Synapsoarchitectonics of the septum of the cat brain

In the medial and lateral septal nuclei, 4 types of axonal terminals are distinguished. Type I contains spherical vesicles and forms asymmetric synapses on small and middle stems and spines of the dendrites; type I terminals comprise 63% in the medial nucleus of the total number of axons, and in the lateral one--52%. Type II contains polymorphic vesicles and forms symmetrical synapses on the soma and large dendrites. In the medial nucleus they comprise 6%, and in the lateral one--3%. Type III contains either clear spherical (IIIa), or polymorphic (IIIb) vesicles, as well as 1-2 vesicles with a dense core. They form axodendritic, axospine and axosomatic synapses. In the medial nucleus they comprise 25% and 3%, respectively, in the lateral one--40% and 2%. Type IV contains a great number of vesicles with a dense core. These terminals in both septal nuclei comprise 3% and do not participate in formation of active contacts.     

Observations on the ultrastructure of nerve cells in the brain of the planarian,Dugesia gonocephala

Summary The submicroscopic structure of the nerve cells in the planarian brain was studied. Close similarities with neurons of other invertebrates were noted. In the cytoplasm of the planarian nerve cells there are at least three types of vesicular inclusions: 1) Clear vesicles (200–800 Å in epon embedded tissue) similar in morphological appearance to classical synaptic vesicles. These have generally some content of extremely low density but occasionally a dense core. 2) Dense vesicles (400–1,200 Å in epon embedded tissue) containing highly osmiophilic granules. Between the limiting membrane of the vesicle and the granule there is always a clear rim of variable width. These vesicles closely resemble synaptic vesicles described in vertebrate adrenergic endings. 3) Neurosecretory vesicles (600–1,300 Å in Vestopal embedded tissue) similar to elementary granules observed in neurosecretory systems in vertebrates and invertebrates. All three vesicle types have the same mode of origin from the Golgi membranes. All are present in the nerve cell processes of the neuropil as well as in the perikarya. Any given perikaryon or axon contains only one of the three vesicle types. All of these vesicles are considered to be discharged into the axons from their site of origin within the perikaryon.     

Catecholamine-rich cells and varicosities in bovine splenic nerve, vesicle contents and evidence for exocytosis.

The bovine splenic nerve trunk contains mast cells, ganglion cells, small intensely fluorescent (SIF) cells, and varicosities which exhibit a brilliant fluorescence characteristic for noradrenaline (NA) and dopamine (DA) after formaldehyde exposure. All these catecholamine-rich structures could contribute particles to isolated nerve vesicle fractions. Mast cells are recognized ultrastructurally by their large (300-800 nm) dense granules. SIF cells may be represented by cells and processes containing dense cored vesicles (120-140 nm) which are larger than the typical vesicles in axons and terminals. Terminal-like areas with typical large dense cored vesicles (LDV, 75 nm) and small dense cored vesicles (SDV, 45-55 nm) probably correspond to the fluorescent varicosities. The LDV constitute about 40% of all vesicles in terminal-like areas and terminals. Their staining properties indicate the presence of protein, phospholipids, and ATP. Tyramine depletes NA without loss of matrix density. The LDV can fuse with the terminal membrane, and released material outside omega profiles is interpreted to depict exocytosis. Large and small vesicles are easily distinguished from the very large mast cell granules and the moderately dense Schwann cell vesicles. Neither appear to contaminate the LDV fractions but the latter may contain a small population of SIF cell vesicles. Golgi vesicles from the Schwann cells mainly occur in the lighter zones of the gradient.     

The brain of the horseshoe crab (Limulus polyphemus). III. Cellular and synaptic organization of the corpora pedunculata.

