Your search keyword '"Muller KJ"' showing total 81 results

1. Action potential initiation site depends on neuronal excitation

Author

Melinek, R, primary and Muller, KJ, additional

Published

1996

2. The S cell: an interneuron essential for sensitization and full dishabituation of leech shortening

Author

Sahley, CL, primary, Modney, BK, additional, Boulis, NM, additional, and Muller, KJ, additional

Published

1994

3. Competitive interactions between neurons making axosomatic contacts in the leech

Author

Gu, XN, primary and Muller, KJ, additional

Published

1990

4. Regeneration of axons and synaptic connections by touch sensory neurons in the leech central nervous system

Author

Macagno, ER, primary, Muller, KJ, additional, and DeRiemer, SA, additional

Published

1985

5. Regeneration of a distinctive set of axosomatic contacts in the leech central nervous system

Author

French, KA, primary and Muller, KJ, additional

Published

1986

6. Sprouting and regeneration of sensory axons after destruction of ensheathing glial cells in the leech central nervous system

Author

Elliott, EJ, primary and Muller, KJ, additional

Published

1983

7. Physiologic maturation is both extrinsically and intrinsically regulated in progenitor-derived neurons.

Author

Venugopalan P, Cameron EG, Zhang X, Nahmou M, Muller KJ, and Goldberg JL

Subjects

Animals, Calcium metabolism, Cells, Cultured, Rats, Retinal Ganglion Cells cytology, Retinal Neurons cytology, Stem Cells cytology, K Cl- Cotransporters, Receptors, GABA-A metabolism, Retinal Ganglion Cells physiology, Retinal Neurons physiology, Stem Cells physiology, Symporters metabolism, gamma-Aminobutyric Acid metabolism

Abstract

During development, newly-differentiated neurons undergo several morphological and physiological changes to become functional, mature neurons. Physiologic maturation of neuronal cells derived from isolated stem or progenitor cells may provide insight into maturation in vivo but is not well studied. As a step towards understanding how neuronal maturation is regulated, we studied the developmental switch of response to the neurotransmitter GABA, from excitatory depolarization to inhibitory hyperpolarization. We compared acutely isolated retinal ganglion cells (RGCs) at various developmental stages and RGCs differentiated in vitro from embryonic retinal progenitors for the effects of aging and, independently, of retinal environment age on their GABA A receptor (GABA A R) responses, elicited by muscimol. We found that neurons generated in vitro from progenitors exhibited depolarizing, immature GABA responses, like those of early postnatal RGCs. As progenitor-derived neurons aged from 1 to 3 weeks, their GABA responses matured. Interestingly, signals secreted by the early postnatal retina suppressed acquisition of mature GABA responses. This suppression was not associated with changes in expression of GABA A R or of the chloride co-transporter KCC2, but rather with inhibition of KCC2 dimerization in differentiating neurons. Taken together, these data indicate GABA response maturation depends on release of inhibition by developmentally regulated diffusible signals from the retina.

Published

2020

8. Novel Regulatory Mechanisms for the SoxC Transcriptional Network Required for Visual Pathway Development.

Author

Chang KC, Hertz J, Zhang X, Jin XL, Shaw P, Derosa BA, Li JY, Venugopalan P, Valenzuela DA, Patel RD, Russano KR, Alshamekh SA, Sun C, Tenerelli K, Li C, Velmeshev D, Cheng Y, Boyce TM, Dreyfuss A, Uddin MS, Muller KJ, Dykxhoorn DM, and Goldberg JL

Subjects

Animals, Cells, Cultured, Feedback, Physiological physiology, Female, Gene Expression Regulation, Developmental physiology, Male, Mice, Rats, Sprague-Dawley, Aging physiology, Gene Regulatory Networks physiology, Retinal Ganglion Cells physiology, SOXC Transcription Factors metabolism, Transcriptional Activation physiology, Visual Pathways physiology

Abstract

What pathways specify retinal ganglion cell (RGC) fate in the developing retina? Here we report on mechanisms by which a molecular pathway involving Sox4/Sox11 is required for RGC differentiation and for optic nerve formation in mice in vivo , and is sufficient to differentiate human induced pluripotent stem cells into electrophysiologically active RGCs. These data place Sox4 downstream of RE1 silencing transcription factor in regulating RGC fate, and further describe a newly identified, Sox4-regulated site for post-translational modification with small ubiquitin-related modifier (SUMOylation) in Sox11, which suppresses Sox11's nuclear localization and its ability to promote RGC differentiation, providing a mechanism for the SoxC familial compensation observed here and elsewhere in the nervous system. These data define novel regulatory mechanisms for this SoxC molecular network, and suggest pro-RGC molecular approaches for cell replacement-based therapies for glaucoma and other optic neuropathies. SIGNIFICANCE STATEMENT Glaucoma is the most common cause of blindness worldwide and, along with other optic neuropathies, is characterized by loss of retinal ganglion cells (RGCs). Unfortunately, vision and RGC loss are irreversible, and lead to bilateral blindness in ∼14% of all diagnosed patients. Differentiated and transplanted RGC-like cells derived from stem cells have the potential to replace neurons that have already been lost and thereby to restore visual function. These data uncover new mechanisms of retinal progenitor cell (RPC)-to-RGC and human stem cell-to-RGC fate specification, and take a significant step toward understanding neuronal and retinal development and ultimately cell-transplant therapy., (Copyright © 2017 the authors 0270-6474/17/374967-15$15.00/0.)

Published

2017

9. Transplanted neurons integrate into adult retinas and respond to light.

Author

Venugopalan P, Wang Y, Nguyen T, Huang A, Muller KJ, and Goldberg JL

Subjects

Animals, Cell Count, Female, Green Fluorescent Proteins, Immunohistochemistry, Intravitreal Injections, Male, Mice, Patch-Clamp Techniques, Rats, Rats, Sprague-Dawley, Retina, Axons, Dendrites, Geniculate Bodies, Light, Optic Nerve, Retinal Ganglion Cells transplantation, Superior Colliculi

Abstract

Retinal ganglion cells (RGCs) degenerate in diseases like glaucoma and are not replaced in adult mammals. Here we investigate whether transplanted RGCs can integrate into the mature retina. We have transplanted GFP-labelled RGCs into uninjured rat retinas in vivo by intravitreal injection. Transplanted RGCs acquire the general morphology of endogenous RGCs, with axons orienting towards the optic nerve head of the host retina and dendrites growing into the inner plexiform layer. Preliminary data show in some cases GFP(+) axons extending within the host optic nerves and optic tract, reaching usual synaptic targets in the brain, including the lateral geniculate nucleus and superior colliculus. Electrophysiological recordings from transplanted RGCs demonstrate the cells' electrical excitability and light responses similar to host ON, ON-OFF and OFF RGCs, although less rapid and with greater adaptation. These data present a promising approach to develop cell replacement strategies in diseased retinas with degenerating RGCs.

Published

2016

10. Innexin and pannexin channels and their signaling.

Author

Dahl G and Muller KJ

Subjects

Adenosine Triphosphate metabolism, Animals, Connexins genetics, Gap Junctions metabolism, Gap Junctions physiology, Invertebrates chemistry, Invertebrates metabolism, Neuroglia metabolism, Neuroglia physiology, Calcium Signaling, Connexins metabolism, Membrane Potentials

Abstract

Innexins are bifunctional membrane proteins in invertebrates, forming gap junctions as well as non-junctional membrane channels (innexons). Their vertebrate analogues, the pannexins, have not only lost the ability to form gap junctions but are also prevented from it by glycosylation. Pannexins appear to form only non-junctional membrane channels (pannexons). The membrane channels formed by pannexins and innexins are similar in their biophysical and pharmacological properties. Innexons and pannexons are permeable to ATP, are present in glial cells, and are involved in activation of microglia by calcium waves in glia. Directional movement and accumulation of microglia following nerve injury, which has been studied in the leech which has unusually large glial cells, involves at least 3 signals: ATP is the "go" signal, NO is the "where" signal and arachidonic acid is a "stop" signal., (Copyright © 2014 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2014

11. Arachidonic acid closes innexin/pannexin channels and thereby inhibits microglia cell movement to a nerve injury.

Author

Samuels SE, Lipitz JB, Wang J, Dahl G, and Muller KJ

Subjects

Animals, Calcium metabolism, Cell Movement physiology, Gap Junctions drug effects, Leeches metabolism, Nerve Crush methods, Oocytes metabolism, Arachidonic Acid pharmacology, Cell Movement drug effects, Connexins metabolism, Microglia metabolism

