Ionic mechanism of 5-hydroxytryptamine induced hyperpolarization and inhibitory junctional potential in body wall muscle cells of Hirudo medicinalis

Five-hydroxy tryptamine (5-HT) causes a hyperpolarization and increased conductance of the leech body wall muscle cell membrane. If 5-HT is applied in the absence of the Cl^?ion, the response appears as a depolarization, whereas if 5-HT is applied in the absence of the K⁺ion, the response is a hyperpolarization. In both cases, the conductance of the muscle cell membrane is increased. Stimulation of the peripheral nerve to the body wall muscle produces a complex junctional potential in muscle cells. Exposing the muscle to d-tubocurarine (d-TC) eliminates the excitatory component (EJP) of the complex potential. The inhibitory potential (IJP) that remains has an equilibrium potential at approximately 65 m V. Furthermore, this IJP appears as a depolarization when the nerve is stimulated in the presence of d-TC and low CL^?, whereas this is not the case if the nerve is stimulated in the presence of d-TC and low K⁺. The drugs BOL-148 and cyproheptadine block the IJP's in the body wall muscle. These data are interpreted as indicating that 5'HT acts on leech body wall muscle cells by increasing the conductance to the Cl^?ion and that the IJP's caused by nerve stimulation are probably the result of 5-HT release at nerve terminals. As a final point, it has been shown that the inhibition by 5-HT of the spontaneous EJP's that occur on the leech body wall muscle results from an inhibition of central neurons and not from any direct effect on the muscle cell or on peripheral synapses.     

CaMKII inhibition hyperpolarizes membrane and blocks nitrergic IJP by closing a Cl(-) conductance in intestinal smooth muscle

The ionic basis of nitrergic "slow'" inhibitory junction potential (sIJP) is not fully understood. The purpose of the present study was to determine the nature and the role of calmodulin-dependent protein kinase II (CaMKII)-dependent ion conductance in nitrergic neurotransmission at the intestinal smooth muscle neuromuscular junction. Studies were performed in guinea pig ileum. The modified Tomita bath technique was used to induce passive hyperpolarizing electrotonic potentials (ETP) and membrane potential change due to sIJP or drug treatment in the same cell. Changes in membrane potential and ETP were recorded in the same smooth muscle cell, using sharp microelectrode. Nitrergic IJP was elicited by electrical field stimulation in nonadrenergic, noncholinergic conditions and chemical block of purinergic IJP. Modification of ETP during hyperpolarization reflected active conductance change in the smooth muscle. Nitrergic IJP was associated with decreased membrane conductance. The CAMKII inhibitor KN93 but not KN92, the Cl(-) channel blocker niflumic acid (NFA), and the K(ATP)-channel opener cromakalim hyperpolarized the membrane. However, KN93 and NFA were associated with decreased and cromakalim was associated with increased membrane conductance. After maximal NFA-induced hyperpolarization, hyperpolarization associated with KN93 or sIJP was not seen, suggesting a saturation block of the Cl(-) channel signaling. These studies suggest that inhibition of CaMKII-dependent Cl(-) conductance mediates nitrergic sIJP by causing maximal closure of the Cl(-) conductance.     

Unusual potassium channels mediate nonadrenergic noncholinergic nerve-mediated inhibition in opossum esophagus

