Three-Dimensional-Printed Electrochemical Sensor for Simultaneous Dual Monitoring of Serotonin Overflow and Circular Muscle Contraction.

Serotonin (5-HT) is a key signaling molecule within the mucosal epithelium of the intestinal wall and has been shown to be an important modulator of motility. At present, no single approach has been established for simultaneous dual measurement of 5-HT overflow and circular muscle contraction. We developed a 3D-printed carbon black/polylactic acid (PLA) electrochemical sensor, which had a geometry suitable for ex vivo measurement in the anorectum. The device was characterized for sensitivity and stability for 5-HT measurements as well as suitability for accurate tracking of anorectal contractions. The 3D-printed electrochemical sensor had a linear range in physiological concentrations of 5-HT (1-10 µM) present within the intestinal tract and a limit of detection of 540 nM. The sensor was stable for 5-HT measurement following ex vivo tissue measurements. There was a signficant correlation in the amplitude and duration of individual contractions when comparing the measurements using an isometric force transducer and 3D-printed electrochemical sensor. Finally, in the presence of 1 µM fluoxetine, the sensor was able to monitor a reduction in contractility as well as an increase in 5-HT overflow as predicted. Overall, the 3D-printed sensor has the ability to conduct dual simultaneous measurements of 5-HT overflow and contractility. This single device will have significant potential for clinical measurements of anorectum function and signaling that can direct therapeutic management of patients with bowel disorders.

Transcriptome analysis of the central nervous system of the mollusc Lymnaea stagnalis.

BACKGROUND: The freshwater snail Lymnaea stagnalis (L. stagnalis) has served as a successful model for studies in the field of Neuroscience. However, a serious drawback in the molecular analysis of the nervous system of L. stagnalis has been the lack of large-scale genomic or neuronal transcriptome information, thereby limiting the use of this unique model. RESULTS: In this study, we report 7,712 distinct EST sequences (median length: 847 nucleotides) of a normalized L. stagnalis central nervous system (CNS) cDNA library, resulting in the largest collection of L. stagnalis neuronal transcriptome data currently available. Approximately 42% of the cDNAs can be translated into more than 100 consecutive amino acids, indicating the high quality of the library. The annotated sequences contribute 12% of the predicted transcriptome size of 20,000. Surprisingly, approximately 37% of the L. stagnalis sequences only have a tBLASTx hit in the EST library of another snail species Aplysia californica (A. californica) even using a low stringency e-value cutoff at 0.01. Using the same cutoff, approximately 67% of the cDNAs have a BLAST hit in the NCBI non-redundant protein and nucleotide sequence databases (nr and nt), suggesting that one third of the sequences may be unique to L. stagnalis. Finally, using the same cutoff (0.01), more than half of the cDNA sequences (54%) do not have a hit in nematode, fruitfly or human genome data, suggesting that the L. stagnalis transcriptome is significantly different from these species as well. The cDNA sequences are enriched in the following gene ontology functional categories: protein binding, hydrolase, transferase, and catalytic enzymes. CONCLUSION: This study provides novel molecular insights into the transcriptome of an important molluscan model organism. Our findings will contribute to functional analyses in neurobiology, and comparative evolutionary biology. The L. stagnalis CNS EST database is available at http://www.Lymnaea.org/.

Changes in murine anorectum signaling across the life course.

BACKGROUND: Increasing age is associated with an increase in the incidence of chronic constipation and fecal impaction. The contribution of the natural aging process to these conditions is not fully understood. This study examined the effects of increasing age on the function of the murine anorectum. METHODS: The effects of increasing age on cholinergic, nitrergic, and purinergic signaling pathways in the murine anorectum were examined using classical organ bath assays to examine tissue function and electrochemical sensing to determine age-related changes in nitric oxide and acetylcholine release. KEY RESULTS: Nitrergic relaxation increased between 3 and 6 months, peaked at 12 months and declined in the 18 and 24 months groups. These changes were in part explained by an age-related decrease in nitric oxide (NO) release. Cholinergic signaling was maintained with age by an increase in acetylcholine (ACh) release and a compensatory decrease in cholinesterase activity. Age-related changes in purinergic relaxation were qualitatively similar to nitrergic relaxation although the relaxations were much smaller. Increasing age did not alter the response of the anorectum smooth muscle to exogenously applied ACh, ATP, sodium nitroprusside or KCl. Similarly, there was no change in basal tension developed by the anorectum. CONCLUSIONS AND INFERENCES: The decrease in nitrergic signaling with increasing age may contribute to the age-related fecal impaction and constipation previously described in this model by partially obstructing defecation.

