Multiple receptor sites for a molluscan peptide (FMRFamide) and related peptides of Helix

Neurotrophic factors and target-specific retrograde signaling interactions define the specificity of classical and neuropeptide cotransmitter release at identified Lymnaea synapses

Many neurons concurrently and/or differentially release multiple neurotransmitter substances to selectively modulate the activity of distinct postsynaptic targets within a network. However, the molecular mechanisms that produce synaptic heterogeneity by regulating the cotransmitter release characteristics of individual presynaptic terminals remain poorly defined. In particular, we know little about the regulation of neuropeptide corelease, despite the fact that they mediate synaptic transmission, plasticity and neuromodulation. Here, we report that an identified Lymnaea neuron selectively releases its classical small molecule and peptide neurotransmitters, acetylcholine and FMRFamide-derived neuropeptides, to differentially influence the activity of distinct postsynaptic targets that coordinate cardiorespiratory behaviour. Using a combination of electrophysiological, molecular, and pharmacological approaches, we found that neuropeptide cotransmitter release was regulated by cross-talk between extrinsic neurotrophic factor signaling and target-specific retrograde arachidonic acid signaling, which converged on modulation of glycogen synthase kinase 3. In this context, we identified a novel role for the Lymnaea synaptophysin homologue as a specific and synapse-delimited inhibitory regulator of peptide neurotransmitter release. This study is among the first to define the cellular and molecular mechanisms underlying the differential release of cotransmitter substances from individual presynaptic terminals, which allow for context-dependent tuning and plasticity of the synaptic networks underlying patterned motor behaviour.

Synapse formation: from cellular and molecular mechanisms to neurodevelopmental and neurodegenerative disorders

The precise patterns of neuronal assembly during development determine all functional outputs of a nervous system; these may range from simple reflexes to learning, memory, cognition, etc. To understand how brain functions and how best to repair it after injury, disease, or trauma, it is imperative that we first seek to define fundamental steps mediating this neuronal assembly. To acquire the sophisticated ensemble of highly specialized networks seen in a mature brain, all proliferated and migrated neurons must extend their axonal and dendritic processes toward targets, which are often located at some distance. Upon contact with potential partners, neurons must undergo dramatic structural changes to become either a pre- or a postsynaptic neuron. This connectivity is cemented through specialized structures termed synapses. Both structurally and functionally, the newly formed synapses are, however, not static as they undergo consistent changes in order for an animal to meet its behavioral needs in a changing environment. These changes may be either in the form of new synapses or an enhancement of their synaptic efficacy, referred to as synaptic plasticity. Thus, synapse formation is not restricted to neurodevelopment; it is a process that remains active throughout life. As the brain ages, either the lack of neuronal activity or cell death render synapses dysfunctional, thus giving rise to neurodegenerative disorders. This review seeks to highlight salient steps that are involved in a neuron's journey, starting with the establishment, maturation, and consolidation of synapses; we particularly focus on identifying key players involved in the synaptogenic program. We hope that this endeavor will not only help the beginners in this field to understand how brain networks are assembled in the first place but also shed light on various neurodevelopmental, neurological, neurodegenerative, and neuropsychiatric disorders that involve synaptic inactivity or dysfunction.

Structure of cDNA clones and genomic DNA FMRFamide-related peptides (FaRPs) in Helix

A complementary DNA (cDNA) library was prepared from poly(A)(+) RNA isolated from the central ganglia of Helix aspersa from which two classes of FaRP-encoding cDNA clones were identified by hybridization with the Aplysia FMRF-1 clone and oligonucleotides based on known Helix peptides. One type of cDNA (exemplified by HF-1) encodes only the tetrapeptides (FMRFamide and FLRFamide) and is very similar to the tetrapeptide-encoding precursors of other molluscan species. The other type of cDNA (represented by HF-4) encodes no tetrapeptides, but only N-terminally extended peptides, including all of the heptapeptides previously detected in the nervous system as well as some novel predicted peptides, which may be processed into free bio-active peptides. The overall structure of the precursor polypeptide encoded by HF-4 is markedly different from that encoded by HF-1 and more closely resembles the Drosophila FaRP precursor. Restriction digestion and hybridization analysis of genomic DNA indicates that each class of cDNA comes from a single genomic locus and that the two genomic loci span about 14 kbp. Parts of the genomic DNA sequence homologous to HF-1 were determined by PCR of Helix pomatia DNA. All of the coding sequence contained in HF-1 appears to be on one exon since it is contiguous in the genomic PCR products. In the coding region, the sequences from H. aspersa and H. pomatia are about 95% identical, but they are only about 80% identical in the noncoding region.

Morphology of neuropeptide CNP2 modulation of heart activity in terrestrial snail

A family of neuropeptides called Command Neuron Peptides (CNPs) was described ten years ago as the protein products of the gene HCS2, specifically expressed in the identified interneurons of the nervous system of terrestrial snail (Helix lucorum L. and H. pomatia L.). Recently, the CNP-like peptides have been detected by immunochemistry and immunoblotting in nervous systems of representatives of different invertebrate phyla (Mollusca, Annelida, and Insecta). Still, the function of these peptides remains largely unknown. In Helix it is shown that CNPs: modulate the electrical activity of unidentified central neurons, modulate the pneumostome motoneurons, stimulate neural cones growth in neural cultures. Here, we describe for the first time the CNPs-immunoreactive neural fibers in walls of both auricle and ventricle of the snail heart. We show that application of the synthetic neuropeptide CNP2 (DYPRLamide) in perfusion saline affects heart rate and magnitude of beats in isolated snail heart. The results suggest that in Helix the Command Neuron Peptides could participate in neural modulation of cardiovascular system.

A review of FMRFamide- and RFamide-like peptides in metazoa

Neuropeptides are a diverse class of signalling molecules that are widely employed as neurotransmitters and neuromodulators in animals, both invertebrate and vertebrate. However, despite their fundamental importance to animal physiology and behaviour, they are much less well understood than the small molecule neurotransmitters. The neuropeptides are classified into families according to similarities in their peptide sequence; and on this basis, the FMRFamide and RFamide-like peptides, first discovered in molluscs, are an example of a family that is conserved throughout the animal phyla. In this review, the literature on these neuropeptides has been consolidated with a particular emphasis on allowing a comparison between data sets in phyla as diverse as coelenterates and mammals. The intention is that this focus on the structure and functional aspects of FMRFamide and RFamide-like neuropeptides will inform understanding of conserved principles and distinct properties of signalling across the animal phyla.