Field stimulation of the circular muscle of the opossum esophagus produces a transient hyperpolarization (inhibitory junction potential, IJP) followed by an "off" depolarization. A similar nonadrenergic, noncholinergic (NANC) response in guinea pig taenia caecum has been shown to be due to an increase in the potassium ion permeability of the smooth muscle cell membrane. Double sucrose gap studies showed a decrease in resistance during the IJP, and a reversal at an estimated membrane potential of about -90 mV (4 mM K+). The reversal potential was dependent on the extracellular potassium concentration, shifting to -75 mV when the potassium in the superfusion medium was increased to 10 mM. The IJP in the opossum esophageal circular smooth muscle is therefore like the IJP of the guinea pig taenia caecum in that it is probably due to a selective increase in potassium ion permeability. Potassium conductance blocking agents, tetraethylammonium chloride (TEA, 20 mM) and 4-aminopyridine (4-AP, 5 mM) both caused a depolarization of the smooth muscle cell membrane, but TEA increased the membrane resistance, whereas 4-AP did not affect the membrane conductance in a consistent way. A decrease in IJP amplitude owing to these agents was not apparent. Apamin (10 microM) did not affect the membrane potential, the membrane resistance, or the IJP. Quinine (0.1 mM) produced effects quantitatively similar to those of TEA. Quinine (1 mM) did abolish the IJP, however, this was likely due to a blockade of impulse transmission of the intramural nerves.(ABSTRACT TRUNCATED AT 250 WORDS)     

The identification of two inhibitory cells in each segmental ganglion of the leech and studies on the ionic mechanism of the inhibitory junctional potentials produced by these cells.

The present study identifies a pair of inhibitory cells that are located on each anterolateral margin of a leech segmental ganglion. These cells, which we label as cells 119, are electrically interconnected. These cells give rise to inhibitory junctional potentials (ijp's) in contralteral longitudinal body wall muscle cells. The latencies of the ijp's following spikes in cell 119 are variable. The ijp's are caused by transient increases in premeability to the Cl- ion. Previous studies demonstrated that 5-HT causes a hyperpolarization of body wall muscle cells by increasing the permeability of muscle membrane to the Cl- ion. Accordingly, 5-HT was searched for in the 119 cell bodies, but autoradiography, fine structure, and gas chromatography-mass spectrometry gave no indication that 5-HT was present in these cells. However, the variable latencies of the ijp's may indicate that there is a neuron interposed between cell 119 and the muscle cells. If this is the case, then the interposed neuron should be analyzed for 5-HT. Further experiments to locate the terminals of cells 119 and the cell bodies of the presumed interposed neurons are thus desirable.     

The identification of two inhibitory cells in each segmental ganglion of the leech and studies on the ionic mechanism of the inhibitory junctional potentials produced by these cells

The present study identifies a pair of inhibitory cells that are located on each anterolateral margin of a leech segmental ganglion. These cells, which we label as cells 119, are electrically interconnected. These cells give rise to inhibitory junctional potentials (ijp's) in contralateral longitudinal body wall muscle cells. The latencies of the ijp's following spikes in cell 119 are variable. The ijp's are caused by transient increases in premeability to the Cl^? ion. Previous studies demonstrated that 5-HT causes a hyperpolarization of body wall muscle cells by increasing the permeability of muscle membrane to the Cl^? ion. Accordingly, 5-HT was searched for in the 119 cell bodies, but autoradiography, fine structure, and gas chromatography-mass spectrometry gave no indication that 5-HT was present in these cells. However, the variable latencies of the ijp's may indicate that there is a neuron interposed between cell 119 and the muscle cells. If this is the case, then the interposed neuron should be analyzed for 5-HT. Further experiments to locate the terminals of cells 119 and the cell bodies of the presumed interposed neurons are thus desirable.     

Leech Retzius cells and 5-hydroxytryptamine

A pair of giant Retzius (R) cells in each segmental ganglion of the leech contain 5-hydroxytryptamine (5-HT). They are the only 5-HT-containing neurones in the central nervous system to send branches to the periphery, yet many peripheral tissues (e.g. body wall muscles, heart, reproductive organs, nephridia and gut) possess 5-HT-like immunoreactive nerve fibres. 5-HT and/or R cell stimulation relax basal tension of body wall muscles and reduce their relaxation times following contraction, enhance pharyngeal movements and salivary gland secretion but inhibit muscle movements of the posterior gut regions and of the reproductive tract. It is suggested that R cells are multifunction neurones modulating activity of many tissues so that feeding behaviour of the leech is carried out as efficiently as possible.     