Electrochemical sensor for the detection of multiple reactive oxygen and nitrogen species from ageing central nervous system homogenates.

Reactive oxygen and nitrogen species (ROS/RNS) have been widely implicated in the ageing process and various approaches exist for monitoring these species in biological tissues. These approaches at present are limited to monitoring either a single pro-oxidant species or total pro-oxidant levels and therefore provide limited insight into the range of pro-oxidant species and their relative proportions in the ageing process. We have utilised a sensor that allows us to simultaneously monitor hydrogen peroxide, peroxynitrite, nitric oxide and nitrite. Using CNS homogenates from the pond snail, Lymnaea, we were able to show that levels of these ROS/RNS increased between young and old CNS homogenates and were different in various aged CNS regions.

Myenteric neuron numbers are maintained in aging mouse distal colon.

BACKGROUND Age-associated myenteric neuronal loss has been described in several species. In some studies,cholinergic neurons have been reported to be selectively vulnerable, whereas nitrergic neurons are spared. Aging of the mouse enteric nervous system(ENS) and the subtypes of mouse myenteric neurons that may be lost have been little studied. We therefore investigated changes in the numbers of total neurons and two neuronal subpopulations in the mouse distal colon during aging. METHODS Wholemount preparations from 3­4-, 12­13-, 18­19-, and 24­25-month-old C57BL/6 mice were double immunolabeled with HuC/D antibody to identify the total neuronal population and antisera to either calbindin or neuronal nitric oxide synthase (nNOS) to identify myenteric neuronal subpopulations. Samples were analyzed by confocal microscopy. New procedures were employed to ensure unbiased counting and to correct for changes in gut dimensions with age and stretch during sample preparation. The density of nerve fibers in the tertiary plexus was also studied. KEY RESULTS No significant change in numbers of total neurons or of either subpopulation with age was measured, but because of gut growth, the density of myenteric neurons decreased between 3­4 and 12­13 months. The density of nNOS-immunoreactive nerve fibers in the tertiary plexus increased significantly with age, up to 18­19 months. Numerous swollen processes of CB and nNOS-immunoreactive neurons were observed in 18­19- and 24­25-month-old animals. Conclusions &Inferences These results indicate that aging does not result in a loss of myenteric neurons in mouse distal colon at the ages studied, although neurodegenerative changes, which may impact on neuronal function, do occur.

Changes in the innervation of the mouse internal anal sphincter during aging.

BACKGROUND: The innervation of the mouse internal anal sphincter (IAS) has been little studied, and how it changes during aging has not previously been investigated. The aim of this study was therefore to characterize the distribution and density of subtypes of nerve fibers in the IAS and underlying mucosa in 3-, 12- to 13-, 18- and 24- to 25-month-old male C57BL/6 mice. METHODS: Nerve fibers were immunolabeled with antibodies against protein gene product 9.5 (PGP9.5), neuronal nitric oxide synthase (nNOS), vasoactive intestinal polypeptide (VIP), substance P (SP), calcitonin gene-related peptide (CGRP), and calretinin (CR). Immunoreactivity in nerve fibers in the circular muscle and mucosa was quantified using Image J software. KEY RESULTS: In young adult (3 month) mice, nNOS-immunoreactive (IR) nerve fibers were densely distributed in the circular muscle, but relatively few in the mucosa; VIP-IR nerve fibers were abundant in the circular muscle and common in the mucosa; SP-IR nerve fibers were common in circular muscle and mucosa; CGRP- and CR-IR nerve fibers were dense in mucosa and sparse in circular muscle. The density of PGP9.5 immunoreactivity (IRY) was not significantly reduced with age, but a significant reduction in nNOS-IRY and SP-IRY with age was found in the IAS circular muscle. Neuronal nitric oxide synthase-, VIP-, and SP-IRY in the anal mucosa were significantly reduced with age. CGRP-IRY in both circular muscle and mucosa was increased in 18-month-old animals. CONCLUSIONS & INFERENCES: The density of immunoreactivity of markers for some types of IAS nerve fibers decreases during aging, which may contribute to age-related ano-rectal dysfunction.

The use of finite element methods and genetic algorithms in search of an optimal fabric reinforced porous graft system.

