Bag cell neurons

The bag cell neurons are located in the abdominal ganglion of the marine mollusk Aplysia. Their function is to control the onset of egg-laying behavior. They have been widely used as a model system to investigate the mechanisms by which neuropeptides are synthesized, processed and secreted from neurons. Because they respond to brief stimulation with a series of changes in their electrical properties that lasts for up to 18 hrs, they have also been used to investigate the mechanisms by which modulation of ion channels produces long-lasting changes in excitability and controls animal behavior.

Introduction

The bag cell neurons are located in two clusters of ~200-400 cells each at the rostral end of the abdominal ganglion of Aplysia (Kupferman, 1967; Kupfermann & Kandel, 1970; Pinsker & Dudek, 1977). Their primary function is to act as a master switch for a series of reproductive behaviors that culminates in egg laying. The electrophysiological state of these neurons determines whether egg-laying behaviors will occur in response to environmental stimuli.

The series of reproductive behaviors is triggered by the release of several neuropeptides (Arch & Smock, 1977; Pinsker & Dudek, 1977). Their major neurotransmitter is egg-laying hormone (ELH), a 36-amino acid peptide that, like many other neuropeptides, is amidated at its C-terminus, conferring resistance to extracellular proteases (Chiu et al., 1979; Scheller et al., 1983). ELH has actions on numerous other neurons in the abdominal ganglion (Branton et al., 1978), as well as on peripheral targets, particularly the ovotestis (Rothman et al., 1983a). ELH is synthesized as part of a larger precursor (pro-ELH, Figure 1), which also encodes several smaller neuroactive peptides, that are termed \(\alpha\)-, \(\beta\)- and \(\gamma\)-BCP (bag cell peptides). These smaller BCPs are also secreted locally to alter the firing patterns of neurons in the abdominal ganglion, but they do not undergo any posttranslational modification and their actions are rapidly terminated by proteases in the extracellular space (Rothman et al., 1983b; Mayeri et al., 1985; Pulst et al., 1986 & 1987; Sigvardt et al., 1986; Kauer et al., 1987; Fisher et al., 1988; Nagle et al., 1990). Several other peptides, including \(\delta\)-BCP are also secreted during afterdischarge (Hatcher & Sweedler, 2008), but their functions are not yet understood. Interestingly, different combinations of neuropeptides are packaged into different secretory granules and are targeted to different branches of the bag cell neurons (Sossin et al., 1990; Li et al., 1998), presumably in order to coordinate the multiple actions of these neurons on both peripheral and central targets.

Figure 1: Organization of pro-ELH, the precursor to ELH and the small BCPs.

Secretion of ELH and the BCPs from the bag cell neurons normally occurs in response to a prolonged burst of action potentials, termed an afterdischarge. In the absence of stimulation, the cells maintain negative resting potentials and display no spontaneous electrical activity. Brief electrical stimulation (5-15 sec) of an afferent input from the head ganglia causes the cells to depolarize by 15-20 mV and to generate an afterdischarge that lasts for about thirty minutes ( Figure 2). The nature of the synaptic input is poorly understood, but it has been suggested that only a few neurons receive direct afferent input and that excitation subsequently spreads to the remainder of the electrically coupled cells (Mayeri et al., 1979). In addition, once the afterdischarge is underway, peptide release occurs in response to both \(Ca^{2+}\) influx from the extracellular space and \(Ca^{2+}\) release from intracellular stores (Arch, 1972; Stuart et al., 1980; Loechner et al., 1990; Wayne, 1995; Wayne et al .,1998; Michel & Wayne, 2002).

Figure 2: Pattern of firing and of neuropeptide secretion in response to brief stimulation of the input to bag cell neurons.

The series of behaviors that is triggered by neuropeptide release during the afterdischarge lasts about 3-5 hrs. At the end of the afterdischarge, the bag cell neurons enter a prolonged (~18 hr) refractory state during which stimulation evokes action potentials but fails to trigger long-lasting afterdischarges or neuropeptide secretion. This refractory state is believed to prevent the re-initiation of the behavioral sequence once it has begun and to allow for the maturation of a new clutch of eggs in the ovotestis.

