Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are tw... more Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are two major phorbol ester-activated PKCs, Ca 2 �-activated PKC Apl I and Ca 2 �-independent PKC Apl II. Functional Apl II, but not Apl I, in sensory neurons is required for a form of short-term facilitation induced at sensorimotor synapses by the facilitatory transmitter serotonin (5-HT). Because PKCs are activated by translocating from the cytoplasm to the membrane, we used fluorescently tagged PKCs to determine the isoform and cell-type specificity of translocation in living Aplysia neurons. In Sf9 cells, low levels of diacylglycerol translocate Apl II, but not Apl I, which requires calcium for translocation at low concentrations of diacylglycerol. Accordingly, application of 5-HT to Aplysia sensory neurons in the absence of neuronal firing translocates Apl II, but not Apl I, consistent with the role of Apl II in short-term facilitation. This translocation is observed in sensory neurons, b...
Rapid development of to examine the influence of synapse age on the expression synaptic connectio... more Rapid development of to examine the influence of synapse age on the expression synaptic connections and plasticity between sensory neurons and of short-term synaptic modulation. More generally, we were motor neurons of Aplysia in cell culture: implications for learning interested in examining the relationships among synapse forand regulation of synaptic strength. J. Neurophysiol. 77: 2316mation in regenerating adult neurons, in development, and 2327, 1997. We describe here the time course of functional synapse in learning.
We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin... more We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin. These proteins belong to a family of calcium-binding proteins, found primarily in vertebrate brain and retina, that have been proposed to play a role in calcium-dependent regulation of enzymes in signal transduction pathways. Like other members of this family, the Aplysia proteins have consensus sequences for myristoylation, bind calcium, and translocate from cytosol to membrane when the calcium level is raised above the resting intracellular concentration. Both proteins are relatively enriched in Aplysia nervous system, but are also found to a significant degree in other tissues. The expression of mRNA for these proteins in Aplysia nervous tissue is regulated during development, roughly paralleling the reported emergence of several forms of synaptic plasticity. The messages are present at low levels in stage 11, show a large increase by late stage 12, and decline to a plateau of -~~3O% of the peak value afterward. On the basis of the properties of these proteins and by analogy with proposed functions of some of the retinal homologues, we suggest that these proteins may play a role in mediating calcium-dependent processes in neuronal function. The presence of both proteins in other tissues may suggest analogous roles for the proteins in other cell types.
Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are tw... more Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are two major phorbol ester-activated PKCs, Ca 2ϩ -activated PKC Apl I and Ca 2ϩ -independent PKC Apl II. Functional Apl II, but not Apl I, in sensory neurons is required for a form of short-term facilitation induced at sensorimotor synapses by the facilitatory transmitter serotonin (5-HT). Because PKCs are activated by translocating from the cytoplasm to the membrane, we used fluorescently tagged PKCs to determine the isoform and cell-type specificity of translocation in living Aplysia neurons. In Sf9 cells, low levels of diacylglycerol translocate Apl II, but not Apl I, which requires calcium for translocation at low concentrations of diacylglycerol. Accordingly, application of 5-HT to Aplysia sensory neurons in the absence of neuronal firing translocates Apl II, but not Apl I, consistent with the role of Apl II in short-term facilitation. This translocation is observed in sensory neurons, but not in motor neurons. Apl I translocates only if 5-HT is coupled to firing in the sensory neuron; firing alone is ineffective. Because combined 5-HT and firing are required for the induction of one type of intermediate-term facilitation at these synapses, we asked whether this form of synaptic plasticity involves activation of Apl I. We report here that dominantnegative Apl I, but not Apl II, blocks intermediate-term facilitation. Thus, different isoforms of PKC translocate under different conditions to mediate distinct types of synaptic plasticity: Ca 2ϩ -independent Apl II is involved in short-term facilitation, and Ca 2ϩ -dependent Apl I contributes to intermediate-term facilitation.
Regulation of synaptic transmission by modulation of the calcium influx that triggers transmitter... more Regulation of synaptic transmission by modulation of the calcium influx that triggers transmitter release underlies different forms of synaptic plasticity, and thus could contribute to learning. In the mollusk Aplysia, the neuromodulator serotonin (5-HT) increases evoked transmitter release from sensory neurons and thereby contributes to dishabituation and sensitization of defensive reflexes. We combined electrophysiological recording with fluorescence measurements of intracellular calcium in sensory neuron synapses in culture to test whether direct up-modulation by 5-HT of calcium influx triggered by single action potentials contributes to facilitation of transmitter release. We observe increases in a previously undescribed calcium influx that are strongly correlated with increases in the amplitude of the evoked postsynaptic potentials and which cannot be accounted for by action potential prolongation. Our results suggest that direct modulation of a presynaptic calcium conductance that controls neurotransmitter release contributes to the presynaptic facilitation that underlies a simple form of learning.
