Glutamate sensing with enzyme-modified floating-gate field effect transistors.

Neurotransmitter release is the key factor of chemical messaging in the brain. Fast, sensitive and in situ detection of single cell neurotransmitter release is essential for the investigation of synaptic transmission under physiological or pathophysiological conditions. Although various techniques have been developed for detecting neurotransmitter release both in vitro and in vivo, the sensing of such events still remains challenging. First of all, the amount of neurotransmitter released during synaptic transmission is unknown because of the limited number of molecules released and the fast diffusion and reuptake of these molecules after release. On the other hand, advances in microelectronic biosensor devices have made possible the fast detection of various analytes with high sensitivity and selectivity. Specifically, enzyme-modified field-effect (ENFET) devices are attractive for such applications due to their fast response, small dimensions and the possibility to integrate a large number of sensors on the same chip. In this paper, we present a floating-gate FET device coated with glutamate oxidase (GLOD) layer. The surface chemistry was optimized for maximal enzyme loading and long-term stability, and characterized by quartz crystal microbalance and colorimetric assays. Enzyme loading was largest on poly-L-lysin-based surfaces combined with glutaraldehyde. The surface chemistry showed excellent stability for at least one month in Tris buffers stored at 4 degrees C. A glutamate detection limit of 10(-7) M has been obtained with the GLOD-coated FET and our sensor proved to be selective to glutamate only. We show that this biosensor is a promising tool for the in vitro detection of glutamate and can be extended to other neurotransmitters.

Electrically conductive 2D-PAN-containing surfaces as a culturing substrate for neurons.

In the present contribution we report on a novel route to synthesize 2D-polyaniline (2D-PAN) on sulfonated-poly(styrene) (SPS) templates by allowing first monomer assembly followed by chemical oxidation to achieve polymerization. We show that Aplysia neurons grown on 2D-PAN exhibit an unusual growth pattern and adhesion to this conducting substrate that is manifested by the formation of giant lamellipodia. The lamellipodial domains are characterized by small gap between the plasma membrane and the 2D-PAN substrate (ca. 30 nm) and actin rich skeleton resembling the skeleton of growth cones. This behavior is characteristic to uniform substrates containing only 2D-PAN. However, in patterned substrates containing additionally poly(L-lysine) Aplysia neurons prefer to extend new neurites on the poly(L-lysine) domains.

Calcium, protease activation, and cytoskeleton remodeling underlie growth cone formation and neuronal regeneration.

The cytoarchitecture, synaptic connectivity, and physiological properties of neurons are determined during their development by the interactions between the intrinsic properties of the neurons and signals provided by the microenvironment through which they grow. Many of these interactions are mediated and translated to specific growth patterns and connectivity by specialized compartments at the tips of the extending neurites: the growth cones (GCs). The mechanisms underlying GC formation at a specific time and location during development, regeneration, and some forms of learning processes, are therefore the subject of intense investigation. Using cultured Aplysia neurons we studied the cellular mechanisms that lead to the transformation of a differentiated axonal segment into a motile GC. We found that localized and transient elevation of the free intracellular calcium concentration ([Ca2+]i) to 200-300 microM induces GC formation in the form of a large lamellipodium that branches up into growing neurites. By using simultaneous on-line imaging of [Ca2+]i and of intraaxonal proteolytic activity, we found that the elevated [Ca2+]i activate proteases in the region in which a GC is formed. Inhibition of the calcium-activated proteases prior to the local elevation of the [Ca2+]i blocks the formation of GCs. Using retrospective immunofluorescent methods we imaged the proteolysis of the submembrane spectrin network, and the restructuring of the cytoskeleton at the site of GC formation. The restructuring of the actin and microtubule network leads to local accumulation of transported vesicles, which then fuse with the plasma membrane in support of the GC expansion.

Partial uncoupling of neurotransmitter release from [Ca2+]i by membrane hyperpolarization.