FMRFamide-gated sodium channel and ASIC channels: a new class of ionotropic receptors for FMRFamide and related peptides

FMRFamide and related peptides typically exert their action through G-protein coupled receptors. However, two ionotropic receptors for these peptides have recently been identified. They are both members of the epithelial amiloride-sensitive Na+ channel and degenerin (ENaC/DEG) family of ion channels. The invertebrate FMRFamide-gated Na+ channel (FaNaC) is a neuronal Na+-selective channel which is directly gated by micromolar concentrations of FMRFamide and related tetrapeptides. Its response is fast and partially desensitizing, and FaNaC has been proposed to participate in peptidergic neurotransmission. On the other hand, mammalian acid-sensing ion channels (ASICs) are not gated but are directly modulated by FMRFamide and related mammalian peptides like NPFF and NPSF. ASICs are activated by external protons and are therefore extracellular pH sensors. They are expressed both in the central and peripheral nervous system and appear to be involved in many physiological and pathophysiological processes such as hippocampal long-term potentiation and defects in learning and memory, acquired fear-related behavior, retinal function, brain ischemia, pain sensation in ischemia and inflammation, taste perception, hearing functions, and mechanoperception. The potentiation of ASIC activity by endogenous RFamide neuropeptides probably participates in the response to noxious acidosis in sensory and central neurons. Available data also raises the possibility of the existence of still unknown FMRFamide related endogenous peptides acting as direct agonists for ASICs.

The action of RFamide neuropeptides on molluscs, with special reference to the gastropods Buccinum undatum and Busycon canaliculatum

The ever-growing RFamide neuropeptide superfamily has members in all animal phyla. Their effects in molluscs, on both smooth and cardiac muscle as well as on neurons, has been studied in detail. These neuropeptides exert a variety of functions: excitatory, inhibitory or even biphasic. Firstly, the literature on the excitatory effect of the RFamide neuropeptides on molluscan muscle and neurons has been reviewed, with greater emphasis and examples from the gastropods Buccinum undatum and Busycon canaliculatum. The peptides seem to be potent activators of contraction, sometimes generating slow tonic force and other times twitch activity. Secondly, the literature on the inhibitory effect of the superfamily has been reviewed. These peptides can exert an inhibitory effect, hyperpolarizing the cells rather than depolarizing them. Thirdly, the neuropeptides may play a variety of other roles, such as contributing to the regulation or maturation process of the animals. There have been cases recorded of RFamide neuropeptides acting as potent venoms in members of the Conus sp. The pathway of action of these multiple roles, their interaction with the parent neurotransmitters acetylcholine and serotonin, as well as the calcium dependency of the RFamide neuropeptides has been discussed, again with special reference to the above mentioned gastropods. A better understanding of the mode of action, the effects, and the importance of the RFamide neuropeptides on molluscan physiology and pharmacology has been attempted by reviewing the existing literature, recognizing the importance of the RFamide neuropeptide actions on molluscs.

RFamide neuropeptide actions on the molluscan heart

FMRFamide and the related tetrapeptide FLRFamide are highly excitatory in molluscan non-cardiac smooth muscle. They are also exceptionally excitatory in the atrium and internally perfused ventricle of Busycon canaliculatum. These two peptides, usually thought of as classic molluscan cardio-acceleratory agents are in fact simply two members of a large and ever growing superfamily, the RFamide family, whose phylogenetic distribution has been so elegantly mapped by Walker. Members of this family, often with extended peptide chains (e.g. penta, hepta and decapeptides), stretch in their known distribution from the cnidaria to the chordates. The effects of some of the members of this superfamily (FMRFamide. FLRFamide, YMRFamide, TNRNFLRFamide, SDPFLRFamide, LMS) were examined. The neuropeptides were found to be very potent at very low concentrations (10(-9) M) in the ventricle of both Buccinium and Busycon. Other neuropeptides (HFMRdFamide, SCPb, NLERFamide and pEGRFamide) were found to be without any effect. The Ca2+ dependency of these neuropeptides was also tested. The peptides appear to induce contraction of the ventricles by release of Ca2+ from internal pools. The neuropeptides appear to stimulate contraction in these cardiac muscles through a completely different pathway to Serotonin (the main excitatory neurotransmitter for the cardiac muscle). When the peptides were applied together with Serotonin an additive effect was observed clearly indicating the release of Ca2+ through different pathways. The nature of the RFamide receptor was also tested. It appears that the RFamide neuropeptides mobilize the 2nd messenger IP3 (Inositol trisphosphate), since the IP3 blocker Neomycin Sulphate inhibited the response of the neuropeptides.

RFamide neuropeptide actions on molluscan proboscis smooth muscle: interactions with primary neurotransmitters

The potency (muscle force-generated) of a number of long-chain RFamide neuropeptides was examined in mechanical experiments with the radular-retractor and radular-sac muscles of gastropods Buccinum undatum and Neptunea antiqua. Many of the heptapeptides, octapeptides and the decapeptide LMS were found to induce greater contraction than FMRFamide in both smooth muscles and in both species. RFamide neuropeptides interacted with the neurotransmitter acetylcholine in an additive way and RFamide-induced contractions were inhibited by the neuromodulator serotonin. Pre-treatment with a calcium-free saline completely abolished acetylcholine-induced responses but only partially inhibited RFamide responses in the muscles, suggesting that acetylcholine acts to cause influx of extracellular calcium for contraction. In contrast, RFamide neuropeptides may mobilise intracellular calcium to maintain sustained tonic force in calcium-free conditions. This suggests that an additional involvement of a fast calcium channel may be present in the RFamide responses, since loss of the usual superimposed twitch activity is observed. Force regulation in these muscles appears to result from a complex interaction of RFamide neuropeptides with the primary transmitter acetylcholine and the neuromodulator serotonin.

Antagonistic modulation of a hyperpolarization-activated Cl(-) current in Aplysia sensory neurons by SCP(B) and FMRFamide

Whole cell voltage-clamp recordings from Aplysia mechanosensory neurons obtained from the pleural ganglion were used to investigate the actions on membrane currents of the neuropeptides SCP(B) and FMRFamide. At the start of whole cell recording, SCP(B) typically evoked an inward current at a holding potential of -40 mV, due to the cAMP-mediated closure of the S-type K+ channel, whereas FMRFamide evoked an outward current, due to the opening of the S-type K+ channels mediated by 12-lipoxygenase metabolites of arachidonic acid. However, after several minutes of whole cell recording with a high concentration of chloride in the whole cell patch pipette solution, the responses to SCP(B) and FMRF-amide at -40 mV were inverted; SCP(B) evoked an outward current, whereas FMRFamide and YGGFMRFamide evoked inward currents. Ion substitution experiments and reversal potential measurements revealed that these responses were due to the opposing regulation of a Cl(-) current, whose magnitude was greatly enhanced by dialysis with the high Cl(-) - containing pipette solution. SCP(B) inhibited this Cl(-) current through production of cAMP and activation of PKA. YGGFMRFamide activated this Cl(-) current by stimulating a cGMP-activated phosphodiesterase that hydrolyzed cAMP. Thus a cAMP-dependent Cl(-) current undergoes antagonistic modulation by two neuropeptides in Aplysia sensory neurons.

Structure-activity and possible mode of action of S-Iamide neuropeptides on identified central neurons of Helix aspersa

Intracellular recordings were made from identified neurons from the suboesophageal ganglia of Helix aspersa. The inhibitory action of nine S-Iamide peptides was investigated. Structure-activity studies suggest that all act through a common receptor, which normally requires FVRIamide at the C terminal, with a preferred length of seven amino acids. Substitution at the N-terminal with alanine (A), threonine (T), proline (P) or leucine (L) results in little change in potency, suggesting the N-terminal requirements are relatively flexible. Ion substitution experiments suggest that potassium is the main ion involved in the inhibitory response to S-Iamide application. Studies using a range of compounds, which modify second messenger systems, would suggest that S-Iamide peptides may interact with adenylate cyclase. No evidence was found for an interaction with either guanylate cyclase or nitric oxide synthase.

