptors regualtes GABA binding affinity. Regulation of neurotransmitter function may be significant in the study of neuropathological processes, such as Alzheimer's disease, neurotrauma, and experimental epilepsy, in which the cytoskeleton is vulnerable to disruption.

Structural components in the synaptic cleft captured by freeze-substitution and deep etching of directly frozen cerebellar cortex

Structural components in the synaptic cleft were examined in cerebellar excitatory synapses by conventional electron microscopy and by rapid freezing followed by freeze-substitution or deep etching. Two transverse components and one parallel element were identified in the clefts of rapidly frozen and freeze-substituted synapses: (i) bridging fibrils, 4-6 nm in diameter, that span the cleft; (ii) columnar pegs, 4-6 nm wide and 8-15 nm high, projecting from the postsynaptic surface; and (iii) intervening fine fibrils running parallel to the apposed synaptic membranes. These were more clearly visible in deep-etched synapses, although the postsynaptic pegs were difficult to distinguish from intramembrane particles in the cross-fractured postsynaptic membranes. Deep etching also revealed other fibrils on the cytoplasmic surface of the postsynaptic membrane. These appear to contact the membrane surface or the intramembrane particles. Freeze-substituted materials also displayed the fibrillar components in the postsynaptic dense fuzz, but failed to display the presynaptic dense projections typically observed in thin sections or deep-etched replicas of the conventionally fixed materials. The bridging fibrils are likely to play a mechanical role in holding the synapse together, while the short pegs may be integral parts of the receptor molecules.

The cytoskeleton of cryofixed Purkinje cells of the chicken cerebellum

Cerebella of 3- to 6-week-old chickens were cryofixed in a nitrogen-cooled propane jet, deep-etched and rotary-shadowed. The use of a brief perfusion of 0.32 M sucrose improved the quality of the cryofixation and allowed the study of the deeper layers of the cerebellar cortex. It is reported that the cytoskeleton of the Purkinje cells (PC) shows distinct domains and composition of filamentous structures in the different regions of the cell cytoplasm, such as the perikaryon, the cytoplasm of dendrites and the axoplasm. The perikaryon is occupied by a meshwork of fine filaments, 4-7 nm in diameter, that extends from the nuclear outer membrane to the cell membrane. In this zone the cell organelles (e.g., endoplasmic reticulum, mitochondria) adopt a circular arrangement around the nucleus. All structures are anchored by microfilaments to the cytoplasmic network. The dendrites show a dense cytoplasmic network including bundles of microtubules, neurofilaments and microfilaments. Numerous aggregated globular components are attached to this cytoskeleton. The cytoskeleton of the dendritic spines shows axially oriented 10-nm bundles of filaments, which are interconnected and anchored also to the cell membrane and the components of the agranular endoplasmic reticulum by cross-linkers. As described in peripheral nerves, the axoplasm of axons in the central nervous system exhibits predominantly neurofilaments and microtubules aligned along the axis of the neurites in a three-dimensional arrangement and interconnected by cross-linker filaments and filamentous structures.

Detection and characterization of some new basic proteins in chicken postsynaptic densities

Chicken brain postsynaptic density (PSD) polypeptides, obtained by treating synaptosomes with 0.5% Triton X-100 and then further purified on a sucrose gradient, are demonstrated to contain four basic proteins of 76K (pI greater than 9.2), 58K (pI 8.1-8.8, heterogeneous), 40K (pI 9.0), and 24K (pI 8.9). Nonequilibrium pH gradient-sodium dodecyl sulfate two-dimensional gels further reveal six more basic proteins with pI values higher than 9.2: 76K, 52K, 47K, 45K, 36K, and 34K. These basic proteins are a major part of the total chicken PSD polypeptides appearing on the gels. Some of these basic proteins (58K, 52K, 47K, 36K, 24K, and two at 76K) are distinguishable from those of brain mitochondria, the major contaminant. The 40K and 34K proteins may be common mitochondrial polypeptides. The 45K protein is probably a mitochondrial contaminant. A number of proteins including 76K (synapsin I-like protein) and 58K, along with some other minor ones, can be phosphorylated by endogenous protein kinase(s) in the presence of Ca2+, Mg2+, and [gamma-32P]ATP. No PSD basic proteins bind Ca2+.