The dependence of evoked and asynchronous release on intracellular calcium ([Ca2+]i) and presynaptic membrane potential was examined in single-release boutons of the crayfish opener neuromuscular junction. When a single bouton was depolarized by a train of pulses, [Ca2+]i increased to different levels according to the frequency of stimulation. Concomitant measurements of evoked release and asynchronous release, from the same bouton, showed that both increased in a sigmoidal manner as a function of [Ca2+]i. When each of the depolarizing pulses was immediately followed by a hyperpolarizing pulse, [Ca2+]i was elevated to a lesser degree than in the control experiments, and the rate of asynchronous release and the quantal content were reduced; most importantly, evoked quantal release terminated sooner. The diminution of neurotransmitter release by the hyperpolarizing postpulse (HPP) could not be entirely accounted for by the reduction in [Ca2+]i. The experimental results are consistent with the hypothesis that the HPP reduces the sensitivity of the release machinery to [Ca2+]i, thereby not only reducing the quantal content but also terminating the quantal release process sooner.

Simultaneous measurement of evoked release and [Ca2+]i in a crayfish release bouton reveals high affinity of release to Ca2+.

The opener neuromuscular junction of crayfish was used to determine the affinity of the putative Ca2+ receptor(s) responsible for evoked release. Evoked, asynchronous release, and steady-state intracellular Ca2+ concentration, [Ca2+]ss, were measured concomitantly in single release boutons. It was found that, as expected, asynchronous release is highly correlated with [Ca2+]ss. Surprisingly, evoked release was also found to be highly correlated with [Ca2+]ss. The quantal content (m) and the rate of asynchronous release (S) showed sigmoidal dependence on [Ca2+]ss. The slope log m/log [Ca2+]ss varied between 1.6 and 3.3; the higher slope observed at the lower [Ca2+]o. The slope log S/log [Ca2+]ss varied between 3 and 4 and was independent of [Ca2+]o. These results are consistent with the assumption that evoked release is controlled by the sum of [Ca2+]ss and the local elevation of Ca2+ concentration near the release sites resulting from Ca2+ influx through voltage-gated Ca2+ channels (Y). On the basis of the above, we were able to estimate Y. We found Y to be significantly <10 microM even for [Ca2+]o = 13.5 mM. The dissociation constant (Kd) of the Ca2+ receptor(s) associated with evoked release was calculated to be in the range of 4-5 microM. This value of Kd is similar to that found previously for asynchronous release.

Real time imaging of calcium-induced localized proteolytic activity after axotomy and its relation to growth cone formation.

The emergence of a neuronal growth cone from a transected axon is a necessary step in the sequence of events that leads to successful regeneration. Yet, the molecular mechanisms underlying its formation after axotomy are unknown. In this study, we show by real time imaging of the free intracellular Ca2+ concentration, of proteolytic activity, and of growth cone formation that the activation of localized and transient Ca2+-dependent proteolysis is a necessary step in the cascade of events that leads to growth cone formation. Inhibition of this proteolytic activity by calpeptin, a calpain inhibitor, abolishes growth cone formation. We suggest that calpain plays a central role in the reorganization of the axon's cytoskeleton during its transition from a stable differentiated structure into a dynamically extending growth cone.

Induction of growth cone formation by transient and localized increases of intracellular proteolytic activity.

The formation of a growth cone at the tip of a transected axon is a crucial step in the subsequent regeneration of the amputated axon. During this process, the transected axon is transformed from a static segment into a motile growth cone. Despite the importance of this process for regeneration of the severed axon, little is known about the mechanisms underlying this transformation. Recent studies have suggested that Ca2+-activated proteinases underlay the morphological remodeling of neurons after injury. However, this hypothesis was never tested directly. Here we tested the ability of transient and localized increases in intracellular proteolytic activity to induce growth cone formation and neuritogenesis. Minute amounts of the proteinase trypsin were microinjected into intact axonal segments or somata of cultured Aplysia neurons, transiently elevating the intracellular protease concentration to 13-130 nM in the vicinity of the injection site. Such microinjections were followed by the formation of ectopic growth cones and irreversible neuritogenesis. Growth cones were not formed after external application of trypsin, microinjection of the carrier solution, or inactivated trypsin. Growth cone formation was not preceded by increases in free intracellular Ca2+ or changes in passive membrane properties, and was blocked by inhibitors of actin and tubulin polymerization. Trypsin-induced neuritogenesis was associated with ultrastructural alterations similar to those observed by us after axotomy. We conclude that local and transient elevations of cytoplasmic proteolytic activity can induce growth cone formation and neuritogenesis, and suggest that localized proteolytic activity plays a role in growth cone formation after axotomy.