Actions of nematode FMRFamide-related peptides on the pharyngeal muscle of the parasitic nematode, Ascaris suum

The endogenous nematode peptides known as FMRFamide-related peptides (FaRPs) and various "classical" transmitters have a range of effects on nematodes that result in changes in behavior, particularly locomotion, including paralysis and inhibition of feeding. This study describes the application of an in vitro pharmacological approach to further delineate the action of a number of FaRP neurotransmitters on feeding behavior. Contraction of Ascaris suum pharyngeal muscle was monitored using a modified pressure transducer system that detects changes in intrapharyngeal pressure and therefore contraction of the radial muscle of the pharynx. The pharynx did not contract spontaneously. However, serotonin (5-HT, 100 microM) stimulated rhythmic contractions and relaxations (pumping) at a frequency of 0.5 Hz. The native nematode peptide, KNEFIRFamide (AF1), inhibited the pumping elicited by 5-HT. The duration of inhibition was concentration-dependent (1-1000 nM) with a threshold of 1 nM (n = 7). KSAYMRFamide (AF8/PF3) also inhibited pharyngeal pumping. There was no observable effect of any of the following nematode peptides on pharyngeal pumping behavior (1-1000 nM; n = 8): AF2, AF3, AF4, AF6, AF16, PF1/CF1, PF2/CF2, or PF4. Thus, interruption of pharyngeal processes, such as feeding, regulation of hydrostatic pressure, and secretion, may provide a new site of anthelmintic action.

Structure-activity relationships of the Helix neuropeptide, SEPYLRFamide, and its N-terminally modified analogues on identified Helix lucorum neurones

Metabotropic and ionotropic effects evoked by the endogenous Helix heptapeptide, SEPYLRFamide, and four analogues, i.e., where the amino acid sequences at the N-terminal (EPYLRFamide, SEGYLRFamide, SRPYLRFamide and SKPYLRFamide) were modified, were compared on identified Helix lucorum LPa2, LPa3, RPa3, RPa2 neurones using two electrode voltage clamp and current clamp techniques. All peptides (bath application) reduce reversibly the inward current to local ionophoretic application of acetylcholine onto the neurone soma with an order of potency: EPYLRFamide=SEGYLRFamide=SRPYLRFamide>SEPYLRFamide+ ++>SKPYLRFamide. The reductions of the acetylcholine-induced inward current evoked by SEPYLRFamide and its analogues at concentrations of 0.01-10 microM are not accompanied by a change of amplitude of the leak inward current caused by constant negative shift of a holding potential. At concentration of 50 microM all peptides increase reversibly the resting membrane conductance to an equal degree. Local application under pressure of SEPYLRFamide and its analogues onto the soma of neurones evoke hyperpolarizations with similar values. These results indicate that the N-terminal three amino acids of the peptide molecule are not responsible for the degree of ionotropic effect on the neurones studied. In contrast the amino acid sequence at the N-terminal modifies the degree of the modulatory effects of the YLRFamide-related analogues. Changes at the SEPYLRFamide N-terminal (Ser1-Glu2-Pro3) intensify the inhibitory action of the analogues as compared with effect evoked by the endogenous peptide, that is, removal of Ser1 (Glu1-Pro2), replacement of Pro3 with Gly3 (Ser1-Glu2-Gly3), replacement of Glu2 with Arg2 (Ser1-Arg2-Pro3). Replacement of Glu2 with Lys2 (Ser1-Lys2-Pro3) reduces the modulatory potency. It is concluded that ionotropic and metabotropic effects of these YLRFamide-related peptides may occur at different membrane binding sites.

The lymnaea cardioexcitatory peptide (LyCEP) receptor: a G-protein-coupled receptor for a novel member of the RFamide neuropeptide family

A novel G-protein-coupled receptor (GRL106) resembling neuropeptide Y and tachykinin receptors was cloned from the mollusc Lymnaea stagnalis. Application of a peptide extract from the Lymnaea brain to Xenopus oocytes expressing GRL106 activated a calcium-dependent chloride channel. Using this response as a bioassay, we purified the ligand for GRL106, Lymnaea cardioexcitatory peptide (LyCEP), an RFamide-type decapeptide (TPHWRPQGRF-NH2) displaying significant similarity to the Achatina cardioexcitatory peptide (ACEP-1) as well as to the recently identified family of mammalian prolactin-releasing peptides. In the Lymnaea brain, the cells that produce egg-laying hormone are the predominant site of GRL106 gene expression and appear to be innervated by LyCEP-containing fibers. Indeed, LyCEP application transiently hyperpolarizes isolated egg-laying hormone cells. In the Lymnaea pericardium, LyCEP-containing fibers end blindly at the pericardial lumen, and the heart is stimulated by LyCEP in vitro. These data confirm that LyCEP is an RFamide ligand for GRL106.

The lymnaea cardioexcitatory peptide (LyCEP) receptor: a G-protein-coupled receptor for a novel member of the RFamide neuropeptide family

A novel G-protein-coupled receptor (GRL106) resembling neuropeptide Y and tachykinin receptors was cloned from the mollusc Lymnaea stagnalis. Application of a peptide extract from the Lymnaea brain to Xenopus oocytes expressing GRL106 activated a calcium-dependent chloride channel. Using this response as a bioassay, we purified the ligand for GRL106, Lymnaea cardioexcitatory peptide (LyCEP), an RFamide-type decapeptide (TPHWRPQGRF-NH2) displaying significant similarity to the Achatina cardioexcitatory peptide (ACEP-1) as well as to the recently identified family of mammalian prolactin-releasing peptides. In the Lymnaea brain, the cells that produce egg-laying hormone are the predominant site of GRL106 gene expression and appear to be innervated by LyCEP-containing fibers. Indeed, LyCEP application transiently hyperpolarizes isolated egg-laying hormone cells. In the Lymnaea pericardium, LyCEP-containing fibers end blindly at the pericardial lumen, and the heart is stimulated by LyCEP in vitro. These data confirm that LyCEP is an RFamide ligand for GRL106.