The mechanics of arteries result from the properties of the soft tissue constituents and the interaction of the wall layers, predominantly media and adventitia. This concept was adopted in this study for the design of a tissue regenerative vascular graft. To achieve the desired structural properties of the graft, most importantly a diametric compliance of 6%/100 mmHg, finite element methods and genetic algorithms were used in an integrated approach to identify the mechanical properties of an adventitial fabric layer that were required to optimally complement an intimal/medial polyurethane layer with interconnected porosity of three different size classes. The models predicted a compliance of 16.0, 19.2, and 31.5%/100 mmHg for the non-reinforced grafts and 5.3, 5.5, and 6.0%/100 mmHg for the fabric-reinforced grafts. The latter, featuring fabrics manufactured according to the required non-linear mechanical characteristics numerically predicted, exhibited an in vitro compliance of 2.1 +/- 0.8, 3.0 +/- 2.4, and 4.0 +/- 0.7% /100 mmHg. The combination of finite element methods and genetic algorithms was shown to be able to successfully optimize the mechanical design of the composite graft. The method offers potential for the application to alternative concepts of modular vascular grafts and the incorporation of tissue ingrowth and biodegradation.

Changes in the properties of the modulatory cerebral giant cells contribute to aging in the feeding system of Lymnaea.

This study examined whether electrophysiological changes in the endogenous properties and connectivity of the modulatory serotonergic cerebral giant cells (CGCs) contributed to the age-related changes in feeding behavior of the pond snail, Lymnaea. With increasing age there was a decrease in spontaneous CGC firing rates and decreased excitability of the CGCs to both chemosensory stimulation (0.05M sucrose applied to the lips) and direct intracellular current injection. These changes could be accounted for by a decrease in the input resistance of the neuron and an increase in the amplitude and the duration of the after-hyperpolarization. Decreases were also seen in the % of CGC pairs that were electrically coupled causing asynchronous firing. Together these changes would tend to reduce the ability of the CGCs to gate and control the frequency of the feeding behavior. Part of the ability of the CGCs to gate and frequency control the feeding network is to provide a background level of excitation to the feeding motor neurons. Recordings from B1 and B4 motor neurons showed an age-related hyperpolarization of the resting membrane potential consistent with a deficit in CGC function. Increases were seen in the strength of the evoked CGC-->B1 connection, however, this increase failed to compensate for the deficits in CGC excitability. In summary, age-related changes in the properties of the CGCs were consistent with them contributing to the age-related changes in feeding behavior seen in Lymnaea.

Effects of age on feeding behavior and chemosensory processing in the pond snail, Lymnaea stagnalis.

This study used behavioral and electrophysiological techniques to examine age-related changes in the feeding behavior and chemosensory processing in the pond snail, Lymnaea stagnalis. Increasing age was associated with a 50% decrease in long-term food consumption. Analysis of short-term sucrose-evoked feeding bouts showed an age-related increase in the number of animals that failed to respond to the stimulus. Of the animals that did respond increasing age was associated with a decrease in the number of sucrose-evoked bites and a increase in the duration of the swallow phase. These changes were observed with both 0.01 and 0.05M sucrose stimuli but were not seen when 0.1M sucrose was used as the stimulus. Electrophysiological analysis of the chemosensory pathway in semi-intact lip-CNS preparations failed to demonstrate a significant change in the neuronal information entering the cerebral ganglia from the lips via the median lip nerve, but did demonstrate an age-related deficit in the neuronal output from the cerebral ganglia. This deficit was also dependent on the sucrose concentration and mirrored the concentration-dependent changes in feeding behavior. In summary, aging appeared to affect central but not peripheral processing of chemosensory information and suggests that this deficit contributes to the age-related changes in feeding behavior.

Ageing and the nervous system: insights from studies on invertebrates.

Ageing can have profound effects on the post-mitotic organ of behaviour, the brain. As yet the precise causes of these deleterious effects are unknown. However, clear insights into the putative mechanisms and consequences of ageing in the CNS have been achieved through the use of invertebrate models. It is now clear that ageing alters the endogenous properties of neurones, their morphology, the efficacy of the connections that the neurones make with their targets and may even lead to neurone loss. While the precise mechanisms underlying these changes are presently unclear clues from post-mitotic organisms such as C. elegans have provided putative targets which are currently being investigated. It is clear to date that the age-induced changes in CNS function observed in invertebrates are conserved in mammalian species and that further work on invertebrates may provide informative insights in to the mechanisms of neuronal ageing.

Two types of voltage-gated K(+) currents in dissociated heart ventricular muscle cells of the snail Lymnaea stagnalis.