Simultaneous measurement of intracellular Ca2+ and asynchronous transmitter release from the same crayfish bouton.

1. A technique has been developed to monitor neurotransmitter release simultaneously with intracellular Ca2+ concentration ([Ca2+]i) in single release boutons whose diameters range from 3 to 5 microns. 2. Using this technique, we have found a highly non-linear relationship between the rate of asynchronous release and [Ca2+]i. The Hill coefficient lies between 3 and 4. 3. The affinity (Kd) of the putative release-related Ca2+ receptor for asynchronous release was calculated to be in the range of 2-4 microM. 4. The same range of values of Hill coefficient and Kd were obtained when [Ca2+]i was elevated both by bath application of ionomycin and by repetitive stimulation at high frequency. 5. Our results show that the Ca2+ receptor(s) associated with asynchronous release exhibits high affinity for Ca2+.

Localized and transient elevations of intracellular Ca2+ induce the dedifferentiation of axonal segments into growth cones.

The formation of a growth cone at the tip of a severed axon is a key step in its successful regeneration. This process involves major structural and functional alterations in the formerly differentiated axonal segment. Here we examined the hypothesis that the large, localized, and transient elevation in the free intracellular calcium concentration ([Ca2+]i) that follows axotomy provides a signal sufficient to trigger the dedifferentiation of the axonal segment into a growth cone. Ratiometric fluorescence microscopy and electron microscopy were used to study the relations among spatiotemporal changes in [Ca2+]i, growth cone formation, and ultrastructural alterations in axotomized and intact Aplysia californica neurons in culture. We report that, in neurons primed to grow, a growth cone forms within 10 min of axotomy near the tip of the transected axon. The nascent growth cone extends initially from a region in which peak intracellular Ca2+ concentrations of 300-500 microM are recorded after axotomy. Similar [Ca2+]i transients, produced in intact axons by focal applications of ionomycin, induce the formation of ectopic growth cones and subsequent neuritogenesis. Electron microscopy analysis reveals that the ultrastructural alterations associated with axotomy and ionomycin-induced growth cone formation are practically identical. In both cases, growth cones extend from regions in which sharp transitions are observed between axoplasm with major ultrastructural alterations and axoplasm in which the ultrastructure is unaltered. These findings suggest that transient elevations of [Ca2+]i to 300-500 microM, such as those caused by mechanical injury, may be sufficient to induce the transformation of differentiated axonal segments into growth cones.

Low mobility of the Ca2+ buffers in axons of cultured Aplysia neurons.

Cellular Ca2+ buffers determine amplitude and diffusional spread of neuronal Ca2+ signals. Fixed Ca2+ buffers tend to retard the signal and to lower the apparent diffusion coefficient (D(app)) of Ca2+, whereas mobile buffers contribute to Ca2+ redistribution. To estimate the impact of the expression of specific Ca2+-binding proteins or the errors in Ca2+ measurement introduced by indicator dyes, the diffusion coefficient De and the Ca2+-binding ratio kappa(e) of endogenous Ca2+ buffers must be known. In this study, we obtain upper bounds to these quantities (De < 16 microm2/s; kappa(e) < 60) for axoplasm of metacerebral cells of Aplysia california. Due to these very low values, even minute concentrations of indicator dyes will interfere with the spatiotemporal pattern of Ca2+ signals and will conceal changes in the expression of specific Ca2+-binding proteins, which in the native neuron are expected to have significant effects on Ca2+ signals.

Use of Aplysia neurons for the study of cellular alterations and the resealing of transected axons in vitro.

The present report describes the experimental advantages offered by the combined use of Aplysia neurons and contemporary techniques to analyze the cellular events associated with nerve injury in the form of axotomy. The experiments were performed by transecting, under visual control, the main axon of identified Aplysia neurons in primary culture while monitoring several related parameters. We found that in cultured Aplysia neurons axotomy leads to the elevation of the [Ca2+]i in both the proximal and distal axonal segments from a resting level of 100 nM up to the millimolar range for a duration of 3-5 min. This increase in [Ca2+]i led to identical alterations in the cytoarchitecture of the proximal and distal segments. The formation of a membrane seal over the transected ends by their constriction and the subsequent fusion of the membrane is a [Ca2+]i-dependent process and is triggered by the elevation of [Ca2+]i to the microM level. Seal formation was followed by down-regulation of the [Ca2+]i to control levels. Following the formation of the membrane seal an increase in membrane retrieval was observed. We hypothesize that the retrieved membrane serves as an immediately available membrane reservoir for growth cone extension.