Single-channel currents of a peptide-gated sodium channel expressed in Xenopus oocytes

1. Single-channel recordings were made from outside-out membrane patches of Xenopus oocytes injected with the cDNA clone FaNaCh, which encodes a peptide-gated Na+ channel from Helix aspersa. 2. The natural peptides FMRFamide and FLRFamide only activated unitary currents in oocytes injected with FaNaCh; the EC50 values were 1.8 and 11.7 microM, respectively. 3. The slope conductance of the channel was 9.2 pS for both peptides. 4. With FMRFamide, the open probability (Po) of the channel was 0.06 at 0.3 microM and 0.76 at 30 microM, whereas for FLRFamide the open probability increased from 0.04 at 1.8 microM to 0.49 at 50 microM. The Hill coefficient was greater than 1 for both peptides. 5. High concentrations of each peptide evoked very fast flickering between open and closed states which led to decreased unitary current amplitude. 6. At low doses, brief single openings and bursts of longer openings occurred. With higher doses, the occurrence of the brief openings declined and the number of longer openings increased; the duration of the longer openings was shorter with FLRFamide than with FMRFamide. 7. For each peptide, frequency distribution histograms of open events were best fitted by the sum of two exponential components, suggesting the existence of two open states of the channel. Closed events were fitted by the sum of three components, suggesting the existence of three closed states. 8. The data were analysed according to a five-state model in which the brief openings correspond to a single liganded open form of the channel and the longer openings to a doubly liganded open form. According to this interpretation, the greater whole-cell response observed with FMRFamide than with FLRFamide results mostly from a slower closing rate constant for the longer (doubly liganded) channel openings.

The effect of FMRFamide analogs on [35S]GTP-gamma-S stimulation in squid optic lobes

Pharmacological study of Phe-Met-Leu-Phe-amide (FMRFa) receptors is hindered by the lack of selective ligands. The classification of these selective ligands is further hampered by the limited availability of functional assays. In this study, we evaluated several synthetic FMRFa analogs for agonist and antagonist activity by measuring their abilities to produce [35-S]-GTP-gamma-S stimulation or to inhibit FMRFa-induced [35S]-GTP-gamma-S binding in squid optic lobes. Analogs included acetyl-Phe-norLeu-Arg-Phe-amide (acFnLRFa), desamino-Tyr-Phe-Leu-Arg-amide (daYFLRa), desamino Tyr-Phe-norLeu-Arg-Phe-amide (daYFnLRFa), desamino Tyr-Phe-norLeu-Arg-[TIC]-amide (daYFnLR[TIC]a), desamino Tyr-Trp-norLeu-Arg-amide (daYWnLRa), (D)-Tyr-Phe-norLeu-Arg-Phe-amide (D)-YFnLRFa), Phe-Leu-Arg-Phe-amide (FLRFa), and the D-amino acid analogs of FMRFa (D-FMRFa, F-(D)-MRFa and FM-(D)-RFa). For agonist studies, full dose-response curves were generated and analyzed for potency and efficacy (maximal percent effect). FMRFamide as well as analogs ac-FnLRFa, daYFnLRFa, daYFnLR[TIC]a, D-YFnLRFa, FLRFa, and (D)-FMRFa stimulated [35S]-GTP-gamma-S binding. Analogs daYWnLRa, daYFLRa, F-(D)-MRFa, and FM-(D)-RFa failed to stimulate either [35S]-GTP-gamma-S binding or to inhibit FMRFa-induced [35S]-GTP-gamma-S binding. The rank order of potency was daYFnLRFa > or = daYFnLRF[TIC]a > acFnLRFa > (D)YFnLRFa > FLRFa > or = FMRFa >> (D)-FMRFa. The order of efficacy was daYFnLRFa = acFnLRFa = (D)-YFnLRFa > FLRFa = FMRFa > or = (D)-FMRFa > or = daYFnLRF[TIC]a. Peptide analog daYFnLR[TIC]a was less efficacious (59% maximal stimulation) than analogs daYFnLRFa, acFnLRFa, and (D)-YFnLRFa (113-146% maximal stimulation). A maximal concentration of daYFnLR[TIC]a (10 microM) reduced daYFnLRFa, acFnLRFa, and (D)-YFnLRFa induced [35S]-GTP-gamma-S stimulation, indicating that daYFnLR[TIC]a is a partial agonist at the receptor stimulated by the FMRFamide analogs. Analysis of the structural requirements needed for promoting [35S]-GTP-gamma-S binding show that elongation (i.e., daYFnLRFa, D-YFnLRFa) or modification of Phe1 (ac-FnLRFa) leads to increased efficacy and potency. Moreover, elimination of the C-terminal Phe (daYWnLRa, daYFLRa,) leads to a loss of biological activity. However, substitution with L-1,2,3,4 tetrahydroisoquinoline-3-carboxylic acid, a rigid analog of the C-terminal Phe (daYFnLR[TIC]a), leads to decreased efficacy but not loss of potency. The data suggest that immobilization or modification of the C-terminal Phe may produce highly selective and potent FMRFamide antagonists. These results agree with published receptor radioligand studies and indicate that the [35S]GTP-gamma-S assay may be useful in classifying novel FMRFamide-selective ligands.

Phe-Met-Arg-Phe-amide activates a novel voltage-dependent K+ current through a lipoxygenase pathway in molluscan neurones

The neuropeptide Phe-Met-Arg-Phe-amide (FMRFa) dose dependently (ED50 = 23 nM) activated a K+ current in the peptidergic caudodorsal neurones that regulate egg laying in the mollusc Lymnaea stagnalis. Under standard conditions ([K+]o = 1.7 mM), only outward current responses occurred. In high K+ salines ([K+]o = 20 or 57 mM), current reversal occurred close to the theoretical reversal potential for K+. In both salines, no responses were measured below -120 mV. Between -120 mV and the K+ reversal potential, currents were inward with maximal amplitudes at approximately -60 mV. Thus, U-shaped current-voltage relations were obtained, implying that the response is voltage dependent. The conductance depended both on membrane potential and extracellular K+ concentration. The voltage sensitivity was characterized by an e-fold change in conductance per approximately 14 mV at all [K+]o. Since this result was also obtained in nearly symmetrical K+ conditions, it is concluded that channel gating is voltage dependent. In addition, outward rectification occurs in asymmetric K+ concentrations. Onset kinetics of the response were slow (rise time approximately 650 ms at -40 mV). However, when FMRFa was applied while holding the cell at -120 mV, to prevent activation of the current but allow activation of the signal transduction pathway, a subsequent step to -40 mV revealed a much more rapid current onset. Thus, onset kinetics are largely determined by steps preceding channel activation. With FMRFa applied at -120 mV, the time constant of activation during the subsequent test pulse decreased from approximately 36 ms at -60 mV to approximately 13 ms at -30 mV, confirming that channel opening is voltage dependent. The current inactivated voltage dependently. The rate and degree of inactivation progressively increased from -120 to -50 mV. The current is blocked by internal tetraethylammonium and by bath- applied 4-aminopyridine, tetraethylammonium, Ba2+, and, partially, Cd2+ and Cs+. The response to FMRFa was affected by intracellular GTPgammaS. The response was inhibited by blockers of phospholipase A2 and lipoxygenases, but not by a cyclo-oxygenase blocker. Bath-applied arachidonic acid induced a slow outward current and occluded the response to FMRFa. These results suggest that the FMRFa receptor couples via a G-protein to the lipoxygenase pathway of arachidonic acid metabolism. The biophysical and pharmacological properties of this transmitter operated, but voltage-dependent K+ current distinguish it from other receptor-driven K+ currents such as the S-current- and G-protein-dependent inward rectifiers.

