Spatial relationships of connexin36, connexin57 and zonula occludens-1 in the outer plexiform layer of mouse retina

Horizontal cells form gap junctions with each other in mammalian retina, and lacZ reporter analyses have recently indicated that these cells express the Cx57 gene, which codes for the corresponding gap junctional protein. Using anti-connexin57 antibodies, we detected connexin57 protein in immunoblots of mouse retina, and found punctate immunolabeling of this connexin co-distributed with calbindin-positive horizontal cells in the retinal outer plexiform layer. Double immunofluorescence labeling was conducted to determine the spatial relationships of connexin36, connexin57, the gap junction-associated protein zonula occludens-1 and the photoreceptor ribbon synapse-associated protein bassoon in the outer plexiform layer. Connexin36 was substantially co-localized with zonula occludens-1 in the outer plexiform layer, and both of these proteins were frequently located in close spatial proximity to bassoon-positive ribbon synapses. Connexin57 was often found adjacent to, but not overlapping with, connexin36-positive and zonula occludens-1-positive puncta, and was also located adjacent to bassoon-positive ribbon synapses at rod spherules, and intermingled with such synapses at cone pedicles. These results suggest zonula occludens-1 interaction with connexin36 but not with Cx57 in the outer plexiform layer, and an absence of connexin57/connexin36 heterotypic gap junctional coupling in mouse retina. Further, an arrangement of synaptic contacts within rod spherules is suggested whereby gap junctions between horizontal cell terminals containing connexin57 occur in very close proximity to ribbon synapses formed by rod photoreceptors, as well as in close proximity to Cx36-containing gap junctions between rods and cones.     

Essential role of Ca2+-binding protein 4, a Cav1.4 channel regulator, in photoreceptor synaptic function

CaBP1-8 are neuronal Ca(2+)-binding proteins with similarity to calmodulin (CaM). Here we show that CaBP4 is specifically expressed in photoreceptors, where it is localized to synaptic terminals. The outer plexiform layer, which contains the photoreceptor synapses with secondary neurons, was thinner in the Cabp4(-/-) mice than in control mice. Cabp4(-/-) retinas also had ectopic synapses originating from rod bipolar and horizontal cells tha HJt extended into the outer nuclear layer. Responses of Cabp4(-/-) rod bipolars were reduced in sensitivity about 100-fold. Electroretinograms (ERGs) indicated a reduction in cone and rod synaptic function. The phenotype of Cabp4(-/-) mice shares similarities with that of incomplete congenital stationary night blindness (CSNB2) patients. CaBP4 directly associated with the C-terminal domain of the Ca(v)1.4 alpha(1)-subunit and shifted the activation of Ca(v)1.4 to hyperpolarized voltages in transfected cells. These observations indicate that CaBP4 is important for normal synaptic function, probably through regulation of Ca(2+) influx and neurotransmitter release in photoreceptor synaptic terminals.     

The absence of the clathrin-dependent endocytosis in rod bipolar cells of the FVB/N mouse retina

The high rate of exocytosis at the ribbon synapses is balanced by following compensatory endocytosis. Unlike conventional synaptic terminals where clathrin-mediated endocytosis (CME) is a predominant mechanism for membrane retrieval, CME is thought to be only a minor mechanism of endocytosis at the retinal ribbon synapses, but CME is present there and it works. We examined the clathrin expression in the FVB/N rd1 mouse, which is an animal model of retinitis pigmentosa. The broadly distributed pattern of clathrin immunoreactivity in the inner plexiform layer was similar in both the control and FVB/N mouse retinas, but the immunoreactive punta within the rod bipolar axon terminals located in the proximal IPL were decreased in number and reduced in size at postnatal days 14 and they came to disappear at postnatal days 21. This preferential decrease of the clathrin expression at ribbon synapses in the rod bipolar cell axon terminals of the FVB/N mouse retina demonstrates another plastic change after photoreceptor degeneration and this suggests that clathrin may be important for normal synaptic function at the rod bipolar ribbon synapses in the mammalian retina.     