The transformation of the electrical properties of the bag cell neurons from their resting state to the afterdischarge and subsequent refractory state can be attributed to the action of second messenger systems on the characteristics of several ion channels that regulate resting potential and the height and width of action potentials. At least two major second messenger systems are activated on stimulation of the input to the bag cell neurons. Cyclic AMP levels in these neurons rise within two minutes of the onset of stimulation, and the activation of protein kinase A (PKA) results in the activation of a tyrosine phosphatase (Kaczmarek et al., 1978, 1980, & 1982; Loechner & Kaczmarek, 1990; Wilson & Kaczmarek, 1993). Stimulation of the input simultaneously triggers activation of protein kinase C (PKC), and formation of inositol trisphosphate (Fink et al., 1988; Wayne et al., 1999). Many of the ion channels that trigger the afterdischarge, or the refractory state, have been identified and their properties are described below.

Role of ion channels in the control of the bag cell secretory afterdischarge

The brief stimulus train that triggers neuropeptide secretion in the bag cell neurons causes a major change in their electrical properties. Table 1 lists some of the ion channels that modulate the properties of these neurons. The resting membrane potential of these neurons prior to stimulation is usually between -55 mV and -65 mV but, after the onset of afterdischarge, the inter-spike voltage is typically between -30 mV and -40 mV.

Voltage-dependent potassium channels

Over the first 2-3 minutes of afterdischarge there is a progressive increase in the width of evoked action potentials. This increase can be mimicked by elevations of cyclic AMP or the catalytic subunit of PKA, and is prevented by peptide pseudosubstrate inhibitors of PKA (Kaczmarek et al., 1978 & 1980; Conn & Kaczmarek, 1989). Two distinct \(K^+\) currents, originally termed Ik1 and Ik2 (Strong & Kaczmarek, 1986) regulate the width of action potentials. The molecular basis of Ik1, which undergoes relatively little inactivation during sustained depolarizations, has not yet been investigated. In contrast, the gene encoding the Ik2 channel, which undergoes cumulative inactivation during repeated depolarizations, has been identified as Kv2.1, the Aplysia homolog of the Drosophila Shab gene (Quattrocki et al., 1994.)

The voltage-dependent Kv2.1 channels play a major role in spike broadening (Quattrocki et al., 1994). Partial inactivation of Aplysia Kv2.1 during repetitive firing produces frequency-dependent broadening of action potentials during the afterdischarge (Quattrocki et al., 1994). Moreover elevations of cyclic AMP such as occur during the afterdischarge reduce the amplitude of the voltage-dependent \(K^+\) channel, producing further broadening of action potentials (Kaczmarek & Strumwasser, 1984). Kv2.1 channels also undergo rapid clustering and unclustering during afterdischarges (Zhang et al., 2008a). As in mammalian neurons (Misonou et al., 2004), Kv2.1 channels in bag cell neurons are restricted to ring-like clusters in the plasma membrane of the soma and proximal dendrites (Zhang et al., 2008a). Elevation of cyclic AMP levels or direct electrical stimulation of afterdischarge rapidly enhances formation of these clusters on the somata, and the formation of these clusters is associated with a decrease in current amplitude (Zhang et al., 2008a).

Calcium and sodium-dependent potassium channels

Large-conductance \(Ca^{2+}\)-activated \(K^+\) (BK) channels are encoded by the Slo gene. In bag cell neurons, these set the overall level of excitability, and a decrease in the activity of these channels may also, in part, contribute to PKA-dependent broadening of action potentials following stimulation (Zhang et al., 2004). Potent but transient activation of these channels can be observed in response to injection of the second messenger IP₃, which releases \(Ca^{2+}\) from intracellular stores in bag cell neurons (Fink et al., 1988) and such IP₃-dependent activation is thought to produce the brief hyperpolarization that occurs immediately before the onset of afterdischarge. A high density of \(Ca^{2+}\)-activated \(K^+\) (BK) current normally inhibits the onset of afterdischarge (Nick et al., 1996) and an increase in BK current follows an afterdischarge in mature animals, contributing to the subsequent refractory state that limits further ELH secretion (Zhang et al., 2002).

