Milton P. Charlton

The GTPase dMiro is required for axonal transport of mitochondria to drosophila synapses

We have identified EMS-induced mutations in Drosophila Miro (dMiro), an atypical mitochondrial GTPase that is orthologous to human Miro (hMiro). Mutant dmiro animals exhibit defects in locomotion and die prematurely. Mitochondria in dmiro mutant muscles and neurons are abnormally distributed. Instead of being transported into axons and dendrites, mitochondria accumulate in parallel rows in neuronal somata. Mutant neuromuscular junctions (NMJs) lack presynaptic mitochondria, but neurotransmitter release and acute Ca2+ buffering is only impaired during prolonged stimulation. Neuronal, but not muscular, expression of dMiro in dmiro mutants restored viability, transport of mitochondria to NMJs, the structure of synaptic boutons, the organization of presynaptic microtubules, and the size of postsynaptic muscles. In addition, gain of dMiro function causes an abnormal accumulation of mitochondria in distal synaptic boutons of NMJs. Together, our findings suggest that dMiro is required for controlling anterograde transport of mitochondria and their proper distribution within nerve terminals.

Strategic location of calcium channels at transmitter release sites of frog neuromuscular synapses

The localization of Ca2+ channels relative to the position of transmitter release sites was investigated at the frog neuromuscular junction (NMJ). Ca2+ channels were labeled with fluorescently tagged omega-conotoxin GVIA, an irreversible Ca2+ channel ligand, and observed with a confocal laser scanning microscope. The Ca2+ channel labeling almost perfectly matched that of acetylcholine receptors which were labeled with fluorescent alpha-bung-arotoxin. This indicates that groups of Ca2+ channels are localized exclusively at the active zones of the frog NMJ. Cross sections of NMJs showed that Ca2+ channels are clustered on the presynaptic membrane adjacent to the postsynaptic membrane.

Distinct influx pathways, not calcium load, determine neuronal vulnerability to calcium neurotoxicity.

Abstract: Many forms of neurodegeneration are ascribed to excessive cellular Ca2+ loading (Ca2+ hypothesis). We examined quantitatively whether factors other than Ca2+ loading were determinants of excitotoxic neurodegeneration. Cell survival, morphology, free intracellular Ca2+ concentration ([Ca2+]i), and 45Ca2+ accumulation were measured in cultured cortical neurons loaded with known quantities of Ca2+ through distinct transmembrane pathways triggered by excitatory amino acids, cell membrane depolarization, or Ca2+ ionophores. Contrary to the Ca2+ hypothesis, the relationships between Ca2+ load and cell survival, free [Ca2+]i, and Ca2+‐induced morphological alterations depended primarily on the route of Ca2+ influx, not the Ca2+ load. Notably, Ca2+ loading via NMDA receptor channels was toxic, whereas identical Ca2+ loads incurred through voltage‐sensitive Ca2+ channels were completely innocuous. Furthermore, accounting quantitatively for Ca2+ loading via NMDA receptors uncovered a previously unreported component of l‐glutamate neurotoxicity apparently not mediated by ionotropic or metabotropic glutamate receptors. It was synergistic with toxicity attributable to glutamate‐evoked Ca2+ loading, and correlated with enhanced cellular ATP depletion. This previously unrecognized toxic action of glutamate constituted a chief excitotoxic mechanism under conditions producing submaximal Ca2+ loading. We conclude that (a) Ca2+ neurotoxicity is a function of the Ca2+ influx pathway, not Ca2+ load, and (b) glutamate toxicity may not be restricted to its actions on glutamate receptors.

Calcium entry and transmitter release at voltage‐clamped nerve terminals of squid.