Synapsin I expression in the rat retina during postnatal development

Summary The expression of the synapsin I gene was studied during postnatal development of the rat retina at the mRNA and protein levels. In situ hybridization histochemistry showed that synapsin I mRNA was expressed already in nerve cells in the ganglion cell layer of the neonatal retina, while it appeared in neurons of the inner nuclear layer from postnatal day 4 onward. Maximal expression of synapsin I mRNA was observed at P12 in ganglion cells and in neurons of the inner nuclear layer followed by moderate expression in the adult. At the protein level a shift of synapsin I appearance was observed from cytoplasmic to terminal localization during retinal development by immunohistochemistry. In early stages (P4 and P8), synapsin I was seen in neurons of the ganglion cell layer and in neurons of the developing inner nuclear layer as well as in the developing inner plexiform layer. In the developing outer plexiform layer synapsin I was localized only in horizontal cells and in their processes. Its early appearance at P4 indicated the early maturation of this cell type. A shift and strong increase of labelling to the plexiform layers at P12 indicated the localization of synapsin I in synaptic terminals. The inner plexiform layer exhibited a characteristic stratified pattern. Photoreceptor cells never exhibited synapsin I mRNA or synapsin I protein throughout development.Abbreviations GCL ganglion cell layer - INB inner neuroblast layer - INL inner nuclear layer - IPL inner plexiform layer - ONB outer neuroblast layer - ONL outer nuclear layer - OPL outer plexiform layer     

Homer1a regulates the activity-induced remodeling of synaptic structures in cultured hippocampal neurons

Activity-dependent re-organizations of central synapses are thought to play important roles in learning and memory. Although the precise mechanisms of how neuronal activities modify synaptic connections remain to be elucidated, the activity-induced neuronal proteins such as Homer1a may contribute to the onset of synaptic remodeling. To further understand the physiological roles of Homer1a, we first examined prolonged effects of neuronal stimulation capable of inducing Homer1a on the distribution of a postsynaptic protein Homer1c by live imaging and immunostaining. We found that glutamate stimulation induced a biphasic change in the distribution of Homer1c, in which the postsynaptic clusters of Homer1c defused initially after 30 min to 1 h, and then reassembled more than the original level after 4–8 h. When other synaptic proteins (postsynaptic density-95 (PSD95), Filamentous actin (F-actin), glutamate receptors, synaptotagmin, synaptophysin and synapsin) were analyzed by immunocytochemical methods, the distribution of these proteins also showed a similar biphasic pattern, suggesting that glutamate stimulation induces a global alteration in synaptic structures. To further dissect the functions of Homer1a in the activity-induced synaptic remodeling, the short hairpin RNA (shRNA) vectors that specifically block the expression of endogenous Homer1a were constructed. When the shRNA of Homer1a was introduced to the cells, the activity-induced changes were almost completely suppressed. The expression of surface glutamate receptor 2 was also inhibited, suggesting that Homer1a may modulate the efficacy of synaptic transmission.

Furthermore, we found that Homer1a contributes to the presynaptic remodeling in a retrograde manner. Our data indicate that Homer1a regulates the activity-induced biphasic changes of post- and pre-synaptic sites.     

Synapsin-dependent development of glutamatergic synaptic vesicles and presynaptic plasticity in postnatal mouse brain

Inactivation of the genes encoding the neuronal, synaptic vesicle-associated proteins synapsin I and II leads to severe reductions in the number of synaptic vesicles in the CNS. We here define the postnatal developmental period during which the synapsin I and/or II proteins modulate synaptic vesicle number and function in excitatory glutamatergic synapses in mouse brain. In wild-type mice, brain levels of both synapsin I and synapsin IIb showed developmental increases during synaptogenesis from postnatal days 5-20, while synapsin IIa showed a protracted increase during postnatal days 20-30. The vesicular glutamate transporters (VGLUT) 1 and VGLUT2 showed synapsin-independent development during postnatal days 5-10, following which significant reductions were seen when synapsin-deficient brains were compared with wild-type brains following postnatal day 20. A similar, synapsin-dependent developmental profile of vesicular glutamate uptake occurred during the same age periods. Physiological analysis of the development of excitatory glutamatergic synapses, performed in the CA1 stratum radiatum of the hippocampus from the two genotypes, showed that both the synapsin-dependent part of the frequency facilitation and the synapsin-dependent delayed response enhancement were restricted to the period after postnatal day 10. Our data demonstrate that while both synaptic vesicle number and presynaptic short-term plasticity are essentially independent of synapsin I and II prior to postnatal day 10, maturation and function of excitatory synapses appear to be strongly dependent on synapsin I and II from postnatal day 20.     