The large, hemispherical mass of the Limulus corpora pedunculata consists of two highly branched lobes, each connected to the protocerebrum by a narrow stalk. About 10(4) afferent fibers enter through the stalks and make diverse, profuse, and often reciprocal contacts with several million Kenyon (intrinsic) cells and one another. The Kenyon cell axonal arborizations converge on a few hundred efferent dendrites. The afferent fiber types can be classified into five types. Type A forms the club-shaped core of glomeruli and circumglomerular annuli, and contains small flat vesicles, suggesting an inhibitory function. Type B terminates with bushy endings in glomeruli and is presynaptic to both Kenyon cells and to Type A terminals. It has clear round vesicles and is the presumptive excitatory input. Type C terminates on other afferents, in glomeruli, and rarely on Kenyon cell bodies, contains angular (neurosecretory) granules and is postulated to impart circadian rhythm. Type D terminates on Kenyon cell somata and the initial neurite segment (but not in glomeruli), and contains dense-cored vesicles. Type E terminates in peduncles on other afferents and Kenyon cell telodendria. It contains dense vesicles. The C, D, and E afferents have reciprocal synaptic connections with Kenyon cell axon terminals. Glomeruli thus receive three different inputs of presumptive inhibitory (A), excitatory (B), and neuromodulatory nature (C). Kenyon cells, increasing in number up to about 1 x 10(8) in the adult, show minor variations in their dendritic pattern and have only one rare variant cell type. Interactions between them occur primarily at their axonal boutons as they crowd around efferent fibers. The latter have large receptive fields, some of their large somata are located within the confines of the corpora pedunculata, and they receive input almost only from Kenyon cells. Numerical and directional details of the circuitry in the corpora pedunculata have been extracted by a combination of light and electron microscopy, serial sectioning, silver staining, and stereology. The corpora pedunculata appear to process primarily the voluminous chemosensory input from the appendages, an assumption that is supported by the major connections of the organ.     

Cotton embryogenesis: The pollen cytoplasm

Summary The ultrastructure and composition of cotton (Gossypium hirsutum) pollen, exclusive of the wall, was examined immediately before and after germination. The pollen grain before germination consists of two parts: the outer layer and a central core. The outer layer contains large numbers of mitochondria and dictyosomes as well as endoplasmic reticulum (ER). The core contains units made of spherical pockets of ER which are lined with lipid droplets and filled with small vesicles; the ER is rich in protein and may contain carbohydrate while the vesicles are filled with carbohydrate. Starch-containing plastids are also present in the core as are small vacuoles. The cytoplasm of the pore regions contains many 0.5 spherical bodies containing carbohydrate. After germination the ER pockets open and the lipid droplets and small vesicles mix with the other portions of the cytoplasm. With germination the pore region becomes filled with mitochondria and small vesicles. The vegetative nucleus is large, extremely dense and contains invaginations filled with coils of ER. A greatly reduced nucleolus is present in the generative cell which is surrounded by a carbohydrate wall. The cytoplasm of the generative cell is dense and contains many ribosomes, a few dictyosomes and mitochondria, many vesicles of several sizes, and some ER. No plastids were identified. The generative nucleus is also dense with masses of DNA clumped near the nuclear membrane. An unusual tubular structure of unknown origin or function was observed in the generative cell.     

The cerebral ganglia of Milnesium tardigradum Doyère (Apochela, Tardigrada): Three dimensional reconstruction and notes on their ultrastructure

Differential interference contrast micrographs from stretched animals, serially sectioned semi-thin and ultrathin sections revealed that the cerebral ganglia (supraoesophageal mass) of the eulardigrade Milnesium tardigradum lie above the buccal tube and adjacent tissue like a saddle. It has an anterior indentation which is penetrated by two muscles that arise from the cuticle of the forehead. The cerebral ganglia consist of lateral outer lobes bearing an eye on each side, and two inner lobes which extend caudally. Between the inner lobes a cone-like projection tapers into a nerve bundle. Each outer lobe is joined with the first ventral ganglion. From the outer lobe near the eye the ganglion for a posterolateral sensory field extends to the epidermis. Anterior to the supraoesophageal mass are three dorsal ganglia for the upper three peribuccal papillae. Two additional ganglia attached to the cerebral mass supply the lateral cephalic papillae. The cerebral ganglia are covered by a thin neural lamella. The pericarya which surround the neuropil have large nuclei. Near the axons in the centre of the supraoesophageal mass the cytoplasm is crowded with vesicles of different size and appearance. Some of them resemble synaptic vesicles while others resemble dense core bodies. Structurally different types of synapses and axons can be distinguished within the neuropil.     

