Association of synapsin I with neuronal cytoskeleton. Identification in cytoskeletal preparations in vitro and immunocytochemical localization in brain of synapsin I

Calmodulin-dependent protein kinase II (CaM kinase II) is associated with microtubule preparations and phosphorylates several endogenous proteins including microtubule-associated protein 2, tubulin, and an 80,000-dalton protein doublet (pp80). We now report that pp80 is identical to synapsin I by all criteria studied including molecular weight, isoelectric point, phosphopeptide mapping of cAMP- and calmodulin-dependent phosphorylated protein, comigration with authentic synapsin I, and sensitivity to digestion with collagenase. Synapsin I and CaM kinase II were found in association with both microtubule preparations and preparations enriched in neurofilaments. Antibodies to synapsin I specifically labeled neurofilaments prepared in vitro. Immunocytochemical studies on rat brain tissue demonstrated synapsin I immunoreactivity specifically associated with the neuronal cytoskeleton as well as synaptic vesicles. The observed synapsin I staining on cytoskeletal elements was considerably diminished or abolished by the inclusion of Triton X-100 in the staining solutions. These results indicate that synapsin I is associated with the cytoskeleton and may be an important link between cytoskeletal elements as well as between the cytoskeleton and membrane.     

Compared intracellular localization of the glucocorticosteroid and progesterone receptors: an immunocytochemical study

The intracellular distribution of the glucocorticosteroid and progesterone receptors (GR and PR, respectively) was studied immunohistochemically. In control adrenalectomized (Adx) rat liver, immunostaining of paraffin sections revealed GR in cell nuclei, with a wide range of intensity between individuals. Following dexamethasone (Dex) treatment, the nuclear staining was uniformly high in all animals; the cytoplasmic staining was always weak and remained unchanged after Dex treatment. In frozen sections, the GR immunoreactivity in cell nuclei was weak in the absence and very strong in the presence of Dex, while no GR-specific cytoplasmic staining was observed. In frozen sections fixed in vapor of formaldehyde to avoid any artifactual redistribution of the receptor, some GR immunostaining was observed in the cytoplasm and the nucleus. In contrast, in paraffin as well as in frozen sections of chick oviduct, fixed by immersion or in vapor, PR was exclusively nuclear, including in the absence of progesterone, and the intensity of immunostaining was not modified by progesterone treatment. In order to verify if loss of nuclear receptors during tissue preparation could explain the differences in nuclear immunostaining observed between hormone-free and hormone-occupied GR, and between GR and PR, frozen sections of Adx rat liver and chick oviduct were preincubated at 4 degrees C in buffer solutions before the fixation procedure. It was found that hormone-free GR diffused out of the nucleus faster than hormone-occupied GR nuclei, and that nuclear GR diffused faster than nuclear PR. Based on these results, we propose that, during the fixation procedure, the fraction of nuclear GR which diffuses out of the nucleus is much smaller in the presence than in the absence of Dex. This lesser loss of nuclear GR after Dex treatment results in an increase of immunostaining after hormonal administration, which might have been erroneously interpreted as a sign of translocation from cytoplasm to nucleus. That the nuclear PR detection is not modified by progesterone treatment may be explained by its reduced diffusibility as compared to nuclear GR. This hypothesis does not rule out the existence of some cytoplasmic GR, whose significance remains unclear, but it offers a unified mechanism of action for all steroid hormone receptors. In the case of glucocorticosteroids, as already proposed for estradiol and progesterone, no step of cytoplasm to nucleus translocation would be required for hormone action, and transformation-activation would occur in the nucleus, resulting in tighter binding of the hormone receptor complexes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunocytochemical localization of synapsin I in the adrenal medulla of rats

Summary The localization of synapsin I in the rat adrenal medulla was studied using the light- and electronmicroscopic immunohistochemistry. By light microscopy, many dot-like reaction products for synapsin I were recognized to be distributed throughout the medullary tissue. The immunoelectron microscopy clearly revealed that gold particles for synapsin I accumulated in abundance in the nerve terminals forming synapses with the chromaffin cell, while the particles were not localized in the chromaffin cells at all. In the nerve terminal, the gold particles were localized exclusively in the region occupied by synaptic vesicles except for the region just beneath the presynaptic plasma membrane. The synaptic vesicles were frequently linked with the adjacent ones by filamentous structures implicated in synapsin I. It is concluded morphologically that synapsin I is a highly-specific protein for the genuine neuron, and is not detected even in the chromaffin cell which originates from the neural crest.     