Presynaptic and post‐synaptic cells of the squid giant synapse were voltage‐clamped simultaneously to study the relationship between presynaptic Ca current and transmitter‐induced post‐synaptic current (p.s.c.). Local Ca application was used to restrict Ca current and transmitter release to a limited region of the presynaptic terminal and thus minimize errors due to spatial heterogeneity of presynaptic membrane potential. Presynaptic terminals were depolarized by brief (3‐6 ms) voltage‐clamp pulses of varying amplitude to collect graded series of presynaptic Ca current and p.s.c. records. During presynaptic depolarization at 14 degrees C, Ca current activation preceded initial onset of p.s.c. (on‐p.s.c.) by an interval of approximately 1 ms. The main component of on‐p.s.c. followed Ca current activation by about 2 ms. The delay between a brief Ca tail current and peak response of the p.s.c. produced after pulse termination (off‐p.s.c.) was also approximately 2 ms. Curves relating both Ca current and p.s.c. magnitudes to presynaptic potential were bell shaped with peaks near ‐10 mV, but the p.s.c. curve showed stronger voltage dependence on both sides of the peak. With very small and very large presynaptic command pulses, Ca current could be observed without measureable p.s.c. Synaptic transfer curves, plotting p.s.c. as a function of presynaptic Ca current, resembled third‐power functions. On the average, p.s.c.s fit a curve representing the 2.9 power of Ca current (range 2.4‐3.5 in eighteen experiments). Transfer curves consisted of two limbs: one from presynaptic pulses below ‐10 mV and the other from more positive pulses. These two limbs were similar and generally resembled power functions of identical exponent. It is thus likely that the third‐power function accurately reflects synaptic current transfer, rather than interference from some other voltage‐dependent process. Power functions fitting small‐pulse and large‐pulse limbs of some transfer curves had different scale coefficients, even though exponent values were the same. Consideration of synaptic transmission kinetics suggests that the voltage dependence of Ca channel opening rates can probably explain the difference in transfer curve limbs. Our experiments provide no evidence for an intrinsic voltage dependence of the transmitter release process.

A post-docking role for synaptobrevin in synaptic vesicle fusion

We have used the squid giant synapse to determine the role of synaptobrevin, integral membrane proteins of small synaptic vesicles, in neurotransmitter release. The sequence of squid synaptobrevin, deduced by cDNA cloning, is 65%-68% identical to mammalian isoforms and includes the conserved cleavage site for tetanus and botulinum B toxins. Injection of either toxin into squid nerve terminals caused a slow, irreversible inhibition of release without affecting the Ca2+ signal which triggers release. Microinjection of a recombinant protein corresponding to the cytoplasmic domain of synaptobrevin produced a more rapid and reversible inhibition of release, whereas two smaller peptide fragments were without effect. Electron microscopy of tetanus-injected terminals revealed an increased number of both docked and undocked synaptic vesicles. These data indicate that synaptobrevin participates in neurotransmitter release at a step between vesicle docking and fusion.

Role of presynaptic calcium ions and channels in synaptic facilitation and depression at the squid giant synapse.

1. The roles of presynaptic calcium influx and calcium accumulation in synaptic facilitation and depression were explored at the giant synapse in the stellate ganglion of the squid. 2. Calcium currents were recorded in the presynaptic terminal, using a three‐electrode voltage clamp and blocking sodium and potassium currents pharmacologically. The calcium influx was constant during pairs or trains of brief depolarizing pulses that elicited facilitating or depressing excitatory post‐synaptic potentials (e.p.s.p.s). 3. The relationship between calcium influx and transmitter release during brief depolarizing pulses of varying amplitude resembled a power function with exponent of about 2. 4. Presynaptic calcium concentration transients were measured by injecting the dye arsenazo III and detecting absorbance changes microspectrophotometrically. Increments in intracellular free calcium accompanying single action potentials appeared constant for repeated action potentials that elicited facilitating e.p.s.p.s. 5. The presynaptic calcium concentration remains elevated for several seconds following action potentials. 6. Presynaptic injection of calcium ions by interbarrel ionophoresis evokes a postsynaptic depolarization, apparently reflecting a large increase in miniature e.p.s.p. frequency. Presynaptic action potentials remain unaffected by this treatment, but e.p.s.p.s triggered by them are facilitated for several seconds, and then depressed. 7. The results are consistent with the hypothesis that synaptic facilitation is due to the action of residual calcium or a calcium complex remaining in the presynaptic terminal after electrical activity. The late depression of release during calcium injection may be a result of the continual release of transmitter and consequent depletion of a presynaptic store.