Dense cored vesicles in presynaptic profiles of the rabbit dorsal lateral geniculate nucleus

We are carrying out a study about the synaptic relations between identified synaptic profiles in the dorsal lateral geniculate nucleus (dLGN) of the rabbit. Here, the types of synaptic vesicle containing profiles of the dLGN are described. There are presynaptic large profiles containing round vesicles and pale mitochondria (RLP terminals) and small profiles that contain round vesicles and dark mitochondria (RSD terminals) which respectively arise from the retina and the visual cortex. Another type of presynaptic profile contains elliptical vesicles (F-boutons) which can be subdivided according to their cytoplasmic content. These F-boutons arise from dLGN interneurons. We have found different sized vesicles that have a dense core within RLP, and F terminals and a possible RSD terminal. The significance of the coexistance of pale and dense cored vesicles in the presynaptic profiles of the rabbit dLGN is discussed.     

Electron microscopic study on the innervation of the pancreas of the domestic fowl

Summary The innervation of the pancreas of the domestic fowl was studied electron microscopically. The extrapancreatic nerve is composed mostly of unmyelinated nerve fibers with a smaller component of myelinated nerve fibers. The latter are not found in the parenchyma. The pancreas contains ganglion cells in the interlobular connective tissue. The unmyelinated nerve fibers branch off along blood vessels. Their synaptic terminals contact with the exocrine and endocrine tissues. The synaptic terminals can be divided into four types based on a combination of three kinds of synaptic vesicles. Type I synaptic terminals contain only small clear vesicles about 600 Å in diameter. Type II terminals are characterized by small clear and large dense core vesicles 1,000 Å in diameter. Type III terminals contain small clear vesicles and small dense core vesicles 500 Å in diameter. Type IV terminals are characterized by small and large dense core vesicles. The exocrine tissue receives a richer nervous supply than the endocrine tissue. Type II and IV terminals are distributed in the acinus, and they contact A and D cells of the islets. B cells and pancreatic ducts are supplied mainly by Type II terminals, the blood vessels by Type IV terminals.This work was supported by a scientific research grant (No. 144017) and (No. 136031) from the Ministry of Education of Japan to Prof. M. Yasuda     

On different types of nerve endings in the frog median eminence after fixation with permanganate and glutaraldehyde-osmium

Summary In the frog median eminence, fixed with glutaraldehyde and osmium tetroxide, four types of nerve endings can be generally distinguished. These endings are in contact with the pericapillary spaces of primary portal vessels and can be identified by the internal structure and the size of their granules and vesicles. Type 1 contains large granules (1500–2400 Å in diameter) and small clear vesicles (300–500 Å in diameter), type 2 intermediate granules (about 1100–1700 Å in diameter) and small clear vesicles, type 3 small granules (about 600–1000 Å in diameter) and small clear vesicles, type 4 only numerous small clear vesicles. The mixed types containing the large, intermediate and small dense granules in the same ending are infrequently found.After KMnO₄ or LiMnO₄ fixation the granules and vesicles mentioned above are observed as follows. The large granules in the type 1 nerve ending appear mostly pale or less-dense. The intermediate granules in the type 2 also appear mostly pale or less-dense, but some frequently show granules of high density. The small granules in the type 3 consistently contain the dense substance and these endings can be subdivided into two different types according to the populations of different sizes of dense granules [type 3a (900–1000 Å) and type 3b (500–800 Å)]. Dense-cored and cleared-synaptic vesicles are frequently present with together in the type 3 endings. The small vesicles (300–400 Å), in the type 4, appear generally pale (type 4a), but some nerve endings contain small dense cored-vesicles (type 4b).The author wishes to thank Prof. H. Fujita for his advice and criticism.     