Immunocytochemical localization of synapsin I in the adrenal medulla of rats

The localization of synapsin I in the rat adrenal medulla was studied using the light- and electronmicroscopic immunohistochemistry. By light microscopy, many dot-like reaction products for synapsin I were recognized to be distributed throughout the medullary tissue. The immunoelectron microscopy clearly revealed that gold particles for synapsin I accumulated in abundance in the nerve terminals forming synapses with the chromaffin cell, while the particles were not localized in the chromaffin cells at all. In the nerve terminal, the gold particles were localized exclusively in the region occupied by synaptic vesicles except for the region just beneath the presynaptic plasma membrane. The synaptic vesicles were frequently linked with the adjacent ones by filamentous structures implicated in synapsin I. It is concluded morphologically that synapsin I is a highly-specific protein for the genuine neuron, and is not detected even in the chromaffin cell which originates from the neural crest.     

Cystein-proteinase localization in osteoclasts: An immunocytochemical study

Summary Cysteine-proteinases such as cathepsin B and G were localized in rat osteoclasts, by an indirect protein A-immunogold labeling technique, on post-embedded ultrathin sections. In osteoclasts, specific immunogold labeling of both anti-cathepsin B and G was localized in Golgi vesicles, lysosomes, pale vacuoles of various sizes, and the extracellular canals of ruffled borders; no immunoreactivity was seen in the cytoplasmic matrix, mitchondria, cisterns of the rough endoplasmic reticulum, or nuclei. The presence of immunolabeling of cathepsins in osteoclasts and in the subosteoclastic compartment suggests that these enzymes are involved in the extracellular degradation of collagen and other noncollagenous bone matrix proteins.     

Static and dynamic properties of gravity-sensitive receptors in the cat vestibular system

Summary The spike activity of eighth cranial nerve units tonically responsive to head position was recorded in cats anesthetized with pentobarbital sodium, and related with linear accelerations induced by gravity during maintained positions and during dynamic trajectories achieved through rolling around a rostro-caudal axis.The steady-state discharge of 80% of the cells had relatively small coefficients of variation, narrow histograms and periodic autocorrelograms. That of most remaining cells had large coefficients variation, nearly exponential histograms and flat or weakly periodic autocorrelograms.The static relation between head position and discharge showed that each cell had directional sensitivity, i.e. a characteristic change associated with each movement sense. Sixty-six percent of the cells had side-up increases in interval mean and standard deviation, with translation of the histogram to the right and reduction in the average autocorrelogram value: 34% had the opposite relations. Many cells showed multivaluedness, i.e. the interval mean (and other statistics) from different stations at any given position covered a range greater than that at each station. Multivaluedness varied from cell to cell.In the dynamic experiments the discharge was recorded during a continuous motion that involved a single sine wave or a mixture of sinusoids at frequencies up to 0.1 Hz. The spike trains exhibited a continuous mapping of the time varying tilt angle into the instantaneous rate with little or no evidence of multivaluedness. In addition to a tonic part, responses showed a phasic component with the characteristics of a unidirectional rate sensitivity that determined a phase-lead of the response with respect to the stimulus. The relative proportions of tonic and phasic components varied from cell to cell.Based upon anatomical and mechanical considerations (see Appendix) and upon the present results it is suggested that deformations of the trampoline-like membrane occur in a distributed manner. Multivaluedness may be due to forces which, like stiction, prevent complete relaxation of the membrane under static but not under dynamic conditions. The phasic response, whose origin is obscure, argues in favor of the otolithic receptors having a dynamic function, in addition to their role in detecting head positions with respect to gravity.     

Developmental changes of synapsin I subcellular localization in rat cerebellar neurons

Synapsin I, one of the major synaptic proteins, is thought to associate with synaptic vesicles and to play a regulatory role in neurotransmitter release. In mature neurons, it is concentrated almost exclusively in presynaptic nerve endings. Here, we studied the subcellular localization of synapsin I during the development of rat cerebellar cortices by immunocytochemistry, using anti-synapsin I antibodies and found that during the development of rat cerebellar cortices it tentatively exists in the dendritic growth cones of immature internal granule cells and in the axonal growth cones of mossy fibers as well as mature presynaptic endings. Also, we found that synapsin I, in the axonal and dendritic growth cones does not necessarily associate with vesicles, but rather with fuzzy filamentous structures in the cytoplasm. In search of the structure of synapsin I in vivo, we employed the quick-freeze, deep-etch technique after immunogold labeling. Synapsin I seems to thereby connect synaptic vesicles or anchor them to cytoskeletons in presynaptic endings.     