We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin... more We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin. These proteins belong to a family of calcium-binding proteins, found primarily in vertebrate brain and retina, that have been proposed to play a role in calcium-dependent regulation of enzymes in signal transduction pathways. Like other members of this family, the Aplysia proteins have consensus sequences for myristoylation, bind calcium, and translocate from cytosol to membrane when the calcium level is raised above the resting intracellular concentration. Both proteins are relatively enriched in Aplysia nervous system, but are also found to a significant degree in other tissues. The expression of mRNA for these proteins in Aplysia nervous tissue is regulated during development, roughly paralleling the reported emergence of several forms of synaptic plasticity. The messages are present at low levels in stage 11, show a large increase by late stage 12, and decline to a plateau of -~~3O% of the peak value afterward. On the basis of the properties of these proteins and by analogy with proposed functions of some of the retinal homologues, we suggest that these proteins may play a role in mediating calcium-dependent processes in neuronal function. The presence of both proteins in other tissues may suggest analogous roles for the proteins in other cell types.
Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from me... more Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from mechanoreceptor sensory neurons of Aplysia are involved in habituation and sensitization, respectively, of defensive withdrawal reflexes. We investigated whether synaptic ...
Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from me... more Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from mechanoreceptor sensory neurons of Aplysia are involved in habituation and sensitization, respectively, of defensive withdrawal reflexes. We investigated whether synaptic transmission is regulated in these forms of plasticity by means of changes in the size of the pool of transmitter available for immediate release [the readily releasable pool (RRP)] or in the efficacy of release from an unchanging pool. Using sensorimotor synapses formed in cell culture, we estimated the number of transmitter quanta in the RRP from the asynchronous release of neurotransmitter caused by application of a hypertonic bathing solution. Our experiments indicate that the transmitter released by action potentials and by hypertonic solution comes from the same pool. The RRP was reduced after homosynaptic depression of the EPSP by low-frequency stimulation and increased after facilitation of the EPSP by application of the endog-enous facilitatory transmitter serotonin (5-HT) after homosynaptic depression. However, although the fractional changes in the RRP and in the EPSP were similar for both synaptic depression and facilitation when depression was induced by repeated hypertonic stimulation, the changes in the EPSP were significantly greater than the changes in the RRP when depression was induced by repeated electrical stimulation. These observations indicate that homosynaptic depression and restoration of depressed transmission by 5-HT are caused by changes in both the amount of transmitter available for immediate release and in processes involved in the coupling of the action potential to transmitter release.
Proceedings of the National Academy of Sciences of the United States of America, Dec 1, 1984
Noxious stimulation of the tail of Aplysia californica produces behavioral sensitization; it enha... more Noxious stimulation of the tail of Aplysia californica produces behavioral sensitization; it enhances several related defensive reflexes. This reflex enhancement involves heterosynaptic facilitation of transmitter release from sensory neurons of the reflex. The facilitation is stimulated by serotonin (5-HT) and involves suppression of a 5-HT-sensitive K+ current (the S current). Suppression of the S current broadens the action potential of the sensory neurons and is thought to enhance transmitter release by prolonging entry of Ca2+ in the presynaptic terminals. We now report a component of enhanced Ca2+ accumulation that is independent of changes in spike shape. We have measured intracellular free Ca2+ transients during long depolarizing steps in voltage-clamped sensory neuron cell bodies injected with the Ca2+-sensitive dye arsenazo III. The free Ca2+ transients elicited by a range of depolarizing voltage-clamp steps increase in amplitude by 75% following application of 5-HT. Since it is observed under voltage-clamp conditions, this increase in the free Ca2+ transients is not merely secondary to the changes in K+ current but must reflect an additional mechanism, an intrinsic change in the handling of Ca2+ by the cell. We have not yet determined whether this change in Ca2+ handling reflects an increase in Ca2+ influx, a reduction in intracellular Ca2+ uptake, or a release of Ca2+ from intracellular stores. Regardless of the underlying mechanism, however, it seems possible that the enhancement of Ca2+ accumulation and the reduction in K+ current act synergistically in producing short-term presynaptic facilitation. Alternatively, this additional modulation of Ca2+ by 5-HT might contribute to processes such as classical conditioning or long-term sensitization that may depend on Ca2+.
Recent studies indicate that in invertebrates short-term memory for various forms of learning inv... more Recent studies indicate that in invertebrates short-term memory for various forms of learning involves covalent modifications of pre-existing proteins. By contrast, long-term memory utilizes genes and proteins not required for short-term memory.