There are two alternative transcripts of the Slo gene expressed in bag cell neurons. These two isoforms differ in the presence (Slo-a) or absence (Slo-b) of a consensus phosphorylation site for PKA (Zhang et al., 2004). The isoforms differ, predictably, in their response to application of the catalytic subunit of PKA. Activation of PKA reduces the open probability of Slo-a, an effect that is reversed by a PKA inhibitor. By contrast, PKA had no effect on Slo-b. The PKA-regulated Slo-a subunit is present in adult, but not juvenile, bag cell neurons. In juvenile animals, afterdischarges are inhibited by a high density of BK channels (Nick et al., 1996) <vida supra> . Patch clamp recordings from adult and juvenile neurons have confirmed that PKA decreases BK channel activity only in adults (Zhang et al., 2004).

Recent work has also demonstrated a prominent \(K^+\) channel that is activated by intracellular \(Na^+\) in the bag cell neurons. This large-conductance channel is encoded by the Aplysia Slack gene and its function is currently under investigation (Chen et al., 2007, Zhang et al., 2008c).

A voltage-gated non-selective cation channel is activated by association with PKC and calmodulin at the onset of afterdischarge

A non-selective cation channel that is permeable to \(Na^+\ ,\) \(K^+\) and \(Ca^{2+}\)ions provides the prolonged depolarization that drives afterdischarge (Wilson & Kaczmarek, 1993; Wilson et al., 1996; Magoski & Kaczmarek, 2005, Magoski & Geiger, 2006). Activation of this channel requires a physical association between the channel and both calmodulin and PKC (Wilson et al., 1998; Lupinsky & Magoski 2006). Calmodulin acts as a transducer for the stimulatory effects of \(Ca^{2+}\ ,\) which is elevated during the afterdischarge (Lupinsky & Magoski, 2006; Fisher et al., 1994).

The association between this cation channel and PKC is dependent on src homology 3 domain protein-protein interactions (Magoski et al., 2002). Moreover, this channel-PKC association is plastic and regulated by src tyrosine kinase itself (Magoski, 2004; Magoski & Kaczmarek, 2005). This physical association/dissociation of the ion channel-enzyme complex appears to represent the major mechanism that controls the transition from afterdischarge to the refractory state (see Figure 2). Entry of the bag cell neurons into the prolonged refractory period that follows an afterdischarge includes dissociation of the channel/PKC complex and an elevation of phosphotyrosine levels (Magoski, 2004; Magoski & Kaczmarek, 2005). Thus, the loss of the channel-PKC association, in association with the increase in BK current described above, represents a molecular basis for the prolonged refractory state. Interestingly it is \(Ca^{2+}\)influx through the cation channel that appears selectively to initiate the biochemical pathway that ultimately renders the neurons refractory (Kaczmarek & Kauer, 1983; Magoski et al., 2000).

Insertion of calcium channels at neuropeptide release sites

Activation of PKC at the onset of an afterdischarge causes the recruitment of new voltage-dependent \(Ca^{2+}\) channels to the plasma membrane. In channel recordings at the soma, the increase in current produced by activation of PKC is associated with the appearance of a new 24 pS conductance (Strong et al., 1987). Fura-2 \(Ca^{2+}\) imaging <here and subsequently Ca has become monovalent, needs correction> shows that activation of PKC produces new sites of \(Ca^+\) entry at the distal tips of bag cell neurites (Knox et al., 1992), where neuropeptide secretion is believed to occur (Frazier et al., 1967).