Acceleration of membrane recycling by axotomy of cultured aplysia neurons.

The rapid transition of a stationary axon into a motile growth cone requires the recruitment of membrane and its strategic insertion into the neurolemma. The source of membrane to support the initial rapid growth postaxotomy is not known. Using membrane capacitance measurements, we examined quantitative aspects of membrane dynamics following axotomy of cultured Aplysia neurons. Axotomy activates two processes in parallel: membrane retrieval and exocytosis. Unexpectedly, membrane retrieval is the dominant process in the majority of the experiments. Thus, while a growth cone is vigorously extending, the total neuronal surface area decreases. We suggest that the initial rapid extension phase of the newly formed growth cone postaxotomy is supported by a pool of intracellular membrane that is rapidly retrieved from the neurolemma.

Axotomy induces a transient and localized elevation of the free intracellular calcium concentration to the millimolar range.

1. Axonal transection triggers a cascade of pathological processes that frequently lead to the degeneration of the injured neuron. It is generally believed that the degenerative process is triggered by an overwhelming influx of calcium through the cut end of the axon. 2. Theoretical considerations and indirect observations suggest that axotomy is followed by an increase in the free intracellular calcium concentration ([Ca2+]i) to the millimolar level. In contrast, only relatively modest and transient elevation in [Ca2+]i to the micromolar level was revealed by recent fura-2 studies. 3. In the current study we used the low-affinity Ca2+ indicator mag-fura-2 to reexamine the spatiotemporal distribution pattern of Ca2+ after axotomy and to map the free intracellular Mg2+ concentration gradients. 4. We report that axotomy elevates [Ca2+]i well beyond the "physiological" range of calcium concentrations, to levels > 1 mM near the tip of the cut axon and to hundreds of micromolars along the axon further away from the cut end. Nevertheless, [Ca2+]i recovers to the control levels within 2-3 min after the resealing of the cut end. 5. A comparison of the behavior of fura-2 and mag-fura-2 in the cytosol of the axotomized neurons reveals that the determination of [Ca2+]i by fura-2 largely underestimates the actual intracellular Ca2+ concentrations. 6. Experiments in which one branch of a bifurcated axon was transected revealed that the elevation in [Ca2+]i is confined to the transected axonal branch and does not spread beyond the bifurcation point. 7. After axotomy, the intracellular Mg2+ concentration equilibrates rapidly with the external concentration and then recovers at a rate somewhat slower than that of [Ca2+]i. 8. To the best of our knowledge, this study is the first direct demonstration that axotomy elevates [Ca2+]i to the millimolar range and that neurons are able to recover from these extreme calcium concentrations.

A new family of conotoxins that blocks voltage-gated sodium channels.

Conus peptides, including omega-conotoxins and alpha-conotoxins (targeting calcium channels and nicotinic acetylcholine receptors, respectively) have been useful ligands in neuroscience. In this report, we describe a new family of sodium channel ligands, the mu-O-conotoxins. The two peptides characterized, mu-O-conotoxins MrVIA and MrVIB from Conus marmoreus potently block the sodium conductance in Aplysia neurons. This is in marked contrast to standard sodium channel blockers that are relatively ineffective in this system. The sequences of the peptides are as follows. mu-O-conotoxin MrVIA: ACRKKWEYCIVPIIGFIYCCPGLICGPFVCV mu-O-conotoxin MrVIB: ACSKKWEYCIVPILGFVYCCPGLICGPFVCV mu-O-conotoxin MrVIA was chemically synthesized and proved indistinguishable from the natural product. Surprisingly, the mu-O-conotoxins show no sequence similarity to the mu-O-conotoxins. However, ananalysis of cDNA clones encoding the mu-O-conotoxin MrVIB demonstrated striking sequence similarity to omega- and delta-conotoxin precursors. Together, the omega-, delta-, and mu-O-conotoxins define the O-superfamily of Conus peptides. The probable biological role and evolutionary affinities of these peptides are discussed.