We have used a combination of current-clamp and voltage-clamp techniques to characterize the electrophysiological properties of enzymatically dissociated Lymnaea heart ventricle cells. Dissociated ventricular muscle cells had average resting membrane potentials of -55 +/- 5 mV. When hyperpolarized to potentials between -70 and -63 mV, ventricle cells were capable of firing repetitive action potentials (8.5 +/- 1.2 spikes/min) that failed to overshoot 0 mV. The action potentials were either simple spikes or more complex spike/plateau events. The latter were always accompanied by strong contractions of the muscle cell. The waveform of the action potentials were shown to be dependent on the presence of extracellular Ca(2+) and K(+) ions. With the use of the single-electrode voltage-clamp technique, two types of voltage-gated K(+) currents were identified that could be separated by differences in their voltage sensitivity and time-dependent kinetics. The first current activated between -50 and -40 mV. It was relatively fast to activate (time-to-peak; 13.7 +/- 0.7 ms at +40 mV) and inactivated by 53.3 +/- 4.9% during a maintained 200-ms depolarization. It was fully available for activation below -80 mV and was completely inactivated by holding potentials more positive than -40 mV. It was completely blocked by 5 mM 4-aminopyridine (4-AP) and by concentrations of tetraethylammonium chloride (TEA) >10 mM. These properties characterize this current as a member of the A-type family of voltage-dependent K(+) currents. The second voltage-gated K(+) current activated at more depolarized potentials (-30 to -20 mV). It activated slower than the A-type current (time-to-peak; 74.1 +/- 3.9 ms at +40 mV) and showed little inactivation (6.2 +/- 2.1%) during a maintained 200-ms depolarization. The current was fully available for activation below -80 mV with a proportion of the current still available for activation at potentials as positive as 0 mV. The current was completely blocked by 1-3 mM TEA. These properties characterize this current as a member of the delayed rectifier family of voltage-dependent K(+) currents. The slow activation rates and relatively depolarized activation thresholds of the two K(+) currents are suggestive that their main role is to contribute to the repolarization phase of the action potential.

A cholinergic modulatory interneuron in the feeding system of the snail, Lymnaea.

1. Pharmacological and physiological methods were used to examine the role of acetylcholine (ACh) in modulation of the Lymnaea feeding central pattern generator (CPG) by the slow oscillator (SO) interneuron. 2. Extracts of dissected SO cell bodies inhibited spontaneous ventricular contractions of the clam Mya arenaria, indicating the presence of ACh. These effects were blocked by the specific antagonist benzoquinonium chloride (10(-7) M). 3. Isolated SO cells grown in culture synthesized ACh from tritiated choline. 4. High [K+] saline induced release of synthesized ACh from cultured SO cells into the medium. 5. The specific ACh antagonist phenyltrimethylammonium (10(-4) M) blocked both excitatory, biphasic (inhibitory-excitatory) and inhibitory monosynaptic connections from the SO to feeding CPG interneurons and motor neurons. Less specific cholinergic antagonists blocked either excitatory (hexamethonium, 10(-4) M) or both excitatory and inhibitory connections (d-tubo-curarine, 10(-4) M). 6. The synaptic responses of the SO could be mimicked by brief (20 ms) pressure-pulsed application of ACh onto the cell bodies of the postsynaptic cells in high-Mg2+ saline. In normal saline, ACh elicited bursts of spikes in the N1 cells, indicating that a fictive feeding pattern had been induced in the CPG. This mimics the main mechanism by which the SO activates the CPG, which is by exciting the N1s. 7. The frequency of SO-induced fictive feeding rhythm was reduced by bath application of hexamethonium chloride to the buccal ganglia. This reduced the amplitude of the SO-->N1 excitatory synaptic response (30% of controls) and is probably the main mechanism for the reduction in the frequency of the rhythm. 8. The evidence suggests that ACh is the main neurochemical involved in allowing the SO to initiate and control the frequency of the Lymnaea feeding CPG.

Central pattern generator interneurons are targets for the modulatory serotonergic cerebral giant cells in the feeding system of Lymnaea.

