Laser microbeam axotomy and conduction block show that electrical transmission at a central synapse is distributed at multiple contacts

Cell anatomy and network input explain differences within but not between leech touch cells at two different locations

Mechanosensory cells in the leech share several common features with mechanoreceptors in the human glabrous skin. Previous studies showed that the six T (touch) cells in each body segment of the leech are highly variable in their responses to somatic current injection and change their excitability over time. Here, we investigate three potential reasons for this variability in excitability by comparing the responses of T cells at two soma locations (T2 and T3): (1) Differential effects of time-dependent changes in excitability, (2) divergent synaptic input from the network, and (3) different anatomical structures. These hypotheses were explored with a combination of electrophysiological double recordings, 3D reconstruction of neurobiotin-filled cells, and compartmental model simulations. Current injection triggered significantly more spikes with shorter latency and larger amplitudes in cells at soma location T2 than at T3. During longer recordings, cells at both locations increased their excitability over time in the same way. T2 and T3 cells received the same amount of synaptic input from the unstimulated network, and the polysynaptic connections between both T cells were mutually symmetric. However, we found a striking anatomical difference: While in our data set all T2 cells innervated two roots connecting the ganglion with the skin, 50% of the T3 cells had only one root process. The sub-sample of T3 cells with one root process was significantly less excitable than the T3 cells with two root processes and the T2 cells. To test if the additional root process causes higher excitability, we simulated the responses of 3D reconstructed cells of both anatomies with detailed multi-compartment models. The anatomical subtypes do not differ in excitability when identical biophysical parameters and a homogeneous channel distribution are assumed. Hence, all three hypotheses may contribute to the highly variable T cell responses, but none of them is the only factor accounting for the observed systematic difference in excitability between cells at T2 vs. T3 soma location. Therefore, future patch clamp and modeling studies are needed to analyze how biophysical properties and spatial distribution of ion channels on the cell surface contribute to the variability and systematic differences of electrophysiological phenotypes.

Initial Variability and Time-Dependent Changes of Neuronal Response Features Are Cell-Type-Specific

Different cell types are commonly defined by their distinct response features. But several studies proved substantial variability between cells of the same type, suggesting rather the appraisal of response feature distributions than a limitation to "typical" responses. Moreover, there is growing evidence that time-dependent changes of response features contribute to robust and functional network output in many neuronal systems. The individually characterized Touch (T), Pressure (P), and Retzius (Rz) cells in the medicinal leech allow for a rigid analysis of response features, elucidating differences between and variability within cell types, as well as their changes over time. The initial responses of T and P cells to somatic current injection cover a wide range of spike counts, and their first spike is generated with a high temporal precision after a short latency. In contrast, all Rz cells elicit very similar low spike counts with variable, long latencies. During prolonged electrical stimulation the resting membrane potential of all three cell types hyperpolarizes. At the same time, Rz cells reduce their spiking activity as expected for a departure from the spike threshold. In contrast, both mechanoreceptor types increase their spike counts during repeated stimulation, consistent with previous findings in T cells. A control experiment reveals that neither a massive current stimulation nor the hyperpolarization of the membrane potential is necessary for the mechanoreceptors' increase in excitability over time. These findings challenge the previously proposed involvement of slow K+-channels in the time-dependent activity changes. We also find no indication for a run-down of HCN channels over time, and a rigid statistical analysis contradicts several potential experimental confounders as the basis of the observed variability. We conclude that the time-dependent change in excitability of T and P cells could indicate a cell-type-specific shift between different spiking regimes, which also could explain the high variability in the initial responses. The underlying mechanism needs to be further investigated in more naturalistic experimental situations to disentangle the effects of varying membrane properties versus network interactions. They will show if variability in individual response features serves as flexible adaptation to behavioral contexts rather than just "randomness".