Alterations of voltage-activated sodium current by a novel conotoxin from the venom of Conus gloriamaris.

1. The novel peptide toxin delta-conotoxin-GmVIA, recently purified by us from the mollusk-hunting snail Conus gloriamaris, induces convulsive-like contractions when injected into land snails but has no detectable effects in mammals. 2. At concentrations of 0.5-0.75 microM, the toxin induces action potential broadening and increased excitability of cultured Aplysia neurons. 3. Whole cell patch-clamp experiments on cultured Aplysia neurons revealed that the toxin does not alter potassium or calcium currents, but induces action potential broadening by slowing the inactivation kinetics of the sodium current. Under control conditions, the inactivation kinetics of the sodium current follows a single exponential with tau = 0.47 +/- 0.14 (SE) ms. After toxin application the sodium current inactivation is composed of two phases: an early phase with tau = 0.86 +/- 0.12 ms and a late phase of slowly inactivating sodium current with tau = 488 +/- 120 ms. In addition, the toxin shifts the voltage-dependent steady-state inactivation curve to more positive values and the steady-state activation curve to more negative values. These alterations are not associated with changes in the rise time or the peak value of the sodium current. 4. The novel delta-conotoxin-GmVIA, and the previously described "King Kong peptide," purified from another mollusk-hunting cone (Conus textile), share a similar cystein framework also found in the calcium channel blocking peptide omega-conotoxin but represent a new class of conotoxins with unusual specificity for molluscan sodium channels.

The survival of transected axonal segments of cultured Aplysia neurons is prolonged by contact with intact nerve cells.

Axonal segments transected from their cell body in vivo commonly undergo degeneration within 3-4 days (Wallerian degeneration). In lower vertebrates and invertebrates, however, some transected axonal segments survive for long periods ranging between 30 and 200 days. To circumvent the technical complications of studying the mechanisms underlying long-term survival of transected axons in vivo, we developed an in vitro system. We found previously that isolated axonal segments of cultured Aplysia neurons preserved their morphological integrity for an average duration of 7.6 days (range 2-14 days) and maintain their passive and excitable membrane properties. This survival occurred in the absence of de novo protein synthesis. In the present study we examined the influence of homologous neurons on the survival of transected axonal segments. We found that the average survival time of transected axons was doubled when co-cultured in physical contact with intact homologous neurons (average 15.3 days, range 2-27 days). During this period, the transected axons extended neurites, maintained normal passive and excitable membrane properties, formed electrotonic junctions with the intact neurons and maintained normal free intracellular Ca2+ levels. Consistent with these observations, electron micrographs of the transected axon revealed that the cytoskeletal elements of the axon appeared normal even 20 days after transection. In contrast, the mitochondria and smooth endoplasmic reticulum appeared damaged. As the prolonged survival was conditional on physical contact between the transected axon and the surrounding intact neurons, we suggest that the prolongation of survival time is promoted by the direct transfer of material from the intact neurons to the transected axon. However, co-culture of transected axons with homologous neurons did not fully mimic in vivo conditions, in which transected axons can survive for several months.

Delta-conotoxin GmVIA, a novel peptide from the venom of Conus gloriamaris.

A novel peptide toxin, delta-conotoxin GmVIA, was purified from the venom of Conus gloriamaris, a mollusc-hunting snail. It consists of 29 amino acids, including six Cys residues: [sequence: see text] The pattern of disulfide connectivity (4-19, 12-24, and 18-29) is the same as for the omega-conotoxins, which are Ca2+ channel ligands. However, the peptide does not compete with omega-conotoxin for binding to membrane preparations from frog, rat, and chick brain. Instead, initial electrophysiological results suggest that the peptide induces action potential broadening in molluscan neurons by slowing down Na+ current inactivation. Synthetic delta-conotoxin GmVIA was prepared by solid-phase methods and appeared identical in all respects to the natural material. The chromatographic behavior of native and reduced delta-conotoxins is quite remarkable, suggesting that the disulfides form a core which forces hydrophobic residues to point out toward the solvent.