Effects of restraint stress on the expression of proteins involved in synaptic vesicle exocytosis in the hippocampus

Chronic restraint stress has been associated with induction of morphological changes in the hippocampus. Postsynaptically, these changes include decreased length and branching of apical dendrites from CA3 pyramidal neurons, while presynaptically, depletion and clustering of synaptic vesicles have been observed. However, the molecular correlates of these changes remain poorly defined; while some studies have identified changes in the levels of some presynaptic proteins, none have assessed the coordinate expression of components of the membrane fusion complex, including synaptobrevin, syntaxin, and synaptosomal-associated protein 25 kDa, and their major regulatory molecules synaptotagmin, synaptophysin, and synapsin. Therefore, we undertook to assess the immunoreactivity of these proteins in hippocampal slices obtained from rats subjected to either acute (one 6 h session) or chronic (21 days at 6 h per day) of restraint stress. Specifically, we observed a significant increase in synaptobrevin immunoreactivity in the inner molecular layer of the dentate gyrus (54.2%; P=0.005), the stratum radiatum in the CA1 subfield (55.5%; P=0.007), and a region including the stratum lucidum and the proximal portion of the stratum radiatum in the CA3 subfield (52.7%; P=0.002); we also observed a trend toward increased synaptophysin levels in the stratum lucidum/radiatum of the CA3 subfield (8.0%; P=0.051) following chronic, but not acute, restraint stress. In that synaptobrevin has been associated with replenishment of the "readily-releasable" pool of synaptic vesicles and the efficiency of neurotransmitter release, the present results suggest that stress-induced changes in synaptobrevin may at least in part underlie the previously observed changes in synaptic and neuronal morphology.     

On the synaptogenic sequence in the chick retina

Study of the developing chick retina with the electron microscope revealed that dyad ribbon synapses begin to form in the inner plexiform layer before synaptic ribbons begin to appear in photoreceptor terminals of the outer plexiform layer. This centrifugal (inner to outer) sequence of synaptogenesis in the predominantly cone retina of the chick differs from the centripetal sequence that has been reported for the predominantly rod retinas of the mouse and rat. This difference does not favor the hypothesis, suggested by others, that the photo-receptor may influence the maturation of inner retinal elements. The different patterns of synaptogenesis are discussed briefly with reference to anatomical differences between the retinas of different species.     

Functions of synapsins in corticothalamic facilitation: important roles of synapsin I

Key points

• The synaptic vesicle associated proteins synapsin I and synapsin II have important functions in synaptic short‐term plasticity.
• We investigated their functions in cortical facilitatory feedback to neurons in dorsal lateral geniculate nucleus (dLGN), feedback that has important functions in state‐dependent regulation of thalamic transmission of visual input to cortex.
• We compared results from normal wild‐type (WT) mice and synapsin knockout (KO) mice in several types of synaptic plasticity, and found clear differences between the responses of neurons in the synapsin I KO and the WT, but no significant differences between the synapsin II KO and the WT.
• These results are in contrast to the important role of synapsin II previously demonstrated in similar types of synaptic plasticity in other brain regions, indicating that the synapsins can have different roles in similar types of STP in different parts of the brain.