1. The objective of the experiments was to explore the modulatory functions of the serotonergic cerebral giant cells (CGCs) of the Lymnaea feeding system by examining their synaptic connections with the central pattern generator (CPG) interneurons and the modulatory slow oscillator (SO) interneuron. 2. One type of modulatory function, "gating," requires that the CGCs fire tonically at a minimum of 7 spikes/min. Above this minimum level the CGCs control the frequency of CPG interneuron oscillation-- "frequency control," a second type of modulation. In an SO-driven fictive feeding rhythm, an increase in the frequency of the rhythm, with increased CGC firing rate, resulted from a reduction in the duration of the N1 (protraction) and N2 (rasp) phases of the feeding cycle with little effect on the N3 (swallow) phase. 3. The CGCs excited the N1 phase interneurons SO and N1M (N1 medial) cells but had no consistent effects on the N1 lateral cells. The CGC-->SO postsynaptic response was probably monosynaptic (< or = 200 ms in duration) with unitary 1:1 excitatory postsynaptic potentials (EPSPs) following each CGC spike. The CGC-->N1M excitatory response was slow and nonunitary, and a burst of CGC spikes evoked a depolarization of the N1M cells that lasted up to 10 s and triggered N1M cell bursts. Both CGC-->SO and CGC-->N1M excitatory responses could be mimicked by the focal application of serotonin (5-HT). 4. Both CGC-->SO and CGC-->N1M excitatory connections systematically increased the N1M cell firing rate within the CGCs' physiological firing range (0-40 spikes/min). This was due to both the direct (CGC-->N1M) and indirect (CGC-->SO-->N1M) excitatory synaptic pathways. The CGC-induced increase in N1M cell firing rate probably accounted for the reduced duration of the N1M cell feeding burst by causing a more rapid reversal of the feeding cycle from the N1 phase to the N2 phase. This phase reversal was due to the previously described recurrent inhibitory pathway (N1-->N2 excitation followed by N2-->N1 inhibition). 5. The CGCs' ability to provide a depolarizing drive to the N1M cells meant that this excitatory connection was also likely to be important for gating. 6. Activity in the CGCs produced nonunitary, long-lasting, excitatory postsynaptic responses on the N2 ventral (N2v) CPG interneurons, and these were likely to be involved in both the gating and the frequency control by the CGCs on the N2 phase of the feeding rhythm. Suppressing CGC tonic firing initially increased the duration of the N2v plateau (which determines the duration of the N2 phase of the feeding cycle, frequency function) but eventually led to a loss of N2v plateauing (gating function). 7. Nonunitary, weakly inhibitory CGC-->N2 dorsal responses were recorded that could be mimicked by the application of 5-HT. 8. Spikes in the CGCs evoked 1:1 monosynaptic EPSPs in the N3 tonic (N3t) CPG interneurons. This excitatory effect could be mimicked by the application of 5-HT. Within the physiological range of CGC firing, this excitation did not appear to influence the firing rate of the N3t cells. 9. N3 phasic (N3p) CPG interneurons showed biphasic (hyperpolarizing followed by depolarizing) unitary responses to spikes evoked in the CGCs. The inhibitory synaptic response was maintained in a high-Ca2+/high-Mg2+ (Hi-Di) saline and was mimicked by the focal application of 5-HT, indicating that it was probably monosynaptic. The excitatory component was, however, reduced in a Hi-Di saline, indicating that it was probably polysynaptic. Suppressing the CGCs during an SO-driven feeding rhythm caused the N3p cells to fire less, suggesting that the removal of the excitatory component of the response might be significant. 10. We conclude that the general depolarizing effects of the CGCs on a number of the CP

Glutamatergic N2v cells are central pattern generator interneurons of the lymnaea feeding system: new model for rhythm generation.

We aimed to show that the paired N2v (N2 ventral) plateauing cells of the buccal ganglia are important central pattern generator (CPG) interneurons of the Lymnaea feeding system. N2v plateauing is phase-locked to the rest of the CPG network in a slow oscillator (SO)-driven fictive feeding rhythm. The phase of the rhythm is reset by artificially evoked N2v bursts, a characteristic of CPG neurons. N2v cells have extensive input and output synaptic connections with the rest of the CPG network and the modulatory SO cell and cerebral giant cells (CGCs). Synaptic input from the protraction phase interneurons N1M (excitatory), N1L (inhibitory), and SO (inhibitory-excitatory) are likely to contribute to a ramp-shaped prepotential that triggers the N2v plateau. The prepotential has a highly complex waveform due to progressive changes in the amplitude of the component synaptic potentials. Most significant is the facilitation of the excitatory component of the SO --> N2v monosynaptic connection. None of the other CPG interneurons has the appropriate input synaptic connections to terminate the N2v plateaus. The modulatory function of acetylcholine (ACh), the transmitter of the SO and N1M/N1Ls, was examined. Focal application of ACh (50-ms pulses) onto the N2v cells reproduced the SO --> N2v biphasic synaptic response but also induced long-term plateauing (20-60 s). N2d cells show no endogenous ability to plateau, but this can be induced by focal applications of ACh. The N2v cells inhibit the N3 tonic (N3t) but not the N3 phasic (N3p) CPG interneurons. The N2v --> N3t inhibitory synaptic connection is important in timing N3t activity. The N3t cells recover from this inhibition and fire during the swallow phase of the feeding pattern. Feedback N2v inhibition to the SO, N1L protraction phase interneurons prevents them firing during the retraction phase of the feeding cycle. The N2v --> N1M synaptic connection was weak and only found in 50% of preparations. A weak N2v --> CGC inhibitory connection prevents the CGCs firing during the rasp (N2) phase of the feeding cycle. These data allowed a new model for the Lymnaea feeding CPG to be proposed. This emphasizes that each of the six types of CPG interneuron has a unique set of synaptic connections, all of which contribute to the generation of a full CPG pattern.