New mollusc-specific alpha-conotoxins block Aplysia neuronal acetylcholine receptors.

Two mollusc-specific neurotoxic peptides from the venom of the molluscivorous snail Conus pennaceus are described. These new toxins block acetylcholine receptors (AChR) of cultured Aplysia neurons. Bath application of 0.5-1 microM toxin induces 5-10-mV membrane depolarization, which recovers to the control level within 1-3 min in the presence of the toxin. This response is blocked by 1 mM hexamethonium. Concomitantly with the transient depolarization, the toxins block approximately 90% of the depolarizing responses evoked by brief iontophoretic application of acetylcholine. The pharmacology and amino acid sequences of the toxins (alpha PnIA, GCCSLPPCAANNPDYC-NH2; alpha PnIB, GCCSLPPCALSNPDYC-NH2) enable their classification as novel alpha-conotoxins. The sequences differ from those of previously described alpha-conotoxins in a number of features, the most striking of which is the presence of a single negatively charged residue in the C-terminal loop. This loop contains a positively charged residue in piscivorous venom alpha-conotoxins. In contrast to other alpha-conotoxins, which are selective for vertebrate skeletal muscle nicotinic ACh receptors, these Conus pennaceus toxins block neuronal ACh receptors in molluscs. As such they are new probes which can be used to define subtypes of ACh receptors, and they should be useful tools in the study of structure-function relationships in ACh receptors.

Chemical and electrophysiological characterization of new peptide neurotoxins from the venom of the molluscivorous snail Conus textile neovicarius: a review.

Three peptide toxins exhibiting strong paralytic activity to molluscs, but with no paralytic effects on arthropods or vertebrates, were purified from the venom of the molluscivorous snail Conus textile neovicarius from the Red Sea. The amino acid sequences of these mollusc specific toxins are: TxIA, WCKQSGEMCNLLDQNCCDGYCIVLVCT (identical to the so-called 'King Kong peptide'); TxIB, WCKQSGEMCNVLDQNCCDGYCIVFVCT; TxIIA, WGGYSTYC gamma VDS gamma CCSDNCVRSYCT (gamma = gamma-carboxyglutamate). There is a similarity of the Cys framework of these toxins to that of the omega-conotoxins; however, their net negative charges, high content of hydrophobic residues, and uneven number of Cys residues in TxIIA are highly unusual for conotoxins. When assayed on isolated cultured Aplysia neurons, all three toxins induced spontaneous repetitive firing. The TxI toxins also induced a marked prolongation of the action potential duration. Voltage clamp experiments revealed that the TxI toxins alter the kinetics of the sodium current either by slowing down the rate of sodium current inactivation, or by recruiting silent sodium channels with slower activation and inactivation kinetics. The toxins shift the voltage-dependent steady-state Na+ current inactivation curve to more positive values by 6 mV. These changes are not associated with alteration in the rate of INa+ activation, in the peak INa+, or the sodium current reversal potential. TxI represents a new class of conotoxins with an unusual phylogenic specificity and may therefore be useful as a probe for the study of voltage gated sodium channels. (This review summarizes previously published papers).

Survival of isolated axonal segments in culture: morphological, ultrastructural, and physiological analysis.

Some transected distal axons survive for months in vivo, generate new neurites, and reconnect to proximal segments before degenerating. To determine the factors regulating these phenomena, we studied the behavior of transected axons in cultured metacerebral neurons (MCn) of Aplysia. The neurons were isolated from the ganglia and cultured at 18 degrees C. The morphology, ultrastructure, and electrophysiological properties of the transected axons, as well as their ability to synthesize protein, were examined at different times postaxotomy. Follow-up studies revealed that cultured isolated axonal segments can preserve their morphological integrity for up to 14 days, maintain their passive and active membrane properties for at least 10 days, and extend new neurites and form electrotonic junctions with their proximal segments and intact MCns. De novo protein synthesis is an unlikely mechanism to account for the survival of the isolated axons since they did not incorporate [35S]methionine. We conclude that the viability of transected axons in culture devoid of other cells depends on pools of proteins synthesized prior to the transection and energy stores sufficiently large to maintain neuronal homeostasis.