Green fluorescent protein as a quantitative tool.

Manipulating the expression of a protein can provide a powerful tool for understanding its function, provided that the protein is expressed at physiologically-significant concentrations. We have developed a simple method to measure (1) the concentration of an overexpressed protein in single cells and (2) the covariation of particular physiological properties with a protein's expression. As an example of how this method can be used, teratocarcinoma cells were transfected with the neuron-specific calcium binding protein calretinin (CR) tagged with green fluorescent protein (GFP). By measuring GFP fluorescence in microcapillaries, we created a standard curve for GFP fluorescence that permitted quantification of CR concentrations in individual cells. Fura-2 measurements in the same cells showed a strong positive correlation between CR-GFP fusion protein expression levels and calcium clearance capacity. This method should allow reliable quantitative analysis of GFP fusion protein expression.

Developmental changes in the subcellular localization of calretinin.

Brainstem auditory neurons in the chick nucleus magnocellularis (NM) express high levels of the neuron-specific calcium-binding protein calretinin (CR). CR has heretofore been considered a diffusible calcium buffer that is dispersed uniformly throughout the cytosol. Using high-resolution confocal microscopy and complementary biochemical analyses, we have found that during the development of NM neurons, CR changes from being expressed diffusely at low concentrations to being highly concentrated beneath the plasma membrane. This shift in CR localization occurs at the same time as the onset of spontaneous activity, synaptic transmission, and synapse refinement in NM. In the chick brainstem auditory pathway, this subcellular localization appears to occur only in NM neurons and only with respect to CR, because calmodulin remains diffusely expressed in NM. Biochemical analyses show the association of calretinin with the membrane is detergent-soluble and calcium-independent. Because these are highly active neurons with a large number of Ca2+-permeable synaptic AMPA receptors, we hypothesize that localization of CR beneath the plasma membrane is an adaptation to spatially restrict the calcium influxes.

Stimulus history alters behavioral responses of neuronal growth cones.

Generally, it is assumed that growth cones respond to a specific guidance cue with a single, specific, and stereotyped behavior. However, there is evidence to suggest that previous exposure to a given cue might alter subsequent responses to that cue (Snow and Letourneau, 1992; Shirasaki et al., 1998). We therefore tested the hypothesis that growth cone responses to stimuli are dependent on the history of previous stimulation. Growth cones of chick dorsal root ganglion neurons were exposed to well characterized stimuli: (1) contact with a laminin-coated bead, which causes growth cone turning, or (2) electrical stimulation, which causes growth cone collapse. Although the expected behavioral responses were observed after the initial stimulation, strikingly different responses to a subsequent stimulation were observed. Growth cones that had recovered from electrical stimulation-induced collapse rapidly developed insensitivity to a second identical electrical stimulation. Growth cones that previously turned in response to contact with a laminin-coated bead responded to a second bead with a "stall" or cessation in outgrowth. This stimulus history dependence of growth cone behavior could be generalized across dissimilar stimuli: after contact with a laminin-coated bead, growth cones failed to collapse in response to electrical stimulation. The calcium/calmodulin-dependent protein kinase II (CaMKII) was implicated in this history dependence by pharmacological experiments. Together, these results demonstrate that growth cones can alter their behavioral response rapidly to a given stimulus in a manner dependent on previous history and that knowledge of past events in growth cone navigation may be required to predict future growth cone behavior.

Membrane recycling in the neuronal growth cone revealed by FM1-43 labeling.

Membrane dynamics within the chick ciliary neuronal growth cone were investigated by using the membrane-impermeant dye FM1-43. A depolarization-evoked endocytosis was observed that shared many properties with the synaptic vesicle recycling previously described at the presynaptic terminal. In addition, in the absence of depolarization a basal level of constitutive endocytotic activity was observed at approximately 30% of the rate of evoked endocytosis. This constitutive endocytosis accounted for large amounts of membrane retrieval: the equivalent of the entire growth cone surface area could be internalized within a 30 min period. Endosomes generated via constitutive and evoked processes were highly mobile and could move considerable distances both within the growth cone and out to the neurite. In addition to their different requirements for formation, evoked and constitutive endosomes displayed a significant difference in release properties. After a subsequent depolarization of labeled growth cones, evoked endosomes were released although constitutive endosomes were not released. Furthermore, treatment with latrotoxin released evoked endosomes, but not constitutive endosomes. Although the properties of evoked endosomes are highly reminiscent of synaptic vesicles, constitutive endosomes appear to be a separate pool resulting from a distinct and highly active process within the neuronal growth cone.