Glutamate is the transmitter for N2v retraction phase interneurons of the Lymnaea feeding system.

Electrophysiological and pharmacological methods were used to examine the role of glutamate in mediating the excitatory and inhibitory responses produced by the N2v rasp phase neurons on postsynaptic cells of the Lymnaea feeding network. The N2v --> B3 motor neuron excitatory synaptic response could be mimicked by focal or bath application of -glutamate at concentrations of >/=10(-3) M. Quisqualate and alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) were potent agonists for the B3 excitatory glutamate receptor (10(-3) M), whereas kainate only produced very weak responses at the same concentration. This suggested that non-N-methyl--aspartate (NMDA), AMPA/quisqualate receptors were present on the B3 cell. The specific non-NMDA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 10(-5) M) blocked 85% of the excitatory effects on the B3 cell produced by focal application of glutamate (10(-3) M), confirming the presence of non-NMDA receptors. CNQX also blocked the major part of the excitatory postsynaptic potentials on the B3 cell produced by spontaneous or current-evoked bursts of spikes in the N2v cell. As with focal application of glutamate, a small delayed component remained that was CNQX insensitive. This provided direct evidence that glutamate acting via receptors of the non-NMDA, AMPA/quisqualate type were responsible for mediating the main N2v --> B3 cell excitatory response. NMDA at 10(-2) M also excited the B3 cell, but the effects were much more variable in size and absent in one-third of the 25 B3 cells tested. NMDA effects on B3 cells were not enhanced by bath application of glycine at 10(-4) M or reduction of Mg2+ concentration in the saline to zero, suggesting the absence of typical NMDA receptors. The variability of the B3 cell responses to NMDA suggested these receptors were unlikely to be the main receptor type involved with N2v --> B3 excitation. Quisqualate and AMPA at 10(-3) M also mimicked N2v inhibitory effects on the B7 and B8 feeding motor neurons and the modulatory slow oscillator (SO) interneuron, providing further evidence for the role of AMPA/quisqualate receptors. Similar effects were seen with glutamate at the same concentration. However, CNQX could not block either glutamate or N2v inhibitory postsynaptic responses on the B7, B8, or SO cells, suggesting a different glutamate receptor subtype for inhibitory responses compared with those responsible for N2v --> B3 excitation. We conclude that glutamate is a strong candidate transmitter for the N2v cells and that AMPA/quisquate receptors of different subtypes are likely to be responsible for the excitatory and inhibitory postsynaptic responses.

LVA and HVA Ca(2+) currents in ventricular muscle cells of the Lymnaea heart.

The single-electrode voltage-clamp technique was used to characterize voltage-gated Ca(2+) currents in dissociated Lymnaea heart ventricular cells. In the presence of 30 mM tetraethylammonium (TEA), two distinct Ca(2+) currents could be identified. The first current activated between -70 and -60 mV. It was fully available for activation at potentials more negative than -80 mV. The current was fast to activate and inactivate. The inactivation of the current was voltage dependent. The current was larger when it was carried by Ca(2+) compared with Ba(2+), although changing the permeant ion had no observable effect on the kinetics of the evoked currents. The current was blocked by Co(2+) and La(3+) (1 mM) but was particularly sensitive to Ni(2+) ions ( approximately 50% block with 100 microM Ni(2+)) and insensitive to low doses of the dihydropyridine Ca(2+) channel antagonist, nifedipine. All these properties classify this current as a member of the low-voltage-activated (LVA) T-type family of Ca(2+) currents. The activation threshold of the current (-70 mV) suggests that it has a role in pacemaking and action potential generation. Muscle contractions were first seen at -50 mV, indicating that this current might supply some of the Ca(2+) necessary for excitation-contraction coupling. The second, a high-voltage-activated (HVA) current, activated at potentials between -40 and -30 mV and was fully available for activation at potentials more negative than -60 mV. This current was also fast to activate and with Ca(2+) as the permeant ion, inactivated completely during the 200-ms voltage step. Substitution of Ba(2+) for Ca(2+) increased the amplitude of the current and significantly slowed the rate of inactivation. The inactivation of this current appeared to be current rather than voltage dependent. This current was blocked by Co(2+) and La(3+) ions (1 mM) but was sensitive to micromolar concentrations of nifedipine ( approximately 50% block 10 microM nifedipine) that were ineffective at blocking the LVA current. These properties characterize this current as a L-type Ca(2+) current. The voltage sensitivity of this current suggests that it is also important in generating the spontaneous action potentials, and in providing some of the Ca(2+) necessary for excitation-contraction coupling. These data provide the first detailed description of the voltage-dependent Ca(2+) currents present in the heart muscle cells of an invertebrate and indicate that pacemaking in the molluscan heart has some similarities with that of the mammalian heart.