There are two voltage-dependent calcium channel genes expressed in bag cell neurons \(Ca_v1\) and \(Ca_v2\) (White & Kaczmarek, 1997; Zhang et al., 2008b).A variety of evidence indicates that the PKC-regulated channels correspond to the \(Ca_v2 \alpha\) subunit (White & Kaczmarek, 1997; White et al., 1998; Zhang et al., 2008b), which is normally confined to the membranes of granules found throughout the soma and in the central region of growth cones (White and Kaczmarek, 1997). Following activation of PKC the organelles containing \(Ca_v2 \alpha\) subunit undergo rapid trafficking to the distal edge of the growth cone where they are inserted into the plasma membrane (Zhang et al., 2008b). The insertion of these channel could represent the rapid assembly of new sites for the secretion of neuropeptides.

Other sources of calcium for neuropeptide release

In addition to the voltage-dependent \(Ca^{2+}\) and non-selective cation channels described above, there exist one or more voltage-independent non-selective cation channels in the plasma membrane of bag cell neurons (Knox et al., 1996; Whim & Kaczmarek, 1998; Hung & Magoski, 2007; Gardam et al., 2008). While the function and molecular identity of these channels in not fully understood it is possible that they play a role in the filling of intracellular stores that release \(Ca^{2+}\) in response to stimulation, thereby maintaining neuropeptide release after the onset of discharge.

\(Ca^{2+}\) ions are known to be released from several independent intracellular stores in the bag cell neurons. In common with all other neurons, these include mitochondria and the endoplasmic reticulum (Knox et al., 1996; Jonas et al., 1997; Geiger & Magoski, 2008). Of particular significance for neuropeptide release, however, is a non-endoplasmic reticulum, non-mitochondrial store that is activated by insulin and causes ELH secretion (Jonas et al., 1997). In contrast to the endoplasmic reticulum, this store is present at the distal tips of neurites,where secretion occurs, and may represent the secretory granules themselves. This hypothesis is supported by the findings of Kachoei et al. (2006), who demonstrated the presence of an acidic store in bag cell neurons, with properties similar to that of the insulin-sensitive store.

Other \(Ca^+\)-release mechanisms include a store-operated Ca2+ influx pathway (Knox et al., 1996; Kachoei et al., 2006), which could also contribute to secretion. Finally, \(Ca^{2+}\) influx-induced \(Ca^{2+}\) release from both the endoplasmic reticulum and mitochondria represents yet another possible mechanism for promoting elevations of internal \(Ca^{2+}\) (Fisher et al., 1994; Geiger & Magoski, 2008).

Summary

Very brief stimulation of an input to the bag cell neurons triggers long-lasting changes in their intrinsic electrical properties, and in their ability to secrete neuropeptides. Because of the reproducible stereotypical nature of the stimulation-induced changes in their cellular properties, and because the biological function of these neurons is relatively well understood, they have served as a model system for investigations of prolonged changes in neuronal excitability, as well as of neuropeptide synthesis, processing and release.