Calcium-dependent alterations in dendritic architecture of hippocampal pyramidal neurons.

Dendritic arbor formation and the underlying mechanisms are crucial for the functional connectivity and plasticity of neurons. We used a focal electric field to locally raise calcium levels in individual dendritic shafts of isolated hippocampal pyramidal neurons, in order to develop an accessible system for studying dendritic branch formation, and to test the role of calcium as an intrinsic signal that may participate in arborization. Filopodia were induced in a manner temporally and spatially related to induced calcium rises. Certain filopodia also thickened and were transformed into dendritic branches. These results suggest that calcium-mediated signaling can induce branching in dendrites, and describe an accessible system for studying the intracellular machinery that drives dendritic arborization.

ATP released from astrocytes mediates glial calcium waves.

Calcium waves represent a widespread form of intercellular communication. Although they have been thought for a long time to require gap junctions, we recently demonstrated that mouse cortical astrocytes use an extracellular messenger for calcium wave propagation. The present experiments identify ATP as a major extracellular messenger in this system. Medium collected from astrocyte cultures during (but not before) calcium wave stimulation contains ATP. The excitatory effects of medium samples and of ATP are blocked by purinergic receptor antagonists and by pretreatment with apyrase; these same purinergic receptor antagonists block propagation of electrically evoked calcium waves. ATP, applied at the concentration measured in medium samples, evokes responses that are qualitatively and quantitatively similar to those evoked by those medium samples. These data implicate ATP as an important transmitter between CNS astrocytes.

Prolonged cytosolic calcium elevations in growth cones contacting muscle.

Encounters by growth cones or neurites of motor neurons with target muscle cells evoke prolonged elevations in the concentrations of neuronal cytosolic free calcium ([Ca(2+)](c)). These calcium elevations are initiated at the point of contact and spread throughout the neuron over a period of tens of minutes. In this study, we addressed how target muscle cells initiate this unique presynaptic response. Primary questions regarding the nature of the muscle signal are whether it is diffusible and whether it must first be induced by a growth cone as part of reciprocal interaction. We addressed whether the signal was strictly target-contact dependent by fixing C2 mouse myotubes with formaldehyde, rinsing extensively and then allowing processes of chick ciliary ganglion neurons to interact with them. We observed frequent sustained elevations in [Ca(2+)](c) in ciliary ganglion processes contacting the fixed myotubes. As a control, ciliary neurons were allowed to interact with fixed myotubes of the S27 variant line. S27 cells were isolated from the parent C2 line on the basis of a defect in glycosaminoglycan biosynthesis and previously shown to be defective in supporting synaptic vesicle localization in contacting neurites. Few elevations in [Ca(2+)](c) were detected in encounters between ciliary processes and fixed S27 cells. In addition, neuron-neuron encounters never elicited prolonged increases in [Ca(2+)](c). These observations demonstrate contact dependence in the neuronal response and rule out reciprocal cellular interactions, diffusible factors or electrical activity in the muscle. The defect in carbohydrate biosynthesis in S27 cells further suggests that cell surface carbohydrates are essential to the signal on the myotube surface that triggers the presynaptic elevation in [Ca(2+)](c). We conclude that growth cone contact with preexisting cell surface structures on target muscle cells induces changes in presynaptic [Ca(2+)](c) that are associated with retrograde signaling, and that proper carbohydrate biosynthesis is required for this signal.

Unique responses of differentiating neuronal growth cones to inhibitory cues presented by oligodendrocytes.