Abstract

The synaptic vesicle associated proteins synapsin I (SynI) and synapsin II (SynII) have important functions in several types of synaptic short‐term plasticity in the brain, but their separate functions in different types of synapses are not well known. We investigated possible distinct functions of the two synapsins in synaptic short‐term plasticity at corticothalamic synapses on relay neurons in the dorsal lateral geniculate nucleus. These synapses provide excitatory feedback from visual cortex to the relay cells, feedback that can facilitate transmission of signals from retina to cortex. We compared results from normal wild‐type (WT), SynI knockout (KO) and SynII KO mice, in three types of synaptic plasticity mainly linked to presynaptic mechanism. In SynI KO mice, paired‐pulse stimulation elicited increased facilitation at short interpulse intervals compared to the WT. Pulse‐train stimulation elicited weaker facilitation than in the WT, and also post‐tetanic potentiation was weaker in SynI KO than in the WT. Between SynII KO and the WT we found no significant differences. Thus, SynI has important functions in these types of synaptic plasticity at corticothalamic synapses. Interestingly, our data are in contrast to the important role of SynII previously shown for sustained synaptic transmission during intense stimulation in excitatory synapses in other parts of the brain, and our results suggest that SynI and SynII may have different roles in similar types of STP in different parts of the brain.

Abbreviations

DKO

double knock‐out

dLGN

dorsal lateral geniculate nucleus

EPSC

excitatory post‐synaptic current

EPSCctr

control EPSC

KO

knockout

PPF

paired‐pulse facilitation

PTP

post‐tetanic potentiation

RRP

readily releasable pool

STP

short‐term plasticity

SV

synaptic vesicle

SynI

synapsin I

SynII

synapsin II

TC

thalamo‐cortical

WT

wild‐type

     

The toxicity of the PrP106-126 prion peptide on cultured photoreceptors correlates with the prion protein distribution in the mammalian and human retina

In patients affected by Creutzfeldt-Jakob disease and in animals affected by transmissible spongiform encephalopathies, retinal functions are altered, and major spongiform changes are observed in the outer plexiform layer where photoreceptors have their synaptic terminals. In the present study, the prion protein PrP(c) was found to form aggregates in rod photoreceptor terminals from both rat and human retina, whereas no labeling was observed in cone photoreceptors. Discrete staining was also detected in the inner plexiform layer where the prion protein was located at human amacrine cell synapses. In mixed porcine retinal cell cultures, the PrP106-126 prion peptide triggered a 61% rod photoreceptor cell loss by apoptosis as indicated by terminal deoxynucleotidyl transferase dUTP nick-end labeling, whereas cone photoreceptors were not affected. Amacrine cells were also reduced by 47% in contrast to ganglion cells. Although this cell loss was associated with a 5.5-fold increase in microglial cells, the strict correlation between the PrP(c) prion protein expression and the peptide toxicity suggested that this toxicity did not rely on the release of a toxic compound by glial cells. These results provide new insights into the retinal pathophysiology of prion diseases and illustrate advantages of adult retinal cell cultures to investigate prion pathogenic mechanisms.     

The organization of the outer plexiform layer in the retina of the cat: electron microscopic observations

Summary The outer plexiform layer of the cat retina has been examined by electron microscopy of random and serial ultrathin sections in order that neural profiles might be positively identified and their synaptic relationships studied. Photoreceptors are interconnected by means of gap junctions as are the A horizontal cells. B horizontal cells and axon terminals do not appear to be engaged in any synapses apart from those with photoreceptors, while A horizontal cells make rare junctions with cone bipolars only. Interplexiform cell processes probably account for all the conventional chemical synapses in the outer plexiform layer of cat retina.     

Growth of postnatal rat retina in vitro. Development of neurotransmitter systems

In this study, we demonstrate that explanted neonatal rat retina can be maintained in culture for periods up to 3 weeks. The cultured retinas displayed a distinct layering that was almost identical to litter-matched retinas of the same age, but the majority of the ganglion cells did not survive and photoreceptor outer segments did not develop properly. Distinct synaptophysin immunoreactivity was expressed in both the inner and outer plexiform layers of cultured retina and the pattern mimicked that one observed in vivo. After 2-3 weeks in vitro, the inner retina expressed immunoreactivities to various components of the cholinergic and nitrergic transmitter systems, including nitric oxide activated cyclic GMP immunoreactivity. The investigated cell populations displayed similar distribution patterns as in situ, but morphological differences appeared in vitro. Such differences were mainly observed as irregularities in the arborization patterns in the inner part of the inner plexiform layer. We suggest that these discrepancies may arise as a result of reduced ganglion cell survival. Our observations demonstrate that some neurotransmitter systems develop in vitro and their neural circuitry appears similar to the in vivo situation. The presence of synapses, receptor proteins and transmitter substances implies that neural communication can occur in cultured retinas.     