References

• Arch, S. (1972) Polypeptide secretion from the isolated parietovisceral ganglion of Aplysia californica. J Gen Physiol 59:47-59.
• Arch, S. and T. Smock (1977) Egg-laying behavior in Aplysia californica. Behav Biol 19:45-54.
• Branton, W., S. Arch, T. Smock, E. Mayeri (1978) Evidence for mediation of a neuronal interaction by a behaviorally active peptide. Proc Natl Acad Sci 75:5732-5736.
• Chen Y, Zhang Y, Brown M, Herman M, Arch S, Kaczmarek, LK (2007) Na+-dependent K+ channels and neuropeptide synthesis in Aplysia bag cell neurons. Soc Neurosci Abstr (CD ROM), 42.21.
• Chiu AY, Hunkapiller MW, Heller E, Stuart DK, Hood LE, Strumwasser F (1979) Purification and primary structure of the neuropeptide egg-laying hormone of Aplysia californica. Proc Natl Acad Sci 76:6656-6660.
• Chun JY, Korner J, Kreiner T, Scheller RH, Axel R (1994) The function and differential sorting of a family of aplysia prohormone processing enzymes. Neuron 12:831-844.
• Conn PJ, Kaczmarek LK (1989) The bag cell neurons of Aplysia. A model for the study of the molecular mechanisms involved in the control of prolonged animal behaviors. Mol Neurobiol 3:237-273.
• de Jong-Brink M, Nagle GT, Dictus WJ, Painter SD, Broers-Vendrig T, Blankenship JE (1990) A calfluxin-related peptide is present in the bag cells and atrial gland of Aplysia. Gen Comp Endocrinol 79:114-122.
• Fink LA, Connor JA, Kaczmarek LK (1988) Inositol trisphosphate releases intracellularly stored calcium and modulates ion channels in molluscan neurons. J Neurosci 8:2544-2555.
• Fisher JM, Sossin W, Newcomb R, Scheller RH (1988) Multiple neuropeptides derived from a common precursor are differentially packaged and transported. Cell 54:813-822.
• Fisher T, Levy S, Kaczmarek LK (1994) Transient changes in intracellular calcium associated with a prolonged increase in excitability in neurons of Aplysia californica. J Neurophysiol 71:1254-1257.
• Frazier WT, Kandel ER, Kupfermann I., Waziri R, Coggeshall RE (1967) Morphological and functional properties of identified neurons in the abdominal ganglionof Aplysia californica. J. Neurophysiol. 30: 1288-1351.
• Gardam KE, Geiger JE, Hickey CM, Hung AY, Magoski NS (2008) Flufenamic acid affects multiple currents and causes intracellular Ca2+ release in Aplysia bag cell neurons. J Neurophysiol 100:38-49.
• Geiger JE, Magoski NS (2008) Ca2+-induced Ca2+-release in Aplysia bag cell neurons requires interaction between mitochondrial and endoplasmic reticulum stores. J Neurophysiol 100:24-37.
• Hatcher NG, Sweedler JV (2008) Aplysia bag cells function as a distributed neurosecretory network. J. Neurophysiol.. 99:333-343.
• Hung AY, Magoski NS (2007) Activity-dependent initiation of a prolonged depolarization in Aplysia bag cell neurons: role for a cation channel. J Neurophysiol 97:2465-2479.
• Jonas EA, Knox RJ, Smith TCM, Wayne NL, Connor JA, Kaczmarek LK 1997 Regulation by insulin of a unique neuronal Ca2+ pool and neuropeptide secretion. Nature 385:343-346
• Kachoei BA, Knox RJ, Uthuza D, Levy S, Kaczmarek LK, Magoski NS (2006) A store-operated Ca(2+) influx pathway in the bag cell neurons of Aplysia. J Neurophysiol 96:2688-2698.
• Kaczmarek LK, Strumwasser F (1984) A voltage-clamp analysis of currents underlying cyclic AMP-induced membrane modulation in isolated peptidergic neurons of Aplysia. J Neurophysiol 52:340-349.
• Kaczmarek LK, Jennings K, Strumwasser F (1978) Neurotransmitter modulation, phosphodiesterase inhibitor effects, and cyclic AMP correlates of afterdischarge in peptidergic neurites. Proc Natl Acad Sci 75:5200-5204.