Serotonin modulates muscle function in the medicinal leech Hirudo verbana

The body wall muscles of sanguivorous leeches power mechanically diverse behaviours: suction feeding, crawling and swimming. These require longitudinal muscle to exert force over an extremely large length range, from 145 to 46 per cent of the mean segmental swimming length. Previous data, however, suggest that leech body wall muscle has limited capacity for force production when elongated. Serotonin (5-HT) alters the passive properties of the body wall and stimulates feeding. We hypothesized that 5-HT may also have a role in allowing force production in elongated muscle by changing the shape of the length-tension relationship (LTR). LTRs were measured from longitudinal muscle strips in vitro in physiological saline with and without the presence of 10 μM 5-HT. The LTR was much broader than previously measured for leech muscle. Rather than shifting the LTR, 5-HT reduced passive muscle tonus and increased active stress at all lengths. In addition to modulating leech behaviour and passive mechanical properties, 5-HT probably enhances muscle force and work production during locomotion and feeding.     

A central inhibitory action of 5-hydroxytryptamine in the leech

Previous studies indicated that 5-HT reduced the number of spontaneous excitatory junctional potentials (ejp's) that occurred in leech body wall muscle cells. The present study confirms these findings and shows that the ejp's arise from impulses in motoneuron L. This study further shows that 5-HT acts by hyperpolarizing and reducing the membrane resistance of neuron L, thus inhibiting the motoneuron and reducing the frequency of spontaneous ejp's on body wall muscle cells. These effects of 5-HT are not seen when the ganglion is bathed in a high magnesium solution, a finding that suggests that 5-HT does not act directly on the membrane of motoneuron L. This study demonstrates that 5-HT can have a central inhibitory effect on body wall muscle contractions. Previous studies provide evidence that 5-HT may act as a direct neuromuscular inhibitory transmitter and may also take part in peripheral presynaptic inhibition. Thus, if further studies confirm these suggestions, the well-known inhibitory effect of 5-HT on leech body wall muscle is a more complex process than was previously thought.     

Effect of exogenous ATP on canine jejunal smooth muscle

Intracellular recordings were made from the circular smooth muscle cells of the canine jejunum to study the effect of exogenous ATP and to compare the ATP response to the nonadrenergic, noncholinergic (NANC) inhibitory junction potential (IJP) evoked by electrical field stimulation (EFS). Under NANC conditions, exogenous ATP evoked a transient hyperpolarization (6.5 +/- 0.6 mV) and EFS evoked a NANC IJP (17 +/- 0.4 mV). Omega-conotoxin GVIA (100 nM) and a low-Ca(2+), high-Mg(2+) solution abolished the NANC IJP but had no effect on the ATP-evoked hyperpolarization. The ATP-evoked hyperpolarization and the NANC IJP were abolished by apamin (1 microM) and N(G)-nitro-L-arginine (100 microM). Oxyhemoglobin (5 microM) partially (38.8 +/- 5.5%) reduced the amplitude of the NANC IJP but had no effect on the ATP-evoked hyperpolarization. Neither the NANC IJP nor the ATP-evoked hyperpolarization was affected by P2 receptor antagonists or agonists, including suramin, reactive blue 2, 1-(N, O-bis-[5-isoquinolinesulfonyl]-N-methyl-L-tyrosyl)-4-phenylpiperazine , pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid, alpha, beta-methylene ATP, 2-methylthioadenosine 5'-triphosphate tetrasodium salt, and adenosine 5'-O-2-thiodiphosphate. The data suggest that ATP evoked an apamin-sensitive hyperpolarization in circular smooth muscle cells of the canine jejunum via local production of NO in a postsynaptic target cell.     