Effect of conditioning lesion on axonal sprout formation at nodes of Ranvier

The effect of a conditioning lesion on the time-course of axonal sprout formation after a subsequent testing lesion was evaluated in myelinated axons of the rat sciatic nerve. Transmission electron microscopy of longitudinal nerve sections was used to examine nodes of Ranvier located 200-500 micron proximal to the testing lesion. The conditioning lesion was a cut of the tibial nerve at the ankle; the testing lesion, made 2 weeks later, was a crush of the sciatic nerve at the hip. Sprouts were defined as unmyelinated evaginations of the nodal axolemma that (1) had reached the basement membrane of the Schwann cell, and (2) were located between the myelin sheath of the distal paranode and the basement membrane. Photomicrographs of the nodes at 9, 18, and 27 hours after the testing lesion were assigned to one of seven categories: normal, retracted, myelin degeneration, axonal degeneration, type A sprout formation (cytoskeleton absent), type B sprout formation (cytoskeleton present), and type B sprout degeneration. By 9 hours after the testing lesion, type B sprout formation was found in 9% of the nodes in control nerves (testing lesion alone) and 33% of those in conditioned nerves (P less than .01). A 33% incidence of type B sprout formation was not reached in control nerves until 27 hours after the testing lesion. Since the conditioning lesion was located 50 mm distal to the testing lesion and did not induce neuronal death, earlier sprout formation can be attributed to a neuronal response to the conditioning lesion rather than to a putative factor that arises from pre-degenerated fibers and acts on newly formed sprouts.

Presynaptic inclusions in mossy fibre terminals of the cerebellar cortex following long-term undernutrition in adult rats

Past work on the C.N.S. of nutritionally deprived immature rats shows widespread structural and functional alterations that were not found in nutritionally deprived adults. In the present work we studied cerebellar mossy fibre terminals of adult rats, given a 8% casein diet for periods of 6, 12 and 18 months. After 12 months of the diet, mossy fibre terminals presented a large number of spherical or disc-shaped membrane-free inclusions herein referred to as presynaptic inclusions, with diameters up to 1.3 micron and formed by fine-textured subunits, compacted into 3 nm strands. This material is an extension of the cytoplasmic network of the terminal. No special relationship was observed with the active zones; synaptic vesicles found in the proximity or embedded in these inclusions were often of the flat type, whereas those close to the active zones always appeared spherical. These results show that even in adult rats synaptic terminals are areas sensitive to protein deprivation.

Reexamination of the reality or artifacts of the microtrabeculae

The polyethylene glycol (PEG) method revealed that model systems such as erythrocytes and protein solutions, which are supposed to lack structured components, exhibit lattice structures not unlike the microtrabeculae. The compactness of the lattice was dependent on the concentration of proteins. The gelated state of gelatin exhibited lattices more compact than those of the solated state at any given concentration. Comparison of images by PEG and rapid-freezing, deep-etching replica methods showed no basic differences in the ultrastructure of the intestinal epithelial cell. This indicates that the PEG method, including chemical fixation, produces little, if any, disorganization of the cytoskeleton. All of the present findings suggest that cytoplasmic protein, nonstructure-bound or structure-forming, might be present in intact cells which could form microtrabecular structures when specimens are fixed by chemical fixatives without any extractions. Therefore, the microtrabeculae should generally be regarded as a simple marker for the presence of proteinaceous macromolecules. It is also suggested that the microtrabecular lattice, as a whole, might represent a gelated state in a given compartment when another, looser lattice is simultaneously present in the same compartment, i.e., within a single cell.