Functional localization of pulmonary stretch receptors in the airways of the cat

During a respiratory effort against a closed airway the afferent activity of vagal fibres from pulmonary stretch receptors does not appreciably increase during the inspiratory phase because the lung is prevented from expanding. The possibility to perform occlusions at different levels of the airways allows the localization of pulmonary stretch receptors in the tracheo-bronchial tree. 100 fibres from pulmonary stretch receptors of the left and right sides of the tracheo-bronchial tree have been studied in 3 cats and their localization found as follows: 10% in the higher half of the intrathoracic trachea, 22% in the lower half of the intrathoracic trachea and the carina, 7% in the main bronchus and 61% in the intrapulmonary airways. Knowing the surface area of the tracheo-bronchial tree at different levels and assuming total of 1200 stretch receptors from each side their average concentration resulted as follows: 50.0 receptors/cm2 in the higher half of the intrathoracic trachea, 108.0/cm2 in the lower half of the intrathoracic trachea and the carina, 213.0/cm2 in the main bronchus and 1.3/cm2 in the intrapulmonary airways.     

Electrostatic and hydrophobic interactions of synapsin I and synapsin I fragments with phospholipid bilayers

Synapsin I, a major neuron-specific phosphoprotein, is localized on the cytoplasmic surface of small synaptic vesicles to which it binds with high affinity. It contains a collagenase-resistant head domain and a collagenase-sensitive elongated tail domain. In the present study, the interaction between synapsin I and phospholipid vesicles has been characterized, and the protein domains involved in these interactions have been identified. When lipid vesicles were prepared from cholesterol and phospholipids using a lipid composition similar to that found in native synaptic vesicle membranes (40% phosphatidylcholine, 32% phosphatidylethanolamine, 12% phosphatidylserine, 5% phosphatidylinositol, 10% cholesterol, wt/wt), synapsin I bound with a dissociation constant of 14 nM and a maximal binding capacity of about 160 fmol of synapsin I/microgram of phospholipid. Increasing the ionic strength decreased the affinity without greatly affecting the maximal amount of synapsin I bound. When vesicles containing cholesterol and either phosphatidylcholine or phosphatidylcholine/phosphatidylethanolamine were tested, no significant binding was detected under any conditions examined. On the other hand, phosphatidylcholine vesicles containing either phosphatidylserine or phosphatidylinositol strongly interacted with synapsin I. The amount of synapsin I maximally bound was directly proportional to the percentage of acidic phospholipids present in the lipid bilayer, whereas the Kd value was not affected by varying the phospholipid composition. A study of synapsin I fragments obtained by cysteine-specific cleavage showed that the collagenase-resistant head domain actively bound to phospholipid vesicles; in contrast, the collagenase-sensitive tail domain, though strongly basic, did not significantly interact. Photolabeling of synapsin I was performed with the phosphatidylcholine analogue 1-palmitoyl-2-[11-[4-[3-(trifluoromethyl)diazirinyl]phenyl] [2-3H]undecanoyl]-sn-glycero-3-phosphocholine; this compound generates a highly reactive carbene that selectively interacts with membrane-embedded domains of membrane proteins. Synapsin I was significantly labeled upon photolysis when incubated with lipid vesicles containing acidic phospholipids and trace amounts of the photoactivatable phospholipid. Proteolytic cleavage of photolabeled synapsin I localized the label to the head domain of the molecule.(ABSTRACT TRUNCATED AT 400 WORDS)     

Synaptophysin and synapsin I as tools for the study of the exo-endocytotic cycle

Synaptophysin, an integral protein of the synaptic vesicle membrane, and synapsin I, a phosphoprotein associated with the cytoplasmic side of synaptic vesicles, represent useful markers that allow to follow the movements of the vesicle membrane during recycling. The use of antibodies against these proteins to label nerve terminals during experimental treatments which stimulate secretion has provided evidence that during the exo-endocytotic cycle synaptic vesicles transiently fuse with the axolemma, from which they are specifically recovered. When recycling is blocked, exocytosis leads to the permanent incorporation of the synaptic vesicle membrane into the axolemma and to diffusion of the vesicle components in the plane of the membrane.     

