Early activation of Ca(2+)-permeable AMPA receptors reduces neurite outgrowth in embryonic chick retinal neurons.

Calcium entry through Ca(2+)-permeable AMPA/kainate receptors may activate signaling cascades controlling neuronal development. Using the fluorescent Ca(2+)-indicator Calcium Green 1-AM we showed that the application of kainate or AMPA produced an increase of intracellular [Ca(2+)] in embryonic chick retina from day 6 (E6) onwards. This Ca(2+) increase is due to entry through AMPA-preferring receptors, because it was blocked by the AMPA receptor antagonist GYKI 52466 but not by the N-methyl-D-aspartic acid (NMDA) receptor antagonist AP5, the voltage-gated Ca(2+) channel blockers diltiazem or nifedipine, or by the substitution of Na+ for choline in the extracellular solution to prevent the depolarizing action of kainate and AMPA. In dissociated E8 retinal cultures, application of glutamate, kainate, or AMPA reduced the number of neurites arising from these cells. The effect of kainate was prevented by the AMPA/kainate receptor antagonist CNQX and by GYKI 52466 but not by AP5, indicating that the reduction in neurite outgrowth resulted from the activation of AMPA receptors. Blocking Ca(2+) influx through L-type voltage-gated Ca(2+) channels with diltiazem and nifedipine prevented the effect of 10-100 microM kainate but not that of 500 microM kainate. In addition, joro spider toxin-3, a blocker of Ca(2+)-conducting AMPA receptors, prevented the effect of all doses of kainate. Neither GABA, which is depolarizing at this age in the retina, nor the activation of metabotropic glutamate receptors with tACPD mimicked the effects of AMPA receptor activation. Calcium entry via AMPA receptor channels themselves may therefore be important in the regulation of neurite outgrowth in developing chick retinal cells.

GABAb receptors regulate chick retinal calcium waves.

Correlated spiking activity and associated Ca(2+) waves in the developing retina are important in determining the connectivity of the visual system. Here, we show that GABA, via GABA(B) receptors, regulates the temporal characteristics of Ca(2+) waves occurring before synapse formation in the embryonic chick retina. Blocking ionotropic GABA receptors did no affect these Ca(2+) transients. However, when these receptors were blocked, GABA abolished the transients, as did the GABA(B) agonist baclofen. The action of baclofen was prevented by the GABA(B) antagonist p-3-aminopropyl-p-diethoxymethyl phosphoric acid (CGP35348). CGP35348 alone increased the duration of the transients, showing that GABA(B) receptors are tonically activated by endogenous GABA. Blocking the GABA transporter GAT-1 with 1-(4,4-diphenyl-3-butenyl)-3-piperidine carboxylic acid (SKF89976A) reduced the frequency of the transients. This reduction was prevented by CGP35348 and thus resulted from activation of GABA(B) receptors by an increase in external [GABA]. The effect of GABA(B) receptor activation persisted in the presence of activators and blockers of the cAMP-PKA pathway. Immunocytochemistry showed GABA(B) receptors and GAT-1 transporters on ganglion and amacrine cells from the earliest times when Ca(2+) waves occur (embryonic day 8). Patch-clamp recordings showed that K(+) channels on ganglion cell layer neurons are not modulated by GABA(B) receptors, whereas Ca(2+) channels are; however, Ca(2+) channel blockade with omega-conotoxin-GVIA or nimodipine did not prevent Ca(2+) waves. Thus, the regulation of Ca(2+) waves by GABA(B) receptors occurs independently of N- and L-type Ca(2+) channels and does not involve K(+) channels of the ganglion cell layer. GABA(B) receptors are likely to be of key importance in regulating retinal development.

Use of pIRES vectors to express EGFP and connexin constructs in studies of the role of gap junctional communication in the early development of the chick retina and brain.

Control of cell proliferation is vital for the normal development of the neural retina. Gap junctional communication has been implicated in the control of retinal cell proliferation. We have previously shown that the expression of the gap junction protein Connexin 43 closely correlates with the first wave of cell proliferation in the retina. Preventing its expression using antisense oligonucleotides in the developing eye and surrounding tissues, produces a reduction in cell number and the formation of a small eye. In order to examine this in more detail we have developed a new means of manipulating connexin expression in the developing chick embryo. We have generated pIRES vectors which use cyclomegalovirus (CMV) to promote the expression of a green fluorescent protein (EGFP) and either wild type Cx43 or a dominant negative form ofthis connexin. Following injection ofthese constructs into the ventricles ofthe stage 10-11 chick embryo they can be incorporated into one side of the chick brain or optic vesicle using an electroporation technique, leaving the other side as a control. EGFP expression can be seen on the electroporated side of the chick brain within 24 hours. Expression of the dominant negative construct in cultures of chick limb bud mesenchyme results in total block of cascade blue transfer when injected into transfected cells. Expression of both wild type and dominant negative constructs in the developing chick retina perturbs the normal development of the eye.