Asymmetric and symmetric synaptic junctions in the dorsal lateral geniculate nucleus of cat and monkey

We have investigated the applicability of traditional classifications of synaptic junctions in the dorsal lateral geniculate nucleus (DLGN) of the cat and monkey. Our principal sample is restricted to synapses made by the retinal terminal (round vesicles) in DLGN and to synapses made by flattened vesicle processes that were postsynaptic to the retinal terminal. We inspected consecutive thin sections through 250 synaptic junctions that showed clear synaptic clefts in every section. The thickness of the membrane and postsynaptic density (PSD) was measured on each section and an average thickness was computed for each synaptic junction. In both species the frequency distribution for these measurements forms an uninterrupted progression from the absence of a continuous PSD through the presence of a heavy density with most synaptic contacts falling in the midrange. Twenty-two of the round vesicle profiles and 40 of the flat vesicle profiles we studied had very modest densities (13-16 nm) and exhibited a continuous PSD on some sections, but only small puffs or a complete lack of density on others. We concluded that this group which constituted 25% of the synaptic contacts we studied could not be classified as asymmetric or symmetric. As a group the round vesicle synaptic junctions exhibited a heavier PSD than the flat vesicle contacts. The difference between the mean thickness in both species was statistically significant. However, we hesitate to describe the round vesicle synapses as asymmetric and the flat vesicle contacts as symmetric because such a large proportion of the former made synaptic contacts with a PSD thickness within the range of the latter.

Synaptic vesicles and the nerve-muscle preparation in resinless sections

Resinless sections have been used to study the fine structural organization of cellular organelles and fibrous components at synapses. Presynaptic elements of the neuromuscular junction, representing the P.N.S., and of cerebral cortical synapses, representing the C.N.S., are examined and compared. Typical ultrastructural features are apparent in presynaptic and postsynaptic components and in the surrounding muscle and neuronal tissue demonstrating the reliability and usefulness of the technique.

Structural organization of filamentous proteins in postsynaptic density

Actin is one of the major protein constituents of the postsynaptic density (PSD), a characteristic structural entity subjacent to the postsynaptic membrane in excitatory synapses of the vertebrate central nervous system. In isolated purified PSD preparations, it is present to the extent of 29 +/- 2 micrograms/mg of total protein, 90% of which is in the filamentous (F-actin) form. Iodination by a discriminatory labeling technique demonstrates that actin is located on the surface of the PSD from which it can be stripped by treatment with a mixture of strong anionic detergents, leaving behind an insoluble core held together by disulfide bridges, consisting in part of tubulin and "PSD protein".

Sonication-enhanced histochemistry of wheat germ agglutinin binding to intracellular sites of rat layer V cortical neurons and spinal motoneurons

Cellular surface carbohydrates have been studied extensively in relation to cell interactions. However, the presence of intracellular carbohydrates not associated with cell surface membranes has not been well-defined histochemically. We describe a technique for the ultrastructural localization of intracytoplasmic carbohydrates using a wheat germ agglutinin peroxidase conjugate. The ultrastructural aspects of wheat germ agglutinin (WGA) binding to intracellular structures of rat somatomotor cortex layer V neurons and spinal cord motoneurons were examined using sonication to enhance penetration of the lectin-peroxidase conjugate. In addition to the membrane-associated structures previously described by others, WGA binding was observed on neuronal nuclear chromatin, nuclear pores, ribosomes, microtubules, vesicular organelles, and to synaptic complexes, primarily in the presynaptic bouton. The results support data indicating that complex carbohydrates may be important in neuronal molecular processing.

Structural destabilization of synaptosomal particles by lysis and sequential chemical treatments

Synaptosomes from rat brains were subjected to a sequence of treatments: osmotic lysis, buffered saline wash, nonionic detergent, EGTA and EDTA. After each treatment, particulate samples were fixed in 2% glutaraldehyde-1% formaldehyde and centrifuged to form pellets which were then processed for and examined by electron microscopy. Five morphological classes of synaptic particle were defined in terms of character and presence of synaptic vesicles, flocculent and stranded material, designated as intervesicular scaffolding (IVS), and presynaptic membrane. During osmotic lysis, the presynaptic compartment was altered by loss of most, but not all, small synaptic vesicles, by increase in proportion of large vesicles, and by disappearance of the presynaptic densities. The retention of vesicles was interpreted in terms of IVS struts interconnecting anchorage sites on synaptic vesicles and the presynaptic junctional membrane. Treatment of lysed synaptosomes with nonionic detergent or EGTA resulted in loss of vesicles and IVS from the junctional region in most particles. The apposition of pre-and postsynaptic junctional membranes along the synaptic cleft was disrupted more by EGTA than by detergent. The final result of the sequential treatments was a sediment containing a high proportion of synaptic particles, about half of which had lost their presynaptic junctional membranes.