Isolation of bioactive compounds from Helix aspersa nerve tissue and the effect of pQPPLPRYamide on heart, esophagus and central neurons of H. aspersa and rectum of Anodonta woodiana

1. Both acetone and methanol extraction was used to isolate bioactive compounds from 1000 Helix aspersa brains. 2. Seven compounds were isolated of which four were identified as follows: Ha-1, 5-hydroxytryptamine; Ha-3, GSPYFVamide; Ha-4, pQPPLPRYamide; Ha-5, SGYLAFPRMamide. There was insufficient material to identify Ha-2, Ha-6 and Ha-7. 3. Ha-4, pQPPLPRYamide, was found to excite the heart of H. aspersa, relax the esophagus and both excite (mainly) and inhibit central neurons. In addition, this peptide contracted the rectum of Anodonta woodiana. 4. It is concluded that pQPPLPRYamide is an example of a new molluscan peptide family, designated as PRYamide.

Actions of FMRFamide-related peptides on the gCa2+ of the C1 neuron in Helix aspersa

The endogenous neuropeptides FMRFamide and FLRFamide (tetrapeptides) reversibly reduced a voltage-activated calcium current in the C1 neuron of Helix aspersa by an average of 20%. Two structurally related heptapeptides, pQDPFLRFamide and pQDPFLRIamide, both derived from another precursor protein in this species, did not reduce the current at all.

Direct and modulatory effects of FMRFamide, SKPYMRFamide and acety1-SKPYMRFamide on LPa2, LPa3, and RPa3 identified neurons of Helix lucorum

Three neuroactive peptides with an RFamide carboxyl terminal, one a tetrapeptide, FMRFamide, and two heptapeptides, SKPYMRFamide and acetyl-SKPYMRFamide, evoke direct and modulatory effects on identified neurons from left (LPa2, LPa3) and right (RPa3) parietal ganglia of the land snail. Helix lucorum. Local application of tetrapeptide and heptapeptides induce hyperpolarization or outward current when neurons are clamped at the resting potential. The reversal potential of these direct responses is near the potassium equilibrium potential. All investigated FMRFamide-related peptides reduce reversibly the inward current to local acetylcholine (ACh) application onto the neuron soma. Threshold concentrations of peptides for an inhibitory action on ACh-induced current are 0.5-1.0 microM, ID50 = 0.7-1.2 microM, SKPYMRFamide evokes parallel shift to right of ACh dose-response curves increasing the ED50 for ACh but without changing the Hill number. SKPYMRFamide does not change the reversal potential of the ACh-induced inward current. It was concluded that SKPYMRFamide reduces the affinity of ACh for ACh receptor without a change in the number of ligand-binding sites per ACh receptor molecule. FMRFamide-related peptides can reduce the affinity of ACh for cholinergic receptors through inhibition of the molecular mechanism connecting the ACh receptor with its ion channels.

Structure-activity relationships of KNEFIRFamide (AF1), a nematode FMRFamide-related peptide, on Ascaris suum muscle

Analogues of KNEFIRFamide (Lys-Asn-Glu-Phe-Ile-Arg-Phe-NH2; AF1), an FMRFamide-related peptide (FaRP) originally isolated from Ascaris suum, were characterized in an A. suum muscle tension assay. AF1 had biphasic effects on this preparation, inducing a brief relaxation followed by excitation and spastic paralysis. Activity of AF1 in this assay was eliminated by N-terminal deletions and by deamidation of the carboxy-terminus. The potency of AF1 was greatly reduced by alanine substitution for any residue. Peptides that retained activity did not show the biphasic response observed with AF1, suggesting that the inhibitory and excitatory phases seen with AF1 may be due to activation of distinct receptors. The basis for the marked differences in potency observed between AF1 and the structurally related nematode FaRP, AF2 (KHEYLRFamide) was also tested. AF2 is approximately 1000-fold more potent than AF1 in this assay, but has physiological effects that are otherwise indistinguishable. KNEYIRFamide and KNEFLRFamide induced characteristic AF1/AF2 responses, but were much less potent than the native peptides. In contrast, KHEYIRFamide resembled AF1 in potency and pattern of responses. These data suggest that AF1 and AF2 act at distinct receptors, and hypothesis supported by the observation that KNEFIAFamide antagonized the effects of AF1 but not of AF2.

Structure-activity studies of RFamide analogues on central neurones of Helix aspersa

The effects of FMRFamide were compared with those of FMRFamide analogues, FLRFamide, LFRFamide, FFRFamide, LLRFamide, D-FMRFamide, F-D-MRFamide and FM-D-RFamide, and the fragments, MRFamide and LRFamide, on identified central neurones, F1, F2, F5 and E16, of the snail Helix aspersa, using intracellular recording and two electrode voltage clamp techniques. All FMRFamide analogues showed an inhibitory effect on F1 neurones with an order of potency: FLRFamide > FMRFamide > FFRFamide > LFRFamide >> LLRFamide. FMRFamide and FLRFamide exhibited a biphasic response on F2 neurones. At lower concentrations (< 10 microM), both peptides usually only excited while at higher concentrations (> 30 microM), exhibited an excitation followed by an inhibition. FFRFamide only excited F2 while LFRFamide and LLRFamide only inhibited F2. LRFamide and MRFamide (100 microM) were inactive on both F1 and F2. FLRFamide, LFRFamide, LLRFamide, FFRFamide and D-FMRFamide showed cross-interaction on the outward current induced by FMRFamide in F5. All peptides induced an outward current and also reduced the FMRFamide-induced current reversibly. In contrast, MRFamide, LRFamide and F-D-MRFamide failed to have direct effects on these neurones nor interact with the FMRFamide-induced current. We conclude that on F2 neurones Phe is essential for the activation of the RFamide receptor mediating the excitation and Met or Leu are important to activate the RFamide receptors mediating the inhibition. Removal of the N-terminal Phe, to give LRFamide and MRFamide render the peptides inactive. Therefore a tetrapeptide sequence is essential for the biological activity of FMRFamide analogues on these Helix neurones. FLRFamide, LFRFamide, LLRFamide, FFRFamide and D-FMRFamide exhibit a cross-interaction with FMRFamide. It is possible that these peptides also act on the same class of RFamide receptors as agonists to cause cross desensitization.

Inhibitory action of SKPYMRFamide on acetylcholine receptors of Helix aspersa neurons: role of second messengers

1. SKPYMRFamide, a novel FMRFamide-like endogenous peptide reversibly decreases excitatory responses (depolarization and inward current) evoked by local ionophoretic application of acetylcholine (ACh) onto the soma of identified neurons F1, F2, F4 and F5/6 of the land snail, Helix aspersa. 2. Threshold concentrations of SKPYMRFamide for an inhibitory action on ACh-induced responses are 0.5-1 mumoll-1. This modulatory action of peptide is dose- and time-dependent. 3. It is concluded that SKPYMRFamide inhibits ACh receptors through activation of specific binding sites on the plasma membrane. 4. The possible role of different second messengers in the modulatory influence of SKPYMRFamide on ACh receptors was tested using 13 modulators of different second messenger systems. 5. The results indicate that SKPYMRFamide may inhibit ACh receptors through activation of one or more of the following systems: phospholipases C, A2, NO-synthase, soluble guanylate cyclase and lipoxygenases which elevate basal intracellulal levels of NO, cGMP, arachidonic acid, acyclic eicosanoids, inositol-1,4,5-trisphosphate (I(1,4,5)P3), I(1,4,5)P3-dependent Ca(2+)-mobilization followed by activation of calmodulin and Ca2+/calmodulin-dependent protein kinase II. Protein kinases A, C and cyclic eicosanoids do not appear to participate in modulatory action of SKPYMRFamide.