• Kaczmarek LK, Jennings KR, Strumwasser F (1982) An early sodium and a late calcium phase in the afterdischarge of peptide-secreting neurons of Aplysia. Brain Res 238:105-115.
• Kaczmarek LK, Jennings KR, Strumwasser F, Nairn AC, Walter U, Wilson FD, Greengard P (1980) Microinjection of catalytic subunit of cyclic AMP-dependent protein kinase enhances calcium action potentials of bag cell neurons in cell culture. Proc Natl Acad Sci 77:7487-7491.
• Kaczmarek LK, Kauer JA (1983) Calcium entry causes a prolonged refractory period in peptidergic neurons of Aplysia. J Neurosci 3:2230-2239.
• Kauer JA, Fisher TE, Kaczmarek LK (1987) Alpha bag cell peptide directly modulates the excitability of the neurons that release it. J Neurosci 7:3623-3632.
• Knox RJ, Quattrocki EA, Connor JA, Kaczmarek LK (1992) Recruitment of Ca2+ channels by protein kinase C during rapid formation of putative neuropeptide release sites in isolated Aplysia neurons. Neuron 8:883-889.
• Knox RJ, Jonas EA, Kao L-S, Smith PJS, Connor JA, Kaczmarek LK (1996) Ca2+ influx and activation of a cation current are coupled to intracellular Ca2+ release in peptidergic neurons of Aplysia californica. J Physiol 494:627-693.
• Kupfermann I (1967) Stimulation of egg laying: possible neuroendocrine function of bag cells of abdominal ganglion of Aplysia californica. Nature 216:814-815.
• Kupfermann I, Kandel ER (1970) Electrophysiological properties and functional interconnections of two symmetrical neurosecretory clusters (bag cells) in abdominal ganglion of Aplysia. J Neurophysiol 33:865-876.
• Li L, Moroz TP, Garden RW, Floyd PD, Weiss KR, Sweedler JV (1998) Mass spectrometric survey of interganglionically transported peptides in Aplysia. Peptides 19: 1425–1433.
• Loechner KJ, Azhderian EM, Dreyer R, Kaczmarek LK (1990) Progressive potentiation of peptide release during a neuronal discharge. J Neurophysiol 63:738-744.
• Loechner KJ, Kaczmarek LK (1990) Control of potassium currents and cyclic AMP levels by autoactive neuropeptides in Aplysia neurons. Brain Res 532:1-6.
• Lupinsky DA, Magoski NS (2006) Ca2+-dependent regulation of a non-selective cation channel from Aplysia bag cell neurones. J Physiol 575:491-506.
• Magoski NS, Knox RJ, Kaczmarek LK (2000) Activation of a Ca2+-permeable cation channel produces a prolonged attenuation of intracellular Ca2+ release in Aplysia bag cell neurones. J Physiol 522:271-283.
• Magoski NS (2004) Regulation of an Aplysia bag cell neuron cation channel by closely associated protein kinase A and a protein phosphatase. J Neurosci 24:6833-6841.
• Magoski NS, Kaczmarek LK (2005) Association/dissociation of a channel-kinase complex underlies state-dependent modulation. J Neurosci 25:8037-8047.
• Magoski NS, Wilson GF, Kaczmarek LK (2002) Protein kinase modulation of a neuronal cation channel requires protein-protein interactions mediated by an Src homology 3 domain. J Neurosci 22:1-9.
• Magoski NS, Geiger JE (2006) Ca2+-entry through a non-selective cation channel in Aplysia bag cell neurons. Soc Neurosci Abstr 32:813.7
• Mayeri E, Brownell P, Branton WD, Simon SB (1979) Multiple, prolonged actions of neuroendocrine bag cells on neurons in Aplysia. I. Effects on bursting pacemaker neurons. J Neurophysiol 42:1165-1184.
• Mayeri E, Rothman BS, Brownell PH, Branton WD, Padgett L (1985) Nonsynaptic characteristics of neurotransmission mediated by egg-laying hormone in the abdominal ganglion of Aplysia. J Neurosci 5:2060-2077.
• Michel S, Wayne NL (2002) Neurohormone secretion persists after post-afterdischarge membrane depolarization and cytosolic calcium elevation in peptidergic neurons in intact nervous tissue. J Neurosci 22:9063-9069.