Changes in the number, size, and shape of synaptic vesicles in an experimental, projected cortical epileptic focus in the rat

A projected epileptic focus was induced in the brains of experimental rats by applying penicillin G sodium to the contralateral hemisphere. Synapses of type I (after Gray) in the second cortical layer of the mirror area were analyzed morphometrically in the electron microscope 30 min after application of the epileptogenic drug. The number of agranular synaptic vesicles was counted per 0.01 micron2 over the active zone of the presynaptic membrane in an area 0.1 micron wide adjacent to the active zone and in an area of the same width 0.1 micron distant from the active zone. A statistically significant increase in the number of synaptic vesicles was found in the experimental animals as compared with the controls. The number of synaptic vesicles per 0.01 micron2 area was evaluated along the inactive presynaptic membrane, both in the area adjacent to the active zone of the presynaptic membrane and in other areas at successively greater distances from the active zone. The counts in some of these latter areas were statistically significantly higher in the experimental animals. The size and shape of synaptic vesicles were evaluated in three zones, each 0.1 micron wide, parallel to the membrane of the synaptic cleft. Zone I was directly adjacent to the membrane of the synaptic cleft; zone II was 0.1 micron distant; and zone III 0.1 micron distant from the membrane. The results show that the synaptic vesicles of both the experimental and control animals are significantly smaller in zone I than in the more distant zones. This trend is more marked in the controls than in the experimental animals. Histograms of vesical areas of zones II and III in the controls point to two populations of vesicles. The volumes of vesicles are approximately 10% greater in zone I of experimental animals than in the controls. The elongation of the vesicles in the three zones does not differ statistically either in controls or in experimental animals. Experimental animals, however, have statistically more rounded vesicles than the controls. Assuming that the synpatic vesicles contain the transmitters, our results might contribute to a better understanding of the increased excitability of the epileptic focus area.

The fine structure of the CNS in multiple sclerosis. I. Interpretation of cytoplasmic papovavirus-like and paramyxovirus-like inclusions

During an electron microscopic study of the white matter in multiple sclerosis (MS), spheroidal reticular particles were found both in MS and in control brains. These particles have previously been described in the brain in MS and in brain-derived cell cultures in subacute sclerosing panencephalitis. In both cases they were interpreted as papovaviruses, but in size, morphology and distribution they are identical to the reticulosomes and related particles which occur as proteinaceous artefacts in a variety of tissues and in subcellular fractions. Inclusions in endothelial cell cytoplasm, previously reported from the CNS in MS as paramyxovirus similar to measles, have also been found in the present study. The were present both in MS and in control brains and are identified as "rod-shaped tubular bodies", normally occurring organelles of endothelial cells. The necessity for a cautious interpretation of virus like inclusions in emphasized.

Form of the postsynaptic density. A serial section study

Through the use of serial sectioning of dog cerebral cortex tissue, holes or perforations could be revealed in the larger postsynaptic densities (PSDs), in confirmation of the earlier work of Peters and Kaisermann-Abramof (1969. Z. Zellforsch. Mikrosk. Anat. 100:487-506). These holes appeared in serial sections which happened to be cut both parallel and normal to the plane of the synaptic junction. Cleft material was absent in that part of the synaptic cleft opposite this hole. Somestimes the presynaptic membrane opposite the hole was indented into the presynaptic cell. In addition, most of the synaptic vesicles in the presynaptic cell close to the membrane were clustered at that part of the membrane opposite the edge of the density disk. The meaning of the hole and of the other features mentioned above for the function of the density is not known at present.

Microtubules associated with postsynaptic 'thickenings'

Using a new albumin technique, microtubules can be seen closely related to or associated with the postsynaptic 'thickening' of mature and immature central nervous synapses. Thus in conventionally fixed synapses (without albumin pretreatment) where microtubules cannot usually be observed running into the postsynaptic dense material, this material could perhaps, in part, consist of the debris of in vivo microtubules. Smooth endoplasmic reticulum (ER) is often seen associated with the microtubules near the postsynaptic 'thickening'. Microtubules, and possibly smooth ER, may have an important role in the initiation of synapse formation and in the maintenance of mature synapses.