Short-term augmentation of synaptic transmission at sensory neuron synapses of Aplysia contribute... more Short-term augmentation of synaptic transmission at sensory neuron synapses of Aplysia contributes to behavioral sensitization and is one of the current models for a cellular mechanism of learning. This neuromodulatory process, mediated at least in part by the facilitatory neurotransmitter serotonin (5-HT) acting through cAMP, has been thought to result largely from prolongation of the sensory neuron action potential (AP). The quantitative contribution of AP prolongation to synaptic augmentation was examined using a new culture preparation that is favorable for controlling the voltage at the presynaptic terminals. Preventing AP prolongation by using unvarying voltage-clamp commands in place of triggered APs did not reduce augmentation significantly, and pharmacological prolongation of APs caused by a high concentration of 5-HT led to a negligible increase in the synaptic response. Together with earlier evidence against the involvement of changes in Ca2+ current, these results suggest that synaptic augmentation may result from modulation of steps in the secretory process that lie distal to the flow of ion currents across the nerve terminal membrane.
Synaptic transmission at the sensory neuron-motor neuron synapses of Aplysia, like transmission a... more Synaptic transmission at the sensory neuron-motor neuron synapses of Aplysia, like transmission at many synapses of both vertebrates and invertebrates, is increased after a short burst of high-frequency stimulation (HFS), a phenomenon known as post-tetanic potentiation (PTP). PTP is generally attributable to an increase in transmitter release from presynaptic neurons. We investigated whether changes in the readily releasable pool of transmitter (RRP) contribute to the potentiation that follows HFS. We compared the changes in EPSPs evoked with action potentials to changes in the RRP as estimated from the asynchronous transmitter release elicited by a hypertonic solution. The changes in the EPSP were correlated with changes in the RRP, but the changes matched quantitatively only at connections whose initial synaptic strength was greater than the median for all experiments. At weaker connections, the increase in the RRP was insufficient to account for PTP. Weaker connections initially released a smaller fraction of the RRP with each EPSP than stronger ones, and this fraction increased at weaker connections after HFS. Moreover, the initial transmitter release in response to the hypertonic solution was accelerated after HFS, indicating that the increase in the efficacy of release was not restricted to excitation-secretion coupling. Modulation of the RRP and of the efficacy of release thus both contribute to the enhancement of transmitter release by HFS.
Up and down-regulation of calcium and potassium conductances are associated with several forms of... more Up and down-regulation of calcium and potassium conductances are associated with several forms of short-term synaptic modulation. Detailed investigation of synaptic plasticity in the marine gastropod Aplysia, and in other mollusks, indicates that synaptic transmission can be influenced in a number of ways by modulatory neurotransmitters acting through several second-messenger cascades. Modulation at the synapse itself occurs by means of the regulation of calcium current as well as through effects on processes directly involved in transmitter mobilization and exocytosis. Modulation of potassium current plays a major role in controlling neuronal excitability and may contribute to a lesser extent to the regulation of transmitter release through actions on the resting potential and on action potential configuration.
Nervous tissue of the marine mollusc, Aplysia californica, generates arachidonic acid metabolites... more Nervous tissue of the marine mollusc, Aplysia californica, generates arachidonic acid metabolites in response to neurotransmitters such as histamine or FMRFamide. In addition, identified neurons of Aplysia respond to the pharmacologic application of some of these products, particularly those of the 12-1ipoxygenase pathway. We investigated the chirality of the initial Aplysia 12-1ipoxygenase product, 12-HPETE, in preparation for more detailed metabolic studies and for the analysis of the physiological activity of the endogenous lipid. Neural homogenates and intact ganglia exclusively generate 12(S)-HPETE as do the better characterized mammalian lipoxygenases. The direct application of 12(S)-HPETE to cultured sensory neurons induced a hyperpolarization which averaged 2.6 mV. We did not find any difference between the response to the naturally-occurring 12(S)-HPETE and its diastereomer, 12(R)-HPETE which is not generated in Aplysia. Both isomers were significantly more effective than 15(S)-HPETE. In contrast, 12(S)-HPETE, but not 12(R)-HPETE, was a potent modulator of the action of the molluscan neuropeptide, FMRFamide. Prior application of 12(S)-HPETE to cultured sensory neurons increased the subsequent response to a submaximal dose of FMRFamide by 60%. On the other hand, 12(R)-HPETE reduced the subsequent response to the peptide by 30%. The lack of stereospecificity in the direct effect of the lipids differs markedly from their stereospecific effects as modulators of FMRFamide action. This suggests that there may be an important neurophysiologic role for these lipid modulators which is distinct from their direct effects, and also indicates that there are multiple sites and mechanisms by which lipid hydroperoxides act on neurons in Aplysia.