Inositol-1,4,5-trisphosphate and inositol-1,3,4,5-tetrakisphosphate are second messenger targets for cardioactive neuropeptides encoded on the FMRFamide gene.

This paper examines the importance of the calcium-mobilizing inositol phosphate pathway in mediating the effects of FMRFamide and its gene-related neuropeptides on the myogenic heart beat of the pond snail Lymnaea stagnalis. These peptides are encoded on a single exon of the FMRFamide gene and mediate diverse physiological effects in the isolated heart. The rate of production of inositol-1,4, 5-trisphosphate [Ins(1,4,5)P(3)] and inositol-1,3,4, 5-tetrakisphosphate [Ins(1,3,4,5)P(4)], measured using an HPLC method, were both significantly elevated in a concentration-dependent manner by FMRFamide (and were also elevated by FLRFamide). The threshold for increasing inositol phosphate production was low (100 pmol l(-1)) with a peak response occurring at 1 micromol l(-1) FMRFamide. The shape of the dose-response curve for FMRFamide-induced elevation of heart-beat frequency, obtained in pharmacological experiments on the isolated whole heart, was similar to that for stimulation of inositol phosphate levels in homogenized heart tissue. FMRFamide and Ins(1,4,5)P(3) produced similar effects on the rate of heart beat in permeabilized whole hearts. In addition, the phospholipase C inhibitor, neomycin (2.5 mmol l(-)(1)), blocked the stimulatory effects of FMRFamide on Ins(1, 4,5)P(3) production in heart homogenate, and attenuated the excitatory effects of this neuropeptide in the isolated heart. The 'isoleucine' pentapeptides, EFLRIamide and pQFYRIamide, also encoded by the FMRFamide gene, produced no significant effects on inositol phosphate production when applied alone or in combination with FMRFamide. These results suggested that FMRFamide (and FLRFamide), but not EFLRIamide and pQFYRIamide, mediated their main effects on heart beat via the inositol phosphate pathway. The fifth peptide, SEQPDVDDYLRDVVLQSEEPLY ('SEEPLY') had no effect when applied alone but appeared to modulate the effects of FMRFamide by delaying the time-to-peak of the Ins(1,4,5)P(3) response from 5 s to 20 s by an unknown mechanism.

Cyclic AMP is involved in cardioregulation by multiple neuropeptides encoded on the FMRFamide gene.

We have used a combination of biochemical and pharmacological techniques to investigate the role of the cyclic nucleotides, 3', 5'-cyclic adenosine monophosphate (cyclic AMP) and 3',5'-cyclic guanosine monophosphate (cyclic GMP), in mediating the cardioregulatory effects of FMRFamide and other neuropeptides encoded on exon II of the FMRFamide gene of Lymnaea stagnalis. The 'isoleucine' peptides (EFLRIamide and pQFYRIamide) produced complex biphasic effects on the frequency, force of contraction and tonus of the isolated heart of L. stagnalis, which were dependent on adenylate cyclase (AC) activity of the heart tissue. At a control rate of cyclic AMP production of less than or equal to 10 pmoles min(-)(1 )mg(-)(1) protein, the 'isoleucine' peptides produced a significant increase in AC activity in heart membrane preparations. This suggested that the enhanced AC activity is responsible for the stimulatory effects of the 'isoleucine' peptides on frequency and force of contraction of heart beat. This excitation sometimes followed an initial 'inhibitory phase' where the frequency of beat, force of contraction and tonus of the heart were reduced by the 'isoleucine' peptides. Hearts that showed the inhibitory phase of the 'isoleucine' response, but characteristically lacked the delayed excitatory phase, were found to have high levels of membrane AC activity (breve)10 pmoles min(-)(1 )mg(-)(1) protein in controls. Application of the 'isoleucine' peptides to membrane homogenate preparation from these hearts failed to increase AC activity. The addition of FMRFamide produced significant increases in the rate of cyclic AMP production in the heart membrane preparations, which could account, at least in part, for the cardioexcitatory effects of this peptide in the isolated whole heart. A membrane-permeable cyclic AMP analogue (8-bromo-cyclic AMP) and an AC activator (forskolin) were also cardioexcitatory. The peptide SEEPLY had no effects on the beat properties of the isolated heart and did not alter AC activity. The activity of the membrane-bound (particulate) guanylate cyclase (GC) was not significantly affected by any of the peptides.