Synaptophysin Expression in Rat Retina Following Acute High Intraocular Pressure

In response to injury, synapse alteration may occur earlier than the changes in the cell body of neurons. Although retinal ganglion cell death and thinning of the inner part of retina were found after acute high intraocular pressure (HIOP), the structural and functional changes of synapses in the retina remain unknown. In the present study, we investigated the protein and mRNA expression of synaptophysin (SYN), an important molecule closely related to synaptic activities, synaptogenesis and synaptic plasticity. In addition, we also studied the ultrastructural changes of the retinal synapses. We found that (1) synaptophysin was upregulated transiently at both protein and mRNA level following HIOP; (2) broadened distribution of synaptophysin protein was present within the outer nuclear layer at the early stage following HIOP; (3) in the outer nuclear layer bouton-like vesicle-containing structures were observed by electron microscopy. This data suggested that, besides degeneration, synapses in rat retina may undergo regenerative events following HIOP.     

Immunohistochemical localization of heat shock protein 27 in the retina of pigs

The expression of heat shock protein 27 (HSP27) was examined in the retinas of pigs. Western blot analysis detected the expression of HSP27 in the retinas of 1-day-old piglets and showed that it was enhanced in the retinas of 6-month-old adult pigs. Immunohistochemically, HSP27 immunostaining was seen mainly in ganglion cell bodies in the ganglion cell layer, and in some processes of astrocytes in the innermost nerve fiber layer. In 1-day-old piglets, HSP27 was detected weakly in the inner plexiform, inner nuclear cell, outer plexiform, and rod and cone layers. The HSP27 immunoreactivity across the retinal layers was enhanced in the retinas of 6-month-old pigs compared with newborn piglets. The HSP27 immunoreactivity in the radial processes of Müller cells was particularly prominent in adult pig retinas. In summary, this finding suggests that HSP27 plays an important role in signal transduction of glial cells and neuronal cells in the retina.     

Synaptic organization of type 2 catecholamine amacrine cells in the rhesus monkey retina

Summary Two types of amacrine cell immunoreactive for tyrosine hydroxylase, the rate-limiting enzyme in the catecholamine synthetic pathway, are present in the retina of the rhesus monkey,Macaca mulatta. The well-known dopaminergic, or type 1 catecholamine amacrine cells have relatively large cell bodies almost exclusively in the inner nuclear layer with processes that densely arborize in the outermost stratum of the inner plexiform layer and fine, radially-oriented fibres in the inner nuclear layer. Type 2 catecholamine amacrine cells, in contrast, have smaller cell bodies in the inner nuclear layer, the inner plexiform layer and the ganglion cell layer, and have sparsely-branching processes ramifying in the centre of the inner plexiform layer. Although type 2 catecholamine cells are more numerous than type 1 catecholamine amacrines, type 2 cells contain less than one-third the amount of tyrosine hydrolase as the type 1 cells. Electron microscopy of retinal tissue immunoreacted for tyrosine hydrolase by the peroxidase-antiperoxidase method revealed synaptic input from amacrine cells at conventional synapses, and bipolar cells at ribbon synapses onto the type 2 catecholamine amacrine cells. Curiously, although the synaptic input is comparatively easily found, the output synapses, or synapses of the type 2 catecholamine amacrine cells onto other neuronal elements, are rarely found. Some synapses of the type 2 catecholamine cells onto non-immunoreactive amacrine cells have been identified, however. This unusual pattern of synaptic organization, with many identifiable input synapses but few morphologically characterizable output synapses, suggests a paracrine function for the dopamine released by the type 2 catecholamine amacrine cells in the primate retina.     