Spontaneous Ca2+ transients and their transmission in the developing chick retina.

The development of the central nervous system is dependent on spontaneous action potentials and changes in [Ca2+]i occurring in neurons [1-4]. In the mammalian retina, waves of spontaneous electrical activity spread between retinal neurons, raising [Ca2+]i as they pass [5-7]. In the ferret retina, the first spontaneous Ca2+ waves have been reported at postnatal day 2 and are thought to result from the Ca2+ influx associated with bursts of action potentials seen in ganglion cells at this time [5-7]. These waves depend on depolarisation produced by voltage-gated sodium channels, but their initiation and/or propagation also depends upon nicotinic cholinergic synaptic transmission between amacrine cells and ganglion cells [8]. Here, we report contrasting results for the chick retina where Ca2+ transients are seen at times before retinal synapse formation but when there are extensive networks of gap junctions. These Ca2+ transients do not require nicotinic cholinergic transmission but are modulated by acetylcholine (ACh), dopamine and glycine. Furthermore, they propagate into the depth of the retina, suggesting that they are not restricted to ganglion and amacrine cells. The transients are abolished by the gap-junctional blocker octanol. Thus, the Ca2+ transients seen early in chick retinal development are triggered and propagate in the absence of synapses by a mechanism that involves several neurotransmitters and gap junctions.

Developmental expression and self-regulation of Ca2+ entry via AMPA/KA receptors in the embryonic chick retina.

Excessive activation of glutamate receptors in the late embryonic and adult retina leads to excitotoxic cell death through an increase in intracellular calcium concentration. Here we use the cobalt-staining technique of Pruss et al. to investigate the developmental expression of Ca(2+)-permeable alpha-amino-3-hydroxy-5-methyl-isoxazole-4-propionic acid/kainate (AMPA/KA) receptors in the embryonic chick retina, and the effects of AMPA/KA receptor activation on cell survival and AMPA/KA receptor expression. Ca(2+)-permeable AMPA/KA receptors are present in the retina as early as embryonic day 6 (E6). While sustained activation of these receptors with KA led to massive cell death in explant and dissociated cultures of the chick retina late in development, continuous application of high doses of KA from early times was not excitotoxic. Cell survival in KA is correlated with both a reduction in cobalt staining and the KA-evoked membrane current, and thus with a reduction in the Ca2+ entry into cells via AMPA/KA receptors. The effects of KA could be blocked by the non-N-methyl-D-aspartic acid (NMDA) receptor antagonist 6-cyano-7-nitro-quinoxaline-2,3-dione (CNQX), but not by the NMDA receptor antagonist D-2-amino-5-phosphonovalerate (AP5) nor the L-type Ca2+ channel blockers diltiazem and nifedipine. The action of AP5 was mimicked by exposure to glutamate but not by the metabotropic receptor agonist 1S,3R-1-aminocyclopentane-1,3-dicarboxylic acid. Thus exposure of retinal neurons to glutamate early in development may protect them from its excitotoxic actions later on.

The phosphoprotein stathmin is essential for nerve growth factor-stimulated differentiation.

Stathmin is a ubiquitous cytosolic protein which undergoes extensive phosphorylation in response to a variety of external signals. It is highly abundant in developing neurons. The use of antisense oligonucleotides which selectively block stathmin expression has allowed us to study directly its role in rat PC12 cells. We show that stathmin depletion prevents nerve growth factor (NGF)-stimulated differentiation of PC12 cells into sympathetic-like neurons although the expression of several NGF-inducible genes was not affected. Furthermore, we found that stathmin phosphorylation in PC12 cells which is induced by NGF depends on mitogen-activated protein kinase (MAPK) activity. We conclude that stathmin is an essential component of the NGF-induced MAPK signaling pathway and performs a key role during differentiation of developing neurons.

Antisense Blockade of Expression : SNAP-25 In Vitro and In Vivo.