• Misonou H, Mohapatra DP, Park EW, Leung V, Zhen D, Misonou K, Anderson AE, Trimmer JS (2004) Regulation of ion channel localization and phosphorylation by neuronal activity. Nat Neurosci 7:711-718.
• Nagle GT, de Jong-Brink M, Painter SD, Bergamin-Sassen MM, Blankenship JE, Kurosky A (1990) Delta-bag cell peptide from the egg-laying hormone precursor of Aplysia. Processing, primary structure, and biological activity. J Biol Chem 265:22329-22335.
• Nick TA, Kaczmarek LK, Carew TJ (1996) Ionic currents underlying developmental regulation of repetitive firing in Aplysia bag cell neurons. J Neurosci 16:7583-7598.
• Painter SD, Kalman VK, Nagle GT, Blankenship JE (1989) Localization of immunoreactive alpha-bag-cell peptide in the central nervous system of Aplysia. J Comp Neurol 287:515-530.
• Pinsker HM, Dudek FE (1977) Bag cell control of egg laying in freely behaving Aplysia. Science 197:490-493.
• Pulst SM, Rothman BS, Mayeri E (1987) Presence of immunoreactive alpha-bag cell peptide[1-8] in bag cell neurons of Aplysia suggests novel carboxypeptidase processing of neuropeptides. Neuropeptides 10:249-259.
• Pulst SM, Gusman D, Rothman BS, Mayeri E (1986) Coexistence of egg-laying hormone and alpha-bag cell peptide in bag cell neurons of Aplysia indicates that they are a peptidergic multitransmitter system. Neurosci Lett 70:40-45.
• Quattrocki EA, Marshall J, Kaczmarek LK (1994) A Shab potassium channel contributes to action potential broadening in peptidergic neurons. Neuron 12:73-86.
• Rothman BS, Weir G, Dudek FE (1983a) Egg-laying hormone: direct action on the ovitestis of Aplysia. Gen Comp Endocrinol 52:134-141.
• Rothman BS, Mayeri E, Brown RO, Yuan PM, Shively JE (1983b) Primary structure and neuronal effects of alpha-bag cell peptide, a second candidate neurotransmitter encoded by a single gene in bag cell neurons of Aplysia. Proc Natl Acad Sci 80:5753-5757.
• Scheller RH, Jackson JF, McAllister LB, Rothman BS, Mayeri E, Axel R (1983) A single gene encodes multiple neuropeptides mediating a stereotyped behavior. Cell 32:7-22.
• Sigvardt KA, Rothman BS, Brown RO, Mayeri E (1986) The bag cells of Aplysia as a multitransmitter system: identification of alpha bag cell peptide as a second neurotransmitter. J Neurosci 6:803-813.
• Sossin WS, Sweet-Cordero A, Scheller RH. (1990) Dale’s hypothesis revisited: different neuropeptides derived from a common prohormone are targeted to different processes. Proc Natl Acad Sci USA 87: 4845–4848.
• Spafford JD, Chen L, Feng ZP, Smit AB, Zamponi GW (2003) Expression and modulation of an invertebrate presynaptic calcium channel alpha1 subunit homolog. J Biol Chem 278:21178-21187.
• Spafford JD, Van Minnen J, Larsen P, Smit AB, Syed NI, Zamponi GW (2004) Uncoupling of calcium channel alpha1 and beta subunits in developing neurons. J Biol Chem 279:41157-41167.
• Strong JA, Kaczmarek LK (1986) Multiple components of delayed potassium current in peptidergic neurons of Aplysia: modulation by an activator of adenylate cyclase. J Neurosci 6:814-822.
• Strong JA, Fox AP, Tsien RW, Kaczmarek LK (1987) Stimulation of protein kinase C recruits covert calcium channels in Aplysia bag cell neurons. Nature 325:714-717.
• Stuart DK, Chiu AY, Strumwasser F (1980) Neurosecretion of egg-laying hormone and other peptides from electrically active bag cell neurons of Aplysia. J Neurophysiol 43:488-498.
• Tang Y, Zucker RS (1997) Mitochondrial involvement in post-tetanic potentiation of synaptic transmission. Neuron 18:483-491.
• Tulsi RS, Coggeshall RE (1971) Neuromuscular junctions on the muscle cells in the central nervous system of the leech, Hirudo medicinalis. J Comp Neurol 141:1-15.
• Wayne NL (1995) The neuroendocrine bag cells of Aplysia: a model system for neural control of hormone secretion. J. Endocrinol. 147:1-4.