The effect of axotomy on firing and ultrastructure of the crayfish mechanoreceptor neurons and satellite glial cells

Neurotrauma is among main causes of human disability and death. We studied effects of axotomy on ultrastructure and neuronal activity of a simple model object - an isolated crayfish stretch receptor that consists of single mechanoreceptor neurons (MRN) enwrapped by multilayer glial envelope. After isolation, MRN regularly fired until spontaneous activity cessation. Axotomy did not change significantly MRN spike amplitude and firing rate. However, the duration of neuron activity from MRN isolation to its spontaneous cessation decreased in axotomized MRN relative to intact neuron. [Ca²⁺] in MRN axon and soma increased 3-10 min after axotomy. Ca²⁺ entry through ion channels in the axolemma accelerated axotomy-stimulated firing cessation. MRN incubation with Ca²⁺ionophore ionomycin accelerated MRN inactivation, whereas Ca²⁺-channel blocker Cd²⁺ prolonged firing. Activity duration of either intact, or axotomized MRN did not change in the presence of ryanodine or dantrolene, inhibitors of ryanodin-sensitive Ca²⁺ channels in endoplasmic reticulum. Thapsigargin, inhibitor of endoplasmic reticulum Ca²⁺-ATPase, or its activator ochratoxin were ineffective. Ultrastructural study showed that the defect in the axon transected by thin scissors is sealed by fused axolemma, glial and collagen layers. Only the 30-50 μm long segment completely lost microtubules and contained swelled mitochondria. The microtubular bundle remained undamaged at 300 μm away from the axotomy site. However, mitochondria within the 200-300 μm segment were strongly condensed and lost matrix and cristae. Glial and collagen layers exhibited greater damage. Swelling and edema of glial layers, collagen disorganization and rupture occurred within this segment. Thus, axotomy stronger damages glia/collagen envelope, axonal microtubules and mitochondria.

Spatially sculpted laser scissors for study of DNA damage and repair

We present a simple and efficient method for controlled linear induction of DNA damage in live cells. By passing a pulsed laser beam through a cylindrical lens prior to expansion, an elongated elliptical beam profile is created with the ability to expose controlled linear patterns while keeping the beam and the sample stationary. The length and orientation of the beam at the sample plane were reliably controlled by an adjustable aperture and rotation of the cylindrical lens, respectively. Localized immunostaining by the DNA double strand break (DSB) markers phosphorylated H2AX (gamma H2AX) and Nbs1 in the nuclei of HeLa cells exposed to the "line scissors" was shown via confocal imaging. The line scissors method proved more efficient than the scanning mirror and scanning stage methods at induction of DNA DSB damage with the added benefit of having a greater potential for high throughput applications.

Multiple spike initiation zones in a neuron implicated in learning in the leech: a computational model

Sensitization of the defensive shortening reflex in the leech has been linked to a segmentally repeated tri-synaptic positive feedback loop. Serotonin from the R-cell enhances S-cell excitability, S-cell impulses cross an electrical synapse into the C-interneuron, and the C-interneuron excites the R-cell via a glutamatergic synapse. The C-interneuron has two unusual characteristics. First, impulses take longer to propagate from the S soma to the C soma than in the reverse direction. Second, impulses recorded from the electrically unexcitable C soma vary in amplitude when extracellular divalent cation concentrations are elevated, with smaller impulses failing to induce synaptic potentials in the R-cell. A compartmental, computational model was developed to test the sufficiency of multiple, independent spike initiation zones in the C-interneuron to explain these observations. The model displays asymmetric delays in impulse propagation across the S-C electrical synapse and graded impulse amplitudes in the C-interneuron in simulated high divalent cation concentrations.

A 3-synapse positive feedback loop regulates the excitability of an interneuron critical for sensitization in the leech

Sensitization of reflexive shortening in the leech has been linked to serotonin (5-HT)-induced changes in the excitability of a single interneuron, the S cell. This neuron is necessary for sensitization and complete dishabituation of reflexive shortening, during which it contributes to the sensory-motor reflex. The S cell does not contain 5-HT, which is released primarily from the Retzius (R) cells, whose firing enhances S-cell excitability. Here, we show that the S cell excites the R cells, mainly via a fast disynaptic pathway in which the first synapse is the electrical junction between the S cell and the coupling interneurons, and the second synapse is a glutamatergic synapse of the coupling interneurons onto the R cells. The S cell-triggered excitatory postsynaptic potential in the R cell diminishes and nearly disappears in elevated concentrations of divalent cations because the coupling interneurons become inexcitable under these conditions. Serotonin released from the R cells feeds back on the S cell and increases its excitability by activating a 5-HT7-like receptor; 5-methoxytryptamine (5-MeOT; 10 microM) mimics the effects of 5-HT on S cell excitability, and effects of both 5-HT and 5-MeOT are blocked by pimozide (10 microM) and SB-269970 [(R)-3-(2-(2-(4-methylpiperidin-1-yl)-ethyl)pyrrolidine-1-sulfonyl)phenol] (5 microM). This feedback loop may be critical for the full expression of sensitization of reflexive shortening.