Immunohistochemical localization of GABAA receptors in the scotopic pathway of the cat retina

The distribution of GABA_A receptors in the inner plexiform layer of cat retina was studied using monoclonal antibodies against the 2/3 subunits. A dense band of receptor labeling was found in the inner region of the inner plexiform layer where the rod bipolar axons terminate. Three forms of evidence indicate that the GABA_A receptor labeling is on the indoleamine-accumulating, GABAergic amacrine cell that is synaptically interconnected with the rod bipolar cell terminal. (1) Electron microscopy showed that the anti-GABA_A receptor antibody (62-3G1) labeled profiles that were postsynaptic to rod bipolar axons and made reciprocal synapses. (2) Indoleamine uptake (and the subsequent autofluorescence) combined with GABA_A receptor immunohistochemistry showed co-localization of the two markers in half of the receptor-positive amacrine cells. (3) Double labeling demonstrated that half of the receptor-positive somata also contained GABA. These results indicate that a GABAergic amacrine cell interconnected with the rod bipolar cell, most likely the so-called A17 amacrine cell, itself bears GABA_A receptors.     

Distinct roles of synapsin I and synapsin II during neuronal development.

The synapsins are a family of neuron-specific proteins, associated with the cytoplasmic surface of synaptic vesicles, which have been shown to regulate neurotransmitter release in mature synapses and to accelerate development of the nervous system. Using neuronal cultures from mice lacking synapsin I, synapsin II, or both synapsins I and II, we have now found that synapsin I and synapsin II play distinct roles in neuronal development. Deletion of synapsin II, but not synapsin I, greatly retarded axon formation. Conversely, deletion of synapsin I, but not synapsin II, greatly retarded synapse formation. Remarkably, the deletion of both synapsins led to partial restoration of the wild phenotype. The results suggest that the synapsins play separate but coordinated developmental roles.     

Interactions of synapsin I with small synaptic vesicles: distinct sites in synapsin I bind to vesicle phospholipids and vesicle proteins

Synapsin I is a major neuron-specific phosphoprotein that is specifically localized to the cytoplasmic surface of small synaptic vesicles. In the present study, the binding of synapsin I to small synaptic vesicles was characterized in detail. The binding of synapsin I was preserved when synaptic vesicles were solubilized and reconstituted in phosphatidylcholine. After separation of the protein and lipid components of synaptic vesicles under nondenaturing conditions, synapsin I bound to both components. The use of hydrophobic labeling procedures allowed the assessment of interactions between phospholipids and synapsin I in intact synaptic vesicles. Hydrophobic photolabeling followed by cysteine-specific cleavage of synapsin I demonstrated that the head domain of synapsin I penetrates into the hydrophobic core of the bilayer. The purified NH2-terminal fragment, derived from the head domain by cysteine-specific cleavage, bound to synaptic vesicles with high affinity confirming the results obtained from hydrophobic photolabeling. Synapsin I binding to synaptic vesicles could be inhibited by the entire molecule or by the combined presence of the NH2-terminal and tail fragments, but not by an excess of either NH2-terminal or tail fragment alone. The purified tail fragment bound with relatively high affinity to synaptic vesicles, though it did not significantly interact with phospholipids. Binding of the tail fragment was competed by holosynapsin I; was greatly decreased by phosphorylation; and was abolished by high ionic strength conditions or protease treatment of synaptic vesicles. The data suggest the existence of two sites of interaction between synapsin I and small synaptic vesicles: binding of the head domain to vesicle phospholipids and of the tail domain to a protein component of the vesicle membrane. The latter interaction is apparently responsible for the salt and phosphorylation dependency of synapsin I binding to small synaptic vesicles.     

Demonstration of a different localization of perikarya immunoreactive to oxytocin and vasopressin in the cat hypothalamus

Using immunohistochemical techniques, we demonstrated oxytocin (OT) and vasopressin (AVP) neurons in the cat hypothalamus. The OT immunoreactive neurons were found mainly in the paraventricular nucleus, supraoptic nucleus and dorsal accessory group located lateral to the fornix. In addition to these hypothalamic structures, the AVP immunoreactive neurons were observed in the suprachiasmatic nucleus, ventral accessory group located in the retrochiasmatic area and lateral accessory group, dorsal to the supraoptic nucleus caudally, and ventral to the medial part of the internal capsule rostrally. We further demonstrated a different localization of the OT and AVP immunoreactive neurons in the paraventricular and supraoptic nuclei.     