During central nervous system development, neurons differentiate distinct axonal and dendritic processes whose outgrowth is influenced by environmental cues. Given the known intrinsic differences between axons and dendrites and that little is known about the response of dendrites to inhibitory cues, we tested the hypothesis that outgrowth of differentiating axons and dendrites of hippocampal neurons is differentially influenced by inhibitory environmental cues. A sensitive growth cone behavior assay was used to assess responses of differentiating axonal and dendritic growth cones to oligodendrocytes and oligodendrocyte- derived, myelin-associated glycoprotein (MAG). We report that >90% of axonal growth cones collapsed after contact with oligodendrocytes. None of the encounters between differentiating, MAP-2 positive dendritic growth cones and oligodendrocytes resulted in growth cone collapse. The insensitivity of differentiating dendritic growth cones appears to be acquired since they develop from minor processes whose growth cones are inhibited (nearly 70% collapse) by contact with oligodendrocytes. Recombinant MAG(rMAG)-coated beads caused collapse of 72% of axonal growth cones but only 29% of differentiating dendritic growth cones. Unlike their response to contact with oligodendrocytes, few growth cones of minor processes were inhibited by rMAG-coated beads (20% collapsed). These results reveal the capability of differentiating growth cones of the same neuron to partition the complex molecular terrain they navigate by generating unique responses to particular inhibitory environmental cues.

Inhibitory neuronal activity can compensate for adverse effects of beta-amyloid in hippocampal neurons.

One of the most prominent effects of Alzheimer disease is the disruption of finely tuned neuronal circuitry of discrete brain regions associated with learning and memory. Results from the present study support a role for the intrinsic inhibitory component of neuronal circuitry in determining the magnitude of beta-amyloid peptide induced cell death in the highly vulnerable pyramidal neurons of the hippocampus. Previous efforts have mostly focused on direct effects on excitatory neurons. By contrast, less emphasis has been placed on addressing a role for the intrinsic inhibitory component of cell-cell interactions of neuronal networks in response to Abeta. The present study provides evidence demonstrating that blockage of the intrinsic inhibitory component between Abeta exposed neurons leads to destabilization of calcium homeostasis and exacerbated neuronal death compared to Abeta treated cultures. Neuronal electrical activity was first silenced by exposing cultures to tetrodotoxin (TTX; 100 nM) plus Abeta, followed by survival counts. Cell death, unexpectedly, did not significantly differ from Abeta-exposed neurons. The intrinsic inhibition in Abeta-exposed cultures was then pharmacologically removed with picrotoxin (40 microM) or bicuculline (25 microM) resulting in significantly greater death than Abeta-exposed neurons alone. From these observations, it is proposed that intrinsic functional inhibition in hippocampal circuits can reduce adverse effects of Abeta on the excitatory component. By considering not just the excitatory component of electrical activity, but the intrinsic balance between excitation and inhibition, new strategies for the treatment of Alzheimer disease may emerge.

Laminin directs growth cone navigation via two temporally and functionally distinct calcium signals.

During development, growth cones navigate to their targets via numerous interactions with molecular guidance cues, yet the mechanisms of how growth cones translate guidance information into navigational decisions are poorly understood. We have examined the role of intracellular Ca2+ in laminin (LN)-mediated growth cone navigation in vitro, using chick dorsal root ganglion neurons. Subsequent to contacting LN-coated beads with filopodia, growth cones displayed a series of stereotypic changes in behavior, including turning toward LN-coated beads and a phase of increased rates of outgrowth after a pause at LN-coated beads. A pharmacological approach indicated that LN-mediated growth cone turning required an influx of extracellular Ca2+, likely in filopodia with LN contact, and activation of calmodulin (CaM). Surprisingly, fluorescent Ca2+ imaging revealed no LN-induced rise in intracellular Ca2+ in filopodia attached to their parent growth cone. However, isolation of filopodia by laser-assisted transection unmasked a rapid, LN-specific rise in intracellular Ca2+ (+73 +/- 11 nM). Additionally, a second, sustained rise in intracellular Ca2+ (+62 +/- 8 nM) occurred in growth cones, with a distinct delay 28 +/- 3 min after growth cone filopodia contacted LN-coated beads. This delayed, sustained Ca2+ signal paralleled the phase of increased rates of outgrowth, and both events were sensitive to the inhibition of Ca2+/CaM-dependent protein kinase II (CaM-kinase II) with 2 microM KN-62. We propose that LN-mediated growth cone guidance can be attributed, in part, to two temporally and functionally distinct Ca2+ signals linked by a signaling cascade composed of CaM and CaM-kinase II.