Abstract

Pannexons are membrane channels formed by pannexins and are permeable to ATP. They have been implicated in various physiological and pathophysiological processes. Innexins, the invertebrate homologues of the pannexins, form innexons. Nerve injury induces calcium waves in glial cells, releasing ATP through glial pannexon/innexon channels. The ATP then activates microglia. More slowly, injury releases arachidonic acid (ArA). The present experiments show that ArA itself reduced the macroscopic membrane currents of innexin- and of pannexin-injected oocytes; ArA also blocked K(+) -induced release of ATP. In leeches, whose large glial cells have been favorable for studying control of microglia migration, ArA blocked glial dye-release and, evidently, ATP-release. A physiological consequence in the leech was block of microglial migration to nerve injuries. Exogenous ATP (100 µM) reversed the effect, for ATP causes activation and movement of microglia after nerve injury, but nitric oxide directs microglia to the lesion. It was not excluded that metabolites of ArA may also inhibit the channels. But for all these effects, ArA and its non-metabolizable analog eicosatetraynoic acid (ETYA) were indistinguishable. Therefore, ArA itself is an endogenous regulator of pannexons and innexons. ArA thus blocks release of ATP from glia after nerve injury and thereby, at least in leeches, stops microglia at lesions., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

12. Tissue engineering the retinal ganglion cell nerve fiber layer.

Author

Kador KE, Montero RB, Venugopalan P, Hertz J, Zindell AN, Valenzuela DA, Uddin MS, Lavik EB, Muller KJ, Andreopoulos FM, and Goldberg JL

Subjects

Animals, Axons physiology, Cell Survival, Electrophysiological Phenomena, Mice, Rats, Rats, Sprague-Dawley, Tissue Scaffolds chemistry, Nerve Fibers physiology, Retinal Ganglion Cells cytology, Tissue Engineering methods

Abstract

Retinal degenerative diseases, such as glaucoma and macular degeneration, affect millions of people worldwide and ultimately lead to retinal cell death and blindness. Cell transplantation therapies for photoreceptors demonstrate integration and restoration of function, but transplantation into the ganglion cell layer is more complex, requiring guidance of axons from transplanted cells to the optic nerve head in order to reach targets in the brain. Here we create a biodegradable electrospun (ES) scaffold designed to direct the growth of retinal ganglion cell (RGC) axons radially, mimicking axon orientation in the retina. Using this scaffold we observed an increase in RGC survival and no significant change in their electrophysiological properties. When analyzed for alignment, 81% of RGCs were observed to project axons radially along the scaffold fibers, with no difference in alignment compared to the nerve fiber layer of retinal explants. When transplanted onto retinal explants, RGCs on ES scaffolds followed the radial pattern of the host retinal nerve fibers, whereas RGCs transplanted directly grew axons in a random pattern. Thus, the use of this scaffold as a cell delivery device represents a significant step towards the use of cell transplant therapies for the treatment of glaucoma and other retinal degenerative diseases., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

13. Neuroglial ATP release through innexin channels controls microglial cell movement to a nerve injury.

Author

Samuels SE, Lipitz JB, Dahl G, and Muller KJ

Subjects

Animals, Calcium Signaling, Cell Movement, Connexins genetics, Leeches, Microglia, Nerve Crush, Oocytes metabolism, RNA Interference, Trauma, Nervous System metabolism, Xenopus, Adenosine Triphosphate metabolism, Connexins metabolism, Neuroglia metabolism, Neuroglia physiology

Abstract

Microglia, the immune cells of the central nervous system, are attracted to sites of injury. The injury releases adenosine triphosphate (ATP) into the extracellular space, activating the microglia, but the full mechanism of release is not known. In glial cells, a family of physiologically regulated unpaired gap junction channels called innexons (invertebrates) or pannexons (vertebrates) located in the cell membrane is permeable to ATP. Innexons, but not pannexons, also pair to make gap junctions. Glial calcium waves, triggered by injury or mechanical stimulation, open pannexon/innexon channels and cause the release of ATP. It has been hypothesized that a glial calcium wave that triggers the release of ATP causes rapid microglial migration to distant lesions. In the present study in the leech, in which a single giant glial cell ensheathes each connective, hydrolysis of ATP with 10 U/ml apyrase or block of innexons with 10 µM carbenoxolone (CBX), which decreased injury-induced ATP release, reduced both movement of microglia and their accumulation at lesions. Directed movement and accumulation were restored in CBX by adding ATP, consistent with separate actions of ATP and nitric oxide, which is required for directed movement but does not activate glia. Injection of glia with innexin2 (Hminx2) RNAi inhibited release of carboxyfluorescein dye and microglial migration, whereas injection of innexin1 (Hminx1) RNAi did not when measured 2 days after injection, indicating that glial cells' ATP release through innexons was required for microglial migration after nerve injury. Focal stimulation either mechanically or with ATP generated a calcium wave in the glial cell; injury caused a large, persistent intracellular calcium response. Neither the calcium wave nor the persistent response required ATP or its release. Thus, in the leech, innexin membrane channels releasing ATP from glia are required for migration and accumulation of microglia after nerve injury.

Published

2010

14. Optical analysis of circuitry for respiratory rhythm in isolated brainstem of foetal mice.

Author

Muller KJ, Tsechpenakis G, Homma R, Nicholls JG, Cohen LB, and Eugenin J

Subjects

Animals, Brain Stem anatomy & histology, Carbon Dioxide metabolism, Fluorescent Dyes, Mice, Nerve Net anatomy & histology, Organic Chemicals, Brain Stem physiology, Calcium metabolism, Fetus physiology, Microscopy, Fluorescence methods, Nerve Net physiology, Respiratory Mechanics physiology

Abstract

Respiratory rhythms arise from neurons situated in the ventral medulla. We are investigating their spatial and functional relationships optically by measuring changes in intracellular calcium using the fluorescent, calcium-sensitive dye Oregon Green 488 BAPTA-1 AM while simultaneously recording the regular firing of motoneurons in the phrenic nerve in isolated brainstem/spinal cord preparations of E17 to E19 mice. Responses of identified cells are associated breath by breath with inspiratory and expiratory phases of respiration and depend on CO(2) and pH levels. Optical methods including two-photon microscopy are being developed together with computational analyses. Analysis of the spatial pattern of neuronal activity associated with respiratory rhythm, including cross-correlation analysis, reveals a network distributed in the ventral medulla with intermingling of neurons that are active during separate phases of the rhythm. Our experiments, aimed at testing whether initiation of the respiratory rhythm depends on pacemaker neurons, on networks or a combination of both, suggest an important role for networks.

Published

2009

15. Central nervous system regeneration: from leech to opossum.

Author

Mladinic M, Muller KJ, and Nicholls JG

Subjects

Animals, Animals, Newborn, Gene Expression physiology, Nerve Regeneration genetics, Neural Pathways physiology, Central Nervous System physiology, Leeches physiology, Nerve Regeneration physiology, Opossums physiology

Abstract

A major problem of neurobiology concerns the failure of injured mammalian spinal cord to repair itself. This review summarizes work done on two preparations in which regeneration can occur: the central nervous system of an invertebrate, the leech, and the spinal cord of an immature mammal, the opossum. The aim is to understand cellular and molecular mechanisms that promote and prevent regeneration. In the leech, an individual axon regrows successfully to re-establish connections with its synaptic target, while avoiding other neurons. Functions that were lost are thereby restored. Moreover, pairs of identified neurons become re-connected with appropriate synapses in culture. It has been shown that microglial cells and nitric oxide play key roles in leech CNS regeneration. In the opossum, the neonatal brain and spinal cord are so tiny that they survive well in culture. Fibres grow across spinal cord lesions in neonatal animals and in vitro, but axon regeneration stops abruptly between postnatal days 9 and 12. A comprehensive search has been made in spinal cords that can and cannot regenerate to identify genes and establish their locations. At 9 days, growth-promoting genes, their receptors and key transcription molecules are up-regulated. By contrast at 12 days, growth-inhibitory molecules associated with myelin are prominent. The complete sequence of the opossum genome and new methods for transfecting genes offer ways to determine which molecules promote and which inhibit spinal cord regeneration. These results lead to questions about how basic research on mechanisms of regeneration could be 'translated' into effective therapies for patients with spinal cord injuries.