A quantitative electron microscopic study of the ageing human cerebral cortex

A recent quantitative electron microscopic study of biopsy samples of the cerebral cortex of neurologically normal individuals, aged between 15 and 54 years, has shown that atypical inclusions are present in neuronal and glial processes in small but appreciable numbers (Rees). It would be of interest to know whether these inclusions accumulate with age. This study therefore applied the same quantitative methods used in the previous study, to autopsy samples of frontal and temporal cortex from 3 non-demented ageing human brains (70-76 years). The results showed that in the areas of cortex examined, the number of inclusions in neuronal processes did not increase with age. However, the number of dense deposits in the cell bodies and processes of oligodendrocytes did increase significantly with age. In agreement with previous studies corpora amylacea were found in astrocytic processes. Senile plaques were not observed.

Stereo high-voltage electron microscopy of whole cells of the human diploid line, WI-38

The human diploid cell line, WI-38, has proven to be an especially good object for high-voltage electron microscopy using whole cells. Cells of intermediate passages were grown on plastic-coated, carbon-shadowed gold grids, fixed with glutaraldehyde, post-fixed with osmium tetroxide, stained with uranyl salts and critical-point dried. The absence of an embedding matrix produces images of increased contrast and resolution. The approach combined with stereo-microscopy has extended our knowledge of cellular ultrastructure. Stereo-images of whole cells reveal nuclei, mitochondria, microtubules, microfilaments, the endoplasmic reticulum and ribosomes in their expected forms. At high magnifications a continuity of microtubules, microfilaments and membranous elements with thin (3-6 nm) strands of the ground substance has been observed. These strands form a three-dimensional lattice or mesh that pervades all parts of the cytoplasm. The entire structure is referred to as a microtrabecular lattice or mesh, the strands being the trabeculae. The inclusion of microtubules, microfilaments, ribosomes and vesicles of the endoplasmic reticulum within the material of the lattice makes them all part of a totally organized cytoplast.

Form and distribution of actin and myosin in non-muscle cells: a study using cultured chick embryo fibroblasts

Attempting to throw light on the mechanical basis of movement of non-muscle (cf. muscle) cells, the present work aims to determine the form and distribution of actin and myosin in chick embryo fibroblasts. These cells were cultured on formvar, fixed in glutaraldehyde then osmium tetroxide vapours, dehydrated, critical-point dried and examined, in toto, in the electron microscope (EM). Stereoscopic pairs of micrographs were studied to define more exactly the form and distribution of cytoplasmic filaments topographically associated with deformations of the cell surface and with organelle movements through the cytoplasm. Permeating the cytoplasm, interconnecting long and short filaments closely surrounded all organelles, linked with microtubules and polyribosomes and joined to the plasma membrane. These filaments, which varied greatly in width (2-13 nm) were closely associated with large numbers of 'comma-shaped' globoid bodies of approximately 15 nm diameter. Attempting to establish the identity, form and distribution of cytoplasmic myosin, cultured cells were extracted with a cold (4 degrees C) glycerol/pyrophosphate solution for 24 h before being fixed and critical-point dried. EM examination of these cells revealed a residual three-dimensional network of branching and anastomosing 4-13 nm diameter smooth filaments, devoid of fine (2 nm) filaments and globoid bodies. Examination of fixed, critical-point dried, skeletal muscle heavy meromyosin showed globoid structures similar in form and size to the globoid bodies found in cultures fibroblasts. Similarly fixed and critical-point dried paracrystals of actin, polymerized in the presence of Mg2+, appeared as branching interconnecting filaments which, in form and dimensions, resembled the network filaments observed in pyrophosphate-extracted cells. It is concluded that the pyrophosphate-extractable globoid bodies found in cultured fibroblasts represent monomers of myosin, that the broader filaments to which these attach represent actin in Mg2+ paracrystalline form and that the various subcellular movements are brought about by interactions between the two, analogous to those occurring in muscle cells.