• Wayne NL, Kim YJ, Lee W (1998) Prolonged hormone secretion from neuroendocrine cells of Aplysia is independent of extracellular calcium. J Neuroendocrionol 10:529-537.
• Wayne NL, Lee W, Kim YJ (1999) Persistent activation of calcium-activated and calcium-independent protein kinase C in response to electrical afterdischarge from peptidergic neurons of aplysia. Brain Res 834:211-213.
• White BH, Kaczmarek LK (1997) Identification of a vesicular pool of calcium channels in the bag cell neurons of Aplysia californica. J Neurosci 17:1582-1595.
• White BH, Nick TA, Carew TJ, Kaczmarek LK (1998) Protein kinase C regulates a vesicular class of calcium channels in the bag cell neurons of Aplysia. J Neurophysiol 80:2514-2520.
• Whim MD, Kaczmarek LK (1998) Heterologous expression of the Kv3.1 potassium channel eliminates spike broadening and the induction of a depolarizing afterpotential in the peptidergic bag cell neurons. J Neurosci 18:9171-9180.
• Wilson GF, Kaczmarek LK (1993) Mode-switching of a voltage-gated cation channel is mediated by a protein kinase A-regulated tyrosine phosphatase. Nature 366:433-438.
• Wilson GF, Richardson FC, Fisher TE, Olivera BM, Kaczmarek LK (1996) Identification and characterization of a Ca(2+)-sensitive nonspecific cation channel underlying prolonged repetitive firing in Aplysia neurons. J Neurosci 16:3661-3671.
• Wilson GF, Magoski NS, Kaczmarek LK (1998) Modulation of a calcium-sensitive nonspecific cation channel by closely associated protein kinase and phosphatase activities. Proc Natl Acad Sci 95:10938-10943.
• Zhang Y, Magoski NS, Kaczmarek LK (2002) Prolonged activation of Ca2+-activated K+ current contributes to long-lasting refractory period of Aplysia bag cell neurons, J Neurosci 22:10134-10141.
• Zhang Y, Joiner WJ, Bhattacharjee A, Rassendren F, Magoski NS, Kaczmarek LK (2004) The appearance of a protein kinase A-regulated splice isoform of slo is associated with the maturation of neurons that control reproductive behavior. Journal of Biological Chemistry 279:52324-52330.
• Zhang Y, McKay SE, Bewley B, Kaczmarek LK (2008a) Repetitive firing triggers clustering of kv2.1 potassium channels in aplysia neurons. J Biol Chem 283:10632-10641.
• Zhang Y, Helm JS, Senatore A, Spafford JD, Kaczmarek LK, Jonas EA (2008b) PKC-induced intracellular trafficking of Ca(V)2 precedes its rapid recruitment to the plasma membrane. J Neurosci 28:2601-2612.
• Zhang Y, Hyland C, Chen Y, Kaczmarek LK (2008c) Characterization and cloning of a sodium-activated potassium channel in bag cell neurons. Soc Neurosci Abstr (CD ROM), in press.

Internal references

• Valentino Braitenberg (2007) Brain. Scholarpedia, 2(11):2918.

• Eugene M. Izhikevich (2006) Bursting. Scholarpedia, 1(3):1300.

• Paul R. Benjamin (2008) Lymnaea. Scholarpedia, 3(1):4124.

Recommended reading

• Arch S, Berry RW (1989) Molecular and cellular regulation of neuropeptide expression: the bag cell model system. Brain Research - Brain Research Reviews. 14:181-201

• Conn PJ, Kaczmarek LK (1989) The bag cell neurons of Aplysia: a model for the study of the molecular mechanisms involved in the control of prolonged animal behaviors, Molecular Neurobiology 3:237-273, 1989

• Nagle GT, Painter SD, Blankenship JE (1989) Post-translational processing in model neuroendocrine systems: precursors and products that coordinate reproductive activity in Aplysia and Lymnaea. J Neuroscience Res 23:359-370, 1989

• Levitan IB, Kaczmarek LK (2002)The Neuron; Cell and Molecular Biology, (3rd Edition) Oxford University Press

External links

• Leonard Kaczmarek’s webpage

See also