Immunocytochemical mapping of FMRFamide-like peptides in the argasid tick Ornithodoros parkeri and the ixodid tick Dermacentor variabilis

FMRFamide-like immunoreactivity was studied in the argasid tick Ornithodoros parkeri and the ixodid tick Dermacentor variabilis using immunocytochemistry based on the peroxidase-antiperoxidase method. FMRFamide-like immunoreactive cells are widely distributed in various regions of the tick synganglion including protocerebral, cheliceral, stomodeal, palpal, pedal I-IV, and opisthosomal regions in both species. However, there is one layer of immunoreactive cells located on the dorsal surface of the postoesophageal part of the synganglion that is found only in D. variabilis. Besides the immunoreactivity within the cell body and its axons, the neuropile and the neural lamella (the extracellular sheath of the synganglion) are rich in immunoreactive materials. Some coxal muscles are innervated by the FMRFamide-like immunoreactive processes of the nerve from the pedal ganglion.

A new biological activity for the neuropeptide FMRFamide: experimental evidence for a secretagogue effect on amylase secretion in the scallop Pecten maximus

FMRFamide immunoreactivity in the digestive tract of the bivalve mollusc Pecten maximus was investigated by immunocytochemistry. Positive FMRFamide-like immunoreactivity was detected in nerve fibres in close contact with exocrine alpha amylase secreting cells. Physiological studies on enzymatically dissociated cells of the stomach-digestive gland complex demonstrated the involvement of FMRFamide and analogues in the control of alpha amylase release from the cells. The FMRFamide-induced secretion was shown to be time- and dose-dependent. In contrast to most naturally occurring vertebrate secretagogues which are hormones, FMRFamide appears to work in our in vitro system as a paracrine factor.

The neuropeptide Phe-Met-Arg-Phe-NH2 (FMRFamide) directly gates two ion channels in an identified Helix neurone

FMRFamide (i.e. Phe-Met-Arg-Phe-NH2) application to the C2 neurone of Helix caused a depolarizing response which consisted of a large, rapidly developing, and rapidly desensitizing inward current, underlain by a smaller, slower inward current which did not desensitize. Both currents were carried through sodium-selective channels which were insensitive to D-tubocurarine, and the to the fast sodium channel blockers tetrodotoxin (TTX) and lignocaine. Only the faster, desensitizing current could be blocked by amiloride. FMRFamide also activated two types of unitary inward currents with slightly differing amplitudes in outside-out patches taken from the C2 neurone, both through sodium-selective ion channels. Only the smaller unitary currents readily desensitized and were susceptible to block by amiloride, and they also activated more rapidly. Unitary currents of both types were recorded in outside-out patches in the absence of freely diffusible intracellular mediators, and were also activated when guanosine 5'-O-(2-thiodiphosphate) (GDP [beta-S]) was included in the recording pipette solution. This supports a tight receptor/channel coupling for both responses, with no involvement of GTP-binding proteins. Further, the very fast rate of activation of the smaller channels, which generally carry the major part of the FMRFamide-induced current, strongly indicates that these channels are ligand gated.

Actions of Fusinus FMRFamide-related peptides on the identified central neurones of the snail, Helix aspersa

The actions of Fusinus FMRFamide-related peptides, that is FMRFamide, FLRFamide, GSLFRFamide, SSLFRFamide, the analogue, GSFFRFamide, and the fragments, LFRFamide and RFamide, were examined on the F1, F2 and F5 neurones of Helix aspersa. All Fusinus peptides exhibit an inhibitory effect on F1 and F5 neurone. On F2 neurone, FMRFamide and FLRFamide exhibit an excitatory effect but GSLFRFamide and SSLFRFamide exhibit an inhibition. The fragment, LFRFamide, is 10-times less potent than GSLFRFamide. GSFFRFamide and RFamide are inactive on F1, F2 and F5 neurone. This evidence indicates that the fragment, LFRFamide, is crucial for the biological activity of Fusinus hexapeptides. The inhibition induced by Fusinus hexapeptides had a reversal potential around -75/-80 mV. It was potentiated in K(+)-free saline, partially abolished either in 10 mM TEA or in 10 mM Co2+ saline and completely abolished in 500 microM 4-AP saline. This evidence indicates that there are multiple K+ channels which are activated by Fusinus hexapeptides and that the IA is more susceptible than IK and IKCa to these peptides.

Biological activity and receptor binding properties of some C-terminally modified analogues of FMRFamide

The functional role of the C-terminal amide group (-CONH2) of the molluscan regulatory peptide FMRFamide has been examined in two sets of analogues based on FnLKFamide and FnLRFamide (nL = norleucine). In each series the amide group was replaced by -CONHCH3, -CON(CH3)2, -CONHNH2, -COOCH3, -CH2OH, and -COOH. The analogues were tested for their ability to bind to receptors in membranes from Helix aspersa circumoesophageal ganglia and for their biological effects on the isolated Helix heart. The results indicate i) that agonist activity, but not binding to the receptor, requires the presence of the amide carbonyl group; ii) the hydrogen atoms of the amide group are not essential either for binding or for agonist activity (the mono- and dimethylamides were more effective than the parent compounds on both counts); iii) the is more effective an agonist than is the amide in stimulating Helix heart.

Biological activity and receptor binding properties of some analogues of pQDPFLRFamide

To investigate the role of the N-terminal region of the heptapeptide FMRFamide-like peptide, pQDPFLRFamide, three analogues were synthesized. The analogues [pQNPFLRFamide, pQDAibFLRFamide (Aib = aminoisobutyric acid) and pQDGFLRFamide] contained modifications at amino acid residues 2 and 3, which we believed might be critical for maintaining the bioactive conformation of the heptapeptide. The analogues were tested for their ability to bind to receptors in membranes from Helix aspersa circumoesophageal ganglia and for their biological effects on the isolated Helix heart, the Helix tentacle retractor muscle, and extensor-tibiae neuromuscular preparation of the locust. Schistocerca gregaria. The substitution of Asn for Asp2 and that of Aib for Pro3 were conservative with respect to retention of heptapeptide-like biological activity, whereas the substitution of Gly for Pro3 significantly improved the binding affinity of the peptide for the FMRFamide receptors and conferred on the peptide some characteristic FMRFamide-like biological activity. Thus, pQDPFLRFamide bioactivity may depend on a bent conformation in solution.