Published

2009

16. ATP and NO dually control migration of microglia to nerve lesions.

Author

Duan Y, Sahley CL, and Muller KJ

Subjects

Aminoquinolines pharmacology, Analysis of Variance, Animals, Cyclic GMP metabolism, Cyclic N-Oxides pharmacology, Dose-Response Relationship, Drug, Enzyme Inhibitors pharmacology, Free Radical Scavengers pharmacology, Imidazoles pharmacology, In Vitro Techniques, Leeches, Microglia physiology, Nucleotides pharmacology, Trauma, Nervous System physiopathology, Triazines, Adenosine Triphosphate pharmacology, Cell Movement drug effects, Microglia drug effects, Nitric Oxide metabolism, Trauma, Nervous System pathology

Abstract

Microglia migrate rapidly to lesions in the central nervous system (CNS), presumably in response to chemoattractants including ATP released directly or indirectly by the injury. Previous work on the leech has shown that nitric oxide (NO), generated at the lesion, is both a stop signal for microglia at the lesion and crucial for their directed migration from hundreds of micrometers away within the nerve cord, perhaps mediated by a soluble guanylate cyclase (sGC). In this study, application of 100 microM ATP caused maximal movement of microglia in leech nerve cords. The nucleotides ADP, UTP, and the nonhydrolyzable ATP analog AMP-PNP (adenyl-5'-yl imidodiphosphate) also caused movement, whereas AMP, cAMP, and adenosine were without effect. Both movement in ATP and migration after injury were slowed by 50 microM reactive blue 2 (RB2), an antagonist of purinergic receptors, without influencing the direction of movement. This contrasted with the effect of the NO scavenger cPTIO (2-(4-carboxyphenyl)-4,4,5,5-teramethylimidazoline-oxyl-3-oxide), which misdirected movement when applied at 1 mM. The cPTIO reduced cGMP immunoreactivity without changing the immunoreactivity of eNOS (endothelial nitric oxide synthase), which accompanies increased NOS activity after nerve cord injury, consistent with involvement of sGC. Moreover, the sGC-specific inhibitor LY83583 applied at 50 microM had a similar effect, in agreement with previous results with methylene blue. Taken together, the experiments support the hypothesis that ATP released directly or indirectly by injury activates microglia to move, whereas NO that activates sGC directs migration of microglia to CNS lesions., (Copyright 2008 Wiley Periodicals, Inc.)

Published

2009

17. Lasting changes in a network of interneurons after synapse regeneration and delayed recovery of sensitization.

Author

Urazaev AK, Arganda S, Muller KJ, and Sahley CL

Subjects

Action Potentials physiology, Action Potentials radiation effects, Animals, Axotomy methods, Behavior, Animal, Dose-Response Relationship, Radiation, Electric Stimulation methods, In Vitro Techniques, Interneurons physiology, Leeches, Models, Neurological, Recovery of Function radiation effects, Reflex physiology, Synaptic Transmission physiology, Time Factors, Interneurons cytology, Nerve Net cytology, Nerve Regeneration physiology, Neuronal Plasticity physiology, Recovery of Function physiology, Synapses physiology

Abstract

Regeneration of neuronal circuits cannot be successful without restoration of full function, including recovery of behavioral plasticity, which we have found is delayed after regeneration of specific synapses. Experiments were designed to measure neuronal changes that may underlie recovery of function. Sensitization of the leech withdrawal reflex is a non-associative form of learning that depends on the S-interneuron. Cutting an S-cell axon in Faivre's nerve disrupted the capacity for sensitization. The S-cell axon regenerated its electrical synapse with its homologous cell after 3-4 weeks, but the capacity for sensitization was delayed for an additional 2-3 weeks. In the present experiments another form of non-associative conditioning, dishabituation, was also eliminated by S-cell axotomy; it returned following regeneration. Semi-intact preparations were made for behavioral studies, and chains of ganglia with some skin were used for intracellular recording and skin stimulation. In both preparations there was a similar time-course, during 6 weeks, of a lesion-induced decrease and delayed restoration of both S-cell action potential threshold to depolarizing pulses and S-cell firing in response to test stimuli. However, the ability of sensitizing stimuli to decrease S-cell threshold and enhance S-cell activity in response to test stimuli did not fully return after regeneration, indicating that there were lasting changes in the circuit extending beyond the period necessary for full recovery of behavior. Intracellular recordings from the axotomized S-cell revealed a shift in the usual balance of excitatory and inhibitory input, with inhibition enhanced. These results indicate that loss of behavioral plasticity of reflexive shortening following axotomy in the S-cell chain may be related to reduced S-cell activity, and that additional processes underlie full recovery of sensitization of the whole body shortening reflex.

Published

2007

18. Innexins form two types of channels.

Author

Bao L, Samuels S, Locovei S, Macagno ER, Muller KJ, and Dahl G

Subjects

Animals, Calcium Signaling, Cytoplasm metabolism, Gap Junctions metabolism, Leeches metabolism, Models, Biological, Neuroglia metabolism, Oocytes metabolism, Patch-Clamp Techniques, Xenopus metabolism, Connexins physiology

Abstract

Injury to the central nervous system triggers glial calcium waves in both vertebrates and invertebrates. In vertebrates the pannexin1 ATP-release channel appears to provide for calcium wave initiation and propagation. The innexins, which form invertebrate gap junctions and have sequence similarity with the pannexins, are candidates to form non-junctional membrane channels. Two leech innexins previously demonstrated in glia were expressed in frog oocytes. In addition to making gap junctions, innexins also formed non-junctional membrane channels with properties similar to those of pannexons. In addition, carbenoxolone reversibly blocked the loss of carboxyfluorescein dye into the bath from the giant glial cells in the connectives of the leech nerve cord, which are known to express the innexins we assayed.

Published

2007

19. Atypical embryonic synapses fail to regenerate in adulthood.

Author

Kloos AD, Muller KJ, and Modney BK

Subjects

Animals, Axotomy, Electrophysiology, Ganglia, Invertebrate injuries, Ganglia, Invertebrate physiology, Interneurons pathology, Interneurons metabolism, Leeches embryology, Nerve Regeneration physiology, Synapses physiology

Abstract

Functional recovery following central nervous system (CNS) injury in adult animals may depend on the reestablishment of the precise pattern of connections made during development. When the nervous system is injured during embryonic development, functional recovery may involve the formation of atypical connections. Can such atypical synapses regenerate in adults, particularly in a nervous system known for its capacity for repair? When the S interneuron in one segmental ganglion of the leech Hirudo is killed during development, two neighboring S cells extend their axons into the ganglion and restore function by making electrical synapses with the usual synaptic targets of the killed S cell. Although adult S-cell axons reliably regenerated their usual synaptic connections, the novel synapses induced following embryonic injury failed to regenerate in adults. In these preparations severed S-cell axons did not reach the denervated ganglion but grew close to it, independent of the distance required to grow. Thus, the developmental changes that permit aberrant but functional connections in embryos do not lead to a similar change in the capacity for axon growth and subsequent synapse regeneration in adults., ((c) 2007 Wiley-Liss, Inc.)

Published

2007

20. Neuronal competition for action potential initiation sites in a circuit controlling simple learning.

Author

Cruz GE, Sahley CL, and Muller KJ

Subjects

Animals, Electric Stimulation, Electrical Synapses physiology, Ganglia, Invertebrate cytology, Ganglia, Invertebrate physiology, Hirudo medicinalis cytology, Interneurons cytology, Nerve Net cytology, Nerve Net physiology, Neural Pathways cytology, Neurons, Afferent physiology, Reflex physiology, Refractory Period, Electrophysiological physiology, Synaptic Transmission physiology, Action Potentials physiology, Hirudo medicinalis physiology, Interneurons physiology, Learning physiology, Nervous System Physiological Phenomena, Neural Pathways physiology

Abstract

The spatial and temporal patterns of action potential initiations were studied in a behaving leech preparation to determine the basis of increased firing that accompanies sensitization, a form of non-associative learning requiring the S-interneurons. Little is known at the network level about mechanisms of behavioral sensitization. The S-interneurons, one in each ganglion and linked by electrical synapses with both neighbors to form a chain, are interposed between sensory and motor neurons. In sensitized preparations the strength of shortening is related to S-cell firing, which itself is the result of impulses initiating in several S-cells. Because the S-cells, as independent initiation sites, all contribute to activity in the chain, it was hypothesized that during sensitization, increased multi-site activity increased the chain's firing rate. However, it was found that during sensitization, the single site with the largest initiation rate, the S-cell in the stimulated segment, suppressed initiations in adjacent ganglia. Experiments showed this was both because (1) it received the earliest, greatest input and (2) the delayed synaptic input to the adjacent S-cells coincided with the action potential refractory period. A compartmental model of the S-cell and its inputs showed that a simple, intrinsic mechanism of inexcitability after each action potential may account for suppression of impulse initiations. Thus, a non-synaptic competition between neurons alters synaptic integration in the chain. In one mode, inputs to different sites sum independently, whereas in another, synaptic input to a single site precisely specifies the overall pattern of activity.

Published

2007

21. Medullary pacemaker neurons are essential for both eupnea and gasping in mammals vs. medullary pacemaker neurons are essential for gasping, but not eupnea, in mammals.