Role of Ca2+-activated Cl- channels and MLCK in slow IJP in opossum esophageal smooth muscle

The possible contribution of Ca2+-activated Cl- channel [I(Cl(Ca))] and myosin light-chain kinase (MLCK) to nonadrenergic, noncholinergic slow inhibitory junction potentials (sIJP) was studied using conventional intracellular microelectrode recordings in circular smooth muscle of opossum esophageal body and guinea pig ileum perfused with Krebs solution containing atropine (3 microM), guanethidine (3 microM), and substance P (1 microM). In opossum esophageal circular smooth muscle, resting membrane potential (MP) was -51.9 +/- 0.7 mV (n = 89) with MP fluctuations of 1-3 mV. A single square-wave nerve stimulation of 0.5 ms duration and 80 V induced a sIJP with amplitude of 6.3 +/- 0.2 mV, half-amplitude duration of 635 +/- 19 ms, and rebound depolarization amplitude of 2.4 +/- 0.1 mV (n = 89). 9-Anthroic acid (A-9-C), niflumic acid (NFA), wortmannin, and 1-(5-chloronaphthalene-1-sulfonyl)-1H-hexahydro-1,4-diazepine (ML-9) abolished MP fluctuations, sIJP, and rebound depolarization in a concentration-dependent manner. A-9-C and NFA but not wortmannin and ML-9 hyperpolarized MP. In guinea pig ileal circular smooth muscle, nerve stimulation elicited an IJP composed of both fast (fIJP) and slow (sIJP) components, followed by rebound depolarization. NFA (200 microM) abolished sIJP and rebound depolarization but left the fIJP intact. These data suggest that in the tissues studied, activation of I(Cl(Ca)), which requires MLCK, contributes to resting MP, and that closing of I(Cl(Ca)) is responsible for sIJP.     

Characterization of inhibitory innervation in porcine colonic circular muscle

Effects of stimulation of intramural nerves in the circular smooth muscle layer of the porcine colon (Sus scrofa domestica) were studied using the sucrose-gap technique. Electrical field stimulation of the preparation, superfused with Krebs solution at 21 degrees C, induced a transient hyperpolarization of the smooth muscle cell membrane. This hyperpolarization was an inhibitory junction potential (IJP). The responses obtained from circular muscle originating from either the centripetal or centrifugal gyri of the ascending colon did not differ significantly. The IJP was characterized as being mediated by intramural, nonadrenergic, noncholinergic (NANC) nerves. The amplitude and latency of the IJP changed linearly with temperature (15-25 degrees C: +1 mV and -0.1 s per degree Celsius, respectively) reflecting a temperature-dependent synchronization of transmitter release. The membrane resistance decreased during the IJP. The IJP amplitude decreased or increased during conditioning hyperpolarizations or depolarizations, respectively, and reversed at membrane potentials about 30 mV more negative than the resting membrane potential. Potassium conductance blocking agents, barium (1 mM), tetraethylammonium chloride (TEA, 20 mM), 4-aminopyridine (4-AP, 5 mM), apamin (1 microM), and aminacrine (10(-4) M) added to the superfusion medium increased the membrane resistance. Only barium, TEA, and apamin depolarized the smooth muscle cell membrane. The IJP amplitude decreased in the presence of aminacrine and apamin to 75 and 35%, respectively, suggesting that apamin-sensitive Ca2+-activated K+ channels are involved in this response. ATP, adenosine, and related adenine nucleotides in concentrations up to 10(-3) M did not mimic the IJP. Superfusion with ATP for 15 min revealed a gradually increasing attenuation by up to 20% of the IJP. This might suggest that the release of neurotransmitter from intramural NANC nerves is modulated presynaptically via purinoceptors. Exogenously applied vasoactive intestinal polypeptide (VIP) in concentrations of 10(-9) to 10(-4) M did not affect the preparation. Also at elevated temperatures (up to 35 degrees C), VIP (10(-7) to 10(-4) M) did not cause measurable effects. It is concluded that the inhibitory mediator of the intramural NANC nerves present in the circular muscle layers of the porcine colon is neither a purine nor VIP.     