With the advent of modern molecular genetics and molecular biology, we will face more and more situations where novel gene products with unknown functions are identified. Genetic linkage analysis will allow the association of novel or known genes to Important diseases (1). Similarly, sensitlve differential cloning procedures will identify rare genes expressed in specific physiological or pathological situations (1, 3). In both cases, establishing the precise function of the identified gene is an essential step for the understanding of the cellular mechanisms that either lead to the disease or are pivotal in important physiological processes.

Retinal development. Waves are swell.

Waves of spontaneous electrical activity and calcium transients occur in the retina during its development. Recent work raises the question of how these waves are produced and propagated.

Inhibition of axonal growth by SNAP-25 antisense oligonucleotides in vitro and in vivo.

Axonal elongation and the transformation of growth cones to synaptic terminals are major steps of brain development and the molecular mechanisms involved form the basis of the correct wiring of the nervous system. The same mechanisms may also contribute to the remodelling of nerve terminals that occurs in the adult brain, as a morphological substrate to memory and learning. We have investigated the function of the nerve terminal protein SNAP-25 (ref. 2) during development. We report here that SNAP-25 is expressed in axonal growth cones during late stages of elongation and that selective inhibition of SNAP-25 expression prevents neurite elongation by rat cortical neurons and PC-12 cells in vitro and by amacrine cells of the developing chick retina in vivo. These results demonstrate that SNAP-25 plays a key role in axonal growth. They also suggest that high levels of SNAP-25 expression in specific areas of the adult brain may contribute to nerve terminal plasticity.

Rapid onset of neuronal death induced by blockade of either axoplasmic transport or action potentials in afferent fibers during brain development.

We have investigated how neurons in the optic tecta of embryonic day 16 chick embryos depend for survival on their afferents from the retina. To distinguish between activity-mediated effects and other, "trophic," ones, we compared the effects on the tectal neurons of blocking intraocular axoplasmic transport (with colchicine) or action potentials (by means of TTX). Both interventions rapidly induced the appearance of dying (pyknotic) neurons in the tectum, with major increases in their number occurring within 13 hr post-colchicine and within 9 hr post-TTX. Following both drugs, the dying neurons were morphologically similar, and in both cases the cell death depended on protein synthesis. However, the effects of colchicine and of TTX could be dissociated, since the most superficial tectal neurons became pyknotic only in response to colchicine, and, with a sufficiently short survival time (9 hr), the deep cells of the stratum griseum centrale became pyknotic only in response to TTX. We hence argue that the survival of the tectal neurons depends on their ongoing maintenance by substances released from retinotectal axon terminals, the release being activity dependent in the case of the deep neurons but independent of activity in the case of the superficial ones.

Differential expression of the presynaptic protein SNAP-25 in mammalian retina.

We have studied the expression of the nerve terminal protein synaptosomal associated protein 25 (SNAP-25) in the retina of adult rat, mouse, and monkey, as well as in the developing mouse retina. To evaluate SNAP-25 expression, its distribution was compared to those of the synaptic vesicle-associated proteins synapsin I and synaptophysin. In situ hybridization in adult rat retinas suggested that SNAP-25 mRNA is mainly expressed by ganglion, amacrine, and horizontal cells, but not by photoreceptors and bipolar cells. In all species, the SNAP-25 polypeptide was most abundant in the inner part of the inner and outer plexiform layers and was also found in the ganglion cell axons. In adult retina, synapsin I and synaptophysin were also mainly localized in synaptic fields and processes but all three proteins showed a distinct pattern of distribution. Finally, in mouse retina, the three proteins were first detectable at embryonic day 16 and subsequently showed developmentally regulated changes in their cellular localization. These results suggest that SNAP-25 is predominantly expressed in specific subtypes of conventional synapses, but not ribbon synapses, and that it may also be involved in the physiology of nonvesicular terminals of horizontal cells. Our study also suggests that combinatorial expression of different components of the presynaptic specialization may contribute to synaptic functional diversity.

Long-distance intraretinal connections in birds.

Electrophysiological experiments have shown in both birds and mammals that remote parts of the retina, several millimetres apart, interact at the retinal level. The anatomical basis of this is poorly understood, although in mammals some cells in the ganglion cell layer have axons that terminate in the inner plexiform layer several millimetres from the cell body. In birds, the longest previously reported intraretinal connections were from amacrine cells, extending only a few hundred microns. But we here describe very long connections that span almost the entire extent of the retina in chicks and chick embryos. The parent cell bodies are in the inner nuclear layer of the ventral half of the retina, and they project in topographical order onto the dorsal half. They do not project to the brain. They may be involved in selective switching of attention between the upper and lower parts of the visual field, at an unprecedentedly early stage of visual processing.