Author

Eugenín JL and Muller KJ

Subjects

Animals, Anti-Inflammatory Agents pharmacology, Anticonvulsants pharmacology, Biological Clocks drug effects, Flufenamic Acid pharmacology, Ion Channels physiology, Mammals physiology, Neurotransmitter Agents physiology, Periodicity, Respiratory Center physiology, Respiratory Physiological Phenomena, Riluzole pharmacology, Biological Clocks physiology, Medulla Oblongata physiology, Neurons physiology, Respiratory Insufficiency physiopathology, Respiratory Mechanics physiology

Published

2007

22. Reduced axon sprouting after treatment that diminishes microglia accumulation at lesions in the leech CNS.

Author

Ngu EM, Sahley CL, and Muller KJ

Subjects

Adenosine Triphosphate physiology, Animals, Central Nervous System injuries, Central Nervous System physiology, Leeches cytology, Microglia cytology, Nerve Crush, Neurons, Afferent cytology, Neurons, Afferent physiology, Nitric Oxide physiology, Time Factors, Wound Healing physiology, Axons physiology, Central Nervous System cytology, Leeches physiology, Microglia metabolism, Nerve Regeneration physiology

Abstract

The role of mammalian microglia in central nervous system (CNS) repair is controversial. Microglia accumulate at lesions where they act as immune cells and phagocytize debris, and they may secrete neurotrophins, but they also produce molecules that can be cytotoxic, like nitric oxide (NO). To determine the importance of microglial accumulation at lesions on growth of severed CNS axons in the leech (Hirudo medicinalis), in which axon and synapse regeneration are notably successful even when isolated in tissue culture medium, microglial migration to lesions was reduced. Pressure (P) sensory neurons were injected with biocytin to reveal the extent of their sprouting 24 hours after lesioning. To reduce microglia accumulation at lesions, cords were treated for 3.5 hours with 3 mM ATP or 2 mM N(omega)-nitro-L-arginine methyl ester (L-NAME) or 50 microM Reactive blue-2 (RB2) beginning 30 minutes before injury. Lesioned controls were either not treated with drug or treated 3 hours later with one of the drugs, after the migration and subsequent accumulation of most microglia had occurred, but before the onset of axon sprouting, for a total of seven separate conditions. There was a significant reduction in total sprout lengths compared with controls when microglial accumulation was reduced. The results suggest that microglial cells are necessary for the usual sprouting of injured axons.

Published

2007

23. Development and pH sensitivity of the respiratory rhythm of fetal mice in vitro.

Author

Eugenín J, von Bernhardi R, Muller KJ, and Llona I

Subjects

Action Potentials physiology, Age Factors, Animals, Animals, Newborn, Brain Stem cytology, Brain Stem embryology, Embryo, Mammalian, Hydrogen-Ion Concentration, In Vitro Techniques, Mice, Spinal Cord cytology, Spinal Cord Injuries physiopathology, Statistics, Nonparametric, Stimulation, Chemical, Motor Neurons physiology, Periodicity, Respiratory Center physiology, Spinal Cord embryology

Abstract

In newborn and adult mammals, chemosensory drive exerted by CO(2) and H(+) provides an essential tonic input: without it the rhythm of respiration is abolished. It is not known, however, whether this chemosensory drive and the respiratory rhythm appear simultaneously during development. In isolated brainstem-spinal cord preparations from fetal mice, we determined at what stage of fetal life the respiratory rhythm appeared in third to fifth cervical ventral roots (phrenic motoneurons) and whether this fetal rhythm was sensitive to chemosensory inputs. A respiratory-like rhythm consisting of short duration bursts of discharges recurring at 2-16 min(-1) was detected in two of nine embryonic day 13 fetuses; it was abolished by transection of the spinal cord between the first to second cervical segments and was phase-related to rhythmic activity from medullary units of the ventral respiratory group. At embryonic day 13, it coexisted with a slow rhythm (0.1-2.0 min(-1)) of long duration bursts of action potentials which was generated by the spinal cord. At later fetal stages, the respiratory-like rhythm became more robust and of higher frequency, while the spinal cord rhythm became less obvious. At all fetal stages, acidification of the superfusion medium from pH 7.5-7.2 or 7.4-7.3 or 7.4 to 7.2 increased the frequency of both the respiratory-like and the spinal cord rhythms. In addition, acidification reduced the amplitude of the integrated burst activity of the spinal cord rhythm of embryonic day 13-embryonic day 16 fetuses and the respiratory-like rhythm of embryonic day 17 and older fetuses. Our results indicate that the rhythms transmitted by phrenic motoneurons during fetal development are chemosensitive from early fetal stages. Through its effects on induction and patterning of the rhythm, chemosensory drive may play a role in activity-dependent formation of respiratory neural networks.

Published

2006

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

Author

Crisp KM and Muller KJ

Subjects

Animals, Cells, Cultured, Feedback physiology, Neuronal Plasticity physiology, Differential Threshold physiology, Excitatory Postsynaptic Potentials physiology, Interneurons physiology, Leeches physiology, Nerve Net physiology, Reflex physiology, Synaptic Transmission physiology

Abstract

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.

Published

2006

25. Optical recording from respiratory pattern generator of fetal mouse brainstem reveals a distributed network.

Author

Eugenin J, Nicholls JG, Cohen LB, and Muller KJ

Subjects

Animals, Brain Mapping, Female, Medulla Oblongata embryology, Mice, Models, Animal, Nerve Net, Pregnancy, Respiratory Mechanics physiology, Brain Stem embryology, Brain Stem physiology, Medulla Oblongata physiology, Respiratory System embryology

Abstract

Unfailing respiration depends on neural mechanisms already present in mammals before birth. Experiments were made to determine how inspiratory and expiratory neurons are grouped in the brainstem of fetal mice. A further aim was to assess whether rhythmicity arises from a single pacemaker or is generated by multiple sites in the brainstem. To measure neuronal firing, a fluorescent calcium indicator dye was applied to embryonic central nervous systems isolated from mice. While respiratory commands were monitored electrically from third to fifth cervical ventral roots, activity was measured optically over areas containing groups of respiratory neurones, or single neurones, along the medulla from the facial nucleus to the pre-Bötzinger complex. Large optical signals allowed recordings to be made during individual respiratory cycles. Inspiratory and expiratory neurones were intermingled. A novel finding was that bursts of activity arose in a discrete area intermittently, occurring during some breaths, but failing in others. Raised CO2 partial pressure or lowered pH increased the frequency of respiration; neurons then fired reliably with every cycle. Movies of activity revealed patterns of activation of inspiratory and expiratory neurones during successive respiratory cycles; there was no evidence for waves spreading systematically from region to region. Our results suggest that firing of neurons in immature respiratory circuits is a stochastic process, and that the rhythm does not depend on a single pacemaker. Respiratory circuits in fetal mouse brainstem appear to possess a high safety factor for generating rhythmicity, which may or may not persist as development proceeds.

Published

2006

26. Repair and regeneration of functional synaptic connections: cellular and molecular interactions in the leech.

Author

Duan Y, Panoff J, Burrell BD, Sahley CL, and Muller KJ

Subjects

Animals, Leeches physiology, Nerve Regeneration physiology, Neural Pathways physiology, Synapses physiology

Abstract

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.

Published

2005

27. Methylene blue blocks cGMP production and disrupts directed migration of microglia to nerve lesions in the leech CNS.

Author

Duan Y, Haugabook SJ, Sahley CL, and Muller KJ

Subjects

Animals, Axons drug effects, Axons physiology, Cell Movement physiology, Central Nervous System injuries, Central Nervous System pathology, Central Nervous System physiopathology, Microglia physiology, Nerve Crush, Neural Conduction drug effects, Neural Conduction physiology, Nitric Oxide adverse effects, Nitric Oxide Synthase, Nitric Oxide Synthase Type III, Cell Movement drug effects, Cyclic GMP biosynthesis, Enzyme Inhibitors pharmacology, Leeches physiology, Methylene Blue pharmacology, Microglia drug effects

Abstract

Migration and accumulation of microglial cells at sites of injury are important for nerve repair. Recent studies on the leech central nervous system (CNS), in which synapse regeneration is successful, have shown that nitric oxide (NO) generated immediately after injury by endothelial nitric oxide synthase (eNOS) stops migrating microglia at the lesion. The present study obtained results indicating that NO may act earlier, on microglia migration, and aimed to determine mechanisms underlying NO's effects. Injury induced cGMP immunoreactivity at the lesion in a pattern similar to that of eNOS activity, immunoreactivity, and microglial cell accumulation, which were all focused there. The soluble guanylate cyclase (sGC) inhibitor methylene blue (MB) at 60 microM abolished cGMP immunoreactivity at lesions and blocked microglial cell migration and accumulation without interfering with axon conduction. Time-lapse video microscopy of microglia in living nerve cords showed MB did not reduce cell movement but reduced directed movement, with significantly more cells moving away from the lesion or reversing direction and fewer cells moving toward the lesion. The results indicate a new role for NO, directing the microglial cell migration as well as stopping it, and show that NO's action may be mediated by cGMP., (Copyright 2003 Wiley Periodicals, Inc.)