Ultrastructure of the peptidergic and monoaminergic neurons in the hypothalamic neurosecretory system of Anuran Batracians

Summary In the toad Bufo arenarum Hensel the following regions of the hypothalamic — neurohypophyseal system were studied under the electronmicroscope: preoptic and paraventricular nuclei, median eminence and infundibular process of the neurohypophysis.Neuronal perikarya of the preoptic nucleus are loaded with typical neurosecretory granules of peptidergic nature having a mean diameter of 1660 Å. While most neurons of the winter toad are in a storage stage a few show signs of a more active synthetic activity. A distinctive feature of preoptic neurons is the presence of large lipid droplets. The paraventricular nucleus contains small neurons containing granulated vesicles with a mean diameter of 800-1000 Å. In the region extending between these two nuclei and the median eminence axons containing either neurosecretory elementary granules or granulated vesicles are observed.The inner zone of the median eminence is occupied by axons of the preoptic neurohypophyseal tract; two types of axons, according to the size and density of the neurosecretory granules, may be recognized. The outer zone of the median eminence contains mainly axons and nerve terminals containing granulated vesicles of probable monoaminergic nature and only a few with granules of peptidergic type.The neurohypophysis contains two kinds of axons: one with more dense granules of 1800 Å and the other with granules of lesser electron density and 2100 Å. At the ending proper small clear vesicles of synaptic type are found.A progressive increase in volume of the peptidergic granules along the axon is demonstrated. This is of the order of 218% from the preoptic perikarya down to the infundibular process. The physiological significance of the two neurosecretory systems — i.e. the monoaminergic and the peptidergic — and the probable nature of the two types of peptidergic axons is discussed.Supported by grants from the Consejo Nacional de Investigaciones Científicas y Técnicas and by the Air Force Office of Scientific Research (AF-AFOSR 963-67).The authors want to express their gratitude to Mrs. Defilippi-Novoa and Mr. Alberto Sáenz for their skillful assistance.     

Ultrastructure of calcitonin gene-related peptide-immunoreactive nerve fibres in guinea-pig peribronchial ganglia.

Calcitonin gene-related peptide-immunoreactive (CGRP-IR) nerves within guinea-pig peribronchial ganglia were studied at ultrastructural level using pre-embedding immunohistochemistry. Preterminal CGRP-IR axons were unmyelinated and contained singular immunoreactive dense core vesicles. CGRP-IR axon terminals were filled with numerous non-reactive small clear vesicles and few immunoreactive dense core vesicles. Some of these terminals were presynaptic to large neuronal processes emerging from local ganglion cells. Another population of presynaptic varicosities lack CGRP-IR. Within CGRP-IR terminals, non-reactive clear vesicles were clustered at the presynaptic membrane whereas CGRP-IR large vesicles remained in some distance from the synaptic cleft. The present observations indicate that: (1) at least two neurochemically different types of synaptic input exist to guinea-pig peribronchial ganglia. (2) CGRP-IR presynaptic terminals probably utilize a non-peptide transmitter for fast synaptic transmission, whilst the peptides are likely to be released parasynaptically and may act in a modulatory fashion.     

An Ultrastructural Account of Otoplanid Turbellaria Neuroanatomy I. The cerebral ganglion and the peripheral nerve net