The actions of RFamide neuroactive peptides on the isolated heart of the giant African snail, Achatina fulica

1. The effects of a range of RFamide peptides were examined on the frequency, amplitude and tone of the isolated heart of Achatina fulica. 2. FMRFamide, FLRFamide and SDPNFLRFamide were potent excitants while LPLRFamide, KHEYLRFamide and GSFFRFamide were weak excitants. 3. DNFLRFamide and SSLFRFamide were potent inhibitory peptides while LFRFamide, GSLFRFamide and KNEFIRFamide were weak inhibitory peptides. 4. MRFamide, LRFamide and RFamide were inactive. 5. It is concluded that a tetrapeptide sequence is the minimal requirement for activity on the Achatina heart. With the exceptions of DNFLRFamide and in most preparations GSFFRFamide, LRFamide peptides are excitatory while FRFamide peptides are inhibitory. 6. Due to its inhibitory effect and high potency, the sequence DNFLRFamide warrants further investigation.

The wide range of actions of the FMRFamide-related peptides and the biological importance of peptidergic messengers

The importance of peptides as intercellular messengers is discussed. The view is put forward that peptides evolved early in evolution as chemical messengers and that they have come to exert a wide range of actions. Using as an example the FMRFamide (Phe-Met-Arg-Phe-NH2) related peptide family of molluscs, the wide range of peptide actions on membrane currents is discussed and considered in relation to co-localization of peptides with low molecular weight (or "classical") intercellular messengers.

Distinct receptors for Leu- and Met-enkephalin on the metacerebral giant cell of Aplysia

1. The effects of D-Ala2-Leu-enkephalin (DALEU), D-Ala2-Met-enkephalin (DAMET), and FMRFamide on the metacerebral cell (MCC) of Aplysia were determined in current- and voltage-clamp experiments. 2. Distinct receptors exist on this neuron for the three substances. 3. DALEU elicited a depolarizing response due to an inward current but not accompanied by a significant change in membrane conductance. 4. In contrast, DAMET elicited a hyperpolarizing response due to an outward current, also not associated with a significant change in membrane conductance. 5. Both the DALEU and the DAMET responses increased with hyperpolarization, decreased with depolarization, but did not reverse at potentials less than -30 mV. Neither response was sensitive to naloxone. 6. FMRFamide induced a voltage-dependent outward current that reversed at about -76 mV. This neuron was responsive to much lower concentrations of FMRFamide than either of the enkephalins, and the response to FMRFamide appears to be a conductance increase to K+. 7. These results suggest that the MCC neuron has distinct receptors for Leu- and Met-enkephalin that activate unusual responses of opposite polarity, as well as more usual inhibitory responses to FMRFamide.

Differential responses of expressed recombinant human gamma-aminobutyric acidA receptors to neurosteroids

Neuroactive steroids, in particular 3 alpha-hydroxypregnanes, are allosteric modulators of the gamma-aminobutyric acidA (GABAA) receptor. Regionally selective expression of receptor subunit subtypes may account for differential responsiveness of tissues to GABAergic inhibition and neurosteroid modulatory effects. The effect of 5 alpha-pregnan-3 alpha-ol-20-one (epiallopregnanolone) on heterotropic cooperativity on the GABAA receptor complex has been studied in three subtypes of expressed recombinant human receptors and in rat brain and spinal cord. Steroid potentiation of [3H]flunitrazepam binding was greatest for the alpha 3 beta 1 gamma 2 receptor complex, whereas alpha 1 beta 1 gamma 2 and alpha 2 beta 1 gamma 2 complexes showed less than 100% enhancement in binding. Previous studies suggest that the spinal cord is devoid of alpha 1, whereas cerebellum is rich in alpha 1 subunits. Correspondingly, a differential enhancement of [3H]flunitrazepam binding in spinal cord (51%) versus cerebellum (28%) was also observed. The structure of neuroactive steroids is important in determinikng the extent of neuromodulatory activity. The 5 beta-pregnanes,5 beta-pregnan-3 alpha-ol-20-one (epipregnanolone) and 5 beta-pregnan-3 alpha,21-diol-20-one (5 beta-tetrahydrodeoxycorticosterone), were both less potent than their corresponding 5 alpha derivatives. A 3 alpha hydroxyl group is essential for neuromodulatory activity in the expressed receptors, as demonstrated by the observation that 5 alpha-pregnan-3 beta-ol-20-one (allopregnanolone) and 4-pregnen-3, 20-dione (progesterone) were both inactive.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure, bioactivity, and cellular localization of myomodulin B: a novel Aplysia peptide

Important insights into mechanisms by which neuromuscular activity can be modulated have been gained by the study of experimentally advantageous preparations such as the ARC neuromuscular system of Aplysia. Previous studies have indicated that one source of modulatory input to the ARC muscle is its own two motor neurons, B15 and B16. Both of these neurons synthesize multiple peptide cotransmitters in addition to their primary neurotransmitter acetylcholine (ACh). Peptides present in the ARC motor neurons include SCPA, SCPB, buccalin A and B, and myomodulin A. We have now purified a novel neuropeptide, myomodulin B, which is structurally similar to myomodulin A. Myomodulin B is present in two identified Aplysia neurons that contain myomodulin A; the ARC motor neuron B16 and the abdominal neuron L10. Ratios of myomodulin A to myomodulin B are approximately 6:1 in both cells. Like myomodulin A, myomodulin B potentiates ARC neuromuscular activity; it acts postsynaptically, and increases the size and relaxation rate of muscle contractions elicited either by motor neuron stimulation or by direct application of ACh to the ARC. When myomodulin A is applied to the ARC in high doses (e.g., at about 10(-7) M), it decreases the size of motor neuron-elicited muscle contractions. This inhibitory effect is never seen with myomodulin B. Thus, despite the structural similarity between the two myomodulins, there exists what may be an important difference in their bioactivity.

Neuropeptides in the nematode Ascaris suum

Most of the successful anti-nematode drugs currently available affect the nematode locomotory system. Their success is due to their interactions with molecules associated with the main neuro-transmitters of the motor nervous system, acetylcholine and GABA. These drugs tend to have a relatively broad spectrum of action, affecting a wide variety of nematodes, presumably because nematode motor nervous systems are conservative in their use of these transmitters.

Aminopeptidase activities present in tissues of Helix aspersa

1. Tissues of Helix aspersa have been examined for the presence of aminopeptidase activities. 2. Enzyme activities were detected using synthetic peptide substrates containing the fluorescent leaving group 7-amino-4-methyl coumarin. The methods used included continuous fluorimetric assay and activity staining of enzymes in non-denaturing polyacrylamide gels. 3. Several types of peptidase activity were detected, including three distinct aminopeptidases which differ in molecular size and substrate preference.