Published

2003

28. Progressive recovery of learning during regeneration of a single synapse in the medicinal leech.

Author

Burrell BD, Sahley CL, and Muller KJ

Subjects

Animals, Axotomy, Electrophysiology, Neural Conduction physiology, Interneurons physiology, Learning physiology, Leeches physiology, Nerve Regeneration physiology, Synapses physiology

Abstract

The leech escape reflex-shortening of the body-can change with nonassociative conditioning, including sensitization, habituation, and dishabituation. Capacity for sensitization, which is an enhancement of the reflex, is lost when a single S-interneuron is ablated, but the reflex response itself remains. In the present experiments, the S-interneuron's axon in the living leech was filled with 6-carboxyfluorescein (6-CF) dye and cut with an argon laser microbeam (lambda = 488 nm). In contrast to sham-operated animals, axotomized preparations did not sensitize, reflecting the key role of the S-cell. By 2 weeks or more, S-cell axons had regenerated and reestablished synapses at their usual locations with neighboring S-cells. By 4 weeks, this restored the ability to sensitize to a level indistinguishable from that of controls, but an intermediate state of recovery was seen from 2-3 weeks after injury-a period not previously examined. The small capacity for sensitization among newly regenerated preparations was significantly lower than in sham controls but appeared higher than in animals whose cut S-cell axon had not regenerated its synapse. The results confirm the crucial role of the S-cell in sensitization. Moreover, full sensitization does not occur immediately upon synapse regeneration., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

29. Differential effects of serotonin enhance activity of an electrically coupled neural network.

Author

Burrell BD, Sahley CL, and Muller KJ

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Electric Conductivity, Leeches, Nerve Net drug effects, Neuronal Plasticity drug effects, Neuronal Plasticity physiology, Neurons drug effects, Neurotransmitter Agents pharmacology, Nerve Net physiology, Neurons physiology, Serotonin pharmacology

Abstract

Networks of electrically coupled neurons play an important role in coordinating activity among widely distributed neurons in the CNS. Such networks are sensitive to neuromodulation; but how modulation of individual cells affects activity of the entire network is not well understood. In the CNS of the medicinal leech, the S interneuron (S-cell) forms a network of electrically coupled neurons where each S-cell is linked to its two neighboring S-cells by electrical synapses. An action potential initiated in one cell is carried the length of the animal along this S-cell chain. The S-cell network is of interest because it is crucial for sensitization and dishabituation of the whole-body shortening reflex, although it is not necessary for reflexive shortening itself. Mechanosensory stimuli that produce shortening will directly elicit a train of action potentials by the S-cell network. This activity reflects the sum of action potential initiations in several S interneurons within the chain. The activity was enhanced by serotonin (5HT) in terms of both the total number of action potentials initiated and the average frequency of these initiations. Increases in evoked activity were accompanied by differential changes in the rates of action potential initiation in individual S-cells. 5HT only weakly enhanced initiations in S-cells that made a large contribution to the network-level response, while initiations in other, less active, S-cells were strongly enhanced by 5HT. This neurotransmitter also modulated the pattern of how activity was distributed throughout the network. 5HT-induced changes in activity patterns of the S-cell network may represent an important component of learning-related neuroplasticity in the leech shortening reflex.

Published

2002

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

Author

De-Miguel FF, Muller KJ, Adams WB, and Nicholls JG

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Animals, Newborn, Axons radiation effects, Axons ultrastructure, Female, Ganglia, Spinal cytology, Ganglia, Spinal drug effects, Ganglia, Spinal radiation effects, Lasers adverse effects, Nerve Degeneration physiopathology, Nerve Regeneration physiology, Opossums, Organ Culture Techniques, Photic Stimulation instrumentation, Photic Stimulation methods, Photochemistry instrumentation, Spinal Cord growth & development, Spinal Cord radiation effects, Spinal Nerve Roots injuries, Spinal Nerve Roots physiology, Spinal Nerve Roots surgery, 3,3'-Diaminobenzidine pharmacology, Axons drug effects, Axotomy methods, Carbocyanines pharmacology, Fluorescent Dyes pharmacology, Photic Stimulation adverse effects, Photochemistry methods, Spinal Cord drug effects

Abstract

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.

Published

2002

31. Multiple sites of action potential initiation increase neuronal firing rate.

Author

Baccus SA, Sahley CL, and Muller KJ

Subjects

Animals, Electrophysiology, Leeches, Mechanoreceptors physiology, Physical Stimulation, Action Potentials physiology, Models, Neurological, Neurons physiology

Abstract

Sensory input to an individual interneuron or motoneuron typically evokes activity at a single site, the initial segment, so that firing rate reflects the balance of excitation and inhibition there. In a network of cells that are electrically coupled, a sensory input produced by appropriate, localized stimulation can cause impulses to be initiated in several places. An example in the leech is the chain of S cells, which are critical for sensitization of reflex responses to mechanosensory stimulation. S cells, one per segment, form an electrically coupled chain extending the entire length of the CNS. Each S cell receives input from mechanosensory neurons in that segment. Because impulses can arise in any S cell and can reliably propagate throughout the chain, all the S cells behave like a single neuron with multiple initiation sites. In the present experiments, well-defined stimuli applied to a small area of skin evoked mechanosensory action potentials that propagated centrally to several segments, producing S cell impulses in those segments. Following pressure to the skin, impulses arose first in the S cell of the same segment as the stimulus, followed by impulses in S cells in other segments. Often four or five separate initiation sites were observed. This timing of impulse initiation played an important role in increasing the frequency of firing. Impulses arising at different sites did not usually collide but added to the total firing rate of the chain. A computational model is presented to illustrate how mechanosensory neurons distribute the effects of a single sensory stimulus into spatially and temporally separated synaptic input. The model predicts that changes in impulse propagation in mechanosensory neurons can alter S cell frequency of firing by changing the number of initiation sites.

Published

2001

32. Non-associative learning and serotonin induce similar bi-directional changes in excitability of a neuron critical for learning in the medicinal leech.

Author

Burrell BD, Sahley CL, and Muller KJ

Subjects

Animals, Behavior, Animal drug effects, Behavior, Animal physiology, Dose-Response Relationship, Drug, Electric Stimulation, Ganglia, Invertebrate cytology, Ganglia, Invertebrate drug effects, Ganglia, Invertebrate physiology, Habituation, Psychophysiologic physiology, In Vitro Techniques, Interneurons cytology, Interneurons drug effects, Learning drug effects, Leeches, Membrane Potentials drug effects, Microelectrodes, Neuronal Plasticity drug effects, Neuronal Plasticity physiology, Reflex drug effects, Reflex physiology, Serotonin pharmacology, Interneurons metabolism, Learning physiology, Serotonin metabolism

Abstract

In studies of the cellular basis of learning, much attention has focused on plasticity in synaptic transmission in terms of transmitter release and the number or responsiveness of neurotransmitter receptors. However, changes in postsynaptic excitability independent of receptors may also play an important role. Changes in excitability of a single interneuron in the leech, the S-cell, were measured during non-associative learning of the whole-body shortening reflex. This interneuron was chosen because it is known to be necessary for sensitization and full dishabituation of the shortening response. During sensitization, S-cell excitability increased, and this enhancement corresponded to facilitation of the shortening reflex and increased S-cell activity during the elicited response. During habituation training, there was a decrement in both the shortening reflex and the elicited S-cell activity, along with decreased S-cell excitability. Conversely, dishabituation facilitated both the shortening response and S-cell activity during shortening, with an accompanying increase in S-cell excitability. Bath application of 1-10 micrometer serotonin (5HT), a modulatory neurotransmitter that is critical for sensitization, for full dishabituation, and for associative learning, increased S-cell excitability. S-cell excitability also increased after stimulation of the serotonergic Retzius cells. However, focal application of serotonin onto the S-cell soma hyperpolarized the interneuron, and bath application of a lower dose of serotonin (0.1 micrometer) decreased excitability. The observed changes in postsynaptic excitability appear to contribute to non-associative learning, and modulatory neurotransmitters, such as serotonin, evidently help regulate excitability. Such changes in S-cell excitability may also be relevant for more complex, associative forms of learning.