The otoplanid nervous system investigated in Otoplana truncaspina Lanfranchi, 1969 and Parotoplanella heterorhabditica Lanfranchi, 1969 consits of: (a) an ellipsoidal cerebral ganglion located between the gut and the cephalic intestine and invested by a fibrillar collagen-like capsule 0.3 μm thick; (b) anterior extracapsular ganglion cell clusters; (c) a peripheral nerve plexus locally thickened at the level of the epithelial sensory and glandular areas, with extensive synaptic connections. At least two neuron types can be identified within the ganglion: (a) an inner layer close to the central neuropile of the 1st type of neurons, showing a vesicular cytoplasm rich in RER and Golgi complexes processing both round, clear, 25–45 nm in diameter, and dense cored vesicles, 50–80 nm in diameter; (b) an outer layer of the 2nd type of neurons, adjoining the capsule and filled with uniformly dense vesicles, 60–90 nm in diameter. Synaptic endings in the neuropile are provided with clear vesicles and dense cored vesicles or uniformly dense vesicles. The presynaptic side has paramembranous projections channelling the vesicles to the active zone; omega-like profiles are also observed. Thin banded muscle fibres run within the brain. A comparison is drawn with the other turbellarian neuron types described in the literature, to suggest their possible function. The functional implications of the synaptic ultrastructure are discussed.     

The effect of ageing on the SIF-cells in the hypogastric (main pelvic) ganglion of the rat

Summary The effect of ageing on SIF-cells was studied by the formaldehyde-induced fluorescence (FIF) method and by electron microscopy (EM). Microspectrofluorimetry was used to record emission spectra in FIF preparations. In newborn and in young adult (8–12 weeks) rats a single type of SIF-cell emitting greenish-yellow FIF was found while in aged rats a second type of SIF-cell emitting yellowish-brown granular FIF was also present. The intensity of the yellowish-brown FIF was lower than that of the greenish-yellow FIF. Also a few bright cytoplasmic fluorescent areas were occasionally found in some SIF-cells. The distribution of the SIF-cells through the ganglion did not change remarkably with age.In EM after glutaraldehyde-fixation in newborn and in young adult rats two types of small granule-containing (SGC) cells were distinguished according to the size of the dense cored vesicles, 1) 50–150 nm and 2) 50–250 nm. In aged rats, a third type of SGC-cells containing 50×250 nm elongated dense core vesicles could also be distinguished. After KMnO₄-fixation in newborn and in young adult rats the classification was identical with glutaraldehyde-fixation. In aged rats three types of storage granules were found after KMnO₄, 1) 100–300 nm empty vesicles and 2) 100–300 nm vesicles with small dense core, 3) 100–500 nm irregular in shape and filled with electron opaque material with a more dense core.     

Membrane contents of distinct subpopulations of coated vesicles determined by scanning transmission electron microscopy

In order to investigate the heterogeneity of clathrin-coated vesicles purified from rat liver, and to quantitate rigorously their membrane contents, we have analyzed scanning transmission electron micrographs of unstained coated vesicles before and after extraction with the non-ionic detergent Triton X-100, as well as of vesicles whose coats had been removed by dialysis against 10 mM or 100 mM Tris (pH 8.2). Their respective distributions of particle masses were thus determined and compared, in light of complementary biochemical quantitations of lipid and protein. Smaller coated particles, 25-45 MDa in mass and 60-80 nm in diameter, lose no mass when extracted with Triton, and disappear when their coats are dissociated. We conclude that they do not contain membrane vesicles, although they have dense, presumably proteinaceous, cores. They may represent particles generated during tissue homogenization or, possibly, a storage form of clathrin. The remaining 70% contain bona fide vesicles: these particles are 75-150 nm in diameter, and their average mass is about 80 MDa, of which 48 MDa is contributed by coat proteins, 10-12 MDa by phospholipid and cholesterol, and 20-22 MDa by vesicle-associated proteins. Their vesicles are of two types: smaller, denser, vesicles that contain substantial amounts of internalized material, and larger, less dense, vesicles that do not. The distinction between them may, in view of other findings, reflect a difference between coated vesicles derived respectively from the Golgi and the plasma membrane.     