Expression of Glutamate and GABA during the Process of Rat Retinal Synaptic Plasticity Induced by Acute High Intraocular Pressure

Acute high intraocular pressure (HIOP) can induce plastic changes of retinal synapses during which the expression of the presynaptic marker synaptophysin (SYN) has a distinct spatiotemporal pattern from the inner plexiform layer to the outer plexiform layer. We identified the types of neurotransmitters in the retina that participated in this process and determined the response of these neurotransmitters to HIOP induction. The model of acute HIOP was established by injecting normal saline into the anterior chamber of the rat eye. We found that the number of glutamate-positive cells increased successively from the inner part to the outer part of the retina (from the ganglion cell layer to the inner nuclear layer to the outer nuclear layer) after HIOP, which was similar to the spatiotemporal pattern of SYN expression (internally to externally) following HIOP. However, the distribution and intensity of GABA immunoreactivity in the retina did not change significantly at different survival time post injury and had no direct correlation with SYN expression. Our results suggested that the excitatory neurotransmitter glutamate might participate in the plastic process of retinal synapses following acute HIOP, but no evidence was found for the role of the inhibitory neurotransmitter GABA.     

惊厥对神经元缝隙连接蛋白基因表达的影响

神经元之间的缝隙连接蛋白Cx32是形成电突触的结构基础,电突触参与惊厥时神经元的同步化放电过程。为探讨惊厥对脑内神经元Cx32基因表达的影响,以遗传性癫痫易感大鼠P77PMC为模型,采用原位杂交的方法观察P77PMC大鼠听源性惊厥后脑内Cx32基因表达的变化。原位杂交结果显示：惊厥后在大脑皮层,海马脑区Cx32mRNA表达呈时间依赖性上调,惊厥后4h表达量明显增加,24h达高峰,结果提示：惊厥能上调神经元Cx32mRNA表达,从而可能使神经元之间的电突触联系增加,有利于神经元的同步化放电,加重惊厥的发生发展。     

Heterogeneity of endocytic proteins: distribution of clathrin adaptor proteins in neurons and glia

Clathrin adaptor protein (AP)180 is a synaptic protein that regulates the assembly of clathrin-coated vesicles. Several endocytic proteins including AP2, CALM, and epsin 1 have functions or molecular structures similar to AP180. We determined if AP180 associates with functional synapses in cultured hippocampal neurons. We also compared the expression pattern of AP180 with the other endocytic proteins. The distribution of AP180 corresponded with the synaptic vesicle-associated protein synapsin I, and with functional presynaptic terminals labeled with the styryl dye FM1-43. Synaptic AP2 colocalized with AP180, but the distribution of AP2 was not limited to synapses of neurons and it was also expressed in glia. CLAM and epsin 1 immunoreactivities were also detected in both neurons and glia. Unlike AP180, the neuronal immunoreactivity of CALM was not intense in the synaptic puncta. Epsin 1 immunoreactivity was found in both synaptic and extrasynaptic sites, and its synaptic distribution only partially overlapped with that of AP180.These results support roles for AP180 in synaptic function in neurons. The findings also provide information on the distribution of AP2, CALM, and epsin 1 in cells of the nervous system that suggest different roles for these endocytic proteins in the biology of these cells.     

Activity-related redistribution of presynaptic proteins at the active zone

Immunogold labeling distributions of seven presynaptic proteins were quantitatively analyzed under control conditions and after high K+ depolarization in excitatory synapses from dissociated rat hippocampal cultures. Three parallel zones in presynaptic terminals were sampled: zones I and II, each about one synaptic vesicle wide extending from the active zone; and zone III, containing a distal pool of vesicles up to 200 nm from the presynaptic membrane. The distributions of SV2 and synaptophysin, two synaptic vesicle integral membrane proteins, generally followed the distribution of synaptic vesicles, which were typically evenly distributed under control conditions and had a notable depletion in zone III after stimulation. Labels of synapsin I and synuclein, two synaptic vesicle-associated proteins, were similar to each other; both were particularly sparse in zone I under control conditions but showed a prominent enrichment toward the active zone, after stimulation. Labels of Bassoon, Piccolo and RIM 1, three active zone proteins, had very different distribution profiles from one another under control conditions. Bassoon was enriched in zone II, Piccolo and RIM 1 in zone I. After stimulation, Bassoon and Piccolo remained relatively unchanged, but RIM 1 redistributed with a significant decrease in zone I, and increases in zones II and III. These results demonstrate that Bassoon and Piccolo are stable components of the active zone while RIM 1, synapsin I and synuclein undergo dynamic redistribution with synaptic activity.