Repair and Regeneration of Functional Synaptic Connections: Cellular and Molecular Interactions in the Leech

A major problem for neuroscience has been to find a means to achieve reliable regeneration of synaptic connections following injury to the adult CNS. This problem has been solved by the leech, where identified neurons reconnect precisely with their usual targets following axotomy, re-establishing in the adult the connections formed during embryonic development. It cannot be assumed that once axons regenerate specific synapses, function will be restored. Recent work on the leech has shown following regeneration of the synapse between S-interneurons, which are required for sensitization of reflexive shortening, a form of non-associative learning, the capacity for sensitization is delayed. The steps in repair of synaptic connections in the leech are reviewed, with the aim of understanding general mechanisms that promote successful repair. New results are presented regarding the signals that regulate microglial migration to lesions, a first step in the repair process. In particular, microglia up to 900 microm from the lesion respond within minutes by moving rapidly toward the injury, controlled in part by nitric oxide (NO), which is generated immediately at the lesion and acts via a soluble guanylate cyclase (sGC). The cGMP produced remains elevated for hours after injury. The relationship of microglial migration to axon outgrowth is discussed.

Axotomy of single fluorescent nerve fibers in developing mammalian spinal cord by photoconversion of diaminobenzidine

A technique has been developed for cutting single nerve fibers in mammalian spinal cord. In the presence of diaminobenzidine (DAB), a laser microbeam was applied to carbocyanine (Dil) stained sensory fibers in cultured spinal cords of the newly born opossum Monodelphis domestica. Digital images of fluorescent fibers were acquired with an intensified video CCD-camera coupled to an image processor. Laser illumination of two spots on a fiber in the presence of 3 mg/ml DAB cut it, so that following DAB wash out, Dil fluorescence did not return after the intermediate segment was bleached. In contrast, when a similar procedure was carried out without DAB, fluorescence of the bleached segment was recovered within minutes in darkness, by dye diffusion from adjacent regions of the uncut fiber. After exposure to DAB, through-conduction of compound action potentials continued in undamaged fibers. The DAB reaction product remained as a dark precipitate, helping to localize the lesion sites. By illuminating a continuous series of spots it was possible to cut whole nerve roots. Fluorescent fibers extended across the cut segment 24 h later. With minor modifications, the procedure described here allows a precise lesioning of single fibers within an intact nervous system.

Action potential reflection and failure at axon branch points cause stepwise changes in EPSPs in a neuron essential for learning

In leech mechanosensory neurons, action potentials reverse direction, or reflect, at central branch points. This process enhances synaptic transmission from individual axon branches by rapidly activating synapses twice, thereby producing facilitation. At the same branch points action potentials may fail to propagate, which can reduce transmission. It is now shown that presynaptic action potential reflection and failure under physiological conditions influence transmission to the same postsynaptic neuron, the S cell. The S cell is an interneuron essential for a form of nonassociative learning, sensitization of the whole body shortening reflex. The P to S synapse has components that appear monosynaptic (termed "direct") and polysynaptic, both with glutamatergic pharmacology. Reflection at P cell branch points on average doubled transmission to the S cell, whereas action potential failure, or conduction block, at the same branch points decreased it by one-half. Each of two different branch points affected transmission, indicating that the P to S connection is spatially distributed around these branch points. This was confirmed by examining the locations of individual contacts made by the P cell with the S cell and its electrically coupled partner C cells. These results show that presynaptic neuronal morphology produces a range of transmission states at a set of synapses onto a neuron necessary for a form of learning. Reflection and conduction block are activity-dependent and are basic properties of action potential propagation that have been seen in other systems, including axons and dendrites in the mammalian brain. Individual branch points and the distribution of synapses around those branch points can substantially influence neuronal transmission and plasticity.