Retinal axon growth cone responses to different environmental cues are mediated by different second-messenger systems.

Numerous studies have shown that the developing tip of a neurite, the growth cone, can respond to environmental cues with behaviors such as guidance or collapse. To assess whether a given cell type can use more than one second-messenger pathway for a single behavior, we compared the influence of two well-characterized guidance cues on growth cones of chick temporal retinal ganglion cells. The first cue was the repulsive activity derived from the posterior optic tectum (p-membranes), and the second was the collapse-inducing activity derived from oligodendrocytes known as NI35/NI250. p-Membranes caused permanent growth cone collapse with no recovery after several hours, while NI35 caused transient collapse followed by recovery after about 10 min. The p-membrane-induced collapse was found to be Ca2+ independent, as shown using the Ca2+-sensitive dye Fura-2 and by the persistence of collapse in Ca2+-free medium. Dantrolene, a blocker of the ryanodine receptor, had only a minor effect on the collapse frequency caused by p-membranes. In contrast, the NI35-induced collapse was clearly Ca2+ dependent. [Ca2+]i increased sevenfold preceding collapse, and both dantrolene and antibodies against NI35 significantly reduced both the Ca2+ increase and the collapse frequency. Thus, even in a single cell type, growth cone collapse induced by two different signals can be mediated by two different second-messenger systems.

Afferent innervation influences the development of dendritic branches and spines via both activity-dependent and non-activity-dependent mechanisms.

The present investigation uses an in vitro co-culture system to study the role of afferent innervation in early development and differentiation of hippocampal neurons. Our experiments indicate that the formation of two key morphological features, dendritic branches and dendritic spines, is induced by afferent innervation. Hippocampal neurons develop multiple dendritic branches and spines only when extensively innervated by living axonal afferents. No morphological changes occurred when hippocampal neurons were plated on other cell surfaces such as fixed axons or astrocytes. Furthermore, afferents exerted their effect locally on individual dendrites that they contacted. When one portion of the dendritic arbor of a neuron was contacted by afferents and the other portion was not, morphological effects were restricted to the innervated dendrites. Innervation of some of the dendrites on a neuron did not produce global effects throughout the neuron. Afferent-induced dendritic branching is independent of activity, since branch induction was unaffected by chronic application of TTX or glutamate receptor blockers. In contrast, the formation of dendritic spines is influenced by activity. The number of developing spines was reduced when TTX or a cocktail of three glutamate receptor blockers was applied. Blockade of individual AMPA, NMDA, or metabotropic glutamate receptors did not affect the number of spines. These results, taken together, demonstrate that afferents can have a prominent influence on the development of postsynaptic target cells via both activity-dependent and non-activity-dependent mechanisms, indicating the presence of multiple signals. Accordingly, this suggests an important interplay between pre- and postsynaptic elements early in development.

Myelin-associated glycoprotein inhibits neurite/axon growth and causes growth cone collapse.

We have previously shown that myelin-associated glycoprotein (MAG) inhibits neurite growth from a neuronal cell line. In this study we show that 60% of axonal growth cones of postnatal day 1 hippocampal neurons collapsed when they encountered polystyrene beads coated with recombinant MAG (rMAG). Such collapse was not observed with denatured rMAG. Neurite growth from rat embryonic hippocampal and neonatal cerebellar neurons was also inhibited about 80% on tissue culture substrates coated with rMAG. To investigate further the inhibitory activity of MAG in myelin, we purified myelin from MAG-deficient mice and separated octylglucoside extracts of myelin by diethylaminoethyl (DEAE) ion-exchange chromatography. Although there was no significant difference in neurite growth on myelin purified from MAG-/- and MAG+/+ mice, differences were observed in the fractionated material. The major inhibitory peak that is associated with MAG in normal mice was significantly reduced in MAG-deficient mice. These results suggest that although MAG contributes significantly to axon growth inhibition associated with myelin, its lack in MAG-deficient mice is masked by other non-MAG inhibitors. Axon regeneration in these mice was also examined after thoracic lesions of the corticospinal tracts. A very small number of anterogradely labeled axons extended up to 13.2 mm past the lesion in MAG-/- mice. Although there is some enhancement of axon generation, the poor growth after spinal cord injury in MAG-/- mice may be due to the presence of other non-MAG inhibitors. The in vitro studies, however, provide the first evidence that MAG modulates growth cone behavior and inhibits neurite growth by causing growth cone collapse.