Ultrastructural localization of IGF-I in the rat kidney; an immunocytochemical study

Summary We have shown recently by light microscopy that insulin-like growth factor I (IGF-I) immunoreactivity is localized in cells in the collecting ducts and in the thin loop of Henle in the normal rat kidney. In the present study, we have investigated the ultrastructural localisation of IGF-I using preembedding immunocytochemistry.The light microscopical findings were confirmed at the electronmicroscopical level. In collecting ducts as well as in the thin limb of Henle's loop a focal expression of IGF-I immunoreactivity was evident, i.e. distinctly IGF-I positive cells were intermingled with cells lacking IGF-I immunoreactivity. IGF-I immunoreactivity was found to have a diffuse cytoplasmatic distribution in both cell types. No specific association to organelles was found.     

Histochemical and immunocytochemical localization of prolactin receptors on Nb2 lymphoma cells: applications of confocal microscopy

We studied prolactin (PRL) binding sites on Nb2 lymphoma cells using two different light microscopic methods. First, histochemical detection was accomplished by using an aminomethyl coumarin-acetic acid-conjugated ovine prolactin molecule (AMCA-oPRL) on both glutaraldehyde-fixed and unfixed Nb2 lymphoma cells. Binding of AMCA-oPRL was studied after UV illumination and appeared as punctate fluorescence associated with many but not all cells. Binding was abolished when tissue sections were treated with excess unlabeled lactogenic hormones and was unchanged when a non-lactogenic hormone was used for displacement. Counting revealed significant differences between the number of labeled cells in populations known to exhibit up- or down-regulated PRL receptors. Second, indirect immunocytochemistry of Nb2 PRL receptors was accomplished by immunological detection of exogenously added ovine PRL using two antisera directed against ovine PRL. Visualization of the ligand-antibody complexes was accomplished by confocal laser scanning microscopy. Staining was restricted to a subpopulation of cells. The morphological results presented here add to the previous physiological and biochemical data on the presence of lactogenic hormone receptors on Nb2 lymphoma cells.     

A quantitative immunocytochemical approach to the analysis of type I cells in the cat carotid body

Digital image analysis of immunostained semithin plastic sections indicates that experimentally induced changes in levels of transmitter-related reaction product in single cells fails to support the concept of clearly defined subsets of type I cells in the carotid body. This objective approach to the quantitation of staining product on a cell-by-cell basis appears to indicate that the observed changes are related to global shifts in the expression of a given neuronal marker throughout a single population of highly labile chemoreceptor elements. Copyright Copyright 1999 S. Karger AG, Basel     

S100A1 codistributes with synapsin I in discrete brain areas and inhibits the F-actin-bundling activity of synapsin I

The Ca2+-sensor protein S100A1 was recently shown to bind in vitro to synapsins, a family of synaptic vesicle phosphoproteins involved in the regulation of neurotransmitter release. In this paper, we analyzed the distribution of S100A1 and synapsin I in the CNS and investigated the effects of the S100A1/synapsin binding on the synapsin functional properties. Subcellular fractionation of rat brain homogenate revealed that S100A1 is present in the soluble fraction of isolated nerve endings. Confocal laser scanning microscopy and immunogold immunocytochemistry demonstrated that S100A1 and synapsin codistribute in a subpopulation (5-20%) of nerve terminals in the mouse cerebral and cerebellar cortices. By forming heterocomplexes with either dephosphorylated or phosphorylated synapsin I, S100A1 caused a dose- and Ca2+-dependent inhibition of synapsin-induced F-actin bundling and abolished synapsin dimerization, without affecting the binding of synapsin to F-actin, G-actin or synaptic vesicles. These data indicate that: (i) synapsins and S100A1 can interact in the nerve terminals where they are coexpresssed; (ii) S100A1 is unable to bind to SV-associated synapsin I and may function as a cytoplasmic store of monomeric synapsin I; and (iii) synapsin dimerization and interaction with S100A1 are mutually exclusive, suggesting an involvement of S100A1 in the Ca2+-dependent regulation of synaptic vesicle trafficking.