MYONEURAL JUNCTIONS OF TWO ULTRASTRUCTURALLY DISTINCT TYPES IN EARTHWORM BODY WALL MUSCLE

The longitudinal muscle of the earthworm body wall is innervated by nerve bundles containing axons of two types which form two corresponding types of myoneural junction with the muscle fibers Type I junctions resemble cholinergic neuromuscular junctions of vertebrate skeletal muscle and are characterized by three features: (a) The nerve terminals contain large numbers of spherical, clear, ~500 A vesicles plus a small number of larger dense-cored vesicles (b) The junctional gap is relatively wide (~900 A), and it contains a basement membrane-like material, (c) The postjunctional membrane, although not folded, displays prominent specializations on both its external and internal surfaces The cytoplasmic surface is covered by a dense matrix ~200 A thick which appears to be the site of insertion of fine obliquely oriented cytoplasmic filaments The external surface exhibits rows of projections ~200 A long whose bases consist of hexagonally arrayed granules seated in the outer dense layer of the plasma membrane The concentration of these hexagonally disposed elements corresponds to the estimated concentration of both receptor sites and acetylcholinesterase sites at cholinergic junctions elsewhere. Type II junctions resemble the adrenergic junctions in vertebrate smooth muscle and exhibit the following structural characteristics: (a) The nerve fibers contain predominantly dense-cored vesicles ~1000 A in diameter (b) The junctional gap is relatively narrow (~150 A) and contains no basement membrane-like material, (c) Postjunctional membrane specialization is minimal. It is proposed that the structural differences between the two types of myoneural junction reflect differences in the respective transmitters and corresponding differences in the mechanisms of transmitter action and/or inactivation.     

Expression of the Dominant-Negative Tail of Myosin Va Enhances Exocytosis of Large Dense Core Vesicles in Neurons

Regulated exocytosis of secretory vesicles is a fundamental process in neurotransmission and the release of hormones and growth factors. The F-actin-binding motor protein myosin Va was recently shown to be involved in exocytosis of peptide-containing large dense core vesicles of neuroendocrine cells. It has not previously been discussed whether it plays a similar role in neurons. We performed live-cell imaging of cultured hippocampal neurons to measure the exocytosis of large dense core vesicles containing fluorescently labelled neuropeptide Y. To address the role of myosin Va in this process, neurons were transfected with the dominant-negative tail domain of myosin Va (myosinVa-tail). Under control conditions, about 0.75% of the labelled large dense core vesicles underwent exocytosis during 5 min of stimulation. This value was doubled to 1.80% of the vesicles when myosinVa-tail was expressed. Depolymerization of F-actin using latrunculin B resulted in a similar increase in exocytosis in both control and myosinVa-tail expressing cells. Interestingly, the increase in exocytosis caused by myosinVa-tail expression was completely abolished in the presence of KN-62, an inhibitor of calcium–calmodulin-dependent kinase II. We suggest that myosinVa-tail causes the liberation of large dense core vesicles from the actin cytoskeleton, leading to an increase in exocytosis in the cultured hippocampal neurons. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The variety of synaptic vesicles in the interpeduncular nucleus (ITP) of the frog.

The electron microscope has revealed a large variety of synaptic vesicles in the interpeduncular nucleus (ITP) of the frog "Rana esculenta". They vary in shape, size and electron density. There are two types of synapses which show only translucent spherical vesicles: in one type the vesicles are 40 nm, in the other type they are 70 nm in diameter. In other types of synapses the translucent vesicles may be mixed with those with dense core. Large granules, 160 nm in diameter, already reported in the ITP (KEMALI 1977a), are also shown as well as tiny flat mixed with large flat dense core vesicles of dumb-bell shape. Two types of axo-axonic synapses are illustrated while no crest synapses have been demonstrated. The results suggest that the afferents to the ITP might be more numerous than those reported in the literature or that--as in the case of the habenular afferents which consist of cholinergic and peptergic fibres--each projecting nucleus to the ITP has different types of fibres with more than one type of transmitter. Furthermore, due to the vesicles sizes, we may consider the ITP as a site in the vertebrate central nervous system where conventional neurotransmitter structures coexist with probable neurohumoral elements.     