Extended wordplays in the narratives of Genesis have been noticed by many readers, although their... more Extended wordplays in the narratives of Genesis have been noticed by many readers, although their full extent may not have been sufficiently appreciated. There are three stories of wrongdoing and resolution that are accompanied by such verbal indicators in Genesis. In each of these stories there are characters sinned against and sinning, and in each of them the conflict resulting from the wrongdoing is finally resolved in forgiveness granted by the one wronged.
Using the highly plastic synapses between mechanoreceptor sensory neurons and siphon motor neuron... more Using the highly plastic synapses between mechanoreceptor sensory neurons and siphon motor neurons of Aplysia as a model, we have investigated whether switching off and on of individual synaptic release sites is a strategy that is used by neurons in forms of short-term synaptic modulation with a time course of minutes to hours. We have modified some of the techniques of classical quantal analysis and examined the kinetics of synaptic depression under different stimulation protocols to answer this question. Our analysis shows that both synaptic depression caused by homosynaptic activity and synaptic facilitation induced by an endogenous facilitatory transmitter occur by means of the shutting off and turning on, respectively, of synaptic sites, without intermediate changes in the probability of release. Our findings imply that other forms of plasticity at these synapses, such as post-tetanic potentiation, long-term facilitation, and long-term potentiation, are also expressed by all-or-none changes in activity at individual sites. We thus show that in addition to the mechanisms of synaptic integration that are known to operate in single cells and networks, neurons can exercise a further layer of fine control, at the level of individual release sites.
Proceedings of The National Academy of Sciences, 1986
Facilitatory transmitters and cAMP can modulate accommodation as well as transmitter release in A... more Facilitatory transmitters and cAMP can modulate accommodation as well as transmitter release in Aplysia sensory neurons: Evidence for parallel processing in a single cell (K+ currents/second messengers/presynaptic facilitation/excltability/sensitization)
Proceedings of The National Academy of Sciences, 1982
Serotonin exerts a long-lasting excitatory action on sensory neurons of Aplysia californica by de... more Serotonin exerts a long-lasting excitatory action on sensory neurons of Aplysia californica by decreasing outward K+ current. The depression of outward current delays repolarization of the action potential and extends the duration of Ca2+ influx into the presynaptic terminals, thereby contributing to the facilitation of transmitter release that underlies behavioral sensitization. We have extended the analysis of serotonin's action and find that it acts on a specific serotonin-sensitive K+ current (S current), which is different from the early K+ current ('A), the delayed K+ current ('K), the Ca2+-dependent K+ current (IC), and the muscarine-sensitive M current. The serotonin-sensitive current in these cells persists when IA and IK are reduced by conditioning depolarization or channel-blocking agents. The S current is not activated by intracellular injection ofCa2+, nor is it affected by substitution of Ba2+ for Ca2+, a treatment that reduces Ic.
In Aplysia sensory and motor neurons in culture, the contributions of the major classes of calciu... more In Aplysia sensory and motor neurons in culture, the contributions of the major classes of calcium current can be selectively examined while transmitter release and its modulation are examined. A slowly inactivating, dihydropyridine-sensitive calcium current does not contribute either to normal synaptic transmission or to any of three different forms of plasticity: presynaptic inhibition, homosynaptic depression, and presynaptic facilitation. This current does contribute, however, to a fourth form of plasticity--modulation of transmitter release by tonic depolarization of the sensory neuron. By contrast, a second calcium current, which is rapidly inactivating and dihydropyridine-insensitive, contributes to release elicited by the transient depolarization of an action potential and to the other three forms of plasticity.
Proceedings of The National Academy of Sciences, 1986
Presynaptic facilitation of transmitter release from Aplysia sensory neurons is an important cont... more Presynaptic facilitation of transmitter release from Aplysia sensory neurons is an important contributor to behavioral sensitization of the gill and siphon withdrawal reflex. The enhanced release is accompanied by reduction of the serotonin-sensitive S current in the sensory neurons and a consequent increase in duration of the presynaptic action potential (ranging from 10% to 30%). We find that changes of similar magnitude in the duration of depolarizing voltage-
Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are tw... more Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are two major phorbol ester-activated PKCs, Ca 2 �-activated PKC Apl I and Ca 2 �-independent PKC Apl II. Functional Apl II, but not Apl I, in sensory neurons is required for a form of short-term facilitation induced at sensorimotor synapses by the facilitatory transmitter serotonin (5-HT). Because PKCs are activated by translocating from the cytoplasm to the membrane, we used fluorescently tagged PKCs to determine the isoform and cell-type specificity of translocation in living Aplysia neurons. In Sf9 cells, low levels of diacylglycerol translocate Apl II, but not Apl I, which requires calcium for translocation at low concentrations of diacylglycerol. Accordingly, application of 5-HT to Aplysia sensory neurons in the absence of neuronal firing translocates Apl II, but not Apl I, consistent with the role of Apl II in short-term facilitation. This translocation is observed in sensory neurons, b...