An extracellular signaling component in propagation of astrocytic calcium waves.

Focally evoked calcium waves in astrocyte cultures have been thought to propagate by gap-junction-mediated intercellular passage of chemical signal(s). In contrast to this mechanism we observed isolated astrocytes, which had no physical contact with other astrocytes in the culture, participating in a calcium wave. This observation requires an extracellular route of astrocyte signaling. To directly test for extracellular signaling we made cell-free lanes 10-300 microns wide in confluent cultures by deleting astrocytes with a glass pipette. After 4-8 hr of recovery, regions of confluent astrocytes separated by lanes devoid of cells were easily located. Electrical stimulation was used to initiate calcium waves. Waves crossed narrow (< 120 microns) cell-free lanes in 15 of 36 cases, but failed to cross lanes wider than 120 microns in eight of eight cases. The probability of crossing narrow lanes was not correlated with the distance from the stimulation site, suggesting that cells along the path of the calcium wave release the extracellular messenger(s). Calculated velocity across the acellular lanes was not significantly different from velocity through regions of confluent astrocytes. Focal superfusion altered both the extent and the direction of calcium waves in confluent regions. These data indicate that extracellular signals may play a role in astrocyte-astrocyte communication in situ.

Transient elevations in intracellular calcium are sufficient to induce sustained responsiveness to the neurotrophic factor bFGF.

The present study investigates how a neuron's past history of neural activity may alter its responsiveness to subsequent signals. We demonstrate that a depolarizing pulse of extracellular potassium can prime neurons to become responsive to basic fibroblast growth factor (bFGF), even when the pulse is brief and occurs prior to addition of bFGF. Specifically, we subjected cultured embryonic chick ciliary ganglion neurons (E7) to a short pulse of elevated extracellular potassium followed by addition of bFGF and tested the effect of such treatment on neuronal survival. Neurons treated in this manner produced high levels of survival, whereas neurons exposed to either the pulse alone or the continuous presence of bFGF alone failed to promote any significant levels of survival. This priming effect of depolarization on bFGF-induced survival was blocked by calcium channel antagonists. To test the time dependency of this effect, we increased the time interval between termination of the calcium pulse and addition of bFGF. Our results demonstrate that a brief elevation in intracellular calcium has long lasting effects, up to 8 h after cessation of the depolarizing pulse, on neuronal responsiveness to bFGF. These findings suggest how a developing neuron's history of activity can alter its subsequent ability to respond to neurotrophic factors and has significant implications on the mechanisms by which activity may influence neuronal survival.

Spatial gradients of cytosolic calcium concentration in neurones during paradoxical activation by calcium.

4-Br-A23187 caused a calcium influx into chick sensory neurones and raised cytosolic calcium from a rest level of 97 +/- 7 nM to a peak of 296 +/- 30 nM. Despite the continued presence of ionophore, however, cytosolic calcium concentrations then fell. After 30 min in ionophore, cytosolic calcium concentration had returned to 105 +/- 5 nM, not significantly different from the value before ionophore addition. The permeability of the plasmalemma to divalent cations, as estimated by the manganese quench technique, was no lower at 30 min than at the peak of the cytosolic calcium transient. Thus the fall of calcium from its peak was not due to a slowing of calcium influx, but was due to an upregulation of mechanisms that remove calcium from the cytosol- an upregulation that persists even though cytosolic calcium has apparently returned to pre-stimulus levels. We used a novel fixed slit confocal microscope to examine the calcium concentration profile close to the plasmalemma. We found that after 25-30 min ionophore treatment, calcium concentration was elevated only in the cytoplasm within 1 micron of the plasmalemma. A maintained, elevated calcium under the plasmalemma can help explain the phenomenon of paradoxical activation seen in this and other cell types.