Histamine and FLRFamide regulate acetylcholine release at an identified synapse in Aplysia in opposite ways

1. The effects of histamine and FLRFamide (Phe-Leu-Arg-Phe-NH2) on acetylcholine (ACh) release were studied in the buccal ganglion of Aplysia californica on an identified synapse (buccal ganglion inhibitory synapse, BGIS) involved in a small neuronal circuit controlling the feeding behaviour. The inhibitory postsynaptic current (IPSC) evoked by a presynaptic spike in the voltage-clamped postsynaptic neurone was decreased by histamine and increased by FLRFamide. 2. Histamine and FLRFamide modified the amplitude of the presynaptic spike. To test if these drugs acted directly on presynaptic calcium influx, we evoked transmitter release by 3 s depolarizations of the presynaptic neurone (to +10 mV) under voltage clamp to avoid modifications of presynaptic membrane polarization induced by changes in presynaptic voltage-dependent K+ and/or Na+ conductances. 3. Statistical analysis of this evoked long-duration (3 s) induced postsynaptic current (LDIPSC) allowed us to calculate the amplitude and the decay time of the miniature postsynaptic current and consequently the number of quanta released by the presynaptic terminal. 4. The amplitude of the LDIPSC decreased during the 3 s presynaptic depolarization. This was not due to a lack of available transmitter, since LDIPSC amplitude could be maintained constant by a 'clamp of the release of ACh' which adequately depolarized the presynaptic neurone, but rather to changes in the calcium influx into the presynaptic neurone. 5. FLRFamide increased more the initial portions of the LDIPSC than the final portions. This effect of FLRFamide was only reduced and delayed by atropine or curare, antagonists of muscarinic-like and nicotinic-like autoreceptors previously demonstrated to be present at the same terminal. Activation of the nicotinic-like receptors, which also increased transmitter release, induced a modification of the shape of the LDIPSC which was completely different from that due to FLRFamide. 6. Histamine decreased the amplitude of the LDIPSC. This effect was more pronounced at the beginning of the response. The effects of histamine were insensitive to curare and atropine, but were completely blocked by cimetidine, a specific histamine receptor antagonist. 7. The modifications of the shape and of the amplitude of the LDIPSC by FLRFamide and histamine suggested that these molecules alter presynaptic influx of calcium. This was confirmed by the analysis of calcium current recorded from the presynaptic neurone: the calcium inward current in the presynaptic neurone was increased by FLRFamide and reduced by histamine, whereas the activation of autoreceptors had no measurable effect on calcium current.(ABSTRACT TRUNCATED AT 400 WORDS)

Activation of protein kinase C by presynaptic FLRFamide receptors facilitates transmitter release at an aplysia cholinergic synapse

Modulation of evoked quantal transmitter release by protein kinase C (PKC) was investigated at an identified cholinergic neuro-neuronal synapse of the Aplysia buccal ganglion. Evoked acetylcholine release was increased by a diacylglycerol analog that activates PKC and was decreased by H-7, a blocker of PKC. FLRFamide facilitated evoked quantal release by increasing presynaptic Ca2+ influx. The inhibition of PKC by H-7 prevented both the increase of presynaptic Ca2+ influx and the facilitation of evoked acetylcholine release induced by the activation of presynaptic FLRFamide receptors. These results provide evidence that the activation of PKC could be a step in the intracellular pathway by which FLRFamide receptors increase evoked quantal acetylcholine release.

Electrophysiological effects of FLFQPQRF amide, an endogenous brain morphine modulating peptide, on cultured mouse spinal-cord neurons

Intracellular recordings were made from dissociated fetal mouse spinal cord neurones in primary culture. Micropressure application of FLFQPQRFamide (10(-5) M in the delivery pipette), an endogenous mammalian brain morphine modulating peptide, onto the surface of spinal cord neurones induced, in a dose dependent manner, a transitory hyperpolarization followed by a long lasting depolarization of the membrane potential (n = 37). In contrast, no response was observed when the peptide was applied on dorsal root ganglia neurones (n = 30). The depolarizing phase of this response was underlied by an increase of the input resistance. Extrapolated reversal potential for the depolarizing phase was close to -80 mV while it was close to -40 mV for the hyperpolarizing phase. Increasing extracellular K+ concentration raised the reversal potential value of depolarizing phases to more positive values. The amplitude of the depolarizing phase was reduced by application of tetraethylammonium (50 mM) while it was enhanced by application of 4-aminopyridine (3 mM). CaCl2 application (3 mM) reversibly blocked the hyperpolarization and decreased the subsequent depolarization. In presence of Ba2+ the extrapollated reversal potential of the hyperpolarizing phase was dramatically shifted to a more positive value. Finally FLFQPQRFamide induced response can be partially mimicked by FMRFamide application. Our observations indicate that FLFQPQRFamide can have multiple effects on membrane conductance of mammalian spinal cord neurones by acting on a single class of receptor. These effects of FLFQPQRFamide were found to be mainly excitatory.

Further characterization of Helix FMRFamide receptors: kinetics, tissue distribution, and interactions with the endogenous heptapeptides

The biphasic binding of 125I-daYFnLRFamide to crude brain membranes of Helix aspersa is due to two discernible sites (high and low affinity) rather than different agonist-induced states. The tissues in the snail that show the greatest specific 125I-daYFnLRFamide binding are the brain, reproductive system, and digestive system. The heart shows moderate binding levels, whereas low values are obtained in the oviduct and retractor muscles. The N-terminal SAR of the Helix heptapeptides (X-DPFLRFamide) indicates that, although the substitution of Leu for Met accounts for some, the dipeptide X-Asp produces most of the loss in potency at FMRFamide receptors in Helix brain.

AF1, a sequenced bioactive neuropeptide isolated from the nematode Ascaris suum

An FMRFamide-like neuropeptide, named AF1, was isolated from head extracts of the nematode Ascaris suum using five steps of HPLC. AF1 is a heptapeptide with the amino acid sequence Lys-Asn-Glu-Phe-Ile-Arg-Phe-NH2. Synthetic AF1 (10(-9) to 10(-7) M) rapidly and reversibly abolished slow membrane potential oscillations of identified ventral and dorsal inhibitory motoneurons and selectively reduced their input resistances. Synaptic transmission was not blocked. In intact Ascaris, AF1 inhibited locomotory movements. This study indicates a potential physiological role for an endogenous neuropeptide in nematodes.

Transient, steady-state and rebreathing responses to carbon dioxide in man, at rest and during light exercise

1. The transient ventilatory response to CO2, measured using short pulses at constant inflow, was compared with the steady-state response at rest and during exercise at 50 W, and with the rebreathing response at rest, in nine healthy subjects. At rest CO2 was given at flow rates of 0.2 and 0.4 l min-1 and during exercise, to compensate for the smaller inhaled CO2 fraction as ventilation increased, at flow rates of 0.4 and 0.8 l min-1. 2. We calculated two indexes of gain for the transient response: the ratio of the peaks of the ventilation and PCO2 pulses, and the ratio of their integrals. 3. The steady-state response was greater than the transient response at rest and during exercise, but there was no correlation between the two. The rebreathing response was greater than both. Both the transient and the steady-state responses were greater during exercise than at rest. 4. To assess alinearity, the steady-state responses to the two CO2 flow rates were compared. At rest, there was no significant difference. During exercise, the response was greater to 0.4 than 0.8 l min-1, indicating alinearity concave downwards. 5. We conclude that the transient response as we calculate it is not representative of steady-state gain, and that the CO2 response in light exercise is steeper, and concave downwards in shape. The rebreathing technique overestimates CO2 sensitivity near the control point.