ELECTRON MICROSCOPY OF THE HUMAN SYNOVIAL MEMBRANE

The structure of the lining cells at the surface of the synovial membrane facing the joint cavity has been studied by electron microscopy. The long cytoplasmic processes of these cells appear to be oriented toward the surface of the membrane, where they overlap and intertwine. The matrix of the lining cells contains dense material but no fibers with the periodicity of collagen. The lining cells are divided into two cell types or states of activity on the basis of their cytoplasmic contents. Type A is more numerous and contains a prominent Golgi apparatus, numerous vacuoles (0.4 to 1.5 microns in diameter) containing varying amounts of a dense granular material, many filopodia, mitochondria, intracellular fibrils, and micropinocytotic-like vesicles. Type B contains large amounts of ergastoplasm with fewer large vacuoles, micropinocytotic-like vesicles, and mitochondria. The probable functions of these cells are discussed in the light of current knowledge of the metabolism and function of the synovial membrane.     

Adaptations to the air breathing in the posterior intestine of the catfish (Corydoras aeneus,Callichthyidae). A histological and ultrastructural study

A light and transmission electron microscopic study of the intestine of catfish C. aeneus shows that the anterior part of the intestine is a site of digestion and absorption and its structure is typical of that of other teleostean fishes. However, in this species the thin-walled posterior intestine is adapted to air breathing. In this region mucosa is smooth and lined with respiratory epithelium with capillary network. Several types of cells are observed in the epithelium: flattened respiratory epithelial cells with short microvili, goblet cells, scarce epithelial cells with numerous longer microvilli, and two types of endocrine cells (EC). The solitary brush cells with several long and thick microvilli described here are the first observation of such cells in the gastrointestinal tract of fishes. Bodies of respiratory epithelial cells lie between capillaries. Their cytoplasm, apart from typical organelles contains dense and lamellar bodies, which are a site of accumulation of surfactant. In regions where capillaries are covered by thin cytoplasmic sheets of respiratory epithelial cells, a thin (0.24-3.00 microm) air-blood barrier is formed, thus enabling gas exchange. Epithelial cells with longer microvilli do not participate in the formation of the air-blood barrier and are probably responsible for absorbtion. EC of the closed type are dispersed within the epithelium. Their cytoplasm contains characteristic round or oval dense core vesicles 69 to 230 nm in diameter. The role of EC and brush cells in the regulation of processes related to absorbtion, and to respiration, is disscused.     

Protein kinase A affects trafficking of the vesicular monoamine transporters in PC12 cells

Previous studies have shown that the vesicular monoamine transporter 2 (VMAT2) is localized to both large dense core vesicles and synaptic vesicles in vivo. However, when exogenously expressed in PC12 cells, VMAT2 localizes only to large dense core vesicles. This distribution is similar to that of the endogenous vesicular monoamine transporter 1 (VMAT1) in PC12 cells. When VMAT2 was expressed in a protein kinase A (PKA)-deficient PC12 cell line it localized to synaptic-like microvesicles. Expression of recombinant VMAT1 in the same cell line showed a heterogeneous distribution to both large dense core vesicles and synaptic-like microvesicles. Coexpression of the PKA catalytic subunit partially restored trafficking of both VMAT2 and VMAT1 to large dense core vesicles; treatment of wild-type PC12 cells with the PKA inhibitor H89 increased VMAT2 on synaptic-like microvesicles. The VMAT1 and VMAT2 in large dense core vesicles exhibit a larger molecular size than those located on synaptic-like microvesicles. This difference is due to differential N-linked glycosylation. In vitro phosphorylation experiments show that PKA does not phosphorylate VMAT2. A chimera containing the VMAT2 cytoplasmic C-terminus fused to vesicular acetylcholine transporter (VAChT) shows mislocalization to synaptic-like microvesicles and VAChT-like glycosylation in the PKA-deficient cell line. However, coexpression with PKA changes the chimera's trafficking to large dense core vesicles and increases the molecular size. These results suggest that protein kinase A affects the formation and/or composition of VMAT trafficking complexes.