Matrix-assisted laser desorption/ionization time of flight mass spectrometric analysis of the pattern of peptide expression in single neurons resulting from alternative mRNA splicing of the FMRFamide gene.

MALDI-ToF MS (matrix-assisted laser desorption/ionization time of flight mass spectrometry) has become a fast, reliable and sensitive technique for the identification of neuropeptides in biological tissues. Here, we applied this technique to identified neurons of the cardioregulatory network in the snail Lymnaea that express the FMRFamide gene. This enabled us to study the complex processing of the FMRFamide gene at the level of single identified neurons. In the CNS of Lymnaea, FMRFamide-like and additional peptides are encoded by a common, multiexon gene. Alternate mRNA splicing of the FMRFamide gene leads to the production of two different mRNAs. Type 1 mRNA (exon II) encodes for the tetrapeptides (FLRF/FMRFamide), whereas Type 2 (exons III-V) encodes for the heptapeptides (SDPFLRFamide/GDPFLRFamide). Previous in situ hybridization and immunocytochemical studies indicated that these two transcripts are expressed in the CNS neurons of Lymnaea in a differential and mutually exclusive manner. Two single identified neurons of the cardiorespiratory network, the Ehe neuron and the visceral white interneuron (VWI), were known to express the FMRFamide gene (Ehe, type 1 mRNA; VWI, type 2 mRNA). MALDI-ToF MS analysis of these neurons and other neurons expressing the FMRFamide gene confirmed the mutually exclusive expression of the distinct sets of peptides encoded on the two transcripts and revealed the pattern of post-translational processing of both protein precursors. From the gene sequence it was predicted that 16 final peptide products from the two precursor proteins could possibly exist. We showed that most of these peptides were indeed present in the identified neurons (13) while others were not (three), suggesting that not all of the potential cleavage sites within the two precursors are utilized. In this way, the neuronal expression of the full range of the peptide products resulting from alternative mRNA splicing was revealed for the first time.

Modulatory role for the serotonergic cerebral giant cells in the feeding system of the snail, Lymnaea. II. Photoinactivation.

1. Photoinactivation of dye-filled neurons was used to examine the modulatory role of the paired cerebral giant cells (CGCs) in the Lymnaea feeding system. 2. Both CGCs were filled with fluorescent dyes. Lucifer yellow was used for "soma" kills and injected via intracellular microelectrodes. CGC axons were retrogradely filled with 5 (6)-carboxyfluorescein (5-CF), through the cut ends of the ventro- and lateral buccal nerves, for "axonal" kills. 3. Irradiation of the CGC soma with a blue laser light (0.5 MW/m2) led to a loss of their recorded membrane potentials and the synaptic responses with their postsynaptic cells (feeding motor neurons). CGC coupling and axonal fluorescence were lost after axonal irradiation. 4. The tonic firing rate of CGC axon spikes in peripheral nerve roots following bilateral soma kills was reduced to approximately 15% of preirradiation levels (n = 2; from 52.5 +/- 3.75 spikes/min to 8.2 +/- 0.95 spikes/min; mean +/- SE) but spike activity was not completely eliminated. 5. The fictive feeding rhythm was evoked by depolarizing a modulatory neuron, the slow oscillator (SO), before and after laser irradiation. Thirty minutes after both the CGCs were irradiated (n = 8), the frequency of the SO-driven feeding rhythm was reduced. Mean fictive feeding rates were reduced from 8.3 to 4.5 cycles/min for soma kills (n = 3) and from 16.2 to 9.6 cycles/min for axonal kills (n = 5; P < 0.05). 6. The results suggest that the CGCs play a modulatory role in controlling the frequency of oscillation of the feeding central pattern generator (CPG) in Lymnaea. The SO could still drive a full fictive feeding rhythm after irradiation but at a reduced rate. At least in the soma kills, the residual spike activity retained in the distal branches of the CGCs appeared sufficient to allow the SO to drive this slow rhythm.