Mechanism of Cl- sensitivity in internal ion receptors of the leech; an inward current gated off by Cl- in the nephridial nerve cells

Summary The nephridial nerve cells of the leech, Hirudo medicinalis, 34 sensory cells, each associated with one nephridium, are sensitive to changes in extracellular Cl^- concentration, an important factor in ion homeostasis. Using single-electrode current- and voltage clamp and ion substitution techniques, the specificity and mechanism of Cl^- sensitivity of the nephridial nerve cell was studied in isolated preparations. Increase of the normally low external Cl^- concentration leads to immediate and sustained hyperpolarization, decrease of the frequency of bursts and decrease of membrane conductance. The response is halogen specific: Cl^- can be replaced by Br^–, but not by organic mono- or divalent anions or inorganic divalent anions.At physiological Cl^- concentrations (36mM extra-cellular Cl^-), the nephridial nerve cell has a high resting conductance for Cl^- and the membrane potential is governed by Cl^-. In high extracellular Cl^- concentrations (110–130 mM), membrane conductance is low, most likely due to the gating off of Cl^- channels. Under these conditions, membrane potential is dominated by the K⁺ distribution and the nephridial nerve cell hyperpolarizes towards E_K.Abbreviations NNC nephridial nerve cell - V _m membrane potential - E _Cl(k) equilibrium potential for Cl (K) - IV-curve current-voltage relationship     

Serotonin as an integrator of leech behavior and muscle mechanical performance

The obliquely striated muscle in the leech body wall has a broad functional repertoire; it provides power for both locomotion and suction feeding. It also operates over an unusually high strain range, undergoing up to threefold changes in length. Serotonin (5-HT) may support this functional flexibility, integrating behavior and biomechanics. It can act centrally, promoting motor outputs that drive body wall movements, and peripherally, modulating the mechanical properties of body wall muscle. During isometric contractions 5-HT enhances active force production and reduces resting muscle tone. We therefore hypothesized that 5-HT would increase net work output during the cyclical contractions associated with locomotion and feeding. Longitudinal strains measured during swimming, crawling and feeding were applied to body wall muscle in vitro with the timing and duration of stimulation selected to maximize net work output. The net work output during all simulated behaviors significantly increased in the presence of 100μM 5-HT relative to the 5-HT-free control condition. Without 5-HT the muscle strips could not achieve a net positive work output during simulated swimming. The decrease in passive tension associated with 5-HT may also be important in reducing muscle antagonist work during longitudinal muscle lengthening. The behavioral and mechanical effects of 5-HT during locomotion are clearly complementary, promoting particular behaviors and enhancing muscle performance during those behaviors. Although 5-HT can enhance muscle mechanical performance during simulated feeding, low in vivo activity in serotonergic neurons during feeding may mean that its mechanical role during this behavior is less important than during locomotion.     

Magnesium-resistant excitatory synaptic potentials in the leech Retzius cell.

Postsynaptic potentials (PSPs) recorded from leech Retzius cells in response to stimulation of interganglionic connective could not be reversed by soma depolarization or abolished by 40 mM Mg ion, nor could input resistance changes be detected during them. Alteration of external Cl and K over a tenfold range provided no clear evidence that the PSPs involved a conductance change to either ion. The method of extrapolation yielded an apparent PSP equilibrium potential of about -20 mV. The steep portion of the relationship between Retzius cell action potential amplitude and membrane potential extrapolated to an apparent reversal potential of -13 mV. It is likely that the connective-to-Retzius cell PSPs were principally electrical events. Their apparent reversal potentials could have been in the range associated with chemical synapses because they traversed an electrical synapse with a variable coupling resistance, or because the polarizing currents, passing "backwards" across electrical synapses, changed the amplitude of the presynaptic action potentials.     