Published

2001

33. Nerve injury induces a rapid efflux of nitric oxide (NO) detected with a novel NO microsensor.

Author

Kumar SM, Porterfield DM, Muller KJ, Smith PJ, and Sahley CL

Subjects

Animals, Central Nervous System chemistry, Citrulline metabolism, Leeches, Microglia cytology, NG-Nitroarginine Methyl Ester pharmacology, Nerve Crush, Nitric Oxide analysis, Nitric Oxide Synthase antagonists & inhibitors, Nitric Oxide Synthase metabolism, Nitric Oxide Synthase Type III, Polarography instrumentation, Central Nervous System physiology, Microelectrodes, Nerve Regeneration physiology, Neurons metabolism, Nitric Oxide metabolism

Abstract

An early step in repair of the leech CNS is the appearance of endothelial nitric oxide synthase (eNOS) immunoreactivity and NOS activity, but coincident generation of NO at the lesion after injury has not been shown. This is important because NO can regulate microglial cell motility and axon growth. Indirect measurement of NO with the standard citrulline assay demonstrated that NO was generated within 30 min after nerve cord injury. A polarographic NO-selective self-referencing microelectrode that measures NO flux noninvasively was developed to obtain higher spatial and temporal resolution. With this probe, it was possible to demonstrate that immediately after the leech CNS was injured, NO left the lesion with a mean peak efflux of 803 +/- 99 fmol NO cm(-2) sec(-1). NO efflux exponentially declined to a constant value, as described through the equation f(t) = y(o) + ae(-t/tau), with tau = 117 +/- 30 sec. The constant y(o) = 15.8 +/- 4.5 fmol cm(-2) represents a sustained efflux of NO. Approximately 200 pmol NO cm(-2) is produced at the lesion (n = 8). Thus, injury activates eNOS already present in the CNS and precedes the accumulation of microglia at the lesion, consistent with the hypothesis that NO acts to stop the migrating microglia at the lesion site.

Published

2001

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

Author

Baccus SA, Burrell BD, Sahley CL, and Muller KJ

Subjects

Action Potentials physiology, Animals, Axons ultrastructure, Axotomy, Fluorescent Dyes, Isoquinolines, Mechanoreceptors physiology, Microscopy, Electron, Neural Conduction physiology, Neurons ultrastructure, Pressure, Reflex, Monosynaptic physiology, Synaptic Transmission physiology, Axons physiology, Excitatory Postsynaptic Potentials physiology, Learning physiology, Leeches physiology, Neurons physiology

Abstract

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.

Published

2000

35. Nitric oxide influences injury-induced microglial migration and accumulation in the leech CNS.

Author

Chen A, Kumar SM, Sahley CL, and Muller KJ

Subjects

Animals, Cell Movement drug effects, Enzyme Inhibitors pharmacology, Leeches, Microglia drug effects, NG-Nitroarginine Methyl Ester pharmacology, Nerve Crush, Nitric Oxide Donors pharmacology, Nitric Oxide Synthase antagonists & inhibitors, Nitrogen Oxides, Spermine analogs & derivatives, Spermine pharmacology, Central Nervous System injuries, Microglia pathology, Microglia physiology, Nitric Oxide physiology, Wounds and Injuries pathology, Wounds and Injuries physiopathology

Abstract

Damage to the leech or mammalian CNS increases nitric oxide (NO) production and causes accumulation of phagocytic microglial cells at the injury site. The aim of this study was to determine whether NO plays a role in microglial migration and accumulation at lesions in which NO is generated by a rapidly appearing endothelial nitric oxide synthase (eNOS) in leeches. Immunohistochemistry and cytochemistry demonstrated active eNOS before and throughout the period of microglial accumulation at the lesion. Decreasing NO synthesis by application of the NOS inhibitor N(w)-nitro-L-arginine methyl ester (1 mM) significantly reduced microglial accumulation, whereas its inactive enantiomer N(w)-nitro-D-arginine methyl ester (1 mM) resulted in microglial accumulation similar to that in crushed controls. Increasing NO with the donor spermine NONOate (SPNO) (1 mM) also inhibited accumulation, but not in the presence of the NO scavenger 2-(4-carboxyphenyl)-4,4,5, 5-teramethylimidazoline-oxyl-3-oxide (50 microM). The effect of SPNO was reversed by washout. SPNO application reduced average microglial migratory speeds and even reversibly arrested cell movement, as measured in living nerve cords. These results suggest that NO produced at a lesion may be a stop signal for microglia to accumulate there and that it can act on microglia early in their migration. Thus, NO may assume a larger role in nerve repair and recovery from injury by modulating accumulation of microglia, which appear to be important for axonal regeneration.

Published

2000

36. Injury-induced expression of endothelial nitric oxide synthase by glial and microglial cells in the leech central nervous system within minutes after injury.

Author

Shafer OT, Chen A, Kumar SM, Muller KJ, and Sahley CL

Subjects

Animals, Calmodulin antagonists & inhibitors, Freezing, Immunohistochemistry, Leeches, Microglia physiology, NADPH Dehydrogenase analysis, Nerve Crush, Nerve Regeneration, Neuroglia physiology, Nitric Oxide Synthase biosynthesis, Nitric Oxide Synthase Type III, Sulfonamides pharmacology, Synapses physiology, Trauma, Nervous System, Gene Expression Regulation, Enzymologic, Microglia enzymology, Nervous System enzymology, Neuroglia enzymology, Nitric Oxide Synthase metabolism

Abstract

It is known that nitric oxide (NO) is produced by injured tissues of the mammalian central nervous system (CNS) within days of injury. The aim of the present experiments was to determine the cellular synthesis of NO in the CNS immediately after injury, using the CNS of the leech which is capable of synapse regeneration, as a step towards understanding the role of NO in nerve repair. We report that within minutes after crushing the nerve cord of the leech, the region of damage stained histochemically for NADPH diaphorase, which is indicative of nitric oxide synthase (NOS) activity, and was immunoreactive for endothelial NOS (eNOS). On immunoblots of leech CNS extract, the same antibody detected a band with a relative molecular mass of 140,000, which is approximately the size of vertebrate eNOS. Cells expressing eNOS immunoreactivity as a result of injury were identified after freezing nerve cords, a procedure that produced less tissue distortion than mechanical crushing. Immunoreactive cells included connective glia and some microglia. Calmodulin was necessary for the eNOS immunoreactivity: it was blocked by calmodulin antagonist W7 (25 microM), but not by similar concentrations of the less potent calmodulin antagonist W12. Thus in the leech CNS, in which axon and synapse regeneration is successful, an increase in NOS activity at lesions appears to be among the earliest responses to injury and may be important for repair of axons.

Published

1998

37. Regeneration of a central synapse restores nonassociative learning.

Author

Modney BK, Sahley CL, and Muller KJ

Subjects

Animals, Axons physiology, Behavior, Animal physiology, Denervation, Electrophysiology, Ganglia, Invertebrate cytology, Ganglia, Invertebrate physiology, Ganglia, Invertebrate surgery, Leeches, Neurons, Afferent physiology, Neurons, Afferent ultrastructure, Sensitivity and Specificity, Conditioning, Psychological physiology, Nerve Regeneration physiology, Synapses physiology

Abstract

Sensitization is a form of nonassociative learning in which a strong or noxious stimulus persistently enhances the response produced by a weaker stimulus. In the leech Hirudo medicinalis, the S-interneuron is required for sensitization of the shortening response. A single S-cell axon was surgically separated from its sole synaptic partner, the neighboring S-cell. This consistently eliminated sensitization without impairing reflexive shortening itself, as measured in semi-intact specimens. Sensitization of the shortening reflex returned after 3 weeks when the severed axon grew and regenerated its specific electrical synapse within the nerve cord, as shown by restored conduction of impulses between S-cells. This confirms the essential role of one neuron, the S-cell, in sensitization, and it demonstrates that regeneration of the synapse between S-cells restores this example of nonassociative learning.

Published

1997

38. Neurite outgrowth through lesions of neonatal opossum spinal cord in culture.

Author

Varga ZM, Fernandez J, Blackshaw S, Martin AR, Muller KJ, Adams WB, and Nicholls JG

Subjects

Animals, Animals, Newborn, Axons physiology, Cells, Cultured, Electric Stimulation, Ganglia, Spinal cytology, Ganglia, Spinal physiology, Nerve Crush, Neurons physiology, Spinal Cord Injuries pathology, Synapses physiology, Video Recording, Nerve Fibers physiology, Nerve Regeneration physiology, Neurites physiology, Spinal Cord Injuries physiopathology

Abstract

The aim of these experiments was to analyze neurite outgrowth during regeneration of opossum spinal cord isolated from Monodelfis domestica and maintained in culture for 3-5 days. Lesions were made by crushing with forceps. In isolated spinal cords of animals aged 3 days, neurites entered the crush and grew along the basal lamina of the pia mater. Growth cones with pleiomorphic appearance containing vesicles, mitochondria and microtubules were abundant in the marginal zone, as were synaptoid contacts with active zones facing basal lamina. In preparations from animals aged 11-12 days, the lesion site was disrupted and contained only degenerating axons, debris and vesicles. Axons and growth cones entered the edge of the lesion but did not extend into it. Lesions in young animals extended over distances of more than 1 mm and contained no radial glia. The damaged area in older preparations was restricted to the crush site with normal astrocytes, oligodendrocytes and neurons immediately adjacent to the lesion. Thus, similar crushes produced more extensive damage in younger spinal cords that were capable of regeneration than in older cords that were not. Dorsal root ganglion fibers labeled with carbocyanine dye (DiI) were observed by video imaging as they grew through lesions. Individual growth cones examined subsequently by electron microscopy had grown again along pial basal lamina. After 5 days in culture dorsal root stimulation gave rise to discharges in ventral roots beyond the lesion indicating that synaptic connections were formed by growing fibers.