Transmitter release increases intracellular calcium in perisynaptic schwann cells in situ

Glial cells isolated from the nervous system are sensitive to neurotransmitters and may therefore be involved in synaptic transmission. The sensitivity of individual perisynaptic Schwann cells to activity of a single synapse was investigated, in situ, at the frog neuromuscular junction by monitoring changes in intracellular Ca2+ in the Schwann cells. Motor nerve stimulation induced an increase in intracellular Ca2+ in these Schwann cells; this increase was greatly reduced when transmitter release was blocked. Furthermore, local application of the cotransmitters acetylcholine and ATP evoked Ca2+ responses even in the absence of extracellular Ca2+. Successive trains of nerve stimuli or applications of transmitters resulted in progressively smaller Ca2+ responses. We conclude that transmitter released during synaptic activity can evoke release of intracellular Ca2+ in perisynaptic Schwann cells. This Ca2+ signal may play a role in the maintenance or modulation of a synapse. These data show that synaptic transmission involves three cellular components with both postsynaptic and glial components responding to transmitter secretion.

Activity-dependent changes in partial VAMP complexes during neurotransmitter release.

The temporal sequence of SNARE protein interactions that cause exocytosis is unknown. Blockade of synaptic neurotransmitter release through cleavage of VAMP/synaptobrevin by tetanus toxin light chain (TeNT-LC) was accelerated by nerve stimulation. Botulinum/B neurotoxin light chain (BoNT/B-LC), which cleaves VAMP at the same site as TeNT-LC, did not require stimulation. Because TeNT-LC requires the N-terminal coil domain of VAMP for binding but BoNT/B-LC requires the C-terminal coil domain, it seems that, before nerve activity, the N-terminal domain is shielded in a protein complex, but the C-terminal domain is exposed. This N-terminal complex lasts until nerve activity occurrs and may serve to cock synaptic vesicles for immediate exocytosis upon Ca2+ entry.

Secondary Ca2+ overload indicates early neuronal injury which precedes staining with viability indicators

Spinal neurons, lethally challenged with excitatory amino acids (EAAs) or with high-K+, underwent a biphasic rise in free intracellular calcium concentration ([Ca2+]i). In contrast to the initial rise in [Ca2+]i which recovered, the secondary, irreversible [Ca2+]i increase was unaffected by antagonists of EAA receptors or Ca2+ channels. Also, it correlated highly with cell death, but preceded vital staining with trypan blue and ethidium homodimer, reflecting damaged cellular Ca2+ regulation rather than plasma membrane leakiness. Our findings suggest that delayed Ca2+ overload is the end-product rather than the cause of Ca(2+)-triggered neurotoxic processes.

Cholesterol and synaptic transmitter release at crayfish neuromuscular junctions

During exocytosis of synaptic transmitters, the fusion of highly curved synaptic vesicle membranes with the relatively planar cell membrane requires the coordinated action of several proteins. The role of membrane lipids in the regulation of transmitter release is less well understood. Since it helps to control membrane fluidity, alteration of cholesterol content may alter the fusibility of membranes as well as the function of membrane proteins. We assayed the importance of cholesterol in transmitter release at crayfish neuromuscular junctions where action potentials can be measured in the preterminal axon. Methyl‐β‐cyclodextrin (MβCD) depleted axons of cholesterol, as shown by reduced filipin labelling, and cholesterol was replenished by cholesterol–MβCD complex (Ch‐MβCD). MβCD blocked evoked synaptic transmission. The lack of postsynaptic effects of MβCD on the time course and amplitude of spontaneous postsynaptic potentials or on muscle resting potential allowed us to focus on presynaptic mechanisms. Intracellular presynaptic axon recordings and focal extracellular recordings at individual boutons showed that failure of transmitter release was correlated with presynaptic hyperpolarization and failure of action potential propagation. All of these effects were reversed when cholesterol was replenished with Ch‐MβCD. However, focal depolarization of presynaptic boutons and administration of a Ca2+ ionophore both triggered transmitter release after cholesterol depletion. Therefore, both presynaptic Ca2+ channels and Ca2+‐dependent exocytosis functioned after cholesterol depletion. The frequency of spontaneous quantal transmitter release was increased by MβCD but recovered when cholesterol was reintroduced. The increase in spontaneous release was not through a calcium‐dependent mechanism because it persisted with intense intracellular calcium chelation. In conclusion, cholesterol levels in the presynaptic membrane modulate several key properties of synaptic transmitter release.