Rapid development of to examine the influence of synapse age on the expression synaptic connectio... more Rapid development of to examine the influence of synapse age on the expression synaptic connections and plasticity between sensory neurons and of short-term synaptic modulation. More generally, we were motor neurons of Aplysia in cell culture: implications for learning interested in examining the relationships among synapse forand regulation of synaptic strength. J. Neurophysiol. 77: 2316mation in regenerating adult neurons, in development, and 2327, 1997. We describe here the time course of functional synapse in learning.
We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin... more We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin. These proteins belong to a family of calcium-binding proteins, found primarily in vertebrate brain and retina, that have been proposed to play a role in calcium-dependent regulation of enzymes in signal transduction pathways. Like other members of this family, the Aplysia proteins have consensus sequences for myristoylation, bind calcium, and translocate from cytosol to membrane when the calcium level is raised above the resting intracellular concentration. Both proteins are relatively enriched in Aplysia nervous system, but are also found to a significant degree in other tissues. The expression of mRNA for these proteins in Aplysia nervous tissue is regulated during development, roughly paralleling the reported emergence of several forms of synaptic plasticity. The messages are present at low levels in stage 11, show a large increase by late stage 12, and decline to a plateau of -~~3O% of the peak value afterward. On the basis of the properties of these proteins and by analogy with proposed functions of some of the retinal homologues, we suggest that these proteins may play a role in mediating calcium-dependent processes in neuronal function. The presence of both proteins in other tissues may suggest analogous roles for the proteins in other cell types.
Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are tw... more Protein kinase Cs (PKCs) are important effectors of synaptic plasticity. In Aplysia, there are two major phorbol ester-activated PKCs, Ca 2ϩ -activated PKC Apl I and Ca 2ϩ -independent PKC Apl II. Functional Apl II, but not Apl I, in sensory neurons is required for a form of short-term facilitation induced at sensorimotor synapses by the facilitatory transmitter serotonin (5-HT). Because PKCs are activated by translocating from the cytoplasm to the membrane, we used fluorescently tagged PKCs to determine the isoform and cell-type specificity of translocation in living Aplysia neurons. In Sf9 cells, low levels of diacylglycerol translocate Apl II, but not Apl I, which requires calcium for translocation at low concentrations of diacylglycerol. Accordingly, application of 5-HT to Aplysia sensory neurons in the absence of neuronal firing translocates Apl II, but not Apl I, consistent with the role of Apl II in short-term facilitation. This translocation is observed in sensory neurons, but not in motor neurons. Apl I translocates only if 5-HT is coupled to firing in the sensory neuron; firing alone is ineffective. Because combined 5-HT and firing are required for the induction of one type of intermediate-term facilitation at these synapses, we asked whether this form of synaptic plasticity involves activation of Apl I. We report here that dominantnegative Apl I, but not Apl II, blocks intermediate-term facilitation. Thus, different isoforms of PKC translocate under different conditions to mediate distinct types of synaptic plasticity: Ca 2ϩ -independent Apl II is involved in short-term facilitation, and Ca 2ϩ -dependent Apl I contributes to intermediate-term facilitation.
Regulation of synaptic transmission by modulation of the calcium influx that triggers transmitter... more Regulation of synaptic transmission by modulation of the calcium influx that triggers transmitter release underlies different forms of synaptic plasticity, and thus could contribute to learning. In the mollusk Aplysia, the neuromodulator serotonin (5-HT) increases evoked transmitter release from sensory neurons and thereby contributes to dishabituation and sensitization of defensive reflexes. We combined electrophysiological recording with fluorescence measurements of intracellular calcium in sensory neuron synapses in culture to test whether direct up-modulation by 5-HT of calcium influx triggered by single action potentials contributes to facilitation of transmitter release. We observe increases in a previously undescribed calcium influx that are strongly correlated with increases in the amplitude of the evoked postsynaptic potentials and which cannot be accounted for by action potential prolongation. Our results suggest that direct modulation of a presynaptic calcium conductance that controls neurotransmitter release contributes to the presynaptic facilitation that underlies a simple form of learning.