Published

1996

39. Accurate synapse regeneration despite ablation of the distal axon segment.

Author

Mason A and Muller KJ

Subjects

Animals, Axons ultrastructure, Electric Stimulation, Electrophysiology, Endopeptidases, Ganglia, Invertebrate cytology, Leeches, Microglia physiology, Microglia ultrastructure, Microscopy, Electron, Nerve Crush, Synapses ultrastructure, Axons physiology, Ganglia, Invertebrate physiology, Nerve Regeneration, Synapses physiology

Abstract

In each body ganglion of the leech Hirudo medicinalis there is a single S-cell. After an S-cell axon is severed, it regenerates along its surviving distal segment and reconnects with its synaptic target, the axon of the neighbouring S-cell. In approximately half the cases the regenerating axon forms a temporary electrical synapse specifically with the distal segment, which remains active and connected to the target, thereby functioning as a splice until regeneration is complete. To determine whether the distal axon segment is required for successful regeneration, distal segments of severed S-cell axons were ablated by intracellular injection of bacterial protease. Fifty-seven preparations were examined from 2 to 212 days after injection of the axon segment. The extent of S-cell axon regeneration was assessed electrophysiologically by intracellular and extracellular recording, and anatomically by intracellular injection of markers followed by light microscopy and electron microscopy. The S-cell axons regenerated successfully in almost 90% of animals examined after 2 weeks or more. In a further four animals the target S-cell was ablated in addition to the distal axon segment, permanently disrupting conduction along the S-cell pathway. Nevertheless, the regenerating axon grew along its usual pathway and there was no evidence that alternative connections were formed. It is concluded that, although the distal axon segment can provide a means for rapid functional repair, the segment is not required for reliable regeneration of the axon along its usual pathway and accurate formation of an electrical synapse.

Published

1996

40. Repair of the central nervous system: lessons from lesions in leeches.

Author

von Bernhardi R and Muller KJ

Subjects

Animals, Central Nervous System cytology, Neurons physiology, Synapses physiology, Central Nervous System physiology, Leeches physiology, Nerve Regeneration physiology

Abstract

In contrast to the limited repair observed in the mammalian central nervous system (CNS), injured neurons in the leech reliably regenerate synapses and restore function with remarkable accuracy at the level of individual neurons. New and recent results reveal important roles for microglial cells and extracellular matrix components, including laminin, in repair. Tissue culture experiments have permitted isolation of neurons and manipulation of their environment, providing insights into the influence of substrate, electrical activity, and other cells, including microglia, on axon growth and synapse formation. The results account for distinctive features of successful repair in the adult leech, where axonal sprouting and target selection can be influenced by unequal competition between neurons. Differences between the formation of connections during embryonic development and repair in the adult include dissimilarities in the roles of glia and microglia in adults and embryos, suggesting that axon growth during regeneration in the CNS is not simply a recapitulation of processes observed during embryonic development. It may be possible in the future to improve mammalian CNS regeneration by recruiting cells whose counterparts in the leech have been identified as instrumental in repair.

Published

1995

41. In situ hybridization reveals transient laminin B-chain expression by individual glial and muscle cells in embryonic leech central nervous system.

Author

Luebke AE, Dickerson IM, and Muller KJ

Subjects

Amino Acid Sequence, Animals, Base Sequence, Central Nervous System cytology, Embryo, Nonmammalian metabolism, In Situ Hybridization, Leeches embryology, Molecular Sequence Data, Neuroglia metabolism, Neuromuscular Junction physiology, Peptide Fragments isolation & purification, Species Specificity, Time Factors, Central Nervous System metabolism, Gene Expression Regulation, Developmental physiology, Laminin chemistry, Nerve Tissue Proteins chemistry, Peptide Fragments genetics

Abstract

Laminin, which strongly stimulates axon outgrowth in vitro, appears transiently within the central nervous system (CNS) in embryos. After CNS injury, laminin reportedly reappears along axonal pathways only in animal species in which central axon regeneration is successful, including the leech Hirudo medicinalis. Although glia have been suspected of making CNS laminin, in adult leeches glia are not required for laminin synthesis and evidently microglia, not present in the early embryo, produce laminin. To determine which embryonic cells make laminin, a 1.2 kb DNA fragment of leech laminin B1 chain, with homology to Drosophila, human, and mouse B1 laminins and rat S laminin, was isolated using reverse-transcription and degenerate polymerase chain reaction (PCR) cloning. In situ hybridization revealed that laminin expression began before embryonic day 8, and by days 8 and 9 it was seen in paired CNS muscle cells. By late day 9, the two neuropil glial cells began to express laminin. Lucifer Yellow dye was injected intracellularly and muscle cells stimulated to contract, confirming the identities of muscle and glial cells. Packet glial cells began to express B1 laminin by embryonic day 12. By day 15, the cells of the perineurial sheath expressed B1 laminin, whereas it was no longer detectable in CNS muscle and glia. The results agree with published immunohistochemistry showing laminin within the CNS among growing axons by day 8, and only later in the perineurial sheath, by which time laminin disappears from within the CNS. Therefore, different cells synthesize laminin in the embryo and during repair in adults.

Published

1995

42. Novel synapses compensate for a neuron ablated in embryos.

Author

Modney BK and Muller KJ

Subjects

Action Potentials, Animals, Embryo, Nonmammalian physiology, Ganglia, Invertebrate embryology, Interneurons cytology, Interneurons physiology, Leeches embryology, Ganglia, Invertebrate physiology, Neurons physiology, Synapses physiology

Abstract

In leeches, as well as mammals, neuronal death in adults produces lasting deficits, whereas the embryonic nervous system is believed to be more plastic. Killing the single S interneuron in an adult leech ganglion permanently interrupts the chain of S cells linked by electrical synapses along the entire animal. Axons that synapsed with the ablated neuron do not change length in response to cell ablation, but they will grow if another axon of the same neuron is injured. In the present experiments, the S cell and surrounding cells in one ganglion were ablated with a fine pin during embryogenesis (day 8-11). Effects were evaluated 1-4 months later. Cell-specific monoclonal antibody confirmed S cell deletions. Intracellular injection of horseradish peroxidase and 6-carboxyfluorescein dye showed that intact S cells' axons projected twice their usual length into the lesioned ganglion and formed electrical synapses with homologues of their usual synaptic targets. Conduction was often restored by these connections, which replaced those of the deleted S cell. Therefore, in both adults and embryos, growing S interneurons respond to loss of a target by greater growth. However, only on the small scale of the embryo is growth sufficient to reach suitable targets.

Published

1994

43. Axonal sprouting and laminin appearance after destruction of glial sheaths.

Author

Masuda-Nakagawa LM, Muller KJ, and Nicholls JG

Subjects

Animals, Axons ultrastructure, In Vitro Techniques, Laminin analysis, Leeches, Nerve Fibers ultrastructure, Nervous System cytology, Neurons cytology, Neurons physiology, Serotonin analysis, Serotonin metabolism, Axons physiology, Laminin metabolism, Nerve Fibers physiology, Nervous System Physiological Phenomena, Neuroglia physiology

Abstract

Laminin, a large extracellular matrix molecule, is associated with axonal outgrowth during development and regeneration of the nervous system in a variety of animals. In the leech central nervous system, laminin immunoreactivity appears after axon injury in advance of the regenerating axons. Although studies of vertebrate nervous system in culture have implicated glial and Schwann cells as possible sources, the cells that deposit laminin at sites crucial for regeneration in the living animal are not known. We have made a direct test to determine whether, in the central nervous system of the leech, cells other than ensheathing glial cells can produce laminin. Ensheathing glial cells of adult leeches were ablated selectively by intracellular injection of a protease. As a result, leech laminin accumulated within 10 days in regions of the central nervous system where it is not normally found, and undamaged, intact axons began to sprout extensively. In normal leeches laminin immunoreactivity is situated only in the basement membrane that surrounds the central nervous system, whereas after ablation of ensheathing glia it appeared in spaces through which neurons grew. Within days of ablation of the glial cell, small mobile phagocytes, or microglia, accumulated in the spaces formerly occupied by the glial cell. Microglia were concentrated at precisely the sites of new laminin appearance and axon sprouting. These results suggest that in the animal, as in culture, leech laminin promotes sprouting and that microglia may be responsible for its appearance.