Synaptic facilitation by reflected action potentials: enhancement of transmission when nerve impulses reverse direction at axon branch points

A rapid, reversible enhancement of synaptic transmission from a sensory neuron is reported and explained by impulses that reverse direction, or reflect, at axon branch points. In leech mechanosensory neurons, where one can detect reflection because it is possible simultaneously to study electrical activity in separate branches, action potentials reflected from branch points within the central nervous system under physiological conditions. Synapses adjacent to these branch points were activated twice in rapid succession, first by an impulse arriving from the periphery and then by its reflection. This fast double-firing facilitated synaptic transmission, increasing it to more than twice its normal level. Reflection occurred within a range of resting membrane potentials, and electrical activity produced by mechanical stimulation changed membrane potential so as to produce and cease reflection. A compartmental model was used to investigate how branch-point morphology and electrical activity contribute to produce reflection. The model shows that mechanisms that hyperpolarize the membrane so as to impair action potential propagation can increase the range of structures that can produce reflection. This suggests that reflection is more likely to occur in other structures where impulses fail, such as in axons and dendrites in the mammalian brain. In leech sensory neurons, reflection increased transmission from central synapses only in those axon branches that innervate the edges of the receptive field in the skin, thereby sharpening spatial contrast. Reflection thus allows a neuron to amplify synaptic transmission from a selected group of its branches in a way that can be regulated by electrical activity.

A detached branch stops being recognized as self by other branches of a neuron

The multiple peripheral projections of a single leech mechanosensory neuron form individual arbors that do not overlap at all with each other, a phenomenon that has been termed "self-avoidance" (Yau, 1976; Kramer and Stent, 1985). This is in marked contrast to the peripheral arbors of adjacent segmental homologues, which partially overlap with each other at their boundaries in target areas of the body wall (Nicholls and Baylor, 1968; Gan and Macagno, 1995). How a neurite differentiates between sibling neurites of the same cell and those of a homologue is not known, but possible mechanisms include the recognition of surface markers of neuronal identity or the detection of cell-specific patterns of activity. In order to test whether this self-recognition requires a neurite to be in direct communication with its soma, we used a laser microbeam to sever a branch of a dye-filled pressure-sensitive (P) neuron in an intact leech embryo. Time-lapse observations of the P cell arbor in the living, unanesthetized, animal for up to 24 h following the surgery showed that the detached branch continued to show dynamic growth behavior throughout the period of observation. However, the detached branch ceased being avoided by the rest of the cell within a few hours, other, attached branches of the neuron overgrowing its territory and directly overlapping with it. Our experiments provide direct evidence for the existence of strong growth-inhibiting interactions between sibling processes, and indicate that self-avoidance by the growing neurites of a cell requires physical continuity between these neurites.

CCD imaging of the electrical activity in the leech nervous system

A single ganglion of the nervous system of the leech Hirudo medicinalis was isolated. One or both roots emerging from each side of the ganglion were sucked into suction pipettes used either for extracellular stimulation or for recording the gross electrical activity. The ganglion was stained with the fluorescence voltage sensitive dye Di-4-Anepps. The fluorescence was measured with a nitrogen cooled CCD camera. Our recording system allowed us to measure in real time slow optical signals corresponding to changes in light intensity of at least 5/1000. These signals were caused by the direct polarization of neuronal structures, the afterhyperpolarization or the afterdischarge induced by a prolonged stimulation. When images were acquired at fixed times, several of them could be averaged and optical signals of at least 2/1000 could be reliably measured. These optical signals originated from well identified neurons, such as T, P and N sensory neurons. By taking images at different times and at different focal planes, electrical events could be followed at a temporal resolution of 50 Hz. The three dimensional dynamics of electrical events, initiated by a specific stimulation, was imaged and the spread of excitation among leech neurons was followed. When two roots were selectively stimulated, their neuronal interactions could be imaged and the linear and non-linear terms of the interaction could be characterized.