We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin... more We report here the sequences of two new proteins from Aplysia, aplycalcin and Aplysia neurocalcin. These proteins belong to a family of calcium-binding proteins, found primarily in vertebrate brain and retina, that have been proposed to play a role in calcium-dependent regulation of enzymes in signal transduction pathways. Like other members of this family, the Aplysia proteins have consensus sequences for myristoylation, bind calcium, and translocate from cytosol to membrane when the calcium level is raised above the resting intracellular concentration. Both proteins are relatively enriched in Aplysia nervous system, but are also found to a significant degree in other tissues. The expression of mRNA for these proteins in Aplysia nervous tissue is regulated during development, roughly paralleling the reported emergence of several forms of synaptic plasticity. The messages are present at low levels in stage 11, show a large increase by late stage 12, and decline to a plateau of -~~3O% of the peak value afterward. On the basis of the properties of these proteins and by analogy with proposed functions of some of the retinal homologues, we suggest that these proteins may play a role in mediating calcium-dependent processes in neuronal function. The presence of both proteins in other tissues may suggest analogous roles for the proteins in other cell types.
Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from me... more Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from mechanoreceptor sensory neurons of Aplysia are involved in habituation and sensitization, respectively, of defensive withdrawal reflexes. We investigated whether synaptic ...
Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from me... more Short-term homosynaptic depression and heterosynaptic facilitation of transmitter release from mechanoreceptor sensory neurons of Aplysia are involved in habituation and sensitization, respectively, of defensive withdrawal reflexes. We investigated whether synaptic transmission is regulated in these forms of plasticity by means of changes in the size of the pool of transmitter available for immediate release [the readily releasable pool (RRP)] or in the efficacy of release from an unchanging pool. Using sensorimotor synapses formed in cell culture, we estimated the number of transmitter quanta in the RRP from the asynchronous release of neurotransmitter caused by application of a hypertonic bathing solution. Our experiments indicate that the transmitter released by action potentials and by hypertonic solution comes from the same pool. The RRP was reduced after homosynaptic depression of the EPSP by low-frequency stimulation and increased after facilitation of the EPSP by application of the endog-enous facilitatory transmitter serotonin (5-HT) after homosynaptic depression. However, although the fractional changes in the RRP and in the EPSP were similar for both synaptic depression and facilitation when depression was induced by repeated hypertonic stimulation, the changes in the EPSP were significantly greater than the changes in the RRP when depression was induced by repeated electrical stimulation. These observations indicate that homosynaptic depression and restoration of depressed transmission by 5-HT are caused by changes in both the amount of transmitter available for immediate release and in processes involved in the coupling of the action potential to transmitter release.
Proceedings of the National Academy of Sciences of the United States of America, Dec 1, 1984
Noxious stimulation of the tail of Aplysia californica produces behavioral sensitization; it enha... more Noxious stimulation of the tail of Aplysia californica produces behavioral sensitization; it enhances several related defensive reflexes. This reflex enhancement involves heterosynaptic facilitation of transmitter release from sensory neurons of the reflex. The facilitation is stimulated by serotonin (5-HT) and involves suppression of a 5-HT-sensitive K+ current (the S current). Suppression of the S current broadens the action potential of the sensory neurons and is thought to enhance transmitter release by prolonging entry of Ca2+ in the presynaptic terminals. We now report a component of enhanced Ca2+ accumulation that is independent of changes in spike shape. We have measured intracellular free Ca2+ transients during long depolarizing steps in voltage-clamped sensory neuron cell bodies injected with the Ca2+-sensitive dye arsenazo III. The free Ca2+ transients elicited by a range of depolarizing voltage-clamp steps increase in amplitude by 75% following application of 5-HT. Since it is observed under voltage-clamp conditions, this increase in the free Ca2+ transients is not merely secondary to the changes in K+ current but must reflect an additional mechanism, an intrinsic change in the handling of Ca2+ by the cell. We have not yet determined whether this change in Ca2+ handling reflects an increase in Ca2+ influx, a reduction in intracellular Ca2+ uptake, or a release of Ca2+ from intracellular stores. Regardless of the underlying mechanism, however, it seems possible that the enhancement of Ca2+ accumulation and the reduction in K+ current act synergistically in producing short-term presynaptic facilitation. Alternatively, this additional modulation of Ca2+ by 5-HT might contribute to processes such as classical conditioning or long-term sensitization that may depend on Ca2+.
Recent studies indicate that in invertebrates short-term memory for various forms of learning inv... more Recent studies indicate that in invertebrates short-term memory for various forms of learning involves covalent modifications of pre-existing proteins. By contrast, long-term memory utilizes genes and proteins not required for short-term memory.