Action of FMRFamide on longitudinal muscle of the leech,Hirudo medicinalis

1. Nerve terminals associated with longitudinal muscle in the leech show FMRFamide-like immunoreactivity. 2. Structure-activity studies using FMRFamide analogs show that the C-terminal RFamide portion of the molecule is crucial for biological activity on leech longitudinal muscle. 3. The putative protease inhibitor FA (Phe-Ala) increases the peak tension produced by longitudinal muscle in response to superfused FMRFamide and the majority of its analogs, suggesting the presence of peripheral proteases capable of degrading RFamide peptides. 4. FMRFamide decreases the relaxation rate of neurally evoked contractions of longitudinal muscle. FA also decreases the relaxation rate of neurally evoked contractions. 5. Intact and isolated muscle cells respond to superfused FMRFamide with a conductance increase, that leads to depolarization and often with a delayed conductance decrease as the membrane potential is restored to resting levels. 6. The depolarizing response of isolated muscle cells to FMRFamide is dependent on external calcium.     

Magnesium-resistant excitatory synaptic potentials in the leech retzius cell

Postsynaptic potentials (PSPs) recorded from leech Retzius cells in response to stimulation of interganglionic connective could not be reversed by soma depolarization or abolished by 40 mM Mg ion, nor could input resistance changes be detected during them. Alteration of external Cl and K over a tenfold range provided no clear evidence that the PSPs involved a conductance change to either ion. The method of extrapolation yielded an apparent PSP equilibrium potential of about ?20 mV. The steep portion of the relationship between Retzius cell action potential amplitude and membrane potential extrapolated to an apparent reversal potential of ?13 mV. It is likely that the connective-to-Retzius cell PSPs were principally electrical events. Their apparent reversal potentials could have been in the range associated with chemical synapses because they traversed an electrical synapse with a variable coupling resistance, or because the polarizing currents, passing “backwards” across electrical synapses, changed the amplitude of the presynaptic action potentials.     

兔肠系膜下神经节细胞的两种非胆碱能性慢突触后电位

以常规细胞内记录技术对兔肠系膜下神经节细胞的跨膜电位进行了观察。对节前神经的短串脉冲刺激,可诱发出一串快兴奋性突触后电位(f-EPSP)或顺向动作电位;在此之后,大多数细胞还出现一个持续约2min 的缓慢去极化电位。该电位具有抗箭毒和阿托品性质,受低钙高镁溶液的可逆性阻抑,因而可称为非胆碱能性兴奋性突触后电位,或者也可归入迟慢兴奋性突触后电位(ls-EPSP)。多数细胞的 ls-EPSP 伴有膜电阻增大,电位的幅度随细胞静息电位的超极化而变小;提示在这些细胞上,钾电导的失活很可能参与了电位的发生。以P物质溶液灌流神经节未见该电位有显著改变。另外,在箭毒化加阿托品化的神经节中,还发现少数细胞对节前神经的串刺激发生一个持续约一分钟的超极化电位。它也具有抗胆碱能受体阻断剂的性质,受低钙高镁溶液可逆性阻抑,为此我们命之为“极慢抑制性突触后电位”(vs-IPSP),以区别于“慢抑制性突触后电位”(s-IPSP),后者是通常用以表示一种胆碱能性的慢电位。本文所述的这两种非胆碱能性的突触电位有关递质,尚待探索。     

Increasing external K+ blocks phase shifts in a circadian rhythm produced by serotonin or 8-benzylthio-cAMP