Synaptic integration at a sensory-motor reflex in the leech

1. In the medicinal leech the distribution of synapses from the pressure sensory (P) neurone to the annulus erector (AE) motoneurone and the site of impulse initiation in the AE cell were determined to understand better the integration of sensory inputs by the motoneurone. 2. The axon of the AE cell bifurcates before leaving the ganglion. Laser photoablation experiments indicated that the axon proximal to the bifurcation is inexcitable. Two techniques, laser photoablation and measurement of impulse timing, each located the site of impulse initiation at the bifurcation. 3. The medial P cell makes a monosynaptic connection with the AE cell, eliciting an excitatory postsynaptic potential (EPSP) of 1-3 mV amplitude recorded in the AE cell soma. 4. Intracellular injection of dyes into separate cells showed that P cell branches appear to contact AE cell branches both ipsilaterally and contralaterally. Laser photoablation of selected portions of the P and AE cells' axons revealed functional contacts on both sides. 5. The primary axon bifurcation of the AE cell is the site of integration of synaptic potentials that spread passively from both sides of the ganglion. These summed synaptic potentials account for the concerted activity of the two AE cells in each ganglion.

Effect of conduction block at axon bifurcations on synaptic transmission to different postsynaptic neurones in the leech

1. The cutaneous receptive field of the medial pressure (mP) sensory neurone in the leech has been examined. The cell has one major receptive field and an anterior and a posterior minor receptive field, principally on lateral and dorsal skin. The two minor receptive fields are contiguous with the major receptive field and are innervated by fine anterior and posterior axons, but there is no overlap between major and minor receptive fields. 2. At low frequencies of stimulation of the minor receptive fields, conduction block takes place in the mP cell at the central branch point within the leech ganglion. 3. The mP cell synapses directly with many other cells in the leech ganglion, including the anterior pagoda (AP) cell, longitudinal (L) motoneurone and the annulus erector (AE) motoneurone, which were studied as a group of postsynaptic neurones. Conduction block in the mP cell affects its synaptic transmission to all three postsynaptic neurones, but the effect can be different in different postsynaptic neurones. Block at the central branch point for an impulse travelling along the anterior axon reduces transmission to the AE cell much more than to the AP or L cells, while block at the central branch for an impulse travelling along the posterior axon has the reverse effect. 4. The distribution of functional connections of the branches of the mP cell with each postsynaptic cell was studied. For this analysis, branches of the mP cell were selectively silenced either during conduction block or by laser microsurgery. Generally, nearly all of the functional connections with the L and AP cell are made by anterior branches of the mP cell while the connection with the AE cell was primarily made by posterior branches of the mP cell. 5. The possible sites of contact between the mP cell and postsynaptic cells were determined by injecting separate markers into the mP cell and a postsynaptic cell. In confirmation of physiology, the mP cell's posterior branches had few, if any, contacts with the AP cell, while anterior branches had few, if any, contacts upon the AE cell. 6. Conduction block can thus act as a switch in the central nervous system (CNS), altering the mP cell's pattern of synaptic transmission to different postsynaptic neurons depending upon the region of a single sensory neurone's receptive field that is stimulated. This effect, dependent upon inputs to a single neurone, may be expected to influence the performance of the system and its outputs.

Modulation of conduction at points of axonal bifurcation by applied electric fields

This study investigated how weak electric fields, on the order of 100 mV/cm, modulate action potential conduction through points of axonal bifurcation in leech touch sensory neurons. Axonal branch points in neurons are ubiquitous structures, and they are sites of low safety-factor for action potential propagation. In this study calibrated electric fields were applied around excised ganglia from the leech central nervous system. The electric fields were generated by 500 ms constant current square waves applied to the bath containing the tissue. Microelectrode penetration of the neurons was used to: 1) record transmembrane potential changes in the cell body of the neuron that resulted from the external field; 2) monitor conduction block when action potentials, evoked in the periphery, propagated into the ganglion; 3) inject current directly into the cell in an experimental analysis of the mechanism by which the externally applied field produced block. Conduction block was reliably induced by electric fields too weak to reach threshold for firing action potentials. In an experimental analysis where block was produced by the direct intracellular injection of negative current, a reversed polarity field relieved it. This indicates that when the external field induces block, it does so by membrane hyperpolarization at the branch point.