Short-term augmentation of synaptic transmission at sensory neuron synapses of Aplysia contribute... more Short-term augmentation of synaptic transmission at sensory neuron synapses of Aplysia contributes to behavioral sensitization and is one of the current models for a cellular mechanism of learning. This neuromodulatory process, mediated at least in part by the facilitatory neurotransmitter serotonin (5-HT) acting through cAMP, has been thought to result largely from prolongation of the sensory neuron action potential (AP). The quantitative contribution of AP prolongation to synaptic augmentation was examined using a new culture preparation that is favorable for controlling the voltage at the presynaptic terminals. Preventing AP prolongation by using unvarying voltage-clamp commands in place of triggered APs did not reduce augmentation significantly, and pharmacological prolongation of APs caused by a high concentration of 5-HT led to a negligible increase in the synaptic response. Together with earlier evidence against the involvement of changes in Ca2+ current, these results suggest that synaptic augmentation may result from modulation of steps in the secretory process that lie distal to the flow of ion currents across the nerve terminal membrane.
Synaptic transmission at the sensory neuron-motor neuron synapses of Aplysia, like transmission a... more Synaptic transmission at the sensory neuron-motor neuron synapses of Aplysia, like transmission at many synapses of both vertebrates and invertebrates, is increased after a short burst of high-frequency stimulation (HFS), a phenomenon known as post-tetanic potentiation (PTP). PTP is generally attributable to an increase in transmitter release from presynaptic neurons. We investigated whether changes in the readily releasable pool of transmitter (RRP) contribute to the potentiation that follows HFS. We compared the changes in EPSPs evoked with action potentials to changes in the RRP as estimated from the asynchronous transmitter release elicited by a hypertonic solution. The changes in the EPSP were correlated with changes in the RRP, but the changes matched quantitatively only at connections whose initial synaptic strength was greater than the median for all experiments. At weaker connections, the increase in the RRP was insufficient to account for PTP. Weaker connections initially released a smaller fraction of the RRP with each EPSP than stronger ones, and this fraction increased at weaker connections after HFS. Moreover, the initial transmitter release in response to the hypertonic solution was accelerated after HFS, indicating that the increase in the efficacy of release was not restricted to excitation-secretion coupling. Modulation of the RRP and of the efficacy of release thus both contribute to the enhancement of transmitter release by HFS.
Up and down-regulation of calcium and potassium conductances are associated with several forms of... more Up and down-regulation of calcium and potassium conductances are associated with several forms of short-term synaptic modulation. Detailed investigation of synaptic plasticity in the marine gastropod Aplysia, and in other mollusks, indicates that synaptic transmission can be influenced in a number of ways by modulatory neurotransmitters acting through several second-messenger cascades. Modulation at the synapse itself occurs by means of the regulation of calcium current as well as through effects on processes directly involved in transmitter mobilization and exocytosis. Modulation of potassium current plays a major role in controlling neuronal excitability and may contribute to a lesser extent to the regulation of transmitter release through actions on the resting potential and on action potential configuration.
Nervous tissue of the marine mollusc, Aplysia californica, generates arachidonic acid metabolites... more Nervous tissue of the marine mollusc, Aplysia californica, generates arachidonic acid metabolites in response to neurotransmitters such as histamine or FMRFamide. In addition, identified neurons of Aplysia respond to the pharmacologic application of some of these products, particularly those of the 12-1ipoxygenase pathway. We investigated the chirality of the initial Aplysia 12-1ipoxygenase product, 12-HPETE, in preparation for more detailed metabolic studies and for the analysis of the physiological activity of the endogenous lipid. Neural homogenates and intact ganglia exclusively generate 12(S)-HPETE as do the better characterized mammalian lipoxygenases. The direct application of 12(S)-HPETE to cultured sensory neurons induced a hyperpolarization which averaged 2.6 mV. We did not find any difference between the response to the naturally-occurring 12(S)-HPETE and its diastereomer, 12(R)-HPETE which is not generated in Aplysia. Both isomers were significantly more effective than 15(S)-HPETE. In contrast, 12(S)-HPETE, but not 12(R)-HPETE, was a potent modulator of the action of the molluscan neuropeptide, FMRFamide. Prior application of 12(S)-HPETE to cultured sensory neurons increased the subsequent response to a submaximal dose of FMRFamide by 60%. On the other hand, 12(R)-HPETE reduced the subsequent response to the peptide by 30%. The lack of stereospecificity in the direct effect of the lipids differs markedly from their stereospecific effects as modulators of FMRFamide action. This suggests that there may be an important neurophysiologic role for these lipid modulators which is distinct from their direct effects, and also indicates that there are multiple sites and mechanisms by which lipid hydroperoxides act on neurons in Aplysia.