Serotonin (5-HT) phase shifts the circadian rhythm from the isolated eye of Aplysia. The discovery of the mechanisms involved in phase shifting by 5-HT may help elucidate the nature of the circadian oscillator. We have found that 5-HT appears to phase shift by causing a change in membrane K+ conductance. Solutions containing zero K+(0-K+) phase shift the rhythm and the phase response curve (PRC) for 0-K+ is similar to one previously obtained for 5-HT. The similarity in PRCs for 0-K+ and 5-HT suggested that these treatments may be phase shifting the rhythm through a common mechanism. The nonadditivity of phase shifting by 0-K+ and 5-HT supports this suggestion. A common mechanism of action of 5-HT and 0-K+ might be effects on membrane potentials. The possible involvement of a membrane potential change in mediating the effect of 5-HT and the lack of an effect of large reductions in Na+, Cl-, and Ca2+ ions on phase shifting by 5-HT led us to examine the role of K+ ions in phase shifting by 5-HT. A change in K+ conductance may mediate the effects of 5-HT on the rhythm because HiK (30mM) solutions blocked the phase shift normally produced by 5-HT. The conductance change produced by 5-HT may be an increase in K+ conductance which would produce a hyperpolarization and not a decrease in K+ conductance which would produce a depolarization since depolarizing treatments, HiK (30-110mM), had no effect on the rhythm at the phase where 5-HT produces its largest phase shifts. Since we previously found that the effects of 5-HT appear to be mediated by cAMP, we examined whether HiK solutions could block the effects of 8-benzylthio-cAMP on the rhythm. HiK (40mM) blocked the phase shifts normally produced by 8-benylthio-cAMP. Our working hypothesis for the 5-HT phase-shifting pathway based on these results is 5-HT leads to increased cAMP leads to elevates K+ conductance leads to membrane hyperpolarization leads to phase shifts the rhythm.     

Effects of monocarboxylates and external pH on some parameters of insect muscle fibres

The resting membrane potential and the conductance of flight muscle fibres of the butterfly Pieris brassicae were measured by means of two intracellular electrodes. The intracellular potassium, chloride, and hydrogen ion concentrations were estimated by measuring the concentrations in diluted muscle homogenates. Chloride in the bath was replaced in part by monocarboxylates and the pH was subsequently lowered. Replacement of chloride by propionate caused decrease in the internal chloride concentration, a marked hyperpolarization and a small increase in conductance. Lowering the pH in the propionate saline caused an additional decrease in the internal chloride concentration, an increase in the internal hydrogen ion concentration, a marked depolarization and a concurrent decrease in conductance. This was followed by an irreversible increase in conductance. With glycolate the effects on the membrane parameters were small and with pyruvate no effect was observed.     

Physiological and pharmacological studies on annelid and nematode body wall muscle

1. This review covers the pharmacology and physiology of the body wall muscle systems of nematodes and annelids.2. Both acetylcholine and gamma-aminobutyric acid (GABA) play important roles in the control of body wall muscle in both phyla. In annelids and nematodes, acetylcholine is the excitatory neuromuscular transmitter while GABA is the inhibitory neuromuscular transmitter. In addition, 5-hydroxytryptamine (5-HT) has a modulatory role at annelid body wall muscle but little if any effect on nematode body wall muscle.3. The acetylcholine receptor of the body wall muscle can be classified as nicotinic-like in both phyla though the annelid receptor has not been analysed in detail. In nematodes, vertebrate ganglionic nicotinic agonists were the most effective of those so far examined while mecamylamine and benzoquinonium were the most effective antagonists. Both neuronal bungarotoxin and neosurugatoxin were potent antagonists of acetylcholine excitation at the nematode receptor.4. The GABA receptor of the body wall muscle exhibits similarities with the vertebrate GABA-A receptor in both phyla. Picrotoxin is a very weak or inactive antagonist at leech and nematode GABA receptors, while bicuculline methiodide blocks leech GABA receptors but is inactive on nematode GABA receptors. Picrotoxin does block GABA responses of earthworm body wall muscle. All these GABA responses are chloride mediated.5. Neuroactive peptides of the RFamide family occur m both phyla and FMRFamide has been identified in leeches. RFamides probably have an important role in heart regulation in leeches and in modulation of their body wall muscles. RFamides also modulate nematode body wall muscle activity with KNEFIRFamide raising muscle tone while SDPNFLRFamide relaxes the muscle. It is likely that this family and other neuroactivc peptides play an important role in the physiology of body wall muscle throughout both phyla.