Microtubules in synapses of the retina

Using a new method, microtubules can be seen running up to, and lying in close relationship with, the synaptic ribbons in the outer and inner plexiform layers of the frog retina. In the inner plexiform layer microtubules can be seen running up to the terminal membrane in the non-ribbon synapses. Unlike non-ribbon C.N.S. synapses (frog and rat) processed by the same method. There is no clear association between synaptic vesicles and microtubules in the approach regions.

Microtubules associated with nuclear pore complexes and coated pits in the CNS

Using a new albumin prefixation technique, microtubules have been observed in close association with the nuclear pores of neurons and glia. Thus, microtubules may be involved in such phenomena as anchoring, migration or rotation of the nucleus or in chemical messenger transport between nucleus and cytoplasm. Microtubules are also seen running close to the coated pits of dendrites. The implications are discussed.

Involvement of vesicle coat material in casein secretion and surface regeneration

The ultrastructure of the apical zone of lactating rat mammary epithelial cells was studied with emphasis on vesicle coat structures. Typical 40-60 nm ID "coated vesicles" were abundant, frequently associated with the internal filamentous plasma membrane coat or in direct continuity with secretory vesicles (SV) or plasma membrane proper. Bristle coats partially or totally covered membranes of secretory vesicles identified by their casein micelle content. This coat survived SV isolation. Exocytotic fusion of SV membranes and release of the casein micelles was observed. Frequently, regularly arranged bristle coat structures were identified in those regions of the plasma membrane that were involved in exocytotic processes. Both coated and uncoated surfaces of the casein-containing vesicles, as well as typical "coated vesicles", were frequently associated with microtubules and/or microfilaments. We suggest that coat materials of vesicles are related or identical to components of the internal coat of the surface membrane and that new plasma membrane and associated internal coat is produced concomitantly by fusion and integration of bristle coat moieties. Postexocytotic association of secreted casein micelles with the cell surface, mediated by finely filamentous extensions, provided a marker for the integrated vesicle membrane. An arrangement of SV with the inner surface of the plasma membrane is described which is characterized by regularly spaced, heabily stained membrane to membrane cross-bridges (pre-exocytotic attachment plaques). Such membrane-interconnecting elements may represent a form of coat structure important to recognition and interaction of membrane surfaces.

Junctional subsurface organs in frog sympathetic ganglion cells

Subsurface cisternae in frog sympathetic ganglion cells were studied and shown to have similar features to those of the C.N.S. A number of special features were, however, revealed by high resolution microscopy. Highly flattened subsurface cisternae occurred in close proximity to the ganglion cell membrane and formed structures comparable to gap junctions. These subsurface cisternae appeared to be elongated plates (about 0.3 X 2.5 mum) specifically restricted to the area of the ganglion cell membrane adjacent to nerve endings, although often with the intervention of a thin satellite sheath. Thus they have been termed here 'junctional subsurface organs', although the nerve terminals opposing them did not show any synaptic specialization. The junctional subsurface organ was often accompanied by closely arrayed endoplasmic reticulum and/or mitochondria. Where the junctional subsurface organ intervened between plasma membrane and endoplasmic reticulum or mitochondria, faint particles appeared to traverse both sides and bridge the narrow spaces to the opposing plasma membrane and endoplasmic reticulum or mitochondria. The possible functional significance of the junctional subsurface organs is discussed.

Electron microscopy of synaptic structures in olfactory cortex of early postnatal rats

Layer 1 of the rat olfactory cortex has been studied with the electron microscope at birth and at several consecutive postnatal days up to 14 days of age. Special attention was directed towards synaptic structures and axons of the lateral olfactory tract (LOT). Numerous mature synapses are seen at birth and estimates were made of their subsequent increase in number. In addition, immature synapses are seen and mature postsynaptic sites occur with atypical, partial, multiple or no contact. The findings suggest: (1) considerable prenatal synaptogenesis in contrast to other cortical systems; (2) the maturation of the postsynaptic site may precede that of the presynaptic contact and vesicle accumulation; (3) there may be competition by more than one process for one postsynaptic specialization; (4) the non-innervated sites may result from deafferentation caused by prenatal cell death, although no degeneration was seen, and the atypical contacts may be a stage in the reinnervation of these sites; (5) the LOT develops in parallel with the synaptic neuropil and (6) by 14 days of age the area closely resembles adult tissue.