Extended wordplays in the narratives of Genesis have been noticed by many readers, although their... more Extended wordplays in the narratives of Genesis have been noticed by many readers, although their full extent may not have been sufficiently appreciated. There are three stories of wrongdoing and resolution that are accompanied by such verbal indicators in Genesis. In each of these stories there are characters sinned against and sinning, and in each of them the conflict resulting from the wrongdoing is finally resolved in forgiveness granted by the one wronged.
Using the highly plastic synapses between mechanoreceptor sensory neurons and siphon motor neuron... more Using the highly plastic synapses between mechanoreceptor sensory neurons and siphon motor neurons of Aplysia as a model, we have investigated whether switching off and on of individual synaptic release sites is a strategy that is used by neurons in forms of short-term synaptic modulation with a time course of minutes to hours. We have modified some of the techniques of classical quantal analysis and examined the kinetics of synaptic depression under different stimulation protocols to answer this question. Our analysis shows that both synaptic depression caused by homosynaptic activity and synaptic facilitation induced by an endogenous facilitatory transmitter occur by means of the shutting off and turning on, respectively, of synaptic sites, without intermediate changes in the probability of release. Our findings imply that other forms of plasticity at these synapses, such as post-tetanic potentiation, long-term facilitation, and long-term potentiation, are also expressed by all-or-none changes in activity at individual sites. We thus show that in addition to the mechanisms of synaptic integration that are known to operate in single cells and networks, neurons can exercise a further layer of fine control, at the level of individual release sites.
Proceedings of The National Academy of Sciences, 1986
Facilitatory transmitters and cAMP can modulate accommodation as well as transmitter release in A... more Facilitatory transmitters and cAMP can modulate accommodation as well as transmitter release in Aplysia sensory neurons: Evidence for parallel processing in a single cell (K+ currents/second messengers/presynaptic facilitation/excltability/sensitization)
Proceedings of The National Academy of Sciences, 1982
Serotonin exerts a long-lasting excitatory action on sensory neurons of Aplysia californica by de... more Serotonin exerts a long-lasting excitatory action on sensory neurons of Aplysia californica by decreasing outward K+ current. The depression of outward current delays repolarization of the action potential and extends the duration of Ca2+ influx into the presynaptic terminals, thereby contributing to the facilitation of transmitter release that underlies behavioral sensitization. We have extended the analysis of serotonin's action and find that it acts on a specific serotonin-sensitive K+ current (S current), which is different from the early K+ current ('A), the delayed K+ current ('K), the Ca2+-dependent K+ current (IC), and the muscarine-sensitive M current. The serotonin-sensitive current in these cells persists when IA and IK are reduced by conditioning depolarization or channel-blocking agents. The S current is not activated by intracellular injection ofCa2+, nor is it affected by substitution of Ba2+ for Ca2+, a treatment that reduces Ic.
In Aplysia sensory and motor neurons in culture, the contributions of the major classes of calciu... more In Aplysia sensory and motor neurons in culture, the contributions of the major classes of calcium current can be selectively examined while transmitter release and its modulation are examined. A slowly inactivating, dihydropyridine-sensitive calcium current does not contribute either to normal synaptic transmission or to any of three different forms of plasticity: presynaptic inhibition, homosynaptic depression, and presynaptic facilitation. This current does contribute, however, to a fourth form of plasticity--modulation of transmitter release by tonic depolarization of the sensory neuron. By contrast, a second calcium current, which is rapidly inactivating and dihydropyridine-insensitive, contributes to release elicited by the transient depolarization of an action potential and to the other three forms of plasticity.
Proceedings of The National Academy of Sciences, 1986
Presynaptic facilitation of transmitter release from Aplysia sensory neurons is an important cont... more Presynaptic facilitation of transmitter release from Aplysia sensory neurons is an important contributor to behavioral sensitization of the gill and siphon withdrawal reflex. The enhanced release is accompanied by reduction of the serotonin-sensitive S current in the sensory neurons and a consequent increase in duration of the presynaptic action potential (ranging from 10% to 30%). We find that changes of similar magnitude in the duration of depolarizing voltage-
There are three stories of wrongdoing, retribution, and ultimate reconciliation in Genesis: the F... more There are three stories of wrongdoing, retribution, and ultimate reconciliation in Genesis: the Flood narrative, the story of Jacob and Esau, and the account of the conflict between Joseph and his brothers. Each of the stories is accompanied by a progression of plays on word roots that parallel the developments in the stories. Here I show that the final wordplay in each story represents a reversal and resolution of the conflict that is similar in all three cases: the final wordplay is associated with the injured party and expresses a gracious laying aside of the wrong that had occasioned the conflict, thus signaling the ultimate reconciliation.
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Papers by Marc Klein