Distinct calcium signaling within neuronal growth cones and filopodia.

Previous findings indicate that spatial restriction of intracellular calcium levels within growth cones can regulate growth cone behavior at many levels, ranging from filopodial disposition to neurite extension. By combining techniques for focal stimulation of growth cones with those for measurement of filopodia and for capturing low intensity calcium signals, we demonstrate that filopodia on individual growth cones can respond to imposed stimuli independently from one another. Moreover, filopodia and their parent growth cones appear to represent functionally and morphologically distinct domains of calcium regulation, possessing distinct calcium sources and sinks. Both are sensitive to calcium influx; however, application of the calcium ionophore A23187 to cells in calcium-free medium demonstrated the presence of potential intracellular calcium pools in the growth cone proper, but not in isolated filopodia. Thapsigargin significantly reduced the rise in growth cone calcium levels associated with excitatory neurotransmitters, further implicating release from calcium pools as one component of growth cone calcium regulation. The relative contributions of these pools were examined in response to excitatory neurotransmitters by quantitative calcium measurements made in both growth cones and isolated filopodia. Striking differences were observed; filopodia were sensitive to a low concentration of dopamine and serotonin, while growth cones displayed an amplified rise at a higher concentration. The spatial distribution of organelles that could serve as morphological correlates to such calcium amplification was examined using confocal microscopy. While the majority of organelles were located in the central core of the growth cone proper, peripheral organelles were detected at the base of a subset of filopodia. The distinctive distribution of calcium regulation within motile growth cones suggests one mechanism by which growth cones may regulate their complex behavior.

Transfected parvalbumin alters calcium homeostasis in teratocarcinoma PCC7 cells.

Indirect evidence supports a protective role of some EF-hand calcium-binding proteins against calcium-induced neurotoxicity. Little is known about how these proteins influence cytosolic calcium levels. After cloning the parvalbumin cDNA into an expression vector, teratocarcinoma cells (PCC7) were transfected. Parvalbumin-transfected and mock-transfected cells were loaded with the calcium indicator fura-2 and were exposed, in the same dish, to different concentrations of the calcium ionophore A23187 or to KCI. The results show that parvalbumin-transfected PCC7 cells had much better calcium buffering capacity than control cells.

Functional compartmentalization of the neuronal growth cone: determining calcium's place in signaling cascades.

The growth cone is generally regarded as the basic unit of neuronal organization concerned with development of connections within the nervous system. The discussion below illustrates that the growth cone itself can be subdivided into distinct units of organization. It is this functional compartmentalization which enables the growth cone to read the molecular terrain it traverses and to convert this information into precise motor events. Our discussion will focus on the flow of information from the environment to the growth cone. In particular, we will follow signaling events from their remote processing within filopodia to the biological equivalent of a central processing unit in the core of the growth cone.

Evidence for glutamate-mediated activation of hippocampal neurons by glial calcium waves.

Communication from astrocytes to neurons has recently been reported by two laboratories, but different mechanisms were though to underlie glial calcium wave activation of associated neurons. Neuronal calcium elevation by glia observed in the present report is similar to that reported previously, where an increase in neuronal calcium was demonstrated in response to glial stimulation. In the present study hippocampal neurons plated on a confluent glial monolayer displayed a transient increase in intracellular calcium following a short delay after the passage of a wave of increased calcium in underlying glia. Activated cells displayed action potentials in response to glial waves and showed antineurofilament immunoreactivity. Finally, the N-methyl-D-aspartate glutamate receptor antagonist DL-2-amino-5-phosphonovaleric acid and the non-NMDA glutamate receptor antagonist 6,7-dinitroquinoxaline-2,3-dione significantly reduced the responsiveness of neurons to glial calcium waves. Our results indicate that hippocampal neurons growing on hippocampal or cortical astrocytes respond to glial calcium waves with elevations in calcium and increased electrical activity. Furthermore, we show that in most cases this communication appears to be mediated by ionotropic glutamate receptor channels.