Published

1993

44. Synaptic integration at a sensory-motor reflex in the leech.

Author

Gu XN, Muller KJ, and Young SR

Subjects

Action Potentials physiology, Animals, Dendrites physiology, In Vitro Techniques, Leeches, Synaptic Transmission physiology, Motor Neurons physiology, Reflex physiology, Synapses physiology

Abstract

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.

Published

1991

45. Unequal competition between axons for neuronal targets.

Author

Muller KJ and Gu XN

Subjects

Animals, Axons ultrastructure, Denervation, Ganglia growth & development, Leeches physiology, Nerve Regeneration physiology, Nervous System Physiological Phenomena, Neurons, Afferent cytology, Leeches growth & development, Nervous System growth & development

Abstract

Precise wiring of the nervous system depends not only on a matching between neurons and their synaptic targets, but also upon competition between neurons for particular targets. Neurons in adult leeches regenerate synaptic connections with their usual neuronal targets in the central nervous system, selecting only those targets with which they connect during embryogenesis. Thus during development axons of nociceptive (N) sensory cells make contacts on the cell bodies of certain neurons in adjacent ganglia but not upon those same types of cells in their own ganglion. After injury the N cell axons accurately regenerate contacts on the appropriate target cells. An abnormal feature observed after injury is that N cell axons sprout and grow to make contacts upon cell bodies within their own ganglion. This is a consequence of the normal innervation of those cells having been removed, thereby eliminating the source of competition. Similar competition during embryogenesis may guide the formation of selective connections.

Published

1991

46. Accumulation of laminin and microglial cells at sites of injury and regeneration in the central nervous system of the leech.

Author

Masuda-Nakagawa LM, Muller KJ, and Nicholls JG

Subjects

Animals, Extracellular Matrix physiology, Fluorescent Antibody Technique, Ganglia cytology, Ganglia physiology, Ganglia ultrastructure, Laminin metabolism, Leeches, Mesoderm physiology, Microscopy, Electron, Nervous System cytology, Serotonin analysis, Laminin physiology, Nervous System Physiological Phenomena, Neurons physiology

Abstract

Profuse sprouting of leech neurons occurs in culture when they are plated on a substrate consisting of laminin molecules extracted from extracellular matrix that surrounds the central nervous system (CNS). To assess the role of laminin as a potential growth-promoting molecule in the animal, its distribution was compared in intact and regenerating CNS by light and electronmicroscopy, after it had been labelled with an anti-leech-laminin monoclonal antibody (206) and conjugated second antibodies. In frozen sections and electron micrographs of normal leeches the label was restricted to the connective-tissue capsule surrounding the connectives that link ganglia. Immediately after the connectives had been crushed the normal structure was disrupted but laminin remained in place. Two days after the crush, axons began to sprout vigorously and microglial cells accumulated in the lesion. At the same time, labelled laminin molecules were no longer restricted to the basement membrane but appeared within the connectives in the regions of neurite outgrowth. The distribution of laminin at these new sites within the CNS was punctate at two days, but changed over the following two weeks: the laminin became aggregated as condensed streaks running longitudinally within the connectives beyond the lesion. The close association of regenerating axons with laminin suggests that it may promote axonal growth in the CNS of the animal as in culture.

Published

1990

47. Expression of surface glycoproteins early in leech neural development.

Author

McGlade-McCulloh E, Muller KJ, and Zipser B

Subjects

Animals, Antibodies, Monoclonal, Embryo, Nonmammalian physiology, Epitopes analysis, Microscopy, Electron, Neurons, Afferent physiology, Neurons, Afferent ultrastructure, Leeches embryology, Membrane Glycoproteins analysis, Nervous System embryology

Abstract

Cell migration and axon growth during neural development rely upon cell-cell and cell-matrix interactions mediated by surface glycoproteins. The surface glycoprotein recognized on leech neurons by monoclonal antibody Lan3-2 has previously been implicated in the process of axon fasciculation during regeneration in adults. In adult leeches, Lan3-2 binds to a carbohydrate epitope of a 130 kD protein. The present study demonstrates that in embryos the antibody binds to the same carbohydrate epitope of glycoproteins with molecular weights of 130 kD and higher. As a first step in evaluating a possible role of the Lan3-2 glycoprotein or the cells that express it during neural development, we determined its distribution in the developing nervous system of the leech Hirudo medicinalis. In embryos, Lan3-2 epitope is expressed on fasciculated sensory afferents and it appears on the cell bodies before neurite outgrowth. The sensory fibers appear rostrally by embryonic day 10, less than halfway through development. Earlier, by 7 days of development at 20 degrees C, Lan3-2 binds to previously undocumented cell types: (1) cells appearing along the embryonic midline and (2) a cluster of cells located at the rostral edge of the germinal plate. These cells only transiently express this antigen and are present at critical left-right and rostrocaudal boundaries during a period of cell proliferation, movement, and migration that produces the nervous system. Thus the Lan3-2 surface glycoprotein or the cells expressing it are candidates for involvement in axon fasciculation, cell migration, and directed axonal growth.

Published

1990

48. Nerve fiber growth and the cellular response to axotomy.

Author

Carbonetto S and Muller KJ

Subjects

Animals, Axonal Transport, Cytoskeleton ultrastructure, Glycosaminoglycans metabolism, Microscopy, Electron, Scanning, Microtubules ultrastructure, Muscles innervation, Nerve Degeneration, Nerve Tissue Proteins metabolism, Neural Conduction, Neurons ultrastructure, Nissl Bodies ultrastructure, Synapses ultrastructure, Synaptic Transmission, Axons ultrastructure, Nerve Fibers ultrastructure, Nerve Regeneration

Published

1982

49. Different properties of synapses between a single sensory neurone and two different motor cells in the leech C.N.S.

Author

Muller KJ and Nicholls JG

Subjects

Animals, Calcium, Cold Temperature, Electric Stimulation, Neural Inhibition, Synaptic Transmission, Action Potentials, Leeches physiology, Mechanoreceptors physiology, Motor Neurons physiology, Synapses physiology

Abstract

In leech ganglia, an individual sensory cell that responds specifically to noxious mechanical stimulation of the skin (N cell) excites two different motoneurones. One raises the annuli of the skin into ridges (the AE cell), while the other innervates logitudinal muscles and thereby shortens the body segment (L cell). A comparison has been made of the way in which these two synapses behave when their common presynaptic cell is stimulated in various conditions.1. Using previously described criteria, N sensory cells have been shown to make monosynaptic chemical connexions with both the AE and L motoneurones (Nicholls & Purves, 1972). Following a single stimulus, the excitatory synaptic potential recorded in the AE motoneurone was only about one tenth the size of that in the L cell (approximately 0.5 mV compared to 5 mV). Trains of impulses in the same N sensory cell gave rise to synaptic potentials in the AE and the L motoneurones that underwent phases of facilitation and depression; the facilitation, however, was characteristically greater and longer lasting at synapses upon the AE motoneurone.2. The differences between the two synapses were accentuated in Ringer fluid containing increased concentrations of Ca and also in the cold. Under both of these conditions repetitive firing by the N sensory cell could give rise to synaptic potentials in the AE motoneurone which progressively increased in amplitude, while those in the L motoneurone became smaller.3. The results suggest that the differences in synaptic transmission can be accounted for by variations in the amount of transmitter released at the presynaptic N cell terminals, rather than by differences in the post-synaptic cells. The animal's behaviour corresponds to expectations from the physiology of the synapses.

Published

1974

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

Author

Gu XN, Macagno ER, and Muller KJ

Subjects

Animals, Evoked Potentials, Lasers, Intercellular Junctions physiology, Leeches physiology, Neurons, Afferent physiology, Synaptic Transmission

Abstract

Touch (T) sensory neurons in the leech innervate defined regions of skin and synapse on other neurons, including other T cells, within the ganglionic neuropil. The cells' receptive fields in the periphery are comprised of a central region, innervated by thick axons, and adjoining regions (minor fields) innervated by thinner axons. Secondary branches, known to be sites of synapses, emerge from the thinner and thicker axons. Pairs of T cells appear to make up to 200 separate contacts distributed within the neuropil. When the T cell is hyperpolarized, as occurs during natural stimulation of the cell, action potentials generated in the minor field and travelling into the ganglion along the thin axons may fail to conduct at central branch points. Evidence is presented, using axon conduction block and laser axotomy of cells filled with 6-carboxy-fluorescein, that synapses between separate groups of branches can function independently. Thus, selective activation of branches of the thin anterior axon produced a synaptic potential 36 +/- 6% of control amplitude, which was consistent with counts of 39 +/- 6% of contacts made by these branches. Laser axotomy of postsynaptic neurons showed that the anterior contacts indeed made the principal or only contacts activated during anterior conduction block. The results show that conduction block can modulate transmission within the ganglion, and it operates by silencing particular